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跟新jemalloc到5.2.1

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This commit is contained in:
LingZhaoHui 2020-09-12 22:49:33 +08:00
parent 86bcece45e
commit c3f02f6552
321 changed files with 80481 additions and 0 deletions
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42
deps/jemalloc/.appveyor.yml vendored Normal file
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version: '{build}'
environment:
matrix:
- MSYSTEM: MINGW64
CPU: x86_64
MSVC: amd64
CONFIG_FLAGS: --enable-debug
- MSYSTEM: MINGW64
CPU: x86_64
CONFIG_FLAGS: --enable-debug
- MSYSTEM: MINGW32
CPU: i686
MSVC: x86
CONFIG_FLAGS: --enable-debug
- MSYSTEM: MINGW32
CPU: i686
CONFIG_FLAGS: --enable-debug
- MSYSTEM: MINGW64
CPU: x86_64
MSVC: amd64
- MSYSTEM: MINGW64
CPU: x86_64
- MSYSTEM: MINGW32
CPU: i686
MSVC: x86
- MSYSTEM: MINGW32
CPU: i686
install:
- set PATH=c:\msys64\%MSYSTEM%\bin;c:\msys64\usr\bin;%PATH%
- if defined MSVC call "c:\Program Files (x86)\Microsoft Visual Studio 14.0\VC\vcvarsall.bat" %MSVC%
- if defined MSVC pacman --noconfirm -Rsc mingw-w64-%CPU%-gcc gcc
- pacman --noconfirm -Suy mingw-w64-%CPU%-make
build_script:
- bash -c "autoconf"
- bash -c "./configure $CONFIG_FLAGS"
- mingw32-make
- file lib/jemalloc.dll
- mingw32-make tests
- mingw32-make -k check

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begin-language: "Autoconf-without-aclocal-m4"
args: --no-cache
end-language: "Autoconf-without-aclocal-m4"

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env:
CIRRUS_CLONE_DEPTH: 1
ARCH: amd64
task:
freebsd_instance:
matrix:
image: freebsd-12-0-release-amd64
image: freebsd-11-2-release-amd64
install_script:
- sed -i.bak -e 's,pkg+http://pkg.FreeBSD.org/\${ABI}/quarterly,pkg+http://pkg.FreeBSD.org/\${ABI}/latest,' /etc/pkg/FreeBSD.conf
- pkg upgrade -y
- pkg install -y autoconf gmake
script:
- autoconf
#- ./configure ${COMPILER_FLAGS:+ CC="$CC $COMPILER_FLAGS" CXX="$CXX $COMPILER_FLAGS" } $CONFIGURE_FLAGS
- ./configure
- export JFLAG=`sysctl -n kern.smp.cpus`
- gmake -j${JFLAG}
- gmake -j${JFLAG} tests
- gmake check

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* text=auto eol=lf

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deps/jemalloc/.gitignore vendored Normal file
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/bin/jemalloc-config
/bin/jemalloc.sh
/bin/jeprof
/config.stamp
/config.log
/config.status
/configure
/doc/html.xsl
/doc/manpages.xsl
/doc/jemalloc.xml
/doc/jemalloc.html
/doc/jemalloc.3
/jemalloc.pc
/lib/
/Makefile
/include/jemalloc/internal/jemalloc_preamble.h
/include/jemalloc/internal/jemalloc_internal_defs.h
/include/jemalloc/internal/private_namespace.gen.h
/include/jemalloc/internal/private_namespace.h
/include/jemalloc/internal/private_namespace_jet.gen.h
/include/jemalloc/internal/private_namespace_jet.h
/include/jemalloc/internal/private_symbols.awk
/include/jemalloc/internal/private_symbols_jet.awk
/include/jemalloc/internal/public_namespace.h
/include/jemalloc/internal/public_symbols.txt
/include/jemalloc/internal/public_unnamespace.h
/include/jemalloc/jemalloc.h
/include/jemalloc/jemalloc_defs.h
/include/jemalloc/jemalloc_macros.h
/include/jemalloc/jemalloc_mangle.h
/include/jemalloc/jemalloc_mangle_jet.h
/include/jemalloc/jemalloc_protos.h
/include/jemalloc/jemalloc_protos_jet.h
/include/jemalloc/jemalloc_rename.h
/include/jemalloc/jemalloc_typedefs.h
/src/*.[od]
/src/*.sym
/run_tests.out/
/test/test.sh
test/include/test/jemalloc_test.h
test/include/test/jemalloc_test_defs.h
/test/integration/[A-Za-z]*
!/test/integration/[A-Za-z]*.*
/test/integration/*.[od]
/test/integration/*.out
/test/integration/cpp/[A-Za-z]*
!/test/integration/cpp/[A-Za-z]*.*
/test/integration/cpp/*.[od]
/test/integration/cpp/*.out
/test/src/*.[od]
/test/stress/[A-Za-z]*
!/test/stress/[A-Za-z]*.*
/test/stress/*.[od]
/test/stress/*.out
/test/unit/[A-Za-z]*
!/test/unit/[A-Za-z]*.*
/test/unit/*.[od]
/test/unit/*.out
/VERSION
*.pdb
*.sdf
*.opendb
*.VC.db
*.opensdf
*.cachefile
*.suo
*.user
*.sln.docstates
*.tmp
.vs/
/msvc/Win32/
/msvc/x64/
/msvc/projects/*/*/Debug*/
/msvc/projects/*/*/Release*/
/msvc/projects/*/*/Win32/
/msvc/projects/*/*/x64/

195
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language: generic
dist: precise
matrix:
include:
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: osx
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=clang CXX=clang++ COMPILER_FLAGS="" CONFIGURE_FLAGS="" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="-m32" CONFIGURE_FLAGS="" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
addons: &gcc_multilib
apt:
packages:
- gcc-multilib
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-debug" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-prof" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-stats" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-libdl" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-opt-safety-checks" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--with-malloc-conf=tcache:false" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--with-malloc-conf=dss:primary" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--with-malloc-conf=percpu_arena:percpu" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--with-malloc-conf=background_thread:true" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: osx
env: CC=clang CXX=clang++ COMPILER_FLAGS="" CONFIGURE_FLAGS="" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: osx
env: CC=gcc CXX=g++ COMPILER_FLAGS="-m32" CONFIGURE_FLAGS="" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: osx
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-debug" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: osx
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-stats" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: osx
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-libdl" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: osx
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-opt-safety-checks" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: osx
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--with-malloc-conf=tcache:false" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=clang CXX=clang++ COMPILER_FLAGS="-m32" CONFIGURE_FLAGS="" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
addons: *gcc_multilib
- os: linux
env: CC=clang CXX=clang++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-debug" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=clang CXX=clang++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-prof" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=clang CXX=clang++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-stats" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=clang CXX=clang++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-libdl" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=clang CXX=clang++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-opt-safety-checks" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=clang CXX=clang++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--with-malloc-conf=tcache:false" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=clang CXX=clang++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--with-malloc-conf=dss:primary" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=clang CXX=clang++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--with-malloc-conf=percpu_arena:percpu" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=clang CXX=clang++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--with-malloc-conf=background_thread:true" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="-m32" CONFIGURE_FLAGS="--enable-debug" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
addons: *gcc_multilib
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="-m32" CONFIGURE_FLAGS="--enable-prof" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
addons: *gcc_multilib
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="-m32" CONFIGURE_FLAGS="--disable-stats" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
addons: *gcc_multilib
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="-m32" CONFIGURE_FLAGS="--disable-libdl" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
addons: *gcc_multilib
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="-m32" CONFIGURE_FLAGS="--enable-opt-safety-checks" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
addons: *gcc_multilib
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="-m32" CONFIGURE_FLAGS="--with-malloc-conf=tcache:false" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
addons: *gcc_multilib
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="-m32" CONFIGURE_FLAGS="--with-malloc-conf=dss:primary" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
addons: *gcc_multilib
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="-m32" CONFIGURE_FLAGS="--with-malloc-conf=percpu_arena:percpu" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
addons: *gcc_multilib
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="-m32" CONFIGURE_FLAGS="--with-malloc-conf=background_thread:true" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
addons: *gcc_multilib
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-debug --enable-prof" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-debug --disable-stats" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-debug --disable-libdl" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-debug --enable-opt-safety-checks" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-debug --with-malloc-conf=tcache:false" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-debug --with-malloc-conf=dss:primary" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-debug --with-malloc-conf=percpu_arena:percpu" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-debug --with-malloc-conf=background_thread:true" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-prof --disable-stats" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-prof --disable-libdl" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-prof --enable-opt-safety-checks" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-prof --with-malloc-conf=tcache:false" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-prof --with-malloc-conf=dss:primary" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-prof --with-malloc-conf=percpu_arena:percpu" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-prof --with-malloc-conf=background_thread:true" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-stats --disable-libdl" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-stats --enable-opt-safety-checks" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-stats --with-malloc-conf=tcache:false" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-stats --with-malloc-conf=dss:primary" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-stats --with-malloc-conf=percpu_arena:percpu" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-stats --with-malloc-conf=background_thread:true" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-libdl --enable-opt-safety-checks" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-libdl --with-malloc-conf=tcache:false" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-libdl --with-malloc-conf=dss:primary" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-libdl --with-malloc-conf=percpu_arena:percpu" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--disable-libdl --with-malloc-conf=background_thread:true" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-opt-safety-checks --with-malloc-conf=tcache:false" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-opt-safety-checks --with-malloc-conf=dss:primary" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-opt-safety-checks --with-malloc-conf=percpu_arena:percpu" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-opt-safety-checks --with-malloc-conf=background_thread:true" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--with-malloc-conf=tcache:false,dss:primary" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--with-malloc-conf=tcache:false,percpu_arena:percpu" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--with-malloc-conf=tcache:false,background_thread:true" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--with-malloc-conf=dss:primary,percpu_arena:percpu" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--with-malloc-conf=dss:primary,background_thread:true" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--with-malloc-conf=percpu_arena:percpu,background_thread:true" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
# Development build
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-debug --disable-cache-oblivious --enable-stats --enable-log --enable-prof" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
# --enable-expermental-smallocx:
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="--enable-debug --enable-experimental-smallocx --enable-stats --enable-prof" EXTRA_CFLAGS="-Werror -Wno-array-bounds"
# Valgrind
- os: linux
env: CC=gcc CXX=g++ COMPILER_FLAGS="" CONFIGURE_FLAGS="" EXTRA_CFLAGS="-Werror -Wno-array-bounds" JEMALLOC_TEST_PREFIX="valgrind"
addons:
apt:
packages:
- valgrind
before_script:
- autoconf
- scripts/gen_travis.py > travis_script && diff .travis.yml travis_script
- ./configure ${COMPILER_FLAGS:+ CC="$CC $COMPILER_FLAGS" CXX="$CXX $COMPILER_FLAGS" } $CONFIGURE_FLAGS
- make -j3
- make -j3 tests
script:
- make check

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Unless otherwise specified, files in the jemalloc source distribution are
subject to the following license:
--------------------------------------------------------------------------------
Copyright (C) 2002-present Jason Evans <jasone@canonware.com>.
All rights reserved.
Copyright (C) 2007-2012 Mozilla Foundation. All rights reserved.
Copyright (C) 2009-present Facebook, Inc. All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are met:
1. Redistributions of source code must retain the above copyright notice(s),
this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright notice(s),
this list of conditions and the following disclaimer in the documentation
and/or other materials provided with the distribution.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDER(S) ``AS IS'' AND ANY EXPRESS
OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO
EVENT SHALL THE COPYRIGHT HOLDER(S) BE LIABLE FOR ANY DIRECT, INDIRECT,
INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
--------------------------------------------------------------------------------

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Building and installing a packaged release of jemalloc can be as simple as
typing the following while in the root directory of the source tree:
./configure
make
make install
If building from unpackaged developer sources, the simplest command sequence
that might work is:
./autogen.sh
make dist
make
make install
Note that documentation is not built by the default target because doing so
would create a dependency on xsltproc in packaged releases, hence the
requirement to either run 'make dist' or avoid installing docs via the various
install_* targets documented below.
## Advanced configuration
The 'configure' script supports numerous options that allow control of which
functionality is enabled, where jemalloc is installed, etc. Optionally, pass
any of the following arguments (not a definitive list) to 'configure':
* `--help`
Print a definitive list of options.
* `--prefix=<install-root-dir>`
Set the base directory in which to install. For example:
./configure --prefix=/usr/local
will cause files to be installed into /usr/local/include, /usr/local/lib,
and /usr/local/man.
* `--with-version=(<major>.<minor>.<bugfix>-<nrev>-g<gid>|VERSION)`
The VERSION file is mandatory for successful configuration, and the
following steps are taken to assure its presence:
1) If --with-version=<major>.<minor>.<bugfix>-<nrev>-g<gid> is specified,
generate VERSION using the specified value.
2) If --with-version is not specified in either form and the source
directory is inside a git repository, try to generate VERSION via 'git
describe' invocations that pattern-match release tags.
3) If VERSION is missing, generate it with a bogus version:
0.0.0-0-g0000000000000000000000000000000000000000
Note that --with-version=VERSION bypasses (1) and (2), which simplifies
VERSION configuration when embedding a jemalloc release into another
project's git repository.
* `--with-rpath=<colon-separated-rpath>`
Embed one or more library paths, so that libjemalloc can find the libraries
it is linked to. This works only on ELF-based systems.
* `--with-mangling=<map>`
Mangle public symbols specified in <map> which is a comma-separated list of
name:mangled pairs.
For example, to use ld's --wrap option as an alternative method for
overriding libc's malloc implementation, specify something like:
--with-mangling=malloc:__wrap_malloc,free:__wrap_free[...]
Note that mangling happens prior to application of the prefix specified by
--with-jemalloc-prefix, and mangled symbols are then ignored when applying
the prefix.
* `--with-jemalloc-prefix=<prefix>`
Prefix all public APIs with <prefix>. For example, if <prefix> is
"prefix_", API changes like the following occur:
malloc() --> prefix_malloc()
malloc_conf --> prefix_malloc_conf
/etc/malloc.conf --> /etc/prefix_malloc.conf
MALLOC_CONF --> PREFIX_MALLOC_CONF
This makes it possible to use jemalloc at the same time as the system
allocator, or even to use multiple copies of jemalloc simultaneously.
By default, the prefix is "", except on OS X, where it is "je_". On OS X,
jemalloc overlays the default malloc zone, but makes no attempt to actually
replace the "malloc", "calloc", etc. symbols.
* `--without-export`
Don't export public APIs. This can be useful when building jemalloc as a
static library, or to avoid exporting public APIs when using the zone
allocator on OSX.
* `--with-private-namespace=<prefix>`
Prefix all library-private APIs with <prefix>je_. For shared libraries,
symbol visibility mechanisms prevent these symbols from being exported, but
for static libraries, naming collisions are a real possibility. By
default, <prefix> is empty, which results in a symbol prefix of je_ .
* `--with-install-suffix=<suffix>`
Append <suffix> to the base name of all installed files, such that multiple
versions of jemalloc can coexist in the same installation directory. For
example, libjemalloc.so.0 becomes libjemalloc<suffix>.so.0.
* `--with-malloc-conf=<malloc_conf>`
Embed `<malloc_conf>` as a run-time options string that is processed prior to
the malloc_conf global variable, the /etc/malloc.conf symlink, and the
MALLOC_CONF environment variable. For example, to change the default decay
time to 30 seconds:
--with-malloc-conf=decay_ms:30000
* `--enable-debug`
Enable assertions and validation code. This incurs a substantial
performance hit, but is very useful during application development.
* `--disable-stats`
Disable statistics gathering functionality. See the "opt.stats_print"
option documentation for usage details.
* `--enable-prof`
Enable heap profiling and leak detection functionality. See the "opt.prof"
option documentation for usage details. When enabled, there are several
approaches to backtracing, and the configure script chooses the first one
in the following list that appears to function correctly:
+ libunwind (requires --enable-prof-libunwind)
+ libgcc (unless --disable-prof-libgcc)
+ gcc intrinsics (unless --disable-prof-gcc)
* `--enable-prof-libunwind`
Use the libunwind library (http://www.nongnu.org/libunwind/) for stack
backtracing.
* `--disable-prof-libgcc`
Disable the use of libgcc's backtracing functionality.
* `--disable-prof-gcc`
Disable the use of gcc intrinsics for backtracing.
* `--with-static-libunwind=<libunwind.a>`
Statically link against the specified libunwind.a rather than dynamically
linking with -lunwind.
* `--disable-fill`
Disable support for junk/zero filling of memory. See the "opt.junk" and
"opt.zero" option documentation for usage details.
* `--disable-zone-allocator`
Disable zone allocator for Darwin. This means jemalloc won't be hooked as
the default allocator on OSX/iOS.
* `--enable-utrace`
Enable utrace(2)-based allocation tracing. This feature is not broadly
portable (FreeBSD has it, but Linux and OS X do not).
* `--enable-xmalloc`
Enable support for optional immediate termination due to out-of-memory
errors, as is commonly implemented by "xmalloc" wrapper function for malloc.
See the "opt.xmalloc" option documentation for usage details.
* `--enable-lazy-lock`
Enable code that wraps pthread_create() to detect when an application
switches from single-threaded to multi-threaded mode, so that it can avoid
mutex locking/unlocking operations while in single-threaded mode. In
practice, this feature usually has little impact on performance unless
thread-specific caching is disabled.
* `--disable-cache-oblivious`
Disable cache-oblivious large allocation alignment for large allocation
requests with no alignment constraints. If this feature is disabled, all
large allocations are page-aligned as an implementation artifact, which can
severely harm CPU cache utilization. However, the cache-oblivious layout
comes at the cost of one extra page per large allocation, which in the
most extreme case increases physical memory usage for the 16 KiB size class
to 20 KiB.
* `--disable-syscall`
Disable use of syscall(2) rather than {open,read,write,close}(2). This is
intended as a workaround for systems that place security limitations on
syscall(2).
* `--disable-cxx`
Disable C++ integration. This will cause new and delete operator
implementations to be omitted.
* `--with-xslroot=<path>`
Specify where to find DocBook XSL stylesheets when building the
documentation.
* `--with-lg-page=<lg-page>`
Specify the base 2 log of the allocator page size, which must in turn be at
least as large as the system page size. By default the configure script
determines the host's page size and sets the allocator page size equal to
the system page size, so this option need not be specified unless the
system page size may change between configuration and execution, e.g. when
cross compiling.
* `--with-lg-hugepage=<lg-hugepage>`
Specify the base 2 log of the system huge page size. This option is useful
when cross compiling, or when overriding the default for systems that do
not explicitly support huge pages.
* `--with-lg-quantum=<lg-quantum>`
Specify the base 2 log of the minimum allocation alignment. jemalloc needs
to know the minimum alignment that meets the following C standard
requirement (quoted from the April 12, 2011 draft of the C11 standard):
> The pointer returned if the allocation succeeds is suitably aligned so
that it may be assigned to a pointer to any type of object with a
fundamental alignment requirement and then used to access such an object
or an array of such objects in the space allocated [...]
This setting is architecture-specific, and although jemalloc includes known
safe values for the most commonly used modern architectures, there is a
wrinkle related to GNU libc (glibc) that may impact your choice of
<lg-quantum>. On most modern architectures, this mandates 16-byte
alignment (<lg-quantum>=4), but the glibc developers chose not to meet this
requirement for performance reasons. An old discussion can be found at
<https://sourceware.org/bugzilla/show_bug.cgi?id=206> . Unlike glibc,
jemalloc does follow the C standard by default (caveat: jemalloc
technically cheats for size classes smaller than the quantum), but the fact
that Linux systems already work around this allocator noncompliance means
that it is generally safe in practice to let jemalloc's minimum alignment
follow glibc's lead. If you specify `--with-lg-quantum=3` during
configuration, jemalloc will provide additional size classes that are not
16-byte-aligned (24, 40, and 56).
* `--with-lg-vaddr=<lg-vaddr>`
Specify the number of significant virtual address bits. By default, the
configure script attempts to detect virtual address size on those platforms
where it knows how, and picks a default otherwise. This option may be
useful when cross-compiling.
* `--disable-initial-exec-tls`
Disable the initial-exec TLS model for jemalloc's internal thread-local
storage (on those platforms that support explicit settings). This can allow
jemalloc to be dynamically loaded after program startup (e.g. using dlopen).
Note that in this case, there will be two malloc implementations operating
in the same process, which will almost certainly result in confusing runtime
crashes if pointers leak from one implementation to the other.
* `--disable-libdl`
Disable the usage of libdl, namely dlsym(3) which is required by the lazy
lock option. This can allow building static binaries.
The following environment variables (not a definitive list) impact configure's
behavior:
* `CFLAGS="?"`
* `CXXFLAGS="?"`
Pass these flags to the C/C++ compiler. Any flags set by the configure
script are prepended, which means explicitly set flags generally take
precedence. Take care when specifying flags such as -Werror, because
configure tests may be affected in undesirable ways.
* `EXTRA_CFLAGS="?"`
* `EXTRA_CXXFLAGS="?"`
Append these flags to CFLAGS/CXXFLAGS, without passing them to the
compiler(s) during configuration. This makes it possible to add flags such
as -Werror, while allowing the configure script to determine what other
flags are appropriate for the specified configuration.
* `CPPFLAGS="?"`
Pass these flags to the C preprocessor. Note that CFLAGS is not passed to
'cpp' when 'configure' is looking for include files, so you must use
CPPFLAGS instead if you need to help 'configure' find header files.
* `LD_LIBRARY_PATH="?"`
'ld' uses this colon-separated list to find libraries.
* `LDFLAGS="?"`
Pass these flags when linking.
* `PATH="?"`
'configure' uses this to find programs.
In some cases it may be necessary to work around configuration results that do
not match reality. For example, Linux 4.5 added support for the MADV_FREE flag
to madvise(2), which can cause problems if building on a host with MADV_FREE
support and deploying to a target without. To work around this, use a cache
file to override the relevant configuration variable defined in configure.ac,
e.g.:
echo "je_cv_madv_free=no" > config.cache && ./configure -C
## Advanced compilation
To build only parts of jemalloc, use the following targets:
build_lib_shared
build_lib_static
build_lib
build_doc_html
build_doc_man
build_doc
To install only parts of jemalloc, use the following targets:
install_bin
install_include
install_lib_shared
install_lib_static
install_lib_pc
install_lib
install_doc_html
install_doc_man
install_doc
To clean up build results to varying degrees, use the following make targets:
clean
distclean
relclean
## Advanced installation
Optionally, define make variables when invoking make, including (not
exclusively):
* `INCLUDEDIR="?"`
Use this as the installation prefix for header files.
* `LIBDIR="?"`
Use this as the installation prefix for libraries.
* `MANDIR="?"`
Use this as the installation prefix for man pages.
* `DESTDIR="?"`
Prepend DESTDIR to INCLUDEDIR, LIBDIR, DATADIR, and MANDIR. This is useful
when installing to a different path than was specified via --prefix.
* `CC="?"`
Use this to invoke the C compiler.
* `CFLAGS="?"`
Pass these flags to the compiler.
* `CPPFLAGS="?"`
Pass these flags to the C preprocessor.
* `LDFLAGS="?"`
Pass these flags when linking.
* `PATH="?"`
Use this to search for programs used during configuration and building.
## Development
If you intend to make non-trivial changes to jemalloc, use the 'autogen.sh'
script rather than 'configure'. This re-generates 'configure', enables
configuration dependency rules, and enables re-generation of automatically
generated source files.
The build system supports using an object directory separate from the source
tree. For example, you can create an 'obj' directory, and from within that
directory, issue configuration and build commands:
autoconf
mkdir obj
cd obj
../configure --enable-autogen
make
## Documentation
The manual page is generated in both html and roff formats. Any web browser
can be used to view the html manual. The roff manual page can be formatted
prior to installation via the following command:
nroff -man -t doc/jemalloc.3

623
deps/jemalloc/Makefile.in vendored Normal file
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@ -0,0 +1,623 @@
# Clear out all vpaths, then set just one (default vpath) for the main build
# directory.
vpath
vpath % .
# Clear the default suffixes, so that built-in rules are not used.
.SUFFIXES :
SHELL := /bin/sh
CC := @CC@
CXX := @CXX@
# Configuration parameters.
DESTDIR =
BINDIR := $(DESTDIR)@BINDIR@
INCLUDEDIR := $(DESTDIR)@INCLUDEDIR@
LIBDIR := $(DESTDIR)@LIBDIR@
DATADIR := $(DESTDIR)@DATADIR@
MANDIR := $(DESTDIR)@MANDIR@
srcroot := @srcroot@
objroot := @objroot@
abs_srcroot := @abs_srcroot@
abs_objroot := @abs_objroot@
# Build parameters.
CPPFLAGS := @CPPFLAGS@ -I$(objroot)include -I$(srcroot)include
CONFIGURE_CFLAGS := @CONFIGURE_CFLAGS@
SPECIFIED_CFLAGS := @SPECIFIED_CFLAGS@
EXTRA_CFLAGS := @EXTRA_CFLAGS@
CFLAGS := $(strip $(CONFIGURE_CFLAGS) $(SPECIFIED_CFLAGS) $(EXTRA_CFLAGS))
CONFIGURE_CXXFLAGS := @CONFIGURE_CXXFLAGS@
SPECIFIED_CXXFLAGS := @SPECIFIED_CXXFLAGS@
EXTRA_CXXFLAGS := @EXTRA_CXXFLAGS@
CXXFLAGS := $(strip $(CONFIGURE_CXXFLAGS) $(SPECIFIED_CXXFLAGS) $(EXTRA_CXXFLAGS))
LDFLAGS := @LDFLAGS@
EXTRA_LDFLAGS := @EXTRA_LDFLAGS@
LIBS := @LIBS@
RPATH_EXTRA := @RPATH_EXTRA@
SO := @so@
IMPORTLIB := @importlib@
O := @o@
A := @a@
EXE := @exe@
LIBPREFIX := @libprefix@
REV := @rev@
install_suffix := @install_suffix@
ABI := @abi@
XSLTPROC := @XSLTPROC@
XSLROOT := @XSLROOT@
AUTOCONF := @AUTOCONF@
_RPATH = @RPATH@
RPATH = $(if $(1),$(call _RPATH,$(1)))
cfghdrs_in := $(addprefix $(srcroot),@cfghdrs_in@)
cfghdrs_out := @cfghdrs_out@
cfgoutputs_in := $(addprefix $(srcroot),@cfgoutputs_in@)
cfgoutputs_out := @cfgoutputs_out@
enable_autogen := @enable_autogen@
enable_doc := @enable_doc@
enable_shared := @enable_shared@
enable_static := @enable_static@
enable_prof := @enable_prof@
enable_zone_allocator := @enable_zone_allocator@
enable_experimental_smallocx := @enable_experimental_smallocx@
MALLOC_CONF := @JEMALLOC_CPREFIX@MALLOC_CONF
link_whole_archive := @link_whole_archive@
DSO_LDFLAGS = @DSO_LDFLAGS@
SOREV = @SOREV@
PIC_CFLAGS = @PIC_CFLAGS@
CTARGET = @CTARGET@
LDTARGET = @LDTARGET@
TEST_LD_MODE = @TEST_LD_MODE@
MKLIB = @MKLIB@
AR = @AR@
ARFLAGS = @ARFLAGS@
DUMP_SYMS = @DUMP_SYMS@
AWK := @AWK@
CC_MM = @CC_MM@
LM := @LM@
INSTALL = @INSTALL@
ifeq (macho, $(ABI))
TEST_LIBRARY_PATH := DYLD_FALLBACK_LIBRARY_PATH="$(objroot)lib"
else
ifeq (pecoff, $(ABI))
TEST_LIBRARY_PATH := PATH="$(PATH):$(objroot)lib"
else
TEST_LIBRARY_PATH :=
endif
endif
LIBJEMALLOC := $(LIBPREFIX)jemalloc$(install_suffix)
# Lists of files.
BINS := $(objroot)bin/jemalloc-config $(objroot)bin/jemalloc.sh $(objroot)bin/jeprof
C_HDRS := $(objroot)include/jemalloc/jemalloc$(install_suffix).h
C_SRCS := $(srcroot)src/jemalloc.c \
$(srcroot)src/arena.c \
$(srcroot)src/background_thread.c \
$(srcroot)src/base.c \
$(srcroot)src/bin.c \
$(srcroot)src/bitmap.c \
$(srcroot)src/ckh.c \
$(srcroot)src/ctl.c \
$(srcroot)src/div.c \
$(srcroot)src/extent.c \
$(srcroot)src/extent_dss.c \
$(srcroot)src/extent_mmap.c \
$(srcroot)src/hash.c \
$(srcroot)src/hook.c \
$(srcroot)src/large.c \
$(srcroot)src/log.c \
$(srcroot)src/malloc_io.c \
$(srcroot)src/mutex.c \
$(srcroot)src/mutex_pool.c \
$(srcroot)src/nstime.c \
$(srcroot)src/pages.c \
$(srcroot)src/prng.c \
$(srcroot)src/prof.c \
$(srcroot)src/rtree.c \
$(srcroot)src/safety_check.c \
$(srcroot)src/stats.c \
$(srcroot)src/sc.c \
$(srcroot)src/sz.c \
$(srcroot)src/tcache.c \
$(srcroot)src/test_hooks.c \
$(srcroot)src/ticker.c \
$(srcroot)src/tsd.c \
$(srcroot)src/witness.c
ifeq ($(enable_zone_allocator), 1)
C_SRCS += $(srcroot)src/zone.c
endif
ifeq ($(IMPORTLIB),$(SO))
STATIC_LIBS := $(objroot)lib/$(LIBJEMALLOC).$(A)
endif
ifdef PIC_CFLAGS
STATIC_LIBS += $(objroot)lib/$(LIBJEMALLOC)_pic.$(A)
else
STATIC_LIBS += $(objroot)lib/$(LIBJEMALLOC)_s.$(A)
endif
DSOS := $(objroot)lib/$(LIBJEMALLOC).$(SOREV)
ifneq ($(SOREV),$(SO))
DSOS += $(objroot)lib/$(LIBJEMALLOC).$(SO)
endif
ifeq (1, $(link_whole_archive))
LJEMALLOC := -Wl,--whole-archive -L$(objroot)lib -l$(LIBJEMALLOC) -Wl,--no-whole-archive
else
LJEMALLOC := $(objroot)lib/$(LIBJEMALLOC).$(IMPORTLIB)
endif
PC := $(objroot)jemalloc.pc
MAN3 := $(objroot)doc/jemalloc$(install_suffix).3
DOCS_XML := $(objroot)doc/jemalloc$(install_suffix).xml
DOCS_HTML := $(DOCS_XML:$(objroot)%.xml=$(objroot)%.html)
DOCS_MAN3 := $(DOCS_XML:$(objroot)%.xml=$(objroot)%.3)
DOCS := $(DOCS_HTML) $(DOCS_MAN3)
C_TESTLIB_SRCS := $(srcroot)test/src/btalloc.c $(srcroot)test/src/btalloc_0.c \
$(srcroot)test/src/btalloc_1.c $(srcroot)test/src/math.c \
$(srcroot)test/src/mtx.c $(srcroot)test/src/mq.c \
$(srcroot)test/src/SFMT.c $(srcroot)test/src/test.c \
$(srcroot)test/src/thd.c $(srcroot)test/src/timer.c
ifeq (1, $(link_whole_archive))
C_UTIL_INTEGRATION_SRCS :=
C_UTIL_CPP_SRCS :=
else
C_UTIL_INTEGRATION_SRCS := $(srcroot)src/nstime.c $(srcroot)src/malloc_io.c
C_UTIL_CPP_SRCS := $(srcroot)src/nstime.c $(srcroot)src/malloc_io.c
endif
TESTS_UNIT := \
$(srcroot)test/unit/a0.c \
$(srcroot)test/unit/arena_reset.c \
$(srcroot)test/unit/atomic.c \
$(srcroot)test/unit/background_thread.c \
$(srcroot)test/unit/background_thread_enable.c \
$(srcroot)test/unit/base.c \
$(srcroot)test/unit/bitmap.c \
$(srcroot)test/unit/bit_util.c \
$(srcroot)test/unit/binshard.c \
$(srcroot)test/unit/ckh.c \
$(srcroot)test/unit/decay.c \
$(srcroot)test/unit/div.c \
$(srcroot)test/unit/emitter.c \
$(srcroot)test/unit/extent_quantize.c \
$(srcroot)test/unit/extent_util.c \
$(srcroot)test/unit/fork.c \
$(srcroot)test/unit/hash.c \
$(srcroot)test/unit/hook.c \
$(srcroot)test/unit/huge.c \
$(srcroot)test/unit/junk.c \
$(srcroot)test/unit/junk_alloc.c \
$(srcroot)test/unit/junk_free.c \
$(srcroot)test/unit/log.c \
$(srcroot)test/unit/mallctl.c \
$(srcroot)test/unit/malloc_io.c \
$(srcroot)test/unit/math.c \
$(srcroot)test/unit/mq.c \
$(srcroot)test/unit/mtx.c \
$(srcroot)test/unit/pack.c \
$(srcroot)test/unit/pages.c \
$(srcroot)test/unit/ph.c \
$(srcroot)test/unit/prng.c \
$(srcroot)test/unit/prof_accum.c \
$(srcroot)test/unit/prof_active.c \
$(srcroot)test/unit/prof_gdump.c \
$(srcroot)test/unit/prof_idump.c \
$(srcroot)test/unit/prof_log.c \
$(srcroot)test/unit/prof_reset.c \
$(srcroot)test/unit/prof_tctx.c \
$(srcroot)test/unit/prof_thread_name.c \
$(srcroot)test/unit/ql.c \
$(srcroot)test/unit/qr.c \
$(srcroot)test/unit/rb.c \
$(srcroot)test/unit/retained.c \
$(srcroot)test/unit/rtree.c \
$(srcroot)test/unit/safety_check.c \
$(srcroot)test/unit/seq.c \
$(srcroot)test/unit/SFMT.c \
$(srcroot)test/unit/sc.c \
$(srcroot)test/unit/size_classes.c \
$(srcroot)test/unit/slab.c \
$(srcroot)test/unit/smoothstep.c \
$(srcroot)test/unit/spin.c \
$(srcroot)test/unit/stats.c \
$(srcroot)test/unit/stats_print.c \
$(srcroot)test/unit/test_hooks.c \
$(srcroot)test/unit/ticker.c \
$(srcroot)test/unit/nstime.c \
$(srcroot)test/unit/tsd.c \
$(srcroot)test/unit/witness.c \
$(srcroot)test/unit/zero.c
ifeq (@enable_prof@, 1)
TESTS_UNIT += \
$(srcroot)test/unit/arena_reset_prof.c
endif
TESTS_INTEGRATION := $(srcroot)test/integration/aligned_alloc.c \
$(srcroot)test/integration/allocated.c \
$(srcroot)test/integration/extent.c \
$(srcroot)test/integration/malloc.c \
$(srcroot)test/integration/mallocx.c \
$(srcroot)test/integration/MALLOCX_ARENA.c \
$(srcroot)test/integration/overflow.c \
$(srcroot)test/integration/posix_memalign.c \
$(srcroot)test/integration/rallocx.c \
$(srcroot)test/integration/sdallocx.c \
$(srcroot)test/integration/slab_sizes.c \
$(srcroot)test/integration/thread_arena.c \
$(srcroot)test/integration/thread_tcache_enabled.c \
$(srcroot)test/integration/xallocx.c
ifeq (@enable_experimental_smallocx@, 1)
TESTS_INTEGRATION += \
$(srcroot)test/integration/smallocx.c
endif
ifeq (@enable_cxx@, 1)
CPP_SRCS := $(srcroot)src/jemalloc_cpp.cpp
TESTS_INTEGRATION_CPP := $(srcroot)test/integration/cpp/basic.cpp
else
CPP_SRCS :=
TESTS_INTEGRATION_CPP :=
endif
TESTS_STRESS := $(srcroot)test/stress/microbench.c \
$(srcroot)test/stress/hookbench.c
TESTS := $(TESTS_UNIT) $(TESTS_INTEGRATION) $(TESTS_INTEGRATION_CPP) $(TESTS_STRESS)
PRIVATE_NAMESPACE_HDRS := $(objroot)include/jemalloc/internal/private_namespace.h $(objroot)include/jemalloc/internal/private_namespace_jet.h
PRIVATE_NAMESPACE_GEN_HDRS := $(PRIVATE_NAMESPACE_HDRS:%.h=%.gen.h)
C_SYM_OBJS := $(C_SRCS:$(srcroot)%.c=$(objroot)%.sym.$(O))
C_SYMS := $(C_SRCS:$(srcroot)%.c=$(objroot)%.sym)
C_OBJS := $(C_SRCS:$(srcroot)%.c=$(objroot)%.$(O))
CPP_OBJS := $(CPP_SRCS:$(srcroot)%.cpp=$(objroot)%.$(O))
C_PIC_OBJS := $(C_SRCS:$(srcroot)%.c=$(objroot)%.pic.$(O))
CPP_PIC_OBJS := $(CPP_SRCS:$(srcroot)%.cpp=$(objroot)%.pic.$(O))
C_JET_SYM_OBJS := $(C_SRCS:$(srcroot)%.c=$(objroot)%.jet.sym.$(O))
C_JET_SYMS := $(C_SRCS:$(srcroot)%.c=$(objroot)%.jet.sym)
C_JET_OBJS := $(C_SRCS:$(srcroot)%.c=$(objroot)%.jet.$(O))
C_TESTLIB_UNIT_OBJS := $(C_TESTLIB_SRCS:$(srcroot)%.c=$(objroot)%.unit.$(O))
C_TESTLIB_INTEGRATION_OBJS := $(C_TESTLIB_SRCS:$(srcroot)%.c=$(objroot)%.integration.$(O))
C_UTIL_INTEGRATION_OBJS := $(C_UTIL_INTEGRATION_SRCS:$(srcroot)%.c=$(objroot)%.integration.$(O))
C_TESTLIB_STRESS_OBJS := $(C_TESTLIB_SRCS:$(srcroot)%.c=$(objroot)%.stress.$(O))
C_TESTLIB_OBJS := $(C_TESTLIB_UNIT_OBJS) $(C_TESTLIB_INTEGRATION_OBJS) $(C_UTIL_INTEGRATION_OBJS) $(C_TESTLIB_STRESS_OBJS)
TESTS_UNIT_OBJS := $(TESTS_UNIT:$(srcroot)%.c=$(objroot)%.$(O))
TESTS_INTEGRATION_OBJS := $(TESTS_INTEGRATION:$(srcroot)%.c=$(objroot)%.$(O))
TESTS_INTEGRATION_CPP_OBJS := $(TESTS_INTEGRATION_CPP:$(srcroot)%.cpp=$(objroot)%.$(O))
TESTS_STRESS_OBJS := $(TESTS_STRESS:$(srcroot)%.c=$(objroot)%.$(O))
TESTS_OBJS := $(TESTS_UNIT_OBJS) $(TESTS_INTEGRATION_OBJS) $(TESTS_STRESS_OBJS)
TESTS_CPP_OBJS := $(TESTS_INTEGRATION_CPP_OBJS)
.PHONY: all dist build_doc_html build_doc_man build_doc
.PHONY: install_bin install_include install_lib
.PHONY: install_doc_html install_doc_man install_doc install
.PHONY: tests check clean distclean relclean
.SECONDARY : $(PRIVATE_NAMESPACE_GEN_HDRS) $(TESTS_OBJS) $(TESTS_CPP_OBJS)
# Default target.
all: build_lib
dist: build_doc
$(objroot)doc/%.html : $(objroot)doc/%.xml $(srcroot)doc/stylesheet.xsl $(objroot)doc/html.xsl
ifneq ($(XSLROOT),)
$(XSLTPROC) -o $@ $(objroot)doc/html.xsl $<
else
ifeq ($(wildcard $(DOCS_HTML)),)
@echo "<p>Missing xsltproc. Doc not built.</p>" > $@
endif
@echo "Missing xsltproc. "$@" not (re)built."
endif
$(objroot)doc/%.3 : $(objroot)doc/%.xml $(srcroot)doc/stylesheet.xsl $(objroot)doc/manpages.xsl
ifneq ($(XSLROOT),)
$(XSLTPROC) -o $@ $(objroot)doc/manpages.xsl $<
else
ifeq ($(wildcard $(DOCS_MAN3)),)
@echo "Missing xsltproc. Doc not built." > $@
endif
@echo "Missing xsltproc. "$@" not (re)built."
endif
build_doc_html: $(DOCS_HTML)
build_doc_man: $(DOCS_MAN3)
build_doc: $(DOCS)
#
# Include generated dependency files.
#
ifdef CC_MM
-include $(C_SYM_OBJS:%.$(O)=%.d)
-include $(C_OBJS:%.$(O)=%.d)
-include $(CPP_OBJS:%.$(O)=%.d)
-include $(C_PIC_OBJS:%.$(O)=%.d)
-include $(CPP_PIC_OBJS:%.$(O)=%.d)
-include $(C_JET_SYM_OBJS:%.$(O)=%.d)
-include $(C_JET_OBJS:%.$(O)=%.d)
-include $(C_TESTLIB_OBJS:%.$(O)=%.d)
-include $(TESTS_OBJS:%.$(O)=%.d)
-include $(TESTS_CPP_OBJS:%.$(O)=%.d)
endif
$(C_SYM_OBJS): $(objroot)src/%.sym.$(O): $(srcroot)src/%.c
$(C_SYM_OBJS): CPPFLAGS += -DJEMALLOC_NO_PRIVATE_NAMESPACE
$(C_SYMS): $(objroot)src/%.sym: $(objroot)src/%.sym.$(O)
$(C_OBJS): $(objroot)src/%.$(O): $(srcroot)src/%.c
$(CPP_OBJS): $(objroot)src/%.$(O): $(srcroot)src/%.cpp
$(C_PIC_OBJS): $(objroot)src/%.pic.$(O): $(srcroot)src/%.c
$(C_PIC_OBJS): CFLAGS += $(PIC_CFLAGS)
$(CPP_PIC_OBJS): $(objroot)src/%.pic.$(O): $(srcroot)src/%.cpp
$(CPP_PIC_OBJS): CXXFLAGS += $(PIC_CFLAGS)
$(C_JET_SYM_OBJS): $(objroot)src/%.jet.sym.$(O): $(srcroot)src/%.c
$(C_JET_SYM_OBJS): CPPFLAGS += -DJEMALLOC_JET -DJEMALLOC_NO_PRIVATE_NAMESPACE
$(C_JET_SYMS): $(objroot)src/%.jet.sym: $(objroot)src/%.jet.sym.$(O)
$(C_JET_OBJS): $(objroot)src/%.jet.$(O): $(srcroot)src/%.c
$(C_JET_OBJS): CPPFLAGS += -DJEMALLOC_JET
$(C_TESTLIB_UNIT_OBJS): $(objroot)test/src/%.unit.$(O): $(srcroot)test/src/%.c
$(C_TESTLIB_UNIT_OBJS): CPPFLAGS += -DJEMALLOC_UNIT_TEST
$(C_TESTLIB_INTEGRATION_OBJS): $(objroot)test/src/%.integration.$(O): $(srcroot)test/src/%.c
$(C_TESTLIB_INTEGRATION_OBJS): CPPFLAGS += -DJEMALLOC_INTEGRATION_TEST
$(C_UTIL_INTEGRATION_OBJS): $(objroot)src/%.integration.$(O): $(srcroot)src/%.c
$(C_TESTLIB_STRESS_OBJS): $(objroot)test/src/%.stress.$(O): $(srcroot)test/src/%.c
$(C_TESTLIB_STRESS_OBJS): CPPFLAGS += -DJEMALLOC_STRESS_TEST -DJEMALLOC_STRESS_TESTLIB
$(C_TESTLIB_OBJS): CPPFLAGS += -I$(srcroot)test/include -I$(objroot)test/include
$(TESTS_UNIT_OBJS): CPPFLAGS += -DJEMALLOC_UNIT_TEST
$(TESTS_INTEGRATION_OBJS): CPPFLAGS += -DJEMALLOC_INTEGRATION_TEST
$(TESTS_INTEGRATION_CPP_OBJS): CPPFLAGS += -DJEMALLOC_INTEGRATION_CPP_TEST
$(TESTS_STRESS_OBJS): CPPFLAGS += -DJEMALLOC_STRESS_TEST
$(TESTS_OBJS): $(objroot)test/%.$(O): $(srcroot)test/%.c
$(TESTS_CPP_OBJS): $(objroot)test/%.$(O): $(srcroot)test/%.cpp
$(TESTS_OBJS): CPPFLAGS += -I$(srcroot)test/include -I$(objroot)test/include
$(TESTS_CPP_OBJS): CPPFLAGS += -I$(srcroot)test/include -I$(objroot)test/include
ifneq ($(IMPORTLIB),$(SO))
$(CPP_OBJS) $(C_SYM_OBJS) $(C_OBJS) $(C_JET_SYM_OBJS) $(C_JET_OBJS): CPPFLAGS += -DDLLEXPORT
endif
# Dependencies.
ifndef CC_MM
HEADER_DIRS = $(srcroot)include/jemalloc/internal \
$(objroot)include/jemalloc $(objroot)include/jemalloc/internal
HEADERS = $(filter-out $(PRIVATE_NAMESPACE_HDRS),$(wildcard $(foreach dir,$(HEADER_DIRS),$(dir)/*.h)))
$(C_SYM_OBJS) $(C_OBJS) $(CPP_OBJS) $(C_PIC_OBJS) $(CPP_PIC_OBJS) $(C_JET_SYM_OBJS) $(C_JET_OBJS) $(C_TESTLIB_OBJS) $(TESTS_OBJS) $(TESTS_CPP_OBJS): $(HEADERS)
$(TESTS_OBJS) $(TESTS_CPP_OBJS): $(objroot)test/include/test/jemalloc_test.h
endif
$(C_OBJS) $(CPP_OBJS) $(C_PIC_OBJS) $(CPP_PIC_OBJS) $(C_TESTLIB_INTEGRATION_OBJS) $(C_UTIL_INTEGRATION_OBJS) $(TESTS_INTEGRATION_OBJS) $(TESTS_INTEGRATION_CPP_OBJS): $(objroot)include/jemalloc/internal/private_namespace.h
$(C_JET_OBJS) $(C_TESTLIB_UNIT_OBJS) $(C_TESTLIB_STRESS_OBJS) $(TESTS_UNIT_OBJS) $(TESTS_STRESS_OBJS): $(objroot)include/jemalloc/internal/private_namespace_jet.h
$(C_SYM_OBJS) $(C_OBJS) $(C_PIC_OBJS) $(C_JET_SYM_OBJS) $(C_JET_OBJS) $(C_TESTLIB_OBJS) $(TESTS_OBJS): %.$(O):
@mkdir -p $(@D)
$(CC) $(CFLAGS) -c $(CPPFLAGS) $(CTARGET) $<
ifdef CC_MM
@$(CC) -MM $(CPPFLAGS) -MT $@ -o $(@:%.$(O)=%.d) $<
endif
$(C_SYMS): %.sym:
@mkdir -p $(@D)
$(DUMP_SYMS) $< | $(AWK) -f $(objroot)include/jemalloc/internal/private_symbols.awk > $@
$(C_JET_SYMS): %.sym:
@mkdir -p $(@D)
$(DUMP_SYMS) $< | $(AWK) -f $(objroot)include/jemalloc/internal/private_symbols_jet.awk > $@
$(objroot)include/jemalloc/internal/private_namespace.gen.h: $(C_SYMS)
$(SHELL) $(srcroot)include/jemalloc/internal/private_namespace.sh $^ > $@
$(objroot)include/jemalloc/internal/private_namespace_jet.gen.h: $(C_JET_SYMS)
$(SHELL) $(srcroot)include/jemalloc/internal/private_namespace.sh $^ > $@
%.h: %.gen.h
@if ! `cmp -s $< $@` ; then echo "cp $< $<"; cp $< $@ ; fi
$(CPP_OBJS) $(CPP_PIC_OBJS) $(TESTS_CPP_OBJS): %.$(O):
@mkdir -p $(@D)
$(CXX) $(CXXFLAGS) -c $(CPPFLAGS) $(CTARGET) $<
ifdef CC_MM
@$(CXX) -MM $(CPPFLAGS) -MT $@ -o $(@:%.$(O)=%.d) $<
endif
ifneq ($(SOREV),$(SO))
%.$(SO) : %.$(SOREV)
@mkdir -p $(@D)
ln -sf $(<F) $@
endif
$(objroot)lib/$(LIBJEMALLOC).$(SOREV) : $(if $(PIC_CFLAGS),$(C_PIC_OBJS),$(C_OBJS)) $(if $(PIC_CFLAGS),$(CPP_PIC_OBJS),$(CPP_OBJS))
@mkdir -p $(@D)
$(CC) $(DSO_LDFLAGS) $(call RPATH,$(RPATH_EXTRA)) $(LDTARGET) $+ $(LDFLAGS) $(LIBS) $(EXTRA_LDFLAGS)
$(objroot)lib/$(LIBJEMALLOC)_pic.$(A) : $(C_PIC_OBJS) $(CPP_PIC_OBJS)
$(objroot)lib/$(LIBJEMALLOC).$(A) : $(C_OBJS) $(CPP_OBJS)
$(objroot)lib/$(LIBJEMALLOC)_s.$(A) : $(C_OBJS) $(CPP_OBJS)
$(STATIC_LIBS):
@mkdir -p $(@D)
$(AR) $(ARFLAGS)@AROUT@ $+
$(objroot)test/unit/%$(EXE): $(objroot)test/unit/%.$(O) $(C_JET_OBJS) $(C_TESTLIB_UNIT_OBJS)
@mkdir -p $(@D)
$(CC) $(LDTARGET) $(filter %.$(O),$^) $(call RPATH,$(objroot)lib) $(LDFLAGS) $(filter-out -lm,$(LIBS)) $(LM) $(EXTRA_LDFLAGS)
$(objroot)test/integration/%$(EXE): $(objroot)test/integration/%.$(O) $(C_TESTLIB_INTEGRATION_OBJS) $(C_UTIL_INTEGRATION_OBJS) $(objroot)lib/$(LIBJEMALLOC).$(IMPORTLIB)
@mkdir -p $(@D)
$(CC) $(TEST_LD_MODE) $(LDTARGET) $(filter %.$(O),$^) $(call RPATH,$(objroot)lib) $(LJEMALLOC) $(LDFLAGS) $(filter-out -lm,$(filter -lrt -pthread -lstdc++,$(LIBS))) $(LM) $(EXTRA_LDFLAGS)
$(objroot)test/integration/cpp/%$(EXE): $(objroot)test/integration/cpp/%.$(O) $(C_TESTLIB_INTEGRATION_OBJS) $(C_UTIL_INTEGRATION_OBJS) $(objroot)lib/$(LIBJEMALLOC).$(IMPORTLIB)
@mkdir -p $(@D)
$(CXX) $(LDTARGET) $(filter %.$(O),$^) $(call RPATH,$(objroot)lib) $(objroot)lib/$(LIBJEMALLOC).$(IMPORTLIB) $(LDFLAGS) $(filter-out -lm,$(LIBS)) -lm $(EXTRA_LDFLAGS)
$(objroot)test/stress/%$(EXE): $(objroot)test/stress/%.$(O) $(C_JET_OBJS) $(C_TESTLIB_STRESS_OBJS) $(objroot)lib/$(LIBJEMALLOC).$(IMPORTLIB)
@mkdir -p $(@D)
$(CC) $(TEST_LD_MODE) $(LDTARGET) $(filter %.$(O),$^) $(call RPATH,$(objroot)lib) $(objroot)lib/$(LIBJEMALLOC).$(IMPORTLIB) $(LDFLAGS) $(filter-out -lm,$(LIBS)) $(LM) $(EXTRA_LDFLAGS)
build_lib_shared: $(DSOS)
build_lib_static: $(STATIC_LIBS)
ifeq ($(enable_shared), 1)
build_lib: build_lib_shared
endif
ifeq ($(enable_static), 1)
build_lib: build_lib_static
endif
install_bin:
$(INSTALL) -d $(BINDIR)
@for b in $(BINS); do \
echo "$(INSTALL) -m 755 $$b $(BINDIR)"; \
$(INSTALL) -m 755 $$b $(BINDIR); \
done
install_include:
$(INSTALL) -d $(INCLUDEDIR)/jemalloc
@for h in $(C_HDRS); do \
echo "$(INSTALL) -m 644 $$h $(INCLUDEDIR)/jemalloc"; \
$(INSTALL) -m 644 $$h $(INCLUDEDIR)/jemalloc; \
done
install_lib_shared: $(DSOS)
$(INSTALL) -d $(LIBDIR)
$(INSTALL) -m 755 $(objroot)lib/$(LIBJEMALLOC).$(SOREV) $(LIBDIR)
ifneq ($(SOREV),$(SO))
ln -sf $(LIBJEMALLOC).$(SOREV) $(LIBDIR)/$(LIBJEMALLOC).$(SO)
endif
install_lib_static: $(STATIC_LIBS)
$(INSTALL) -d $(LIBDIR)
@for l in $(STATIC_LIBS); do \
echo "$(INSTALL) -m 755 $$l $(LIBDIR)"; \
$(INSTALL) -m 755 $$l $(LIBDIR); \
done
install_lib_pc: $(PC)
$(INSTALL) -d $(LIBDIR)/pkgconfig
@for l in $(PC); do \
echo "$(INSTALL) -m 644 $$l $(LIBDIR)/pkgconfig"; \
$(INSTALL) -m 644 $$l $(LIBDIR)/pkgconfig; \
done
ifeq ($(enable_shared), 1)
install_lib: install_lib_shared
endif
ifeq ($(enable_static), 1)
install_lib: install_lib_static
endif
install_lib: install_lib_pc
install_doc_html:
$(INSTALL) -d $(DATADIR)/doc/jemalloc$(install_suffix)
@for d in $(DOCS_HTML); do \
echo "$(INSTALL) -m 644 $$d $(DATADIR)/doc/jemalloc$(install_suffix)"; \
$(INSTALL) -m 644 $$d $(DATADIR)/doc/jemalloc$(install_suffix); \
done
install_doc_man:
$(INSTALL) -d $(MANDIR)/man3
@for d in $(DOCS_MAN3); do \
echo "$(INSTALL) -m 644 $$d $(MANDIR)/man3"; \
$(INSTALL) -m 644 $$d $(MANDIR)/man3; \
done
install_doc: build_doc install_doc_html install_doc_man
install: install_bin install_include install_lib
ifeq ($(enable_doc), 1)
install: install_doc
endif
tests_unit: $(TESTS_UNIT:$(srcroot)%.c=$(objroot)%$(EXE))
tests_integration: $(TESTS_INTEGRATION:$(srcroot)%.c=$(objroot)%$(EXE)) $(TESTS_INTEGRATION_CPP:$(srcroot)%.cpp=$(objroot)%$(EXE))
tests_stress: $(TESTS_STRESS:$(srcroot)%.c=$(objroot)%$(EXE))
tests: tests_unit tests_integration tests_stress
check_unit_dir:
@mkdir -p $(objroot)test/unit
check_integration_dir:
@mkdir -p $(objroot)test/integration
stress_dir:
@mkdir -p $(objroot)test/stress
check_dir: check_unit_dir check_integration_dir
check_unit: tests_unit check_unit_dir
$(SHELL) $(objroot)test/test.sh $(TESTS_UNIT:$(srcroot)%.c=$(objroot)%)
check_integration_prof: tests_integration check_integration_dir
ifeq ($(enable_prof), 1)
$(MALLOC_CONF)="prof:true" $(SHELL) $(objroot)test/test.sh $(TESTS_INTEGRATION:$(srcroot)%.c=$(objroot)%) $(TESTS_INTEGRATION_CPP:$(srcroot)%.cpp=$(objroot)%)
$(MALLOC_CONF)="prof:true,prof_active:false" $(SHELL) $(objroot)test/test.sh $(TESTS_INTEGRATION:$(srcroot)%.c=$(objroot)%) $(TESTS_INTEGRATION_CPP:$(srcroot)%.cpp=$(objroot)%)
endif
check_integration_decay: tests_integration check_integration_dir
$(MALLOC_CONF)="dirty_decay_ms:-1,muzzy_decay_ms:-1" $(SHELL) $(objroot)test/test.sh $(TESTS_INTEGRATION:$(srcroot)%.c=$(objroot)%) $(TESTS_INTEGRATION_CPP:$(srcroot)%.cpp=$(objroot)%)
$(MALLOC_CONF)="dirty_decay_ms:0,muzzy_decay_ms:0" $(SHELL) $(objroot)test/test.sh $(TESTS_INTEGRATION:$(srcroot)%.c=$(objroot)%) $(TESTS_INTEGRATION_CPP:$(srcroot)%.cpp=$(objroot)%)
check_integration: tests_integration check_integration_dir
$(SHELL) $(objroot)test/test.sh $(TESTS_INTEGRATION:$(srcroot)%.c=$(objroot)%) $(TESTS_INTEGRATION_CPP:$(srcroot)%.cpp=$(objroot)%)
stress: tests_stress stress_dir
$(SHELL) $(objroot)test/test.sh $(TESTS_STRESS:$(srcroot)%.c=$(objroot)%)
check: check_unit check_integration check_integration_decay check_integration_prof
clean:
rm -f $(PRIVATE_NAMESPACE_HDRS)
rm -f $(PRIVATE_NAMESPACE_GEN_HDRS)
rm -f $(C_SYM_OBJS)
rm -f $(C_SYMS)
rm -f $(C_OBJS)
rm -f $(CPP_OBJS)
rm -f $(C_PIC_OBJS)
rm -f $(CPP_PIC_OBJS)
rm -f $(C_JET_SYM_OBJS)
rm -f $(C_JET_SYMS)
rm -f $(C_JET_OBJS)
rm -f $(C_TESTLIB_OBJS)
rm -f $(C_SYM_OBJS:%.$(O)=%.d)
rm -f $(C_OBJS:%.$(O)=%.d)
rm -f $(CPP_OBJS:%.$(O)=%.d)
rm -f $(C_PIC_OBJS:%.$(O)=%.d)
rm -f $(CPP_PIC_OBJS:%.$(O)=%.d)
rm -f $(C_JET_SYM_OBJS:%.$(O)=%.d)
rm -f $(C_JET_OBJS:%.$(O)=%.d)
rm -f $(C_TESTLIB_OBJS:%.$(O)=%.d)
rm -f $(TESTS_OBJS:%.$(O)=%$(EXE))
rm -f $(TESTS_OBJS)
rm -f $(TESTS_OBJS:%.$(O)=%.d)
rm -f $(TESTS_OBJS:%.$(O)=%.out)
rm -f $(TESTS_CPP_OBJS:%.$(O)=%$(EXE))
rm -f $(TESTS_CPP_OBJS)
rm -f $(TESTS_CPP_OBJS:%.$(O)=%.d)
rm -f $(TESTS_CPP_OBJS:%.$(O)=%.out)
rm -f $(DSOS) $(STATIC_LIBS)
distclean: clean
rm -f $(objroot)bin/jemalloc-config
rm -f $(objroot)bin/jemalloc.sh
rm -f $(objroot)bin/jeprof
rm -f $(objroot)config.log
rm -f $(objroot)config.status
rm -f $(objroot)config.stamp
rm -f $(cfghdrs_out)
rm -f $(cfgoutputs_out)
relclean: distclean
rm -f $(objroot)configure
rm -f $(objroot)VERSION
rm -f $(DOCS_HTML)
rm -f $(DOCS_MAN3)
#===============================================================================
# Re-configuration rules.
ifeq ($(enable_autogen), 1)
$(srcroot)configure : $(srcroot)configure.ac
cd ./$(srcroot) && $(AUTOCONF)
$(objroot)config.status : $(srcroot)configure
./$(objroot)config.status --recheck
$(srcroot)config.stamp.in : $(srcroot)configure.ac
echo stamp > $(srcroot)config.stamp.in
$(objroot)config.stamp : $(cfgoutputs_in) $(cfghdrs_in) $(srcroot)configure
./$(objroot)config.status
@touch $@
# There must be some action in order for make to re-read Makefile when it is
# out of date.
$(cfgoutputs_out) $(cfghdrs_out) : $(objroot)config.stamp
@true
endif

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jemalloc is a general purpose malloc(3) implementation that emphasizes
fragmentation avoidance and scalable concurrency support. jemalloc first came
into use as the FreeBSD libc allocator in 2005, and since then it has found its
way into numerous applications that rely on its predictable behavior. In 2010
jemalloc development efforts broadened to include developer support features
such as heap profiling and extensive monitoring/tuning hooks. Modern jemalloc
releases continue to be integrated back into FreeBSD, and therefore versatility
remains critical. Ongoing development efforts trend toward making jemalloc
among the best allocators for a broad range of demanding applications, and
eliminating/mitigating weaknesses that have practical repercussions for real
world applications.
The COPYING file contains copyright and licensing information.
The INSTALL file contains information on how to configure, build, and install
jemalloc.
The ChangeLog file contains a brief summary of changes for each release.
URL: http://jemalloc.net/

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This document summarizes the common approaches for performance fine tuning with
jemalloc (as of 5.1.0). The default configuration of jemalloc tends to work
reasonably well in practice, and most applications should not have to tune any
options. However, in order to cover a wide range of applications and avoid
pathological cases, the default setting is sometimes kept conservative and
suboptimal, even for many common workloads. When jemalloc is properly tuned for
a specific application / workload, it is common to improve system level metrics
by a few percent, or make favorable trade-offs.
## Notable runtime options for performance tuning
Runtime options can be set via
[malloc_conf](http://jemalloc.net/jemalloc.3.html#tuning).
* [background_thread](http://jemalloc.net/jemalloc.3.html#background_thread)
Enabling jemalloc background threads generally improves the tail latency for
application threads, since unused memory purging is shifted to the dedicated
background threads. In addition, unintended purging delay caused by
application inactivity is avoided with background threads.
Suggested: `background_thread:true` when jemalloc managed threads can be
allowed.
* [metadata_thp](http://jemalloc.net/jemalloc.3.html#opt.metadata_thp)
Allowing jemalloc to utilize transparent huge pages for its internal
metadata usually reduces TLB misses significantly, especially for programs
with large memory footprint and frequent allocation / deallocation
activities. Metadata memory usage may increase due to the use of huge
pages.
Suggested for allocation intensive programs: `metadata_thp:auto` or
`metadata_thp:always`, which is expected to improve CPU utilization at a
small memory cost.
* [dirty_decay_ms](http://jemalloc.net/jemalloc.3.html#opt.dirty_decay_ms) and
[muzzy_decay_ms](http://jemalloc.net/jemalloc.3.html#opt.muzzy_decay_ms)
Decay time determines how fast jemalloc returns unused pages back to the
operating system, and therefore provides a fairly straightforward trade-off
between CPU and memory usage. Shorter decay time purges unused pages faster
to reduces memory usage (usually at the cost of more CPU cycles spent on
purging), and vice versa.
Suggested: tune the values based on the desired trade-offs.
* [narenas](http://jemalloc.net/jemalloc.3.html#opt.narenas)
By default jemalloc uses multiple arenas to reduce internal lock contention.
However high arena count may also increase overall memory fragmentation,
since arenas manage memory independently. When high degree of parallelism
is not expected at the allocator level, lower number of arenas often
improves memory usage.
Suggested: if low parallelism is expected, try lower arena count while
monitoring CPU and memory usage.
* [percpu_arena](http://jemalloc.net/jemalloc.3.html#opt.percpu_arena)
Enable dynamic thread to arena association based on running CPU. This has
the potential to improve locality, e.g. when thread to CPU affinity is
present.
Suggested: try `percpu_arena:percpu` or `percpu_arena:phycpu` if
thread migration between processors is expected to be infrequent.
Examples:
* High resource consumption application, prioritizing CPU utilization:
`background_thread:true,metadata_thp:auto` combined with relaxed decay time
(increased `dirty_decay_ms` and / or `muzzy_decay_ms`,
e.g. `dirty_decay_ms:30000,muzzy_decay_ms:30000`).
* High resource consumption application, prioritizing memory usage:
`background_thread:true` combined with shorter decay time (decreased
`dirty_decay_ms` and / or `muzzy_decay_ms`,
e.g. `dirty_decay_ms:5000,muzzy_decay_ms:5000`), and lower arena count
(e.g. number of CPUs).
* Low resource consumption application:
`narenas:1,lg_tcache_max:13` combined with shorter decay time (decreased
`dirty_decay_ms` and / or `muzzy_decay_ms`,e.g.
`dirty_decay_ms:1000,muzzy_decay_ms:0`).
* Extremely conservative -- minimize memory usage at all costs, only suitable when
allocation activity is very rare:
`narenas:1,tcache:false,dirty_decay_ms:0,muzzy_decay_ms:0`
Note that it is recommended to combine the options with `abort_conf:true` which
aborts immediately on illegal options.
## Beyond runtime options
In addition to the runtime options, there are a number of programmatic ways to
improve application performance with jemalloc.
* [Explicit arenas](http://jemalloc.net/jemalloc.3.html#arenas.create)
Manually created arenas can help performance in various ways, e.g. by
managing locality and contention for specific usages. For example,
applications can explicitly allocate frequently accessed objects from a
dedicated arena with
[mallocx()](http://jemalloc.net/jemalloc.3.html#MALLOCX_ARENA) to improve
locality. In addition, explicit arenas often benefit from individually
tuned options, e.g. relaxed [decay
time](http://jemalloc.net/jemalloc.3.html#arena.i.dirty_decay_ms) if
frequent reuse is expected.
* [Extent hooks](http://jemalloc.net/jemalloc.3.html#arena.i.extent_hooks)
Extent hooks allow customization for managing underlying memory. One use
case for performance purpose is to utilize huge pages -- for example,
[HHVM](https://github.com/facebook/hhvm/blob/master/hphp/util/alloc.cpp)
uses explicit arenas with customized extent hooks to manage 1GB huge pages
for frequently accessed data, which reduces TLB misses significantly.
* [Explicit thread-to-arena
binding](http://jemalloc.net/jemalloc.3.html#thread.arena)
It is common for some threads in an application to have different memory
access / allocation patterns. Threads with heavy workloads often benefit
from explicit binding, e.g. binding very active threads to dedicated arenas
may reduce contention at the allocator level.

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#!/bin/sh
for i in autoconf; do
echo "$i"
$i
if [ $? -ne 0 ]; then
echo "Error $? in $i"
exit 1
fi
done
echo "./configure --enable-autogen $@"
./configure --enable-autogen $@
if [ $? -ne 0 ]; then
echo "Error $? in ./configure"
exit 1
fi

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#!/bin/sh
usage() {
cat <<EOF
Usage:
@BINDIR@/jemalloc-config <option>
Options:
--help | -h : Print usage.
--version : Print jemalloc version.
--revision : Print shared library revision number.
--config : Print configure options used to build jemalloc.
--prefix : Print installation directory prefix.
--bindir : Print binary installation directory.
--datadir : Print data installation directory.
--includedir : Print include installation directory.
--libdir : Print library installation directory.
--mandir : Print manual page installation directory.
--cc : Print compiler used to build jemalloc.
--cflags : Print compiler flags used to build jemalloc.
--cppflags : Print preprocessor flags used to build jemalloc.
--cxxflags : Print C++ compiler flags used to build jemalloc.
--ldflags : Print library flags used to build jemalloc.
--libs : Print libraries jemalloc was linked against.
EOF
}
prefix="@prefix@"
exec_prefix="@exec_prefix@"
case "$1" in
--help | -h)
usage
exit 0
;;
--version)
echo "@jemalloc_version@"
;;
--revision)
echo "@rev@"
;;
--config)
echo "@CONFIG@"
;;
--prefix)
echo "@PREFIX@"
;;
--bindir)
echo "@BINDIR@"
;;
--datadir)
echo "@DATADIR@"
;;
--includedir)
echo "@INCLUDEDIR@"
;;
--libdir)
echo "@LIBDIR@"
;;
--mandir)
echo "@MANDIR@"
;;
--cc)
echo "@CC@"
;;
--cflags)
echo "@CFLAGS@"
;;
--cppflags)
echo "@CPPFLAGS@"
;;
--cxxflags)
echo "@CXXFLAGS@"
;;
--ldflags)
echo "@LDFLAGS@ @EXTRA_LDFLAGS@"
;;
--libs)
echo "@LIBS@"
;;
*)
usage
exit 1
esac

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#!/bin/sh
prefix=@prefix@
exec_prefix=@exec_prefix@
libdir=@libdir@
@LD_PRELOAD_VAR@=${libdir}/libjemalloc.@SOREV@
export @LD_PRELOAD_VAR@
exec "$@"

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deps/jemalloc/build-aux/install-sh vendored Executable file
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#! /bin/sh
#
# install - install a program, script, or datafile
# This comes from X11R5 (mit/util/scripts/install.sh).
#
# Copyright 1991 by the Massachusetts Institute of Technology
#
# Permission to use, copy, modify, distribute, and sell this software and its
# documentation for any purpose is hereby granted without fee, provided that
# the above copyright notice appear in all copies and that both that
# copyright notice and this permission notice appear in supporting
# documentation, and that the name of M.I.T. not be used in advertising or
# publicity pertaining to distribution of the software without specific,
# written prior permission. M.I.T. makes no representations about the
# suitability of this software for any purpose. It is provided "as is"
# without express or implied warranty.
#
# Calling this script install-sh is preferred over install.sh, to prevent
# `make' implicit rules from creating a file called install from it
# when there is no Makefile.
#
# This script is compatible with the BSD install script, but was written
# from scratch. It can only install one file at a time, a restriction
# shared with many OS's install programs.
# set DOITPROG to echo to test this script
# Don't use :- since 4.3BSD and earlier shells don't like it.
doit="${DOITPROG-}"
# put in absolute paths if you don't have them in your path; or use env. vars.
mvprog="${MVPROG-mv}"
cpprog="${CPPROG-cp}"
chmodprog="${CHMODPROG-chmod}"
chownprog="${CHOWNPROG-chown}"
chgrpprog="${CHGRPPROG-chgrp}"
stripprog="${STRIPPROG-strip}"
rmprog="${RMPROG-rm}"
mkdirprog="${MKDIRPROG-mkdir}"
transformbasename=""
transform_arg=""
instcmd="$mvprog"
chmodcmd="$chmodprog 0755"
chowncmd=""
chgrpcmd=""
stripcmd=""
rmcmd="$rmprog -f"
mvcmd="$mvprog"
src=""
dst=""
dir_arg=""
while [ x"$1" != x ]; do
case $1 in
-c) instcmd="$cpprog"
shift
continue;;
-d) dir_arg=true
shift
continue;;
-m) chmodcmd="$chmodprog $2"
shift
shift
continue;;
-o) chowncmd="$chownprog $2"
shift
shift
continue;;
-g) chgrpcmd="$chgrpprog $2"
shift
shift
continue;;
-s) stripcmd="$stripprog"
shift
continue;;
-t=*) transformarg=`echo $1 | sed 's/-t=//'`
shift
continue;;
-b=*) transformbasename=`echo $1 | sed 's/-b=//'`
shift
continue;;
*) if [ x"$src" = x ]
then
src=$1
else
# this colon is to work around a 386BSD /bin/sh bug
:
dst=$1
fi
shift
continue;;
esac
done
if [ x"$src" = x ]
then
echo "install: no input file specified"
exit 1
else
true
fi
if [ x"$dir_arg" != x ]; then
dst=$src
src=""
if [ -d $dst ]; then
instcmd=:
else
instcmd=mkdir
fi
else
# Waiting for this to be detected by the "$instcmd $src $dsttmp" command
# might cause directories to be created, which would be especially bad
# if $src (and thus $dsttmp) contains '*'.
if [ -f $src -o -d $src ]
then
true
else
echo "install: $src does not exist"
exit 1
fi
if [ x"$dst" = x ]
then
echo "install: no destination specified"
exit 1
else
true
fi
# If destination is a directory, append the input filename; if your system
# does not like double slashes in filenames, you may need to add some logic
if [ -d $dst ]
then
dst="$dst"/`basename $src`
else
true
fi
fi
## this sed command emulates the dirname command
dstdir=`echo $dst | sed -e 's,[^/]*$,,;s,/$,,;s,^$,.,'`
# Make sure that the destination directory exists.
# this part is taken from Noah Friedman's mkinstalldirs script
# Skip lots of stat calls in the usual case.
if [ ! -d "$dstdir" ]; then
defaultIFS='
'
IFS="${IFS-${defaultIFS}}"
oIFS="${IFS}"
# Some sh's can't handle IFS=/ for some reason.
IFS='%'
set - `echo ${dstdir} | sed -e 's@/@%@g' -e 's@^%@/@'`
IFS="${oIFS}"
pathcomp=''
while [ $# -ne 0 ] ; do
pathcomp="${pathcomp}${1}"
shift
if [ ! -d "${pathcomp}" ] ;
then
$mkdirprog "${pathcomp}"
else
true
fi
pathcomp="${pathcomp}/"
done
fi
if [ x"$dir_arg" != x ]
then
$doit $instcmd $dst &&
if [ x"$chowncmd" != x ]; then $doit $chowncmd $dst; else true ; fi &&
if [ x"$chgrpcmd" != x ]; then $doit $chgrpcmd $dst; else true ; fi &&
if [ x"$stripcmd" != x ]; then $doit $stripcmd $dst; else true ; fi &&
if [ x"$chmodcmd" != x ]; then $doit $chmodcmd $dst; else true ; fi
else
# If we're going to rename the final executable, determine the name now.
if [ x"$transformarg" = x ]
then
dstfile=`basename $dst`
else
dstfile=`basename $dst $transformbasename |
sed $transformarg`$transformbasename
fi
# don't allow the sed command to completely eliminate the filename
if [ x"$dstfile" = x ]
then
dstfile=`basename $dst`
else
true
fi
# Make a temp file name in the proper directory.
dsttmp=$dstdir/#inst.$$#
# Move or copy the file name to the temp name
$doit $instcmd $src $dsttmp &&
trap "rm -f ${dsttmp}" 0 &&
# and set any options; do chmod last to preserve setuid bits
# If any of these fail, we abort the whole thing. If we want to
# ignore errors from any of these, just make sure not to ignore
# errors from the above "$doit $instcmd $src $dsttmp" command.
if [ x"$chowncmd" != x ]; then $doit $chowncmd $dsttmp; else true;fi &&
if [ x"$chgrpcmd" != x ]; then $doit $chgrpcmd $dsttmp; else true;fi &&
if [ x"$stripcmd" != x ]; then $doit $stripcmd $dsttmp; else true;fi &&
if [ x"$chmodcmd" != x ]; then $doit $chmodcmd $dsttmp; else true;fi &&
# Now rename the file to the real destination.
$doit $rmcmd -f $dstdir/$dstfile &&
$doit $mvcmd $dsttmp $dstdir/$dstfile
fi &&
exit 0

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<xsl:stylesheet xmlns:xsl="http://www.w3.org/1999/XSL/Transform" version="1.0">
<xsl:import href="@XSLROOT@/html/docbook.xsl"/>
<xsl:import href="@abs_srcroot@doc/stylesheet.xsl"/>
<xsl:output method="xml" encoding="utf-8"/>
</xsl:stylesheet>

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<xsl:stylesheet xmlns:xsl="http://www.w3.org/1999/XSL/Transform" version="1.0">
<xsl:import href="@XSLROOT@/manpages/docbook.xsl"/>
<xsl:import href="@abs_srcroot@doc/stylesheet.xsl"/>
</xsl:stylesheet>

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<xsl:stylesheet xmlns:xsl="http://www.w3.org/1999/XSL/Transform" version="1.0">
<xsl:param name="funcsynopsis.style">ansi</xsl:param>
<xsl:param name="function.parens" select="0"/>
<xsl:template match="function">
<xsl:call-template name="inline.monoseq"/>
</xsl:template>
<xsl:template match="mallctl">
<quote><xsl:call-template name="inline.monoseq"/></quote>
</xsl:template>
</xsl:stylesheet>

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#ifndef JEMALLOC_INTERNAL_ARENA_EXTERNS_H
#define JEMALLOC_INTERNAL_ARENA_EXTERNS_H
#include "jemalloc/internal/bin.h"
#include "jemalloc/internal/extent_dss.h"
#include "jemalloc/internal/hook.h"
#include "jemalloc/internal/pages.h"
#include "jemalloc/internal/stats.h"
extern ssize_t opt_dirty_decay_ms;
extern ssize_t opt_muzzy_decay_ms;
extern percpu_arena_mode_t opt_percpu_arena;
extern const char *percpu_arena_mode_names[];
extern const uint64_t h_steps[SMOOTHSTEP_NSTEPS];
extern malloc_mutex_t arenas_lock;
extern size_t opt_oversize_threshold;
extern size_t oversize_threshold;
void arena_basic_stats_merge(tsdn_t *tsdn, arena_t *arena,
unsigned *nthreads, const char **dss, ssize_t *dirty_decay_ms,
ssize_t *muzzy_decay_ms, size_t *nactive, size_t *ndirty, size_t *nmuzzy);
void arena_stats_merge(tsdn_t *tsdn, arena_t *arena, unsigned *nthreads,
const char **dss, ssize_t *dirty_decay_ms, ssize_t *muzzy_decay_ms,
size_t *nactive, size_t *ndirty, size_t *nmuzzy, arena_stats_t *astats,
bin_stats_t *bstats, arena_stats_large_t *lstats,
arena_stats_extents_t *estats);
void arena_extents_dirty_dalloc(tsdn_t *tsdn, arena_t *arena,
extent_hooks_t **r_extent_hooks, extent_t *extent);
#ifdef JEMALLOC_JET
size_t arena_slab_regind(extent_t *slab, szind_t binind, const void *ptr);
#endif
extent_t *arena_extent_alloc_large(tsdn_t *tsdn, arena_t *arena,
size_t usize, size_t alignment, bool *zero);
void arena_extent_dalloc_large_prep(tsdn_t *tsdn, arena_t *arena,
extent_t *extent);
void arena_extent_ralloc_large_shrink(tsdn_t *tsdn, arena_t *arena,
extent_t *extent, size_t oldsize);
void arena_extent_ralloc_large_expand(tsdn_t *tsdn, arena_t *arena,
extent_t *extent, size_t oldsize);
ssize_t arena_dirty_decay_ms_get(arena_t *arena);
bool arena_dirty_decay_ms_set(tsdn_t *tsdn, arena_t *arena, ssize_t decay_ms);
ssize_t arena_muzzy_decay_ms_get(arena_t *arena);
bool arena_muzzy_decay_ms_set(tsdn_t *tsdn, arena_t *arena, ssize_t decay_ms);
void arena_decay(tsdn_t *tsdn, arena_t *arena, bool is_background_thread,
bool all);
void arena_reset(tsd_t *tsd, arena_t *arena);
void arena_destroy(tsd_t *tsd, arena_t *arena);
void arena_tcache_fill_small(tsdn_t *tsdn, arena_t *arena, tcache_t *tcache,
cache_bin_t *tbin, szind_t binind, uint64_t prof_accumbytes);
void arena_alloc_junk_small(void *ptr, const bin_info_t *bin_info,
bool zero);
typedef void (arena_dalloc_junk_small_t)(void *, const bin_info_t *);
extern arena_dalloc_junk_small_t *JET_MUTABLE arena_dalloc_junk_small;
void *arena_malloc_hard(tsdn_t *tsdn, arena_t *arena, size_t size,
szind_t ind, bool zero);
void *arena_palloc(tsdn_t *tsdn, arena_t *arena, size_t usize,
size_t alignment, bool zero, tcache_t *tcache);
void arena_prof_promote(tsdn_t *tsdn, void *ptr, size_t usize);
void arena_dalloc_promoted(tsdn_t *tsdn, void *ptr, tcache_t *tcache,
bool slow_path);
void arena_dalloc_bin_junked_locked(tsdn_t *tsdn, arena_t *arena, bin_t *bin,
szind_t binind, extent_t *extent, void *ptr);
void arena_dalloc_small(tsdn_t *tsdn, void *ptr);
bool arena_ralloc_no_move(tsdn_t *tsdn, void *ptr, size_t oldsize, size_t size,
size_t extra, bool zero, size_t *newsize);
void *arena_ralloc(tsdn_t *tsdn, arena_t *arena, void *ptr, size_t oldsize,
size_t size, size_t alignment, bool zero, tcache_t *tcache,
hook_ralloc_args_t *hook_args);
dss_prec_t arena_dss_prec_get(arena_t *arena);
bool arena_dss_prec_set(arena_t *arena, dss_prec_t dss_prec);
ssize_t arena_dirty_decay_ms_default_get(void);
bool arena_dirty_decay_ms_default_set(ssize_t decay_ms);
ssize_t arena_muzzy_decay_ms_default_get(void);
bool arena_muzzy_decay_ms_default_set(ssize_t decay_ms);
bool arena_retain_grow_limit_get_set(tsd_t *tsd, arena_t *arena,
size_t *old_limit, size_t *new_limit);
unsigned arena_nthreads_get(arena_t *arena, bool internal);
void arena_nthreads_inc(arena_t *arena, bool internal);
void arena_nthreads_dec(arena_t *arena, bool internal);
size_t arena_extent_sn_next(arena_t *arena);
arena_t *arena_new(tsdn_t *tsdn, unsigned ind, extent_hooks_t *extent_hooks);
bool arena_init_huge(void);
bool arena_is_huge(unsigned arena_ind);
arena_t *arena_choose_huge(tsd_t *tsd);
bin_t *arena_bin_choose_lock(tsdn_t *tsdn, arena_t *arena, szind_t binind,
unsigned *binshard);
void arena_boot(sc_data_t *sc_data);
void arena_prefork0(tsdn_t *tsdn, arena_t *arena);
void arena_prefork1(tsdn_t *tsdn, arena_t *arena);
void arena_prefork2(tsdn_t *tsdn, arena_t *arena);
void arena_prefork3(tsdn_t *tsdn, arena_t *arena);
void arena_prefork4(tsdn_t *tsdn, arena_t *arena);
void arena_prefork5(tsdn_t *tsdn, arena_t *arena);
void arena_prefork6(tsdn_t *tsdn, arena_t *arena);
void arena_prefork7(tsdn_t *tsdn, arena_t *arena);
void arena_postfork_parent(tsdn_t *tsdn, arena_t *arena);
void arena_postfork_child(tsdn_t *tsdn, arena_t *arena);
#endif /* JEMALLOC_INTERNAL_ARENA_EXTERNS_H */

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#ifndef JEMALLOC_INTERNAL_ARENA_INLINES_A_H
#define JEMALLOC_INTERNAL_ARENA_INLINES_A_H
static inline unsigned
arena_ind_get(const arena_t *arena) {
return base_ind_get(arena->base);
}
static inline void
arena_internal_add(arena_t *arena, size_t size) {
atomic_fetch_add_zu(&arena->stats.internal, size, ATOMIC_RELAXED);
}
static inline void
arena_internal_sub(arena_t *arena, size_t size) {
atomic_fetch_sub_zu(&arena->stats.internal, size, ATOMIC_RELAXED);
}
static inline size_t
arena_internal_get(arena_t *arena) {
return atomic_load_zu(&arena->stats.internal, ATOMIC_RELAXED);
}
static inline bool
arena_prof_accum(tsdn_t *tsdn, arena_t *arena, uint64_t accumbytes) {
cassert(config_prof);
if (likely(prof_interval == 0 || !prof_active_get_unlocked())) {
return false;
}
return prof_accum_add(tsdn, &arena->prof_accum, accumbytes);
}
static inline void
percpu_arena_update(tsd_t *tsd, unsigned cpu) {
assert(have_percpu_arena);
arena_t *oldarena = tsd_arena_get(tsd);
assert(oldarena != NULL);
unsigned oldind = arena_ind_get(oldarena);
if (oldind != cpu) {
unsigned newind = cpu;
arena_t *newarena = arena_get(tsd_tsdn(tsd), newind, true);
assert(newarena != NULL);
/* Set new arena/tcache associations. */
arena_migrate(tsd, oldind, newind);
tcache_t *tcache = tcache_get(tsd);
if (tcache != NULL) {
tcache_arena_reassociate(tsd_tsdn(tsd), tcache,
newarena);
}
}
}
#endif /* JEMALLOC_INTERNAL_ARENA_INLINES_A_H */

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#ifndef JEMALLOC_INTERNAL_ARENA_INLINES_B_H
#define JEMALLOC_INTERNAL_ARENA_INLINES_B_H
#include "jemalloc/internal/jemalloc_internal_types.h"
#include "jemalloc/internal/mutex.h"
#include "jemalloc/internal/rtree.h"
#include "jemalloc/internal/sc.h"
#include "jemalloc/internal/sz.h"
#include "jemalloc/internal/ticker.h"
JEMALLOC_ALWAYS_INLINE bool
arena_has_default_hooks(arena_t *arena) {
return (extent_hooks_get(arena) == &extent_hooks_default);
}
JEMALLOC_ALWAYS_INLINE arena_t *
arena_choose_maybe_huge(tsd_t *tsd, arena_t *arena, size_t size) {
if (arena != NULL) {
return arena;
}
/*
* For huge allocations, use the dedicated huge arena if both are true:
* 1) is using auto arena selection (i.e. arena == NULL), and 2) the
* thread is not assigned to a manual arena.
*/
if (unlikely(size >= oversize_threshold)) {
arena_t *tsd_arena = tsd_arena_get(tsd);
if (tsd_arena == NULL || arena_is_auto(tsd_arena)) {
return arena_choose_huge(tsd);
}
}
return arena_choose(tsd, NULL);
}
JEMALLOC_ALWAYS_INLINE prof_tctx_t *
arena_prof_tctx_get(tsdn_t *tsdn, const void *ptr, alloc_ctx_t *alloc_ctx) {
cassert(config_prof);
assert(ptr != NULL);
/* Static check. */
if (alloc_ctx == NULL) {
const extent_t *extent = iealloc(tsdn, ptr);
if (unlikely(!extent_slab_get(extent))) {
return large_prof_tctx_get(tsdn, extent);
}
} else {
if (unlikely(!alloc_ctx->slab)) {
return large_prof_tctx_get(tsdn, iealloc(tsdn, ptr));
}
}
return (prof_tctx_t *)(uintptr_t)1U;
}
JEMALLOC_ALWAYS_INLINE void
arena_prof_tctx_set(tsdn_t *tsdn, const void *ptr, size_t usize,
alloc_ctx_t *alloc_ctx, prof_tctx_t *tctx) {
cassert(config_prof);
assert(ptr != NULL);
/* Static check. */
if (alloc_ctx == NULL) {
extent_t *extent = iealloc(tsdn, ptr);
if (unlikely(!extent_slab_get(extent))) {
large_prof_tctx_set(tsdn, extent, tctx);
}
} else {
if (unlikely(!alloc_ctx->slab)) {
large_prof_tctx_set(tsdn, iealloc(tsdn, ptr), tctx);
}
}
}
static inline void
arena_prof_tctx_reset(tsdn_t *tsdn, const void *ptr, prof_tctx_t *tctx) {
cassert(config_prof);
assert(ptr != NULL);
extent_t *extent = iealloc(tsdn, ptr);
assert(!extent_slab_get(extent));
large_prof_tctx_reset(tsdn, extent);
}
JEMALLOC_ALWAYS_INLINE nstime_t
arena_prof_alloc_time_get(tsdn_t *tsdn, const void *ptr,
alloc_ctx_t *alloc_ctx) {
cassert(config_prof);
assert(ptr != NULL);
extent_t *extent = iealloc(tsdn, ptr);
/*
* Unlike arena_prof_prof_tctx_{get, set}, we only call this once we're
* sure we have a sampled allocation.
*/
assert(!extent_slab_get(extent));
return large_prof_alloc_time_get(extent);
}
JEMALLOC_ALWAYS_INLINE void
arena_prof_alloc_time_set(tsdn_t *tsdn, const void *ptr, alloc_ctx_t *alloc_ctx,
nstime_t t) {
cassert(config_prof);
assert(ptr != NULL);
extent_t *extent = iealloc(tsdn, ptr);
assert(!extent_slab_get(extent));
large_prof_alloc_time_set(extent, t);
}
JEMALLOC_ALWAYS_INLINE void
arena_decay_ticks(tsdn_t *tsdn, arena_t *arena, unsigned nticks) {
tsd_t *tsd;
ticker_t *decay_ticker;
if (unlikely(tsdn_null(tsdn))) {
return;
}
tsd = tsdn_tsd(tsdn);
decay_ticker = decay_ticker_get(tsd, arena_ind_get(arena));
if (unlikely(decay_ticker == NULL)) {
return;
}
if (unlikely(ticker_ticks(decay_ticker, nticks))) {
arena_decay(tsdn, arena, false, false);
}
}
JEMALLOC_ALWAYS_INLINE void
arena_decay_tick(tsdn_t *tsdn, arena_t *arena) {
malloc_mutex_assert_not_owner(tsdn, &arena->decay_dirty.mtx);
malloc_mutex_assert_not_owner(tsdn, &arena->decay_muzzy.mtx);
arena_decay_ticks(tsdn, arena, 1);
}
/* Purge a single extent to retained / unmapped directly. */
JEMALLOC_ALWAYS_INLINE void
arena_decay_extent(tsdn_t *tsdn,arena_t *arena, extent_hooks_t **r_extent_hooks,
extent_t *extent) {
size_t extent_size = extent_size_get(extent);
extent_dalloc_wrapper(tsdn, arena,
r_extent_hooks, extent);
if (config_stats) {
/* Update stats accordingly. */
arena_stats_lock(tsdn, &arena->stats);
arena_stats_add_u64(tsdn, &arena->stats,
&arena->decay_dirty.stats->nmadvise, 1);
arena_stats_add_u64(tsdn, &arena->stats,
&arena->decay_dirty.stats->purged, extent_size >> LG_PAGE);
arena_stats_sub_zu(tsdn, &arena->stats, &arena->stats.mapped,
extent_size);
arena_stats_unlock(tsdn, &arena->stats);
}
}
JEMALLOC_ALWAYS_INLINE void *
arena_malloc(tsdn_t *tsdn, arena_t *arena, size_t size, szind_t ind, bool zero,
tcache_t *tcache, bool slow_path) {
assert(!tsdn_null(tsdn) || tcache == NULL);
if (likely(tcache != NULL)) {
if (likely(size <= SC_SMALL_MAXCLASS)) {
return tcache_alloc_small(tsdn_tsd(tsdn), arena,
tcache, size, ind, zero, slow_path);
}
if (likely(size <= tcache_maxclass)) {
return tcache_alloc_large(tsdn_tsd(tsdn), arena,
tcache, size, ind, zero, slow_path);
}
/* (size > tcache_maxclass) case falls through. */
assert(size > tcache_maxclass);
}
return arena_malloc_hard(tsdn, arena, size, ind, zero);
}
JEMALLOC_ALWAYS_INLINE arena_t *
arena_aalloc(tsdn_t *tsdn, const void *ptr) {
return extent_arena_get(iealloc(tsdn, ptr));
}
JEMALLOC_ALWAYS_INLINE size_t
arena_salloc(tsdn_t *tsdn, const void *ptr) {
assert(ptr != NULL);
rtree_ctx_t rtree_ctx_fallback;
rtree_ctx_t *rtree_ctx = tsdn_rtree_ctx(tsdn, &rtree_ctx_fallback);
szind_t szind = rtree_szind_read(tsdn, &extents_rtree, rtree_ctx,
(uintptr_t)ptr, true);
assert(szind != SC_NSIZES);
return sz_index2size(szind);
}
JEMALLOC_ALWAYS_INLINE size_t
arena_vsalloc(tsdn_t *tsdn, const void *ptr) {
/*
* Return 0 if ptr is not within an extent managed by jemalloc. This
* function has two extra costs relative to isalloc():
* - The rtree calls cannot claim to be dependent lookups, which induces
* rtree lookup load dependencies.
* - The lookup may fail, so there is an extra branch to check for
* failure.
*/
rtree_ctx_t rtree_ctx_fallback;
rtree_ctx_t *rtree_ctx = tsdn_rtree_ctx(tsdn, &rtree_ctx_fallback);
extent_t *extent;
szind_t szind;
if (rtree_extent_szind_read(tsdn, &extents_rtree, rtree_ctx,
(uintptr_t)ptr, false, &extent, &szind)) {
return 0;
}
if (extent == NULL) {
return 0;
}
assert(extent_state_get(extent) == extent_state_active);
/* Only slab members should be looked up via interior pointers. */
assert(extent_addr_get(extent) == ptr || extent_slab_get(extent));
assert(szind != SC_NSIZES);
return sz_index2size(szind);
}
static inline void
arena_dalloc_large_no_tcache(tsdn_t *tsdn, void *ptr, szind_t szind) {
if (config_prof && unlikely(szind < SC_NBINS)) {
arena_dalloc_promoted(tsdn, ptr, NULL, true);
} else {
extent_t *extent = iealloc(tsdn, ptr);
large_dalloc(tsdn, extent);
}
}
static inline void
arena_dalloc_no_tcache(tsdn_t *tsdn, void *ptr) {
assert(ptr != NULL);
rtree_ctx_t rtree_ctx_fallback;
rtree_ctx_t *rtree_ctx = tsdn_rtree_ctx(tsdn, &rtree_ctx_fallback);
szind_t szind;
bool slab;
rtree_szind_slab_read(tsdn, &extents_rtree, rtree_ctx, (uintptr_t)ptr,
true, &szind, &slab);
if (config_debug) {
extent_t *extent = rtree_extent_read(tsdn, &extents_rtree,
rtree_ctx, (uintptr_t)ptr, true);
assert(szind == extent_szind_get(extent));
assert(szind < SC_NSIZES);
assert(slab == extent_slab_get(extent));
}
if (likely(slab)) {
/* Small allocation. */
arena_dalloc_small(tsdn, ptr);
} else {
arena_dalloc_large_no_tcache(tsdn, ptr, szind);
}
}
JEMALLOC_ALWAYS_INLINE void
arena_dalloc_large(tsdn_t *tsdn, void *ptr, tcache_t *tcache, szind_t szind,
bool slow_path) {
if (szind < nhbins) {
if (config_prof && unlikely(szind < SC_NBINS)) {
arena_dalloc_promoted(tsdn, ptr, tcache, slow_path);
} else {
tcache_dalloc_large(tsdn_tsd(tsdn), tcache, ptr, szind,
slow_path);
}
} else {
extent_t *extent = iealloc(tsdn, ptr);
large_dalloc(tsdn, extent);
}
}
JEMALLOC_ALWAYS_INLINE void
arena_dalloc(tsdn_t *tsdn, void *ptr, tcache_t *tcache,
alloc_ctx_t *alloc_ctx, bool slow_path) {
assert(!tsdn_null(tsdn) || tcache == NULL);
assert(ptr != NULL);
if (unlikely(tcache == NULL)) {
arena_dalloc_no_tcache(tsdn, ptr);
return;
}
szind_t szind;
bool slab;
rtree_ctx_t *rtree_ctx;
if (alloc_ctx != NULL) {
szind = alloc_ctx->szind;
slab = alloc_ctx->slab;
assert(szind != SC_NSIZES);
} else {
rtree_ctx = tsd_rtree_ctx(tsdn_tsd(tsdn));
rtree_szind_slab_read(tsdn, &extents_rtree, rtree_ctx,
(uintptr_t)ptr, true, &szind, &slab);
}
if (config_debug) {
rtree_ctx = tsd_rtree_ctx(tsdn_tsd(tsdn));
extent_t *extent = rtree_extent_read(tsdn, &extents_rtree,
rtree_ctx, (uintptr_t)ptr, true);
assert(szind == extent_szind_get(extent));
assert(szind < SC_NSIZES);
assert(slab == extent_slab_get(extent));
}
if (likely(slab)) {
/* Small allocation. */
tcache_dalloc_small(tsdn_tsd(tsdn), tcache, ptr, szind,
slow_path);
} else {
arena_dalloc_large(tsdn, ptr, tcache, szind, slow_path);
}
}
static inline void
arena_sdalloc_no_tcache(tsdn_t *tsdn, void *ptr, size_t size) {
assert(ptr != NULL);
assert(size <= SC_LARGE_MAXCLASS);
szind_t szind;
bool slab;
if (!config_prof || !opt_prof) {
/*
* There is no risk of being confused by a promoted sampled
* object, so base szind and slab on the given size.
*/
szind = sz_size2index(size);
slab = (szind < SC_NBINS);
}
if ((config_prof && opt_prof) || config_debug) {
rtree_ctx_t rtree_ctx_fallback;
rtree_ctx_t *rtree_ctx = tsdn_rtree_ctx(tsdn,
&rtree_ctx_fallback);
rtree_szind_slab_read(tsdn, &extents_rtree, rtree_ctx,
(uintptr_t)ptr, true, &szind, &slab);
assert(szind == sz_size2index(size));
assert((config_prof && opt_prof) || slab == (szind < SC_NBINS));
if (config_debug) {
extent_t *extent = rtree_extent_read(tsdn,
&extents_rtree, rtree_ctx, (uintptr_t)ptr, true);
assert(szind == extent_szind_get(extent));
assert(slab == extent_slab_get(extent));
}
}
if (likely(slab)) {
/* Small allocation. */
arena_dalloc_small(tsdn, ptr);
} else {
arena_dalloc_large_no_tcache(tsdn, ptr, szind);
}
}
JEMALLOC_ALWAYS_INLINE void
arena_sdalloc(tsdn_t *tsdn, void *ptr, size_t size, tcache_t *tcache,
alloc_ctx_t *alloc_ctx, bool slow_path) {
assert(!tsdn_null(tsdn) || tcache == NULL);
assert(ptr != NULL);
assert(size <= SC_LARGE_MAXCLASS);
if (unlikely(tcache == NULL)) {
arena_sdalloc_no_tcache(tsdn, ptr, size);
return;
}
szind_t szind;
bool slab;
alloc_ctx_t local_ctx;
if (config_prof && opt_prof) {
if (alloc_ctx == NULL) {
/* Uncommon case and should be a static check. */
rtree_ctx_t rtree_ctx_fallback;
rtree_ctx_t *rtree_ctx = tsdn_rtree_ctx(tsdn,
&rtree_ctx_fallback);
rtree_szind_slab_read(tsdn, &extents_rtree, rtree_ctx,
(uintptr_t)ptr, true, &local_ctx.szind,
&local_ctx.slab);
assert(local_ctx.szind == sz_size2index(size));
alloc_ctx = &local_ctx;
}
slab = alloc_ctx->slab;
szind = alloc_ctx->szind;
} else {
/*
* There is no risk of being confused by a promoted sampled
* object, so base szind and slab on the given size.
*/
szind = sz_size2index(size);
slab = (szind < SC_NBINS);
}
if (config_debug) {
rtree_ctx_t *rtree_ctx = tsd_rtree_ctx(tsdn_tsd(tsdn));
rtree_szind_slab_read(tsdn, &extents_rtree, rtree_ctx,
(uintptr_t)ptr, true, &szind, &slab);
extent_t *extent = rtree_extent_read(tsdn,
&extents_rtree, rtree_ctx, (uintptr_t)ptr, true);
assert(szind == extent_szind_get(extent));
assert(slab == extent_slab_get(extent));
}
if (likely(slab)) {
/* Small allocation. */
tcache_dalloc_small(tsdn_tsd(tsdn), tcache, ptr, szind,
slow_path);
} else {
arena_dalloc_large(tsdn, ptr, tcache, szind, slow_path);
}
}
#endif /* JEMALLOC_INTERNAL_ARENA_INLINES_B_H */

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#ifndef JEMALLOC_INTERNAL_ARENA_STATS_H
#define JEMALLOC_INTERNAL_ARENA_STATS_H
#include "jemalloc/internal/atomic.h"
#include "jemalloc/internal/mutex.h"
#include "jemalloc/internal/mutex_prof.h"
#include "jemalloc/internal/sc.h"
JEMALLOC_DIAGNOSTIC_DISABLE_SPURIOUS
/*
* In those architectures that support 64-bit atomics, we use atomic updates for
* our 64-bit values. Otherwise, we use a plain uint64_t and synchronize
* externally.
*/
#ifdef JEMALLOC_ATOMIC_U64
typedef atomic_u64_t arena_stats_u64_t;
#else
/* Must hold the arena stats mutex while reading atomically. */
typedef uint64_t arena_stats_u64_t;
#endif
typedef struct arena_stats_large_s arena_stats_large_t;
struct arena_stats_large_s {
/*
* Total number of allocation/deallocation requests served directly by
* the arena.
*/
arena_stats_u64_t nmalloc;
arena_stats_u64_t ndalloc;
/*
* Number of allocation requests that correspond to this size class.
* This includes requests served by tcache, though tcache only
* periodically merges into this counter.
*/
arena_stats_u64_t nrequests; /* Partially derived. */
/*
* Number of tcache fills / flushes for large (similarly, periodically
* merged). Note that there is no large tcache batch-fill currently
* (i.e. only fill 1 at a time); however flush may be batched.
*/
arena_stats_u64_t nfills; /* Partially derived. */
arena_stats_u64_t nflushes; /* Partially derived. */
/* Current number of allocations of this size class. */
size_t curlextents; /* Derived. */
};
typedef struct arena_stats_decay_s arena_stats_decay_t;
struct arena_stats_decay_s {
/* Total number of purge sweeps. */
arena_stats_u64_t npurge;
/* Total number of madvise calls made. */
arena_stats_u64_t nmadvise;
/* Total number of pages purged. */
arena_stats_u64_t purged;
};
typedef struct arena_stats_extents_s arena_stats_extents_t;
struct arena_stats_extents_s {
/*
* Stats for a given index in the range [0, SC_NPSIZES] in an extents_t.
* We track both bytes and # of extents: two extents in the same bucket
* may have different sizes if adjacent size classes differ by more than
* a page, so bytes cannot always be derived from # of extents.
*/
atomic_zu_t ndirty;
atomic_zu_t dirty_bytes;
atomic_zu_t nmuzzy;
atomic_zu_t muzzy_bytes;
atomic_zu_t nretained;
atomic_zu_t retained_bytes;
};
/*
* Arena stats. Note that fields marked "derived" are not directly maintained
* within the arena code; rather their values are derived during stats merge
* requests.
*/
typedef struct arena_stats_s arena_stats_t;
struct arena_stats_s {
#ifndef JEMALLOC_ATOMIC_U64
malloc_mutex_t mtx;
#endif
/* Number of bytes currently mapped, excluding retained memory. */
atomic_zu_t mapped; /* Partially derived. */
/*
* Number of unused virtual memory bytes currently retained. Retained
* bytes are technically mapped (though always decommitted or purged),
* but they are excluded from the mapped statistic (above).
*/
atomic_zu_t retained; /* Derived. */
/* Number of extent_t structs allocated by base, but not being used. */
atomic_zu_t extent_avail;
arena_stats_decay_t decay_dirty;
arena_stats_decay_t decay_muzzy;
atomic_zu_t base; /* Derived. */
atomic_zu_t internal;
atomic_zu_t resident; /* Derived. */
atomic_zu_t metadata_thp;
atomic_zu_t allocated_large; /* Derived. */
arena_stats_u64_t nmalloc_large; /* Derived. */
arena_stats_u64_t ndalloc_large; /* Derived. */
arena_stats_u64_t nfills_large; /* Derived. */
arena_stats_u64_t nflushes_large; /* Derived. */
arena_stats_u64_t nrequests_large; /* Derived. */
/* VM space had to be leaked (undocumented). Normally 0. */
atomic_zu_t abandoned_vm;
/* Number of bytes cached in tcache associated with this arena. */
atomic_zu_t tcache_bytes; /* Derived. */
mutex_prof_data_t mutex_prof_data[mutex_prof_num_arena_mutexes];
/* One element for each large size class. */
arena_stats_large_t lstats[SC_NSIZES - SC_NBINS];
/* Arena uptime. */
nstime_t uptime;
};
static inline bool
arena_stats_init(tsdn_t *tsdn, arena_stats_t *arena_stats) {
if (config_debug) {
for (size_t i = 0; i < sizeof(arena_stats_t); i++) {
assert(((char *)arena_stats)[i] == 0);
}
}
#ifndef JEMALLOC_ATOMIC_U64
if (malloc_mutex_init(&arena_stats->mtx, "arena_stats",
WITNESS_RANK_ARENA_STATS, malloc_mutex_rank_exclusive)) {
return true;
}
#endif
/* Memory is zeroed, so there is no need to clear stats. */
return false;
}
static inline void
arena_stats_lock(tsdn_t *tsdn, arena_stats_t *arena_stats) {
#ifndef JEMALLOC_ATOMIC_U64
malloc_mutex_lock(tsdn, &arena_stats->mtx);
#endif
}
static inline void
arena_stats_unlock(tsdn_t *tsdn, arena_stats_t *arena_stats) {
#ifndef JEMALLOC_ATOMIC_U64
malloc_mutex_unlock(tsdn, &arena_stats->mtx);
#endif
}
static inline uint64_t
arena_stats_read_u64(tsdn_t *tsdn, arena_stats_t *arena_stats,
arena_stats_u64_t *p) {
#ifdef JEMALLOC_ATOMIC_U64
return atomic_load_u64(p, ATOMIC_RELAXED);
#else
malloc_mutex_assert_owner(tsdn, &arena_stats->mtx);
return *p;
#endif
}
static inline void
arena_stats_add_u64(tsdn_t *tsdn, arena_stats_t *arena_stats,
arena_stats_u64_t *p, uint64_t x) {
#ifdef JEMALLOC_ATOMIC_U64
atomic_fetch_add_u64(p, x, ATOMIC_RELAXED);
#else
malloc_mutex_assert_owner(tsdn, &arena_stats->mtx);
*p += x;
#endif
}
static inline void
arena_stats_sub_u64(tsdn_t *tsdn, arena_stats_t *arena_stats,
arena_stats_u64_t *p, uint64_t x) {
#ifdef JEMALLOC_ATOMIC_U64
uint64_t r = atomic_fetch_sub_u64(p, x, ATOMIC_RELAXED);
assert(r - x <= r);
#else
malloc_mutex_assert_owner(tsdn, &arena_stats->mtx);
*p -= x;
assert(*p + x >= *p);
#endif
}
/*
* Non-atomically sets *dst += src. *dst needs external synchronization.
* This lets us avoid the cost of a fetch_add when its unnecessary (note that
* the types here are atomic).
*/
static inline void
arena_stats_accum_u64(arena_stats_u64_t *dst, uint64_t src) {
#ifdef JEMALLOC_ATOMIC_U64
uint64_t cur_dst = atomic_load_u64(dst, ATOMIC_RELAXED);
atomic_store_u64(dst, src + cur_dst, ATOMIC_RELAXED);
#else
*dst += src;
#endif
}
static inline size_t
arena_stats_read_zu(tsdn_t *tsdn, arena_stats_t *arena_stats,
atomic_zu_t *p) {
#ifdef JEMALLOC_ATOMIC_U64
return atomic_load_zu(p, ATOMIC_RELAXED);
#else
malloc_mutex_assert_owner(tsdn, &arena_stats->mtx);
return atomic_load_zu(p, ATOMIC_RELAXED);
#endif
}
static inline void
arena_stats_add_zu(tsdn_t *tsdn, arena_stats_t *arena_stats,
atomic_zu_t *p, size_t x) {
#ifdef JEMALLOC_ATOMIC_U64
atomic_fetch_add_zu(p, x, ATOMIC_RELAXED);
#else
malloc_mutex_assert_owner(tsdn, &arena_stats->mtx);
size_t cur = atomic_load_zu(p, ATOMIC_RELAXED);
atomic_store_zu(p, cur + x, ATOMIC_RELAXED);
#endif
}
static inline void
arena_stats_sub_zu(tsdn_t *tsdn, arena_stats_t *arena_stats,
atomic_zu_t *p, size_t x) {
#ifdef JEMALLOC_ATOMIC_U64
size_t r = atomic_fetch_sub_zu(p, x, ATOMIC_RELAXED);
assert(r - x <= r);
#else
malloc_mutex_assert_owner(tsdn, &arena_stats->mtx);
size_t cur = atomic_load_zu(p, ATOMIC_RELAXED);
atomic_store_zu(p, cur - x, ATOMIC_RELAXED);
#endif
}
/* Like the _u64 variant, needs an externally synchronized *dst. */
static inline void
arena_stats_accum_zu(atomic_zu_t *dst, size_t src) {
size_t cur_dst = atomic_load_zu(dst, ATOMIC_RELAXED);
atomic_store_zu(dst, src + cur_dst, ATOMIC_RELAXED);
}
static inline void
arena_stats_large_flush_nrequests_add(tsdn_t *tsdn, arena_stats_t *arena_stats,
szind_t szind, uint64_t nrequests) {
arena_stats_lock(tsdn, arena_stats);
arena_stats_large_t *lstats = &arena_stats->lstats[szind - SC_NBINS];
arena_stats_add_u64(tsdn, arena_stats, &lstats->nrequests, nrequests);
arena_stats_add_u64(tsdn, arena_stats, &lstats->nflushes, 1);
arena_stats_unlock(tsdn, arena_stats);
}
static inline void
arena_stats_mapped_add(tsdn_t *tsdn, arena_stats_t *arena_stats, size_t size) {
arena_stats_lock(tsdn, arena_stats);
arena_stats_add_zu(tsdn, arena_stats, &arena_stats->mapped, size);
arena_stats_unlock(tsdn, arena_stats);
}
#endif /* JEMALLOC_INTERNAL_ARENA_STATS_H */

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#ifndef JEMALLOC_INTERNAL_ARENA_STRUCTS_A_H
#define JEMALLOC_INTERNAL_ARENA_STRUCTS_A_H
#include "jemalloc/internal/bitmap.h"
struct arena_slab_data_s {
/* Per region allocated/deallocated bitmap. */
bitmap_t bitmap[BITMAP_GROUPS_MAX];
};
#endif /* JEMALLOC_INTERNAL_ARENA_STRUCTS_A_H */

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#ifndef JEMALLOC_INTERNAL_ARENA_STRUCTS_B_H
#define JEMALLOC_INTERNAL_ARENA_STRUCTS_B_H
#include "jemalloc/internal/arena_stats.h"
#include "jemalloc/internal/atomic.h"
#include "jemalloc/internal/bin.h"
#include "jemalloc/internal/bitmap.h"
#include "jemalloc/internal/extent_dss.h"
#include "jemalloc/internal/jemalloc_internal_types.h"
#include "jemalloc/internal/mutex.h"
#include "jemalloc/internal/nstime.h"
#include "jemalloc/internal/ql.h"
#include "jemalloc/internal/sc.h"
#include "jemalloc/internal/smoothstep.h"
#include "jemalloc/internal/ticker.h"
struct arena_decay_s {
/* Synchronizes all non-atomic fields. */
malloc_mutex_t mtx;
/*
* True if a thread is currently purging the extents associated with
* this decay structure.
*/
bool purging;
/*
* Approximate time in milliseconds from the creation of a set of unused
* dirty pages until an equivalent set of unused dirty pages is purged
* and/or reused.
*/
atomic_zd_t time_ms;
/* time / SMOOTHSTEP_NSTEPS. */
nstime_t interval;
/*
* Time at which the current decay interval logically started. We do
* not actually advance to a new epoch until sometime after it starts
* because of scheduling and computation delays, and it is even possible
* to completely skip epochs. In all cases, during epoch advancement we
* merge all relevant activity into the most recently recorded epoch.
*/
nstime_t epoch;
/* Deadline randomness generator. */
uint64_t jitter_state;
/*
* Deadline for current epoch. This is the sum of interval and per
* epoch jitter which is a uniform random variable in [0..interval).
* Epochs always advance by precise multiples of interval, but we
* randomize the deadline to reduce the likelihood of arenas purging in
* lockstep.
*/
nstime_t deadline;
/*
* Number of unpurged pages at beginning of current epoch. During epoch
* advancement we use the delta between arena->decay_*.nunpurged and
* extents_npages_get(&arena->extents_*) to determine how many dirty
* pages, if any, were generated.
*/
size_t nunpurged;
/*
* Trailing log of how many unused dirty pages were generated during
* each of the past SMOOTHSTEP_NSTEPS decay epochs, where the last
* element is the most recent epoch. Corresponding epoch times are
* relative to epoch.
*/
size_t backlog[SMOOTHSTEP_NSTEPS];
/*
* Pointer to associated stats. These stats are embedded directly in
* the arena's stats due to how stats structures are shared between the
* arena and ctl code.
*
* Synchronization: Same as associated arena's stats field. */
arena_stats_decay_t *stats;
/* Peak number of pages in associated extents. Used for debug only. */
uint64_t ceil_npages;
};
struct arena_s {
/*
* Number of threads currently assigned to this arena. Each thread has
* two distinct assignments, one for application-serving allocation, and
* the other for internal metadata allocation. Internal metadata must
* not be allocated from arenas explicitly created via the arenas.create
* mallctl, because the arena.<i>.reset mallctl indiscriminately
* discards all allocations for the affected arena.
*
* 0: Application allocation.
* 1: Internal metadata allocation.
*
* Synchronization: atomic.
*/
atomic_u_t nthreads[2];
/* Next bin shard for binding new threads. Synchronization: atomic. */
atomic_u_t binshard_next;
/*
* When percpu_arena is enabled, to amortize the cost of reading /
* updating the current CPU id, track the most recent thread accessing
* this arena, and only read CPU if there is a mismatch.
*/
tsdn_t *last_thd;
/* Synchronization: internal. */
arena_stats_t stats;
/*
* Lists of tcaches and cache_bin_array_descriptors for extant threads
* associated with this arena. Stats from these are merged
* incrementally, and at exit if opt_stats_print is enabled.
*
* Synchronization: tcache_ql_mtx.
*/
ql_head(tcache_t) tcache_ql;
ql_head(cache_bin_array_descriptor_t) cache_bin_array_descriptor_ql;
malloc_mutex_t tcache_ql_mtx;
/* Synchronization: internal. */
prof_accum_t prof_accum;
/*
* PRNG state for cache index randomization of large allocation base
* pointers.
*
* Synchronization: atomic.
*/
atomic_zu_t offset_state;
/*
* Extent serial number generator state.
*
* Synchronization: atomic.
*/
atomic_zu_t extent_sn_next;
/*
* Represents a dss_prec_t, but atomically.
*
* Synchronization: atomic.
*/
atomic_u_t dss_prec;
/*
* Number of pages in active extents.
*
* Synchronization: atomic.
*/
atomic_zu_t nactive;
/*
* Extant large allocations.
*
* Synchronization: large_mtx.
*/
extent_list_t large;
/* Synchronizes all large allocation/update/deallocation. */
malloc_mutex_t large_mtx;
/*
* Collections of extents that were previously allocated. These are
* used when allocating extents, in an attempt to re-use address space.
*
* Synchronization: internal.
*/
extents_t extents_dirty;
extents_t extents_muzzy;
extents_t extents_retained;
/*
* Decay-based purging state, responsible for scheduling extent state
* transitions.
*
* Synchronization: internal.
*/
arena_decay_t decay_dirty; /* dirty --> muzzy */
arena_decay_t decay_muzzy; /* muzzy --> retained */
/*
* Next extent size class in a growing series to use when satisfying a
* request via the extent hooks (only if opt_retain). This limits the
* number of disjoint virtual memory ranges so that extent merging can
* be effective even if multiple arenas' extent allocation requests are
* highly interleaved.
*
* retain_grow_limit is the max allowed size ind to expand (unless the
* required size is greater). Default is no limit, and controlled
* through mallctl only.
*
* Synchronization: extent_grow_mtx
*/
pszind_t extent_grow_next;
pszind_t retain_grow_limit;
malloc_mutex_t extent_grow_mtx;
/*
* Available extent structures that were allocated via
* base_alloc_extent().
*
* Synchronization: extent_avail_mtx.
*/
extent_tree_t extent_avail;
atomic_zu_t extent_avail_cnt;
malloc_mutex_t extent_avail_mtx;
/*
* bins is used to store heaps of free regions.
*
* Synchronization: internal.
*/
bins_t bins[SC_NBINS];
/*
* Base allocator, from which arena metadata are allocated.
*
* Synchronization: internal.
*/
base_t *base;
/* Used to determine uptime. Read-only after initialization. */
nstime_t create_time;
};
/* Used in conjunction with tsd for fast arena-related context lookup. */
struct arena_tdata_s {
ticker_t decay_ticker;
};
/* Used to pass rtree lookup context down the path. */
struct alloc_ctx_s {
szind_t szind;
bool slab;
};
#endif /* JEMALLOC_INTERNAL_ARENA_STRUCTS_B_H */

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#ifndef JEMALLOC_INTERNAL_ARENA_TYPES_H
#define JEMALLOC_INTERNAL_ARENA_TYPES_H
#include "jemalloc/internal/sc.h"
/* Maximum number of regions in one slab. */
#define LG_SLAB_MAXREGS (LG_PAGE - SC_LG_TINY_MIN)
#define SLAB_MAXREGS (1U << LG_SLAB_MAXREGS)
/* Default decay times in milliseconds. */
#define DIRTY_DECAY_MS_DEFAULT ZD(10 * 1000)
#define MUZZY_DECAY_MS_DEFAULT (0)
/* Number of event ticks between time checks. */
#define DECAY_NTICKS_PER_UPDATE 1000
typedef struct arena_slab_data_s arena_slab_data_t;
typedef struct arena_decay_s arena_decay_t;
typedef struct arena_s arena_t;
typedef struct arena_tdata_s arena_tdata_t;
typedef struct alloc_ctx_s alloc_ctx_t;
typedef enum {
percpu_arena_mode_names_base = 0, /* Used for options processing. */
/*
* *_uninit are used only during bootstrapping, and must correspond
* to initialized variant plus percpu_arena_mode_enabled_base.
*/
percpu_arena_uninit = 0,
per_phycpu_arena_uninit = 1,
/* All non-disabled modes must come after percpu_arena_disabled. */
percpu_arena_disabled = 2,
percpu_arena_mode_names_limit = 3, /* Used for options processing. */
percpu_arena_mode_enabled_base = 3,
percpu_arena = 3,
per_phycpu_arena = 4 /* Hyper threads share arena. */
} percpu_arena_mode_t;
#define PERCPU_ARENA_ENABLED(m) ((m) >= percpu_arena_mode_enabled_base)
#define PERCPU_ARENA_DEFAULT percpu_arena_disabled
/*
* When allocation_size >= oversize_threshold, use the dedicated huge arena
* (unless have explicitly spicified arena index). 0 disables the feature.
*/
#define OVERSIZE_THRESHOLD_DEFAULT (8 << 20)
#endif /* JEMALLOC_INTERNAL_ARENA_TYPES_H */

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#include "jemalloc/internal/malloc_io.h"
#include "jemalloc/internal/util.h"
/*
* Define a custom assert() in order to reduce the chances of deadlock during
* assertion failure.
*/
#ifndef assert
#define assert(e) do { \
if (unlikely(config_debug && !(e))) { \
malloc_printf( \
"<jemalloc>: %s:%d: Failed assertion: \"%s\"\n", \
__FILE__, __LINE__, #e); \
abort(); \
} \
} while (0)
#endif
#ifndef not_reached
#define not_reached() do { \
if (config_debug) { \
malloc_printf( \
"<jemalloc>: %s:%d: Unreachable code reached\n", \
__FILE__, __LINE__); \
abort(); \
} \
unreachable(); \
} while (0)
#endif
#ifndef not_implemented
#define not_implemented() do { \
if (config_debug) { \
malloc_printf("<jemalloc>: %s:%d: Not implemented\n", \
__FILE__, __LINE__); \
abort(); \
} \
} while (0)
#endif
#ifndef assert_not_implemented
#define assert_not_implemented(e) do { \
if (unlikely(config_debug && !(e))) { \
not_implemented(); \
} \
} while (0)
#endif
/* Use to assert a particular configuration, e.g., cassert(config_debug). */
#ifndef cassert
#define cassert(c) do { \
if (unlikely(!(c))) { \
not_reached(); \
} \
} while (0)
#endif

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#ifndef JEMALLOC_INTERNAL_ATOMIC_H
#define JEMALLOC_INTERNAL_ATOMIC_H
#define ATOMIC_INLINE JEMALLOC_ALWAYS_INLINE
#define JEMALLOC_U8_ATOMICS
#if defined(JEMALLOC_GCC_ATOMIC_ATOMICS)
# include "jemalloc/internal/atomic_gcc_atomic.h"
# if !defined(JEMALLOC_GCC_U8_ATOMIC_ATOMICS)
# undef JEMALLOC_U8_ATOMICS
# endif
#elif defined(JEMALLOC_GCC_SYNC_ATOMICS)
# include "jemalloc/internal/atomic_gcc_sync.h"
# if !defined(JEMALLOC_GCC_U8_SYNC_ATOMICS)
# undef JEMALLOC_U8_ATOMICS
# endif
#elif defined(_MSC_VER)
# include "jemalloc/internal/atomic_msvc.h"
#elif defined(JEMALLOC_C11_ATOMICS)
# include "jemalloc/internal/atomic_c11.h"
#else
# error "Don't have atomics implemented on this platform."
#endif
/*
* This header gives more or less a backport of C11 atomics. The user can write
* JEMALLOC_GENERATE_ATOMICS(type, short_type, lg_sizeof_type); to generate
* counterparts of the C11 atomic functions for type, as so:
* JEMALLOC_GENERATE_ATOMICS(int *, pi, 3);
* and then write things like:
* int *some_ptr;
* atomic_pi_t atomic_ptr_to_int;
* atomic_store_pi(&atomic_ptr_to_int, some_ptr, ATOMIC_RELAXED);
* int *prev_value = atomic_exchange_pi(&ptr_to_int, NULL, ATOMIC_ACQ_REL);
* assert(some_ptr == prev_value);
* and expect things to work in the obvious way.
*
* Also included (with naming differences to avoid conflicts with the standard
* library):
* atomic_fence(atomic_memory_order_t) (mimics C11's atomic_thread_fence).
* ATOMIC_INIT (mimics C11's ATOMIC_VAR_INIT).
*/
/*
* Pure convenience, so that we don't have to type "atomic_memory_order_"
* quite so often.
*/
#define ATOMIC_RELAXED atomic_memory_order_relaxed
#define ATOMIC_ACQUIRE atomic_memory_order_acquire
#define ATOMIC_RELEASE atomic_memory_order_release
#define ATOMIC_ACQ_REL atomic_memory_order_acq_rel
#define ATOMIC_SEQ_CST atomic_memory_order_seq_cst
/*
* Not all platforms have 64-bit atomics. If we do, this #define exposes that
* fact.
*/
#if (LG_SIZEOF_PTR == 3 || LG_SIZEOF_INT == 3)
# define JEMALLOC_ATOMIC_U64
#endif
JEMALLOC_GENERATE_ATOMICS(void *, p, LG_SIZEOF_PTR)
/*
* There's no actual guarantee that sizeof(bool) == 1, but it's true on the only
* platform that actually needs to know the size, MSVC.
*/
JEMALLOC_GENERATE_ATOMICS(bool, b, 0)
JEMALLOC_GENERATE_INT_ATOMICS(unsigned, u, LG_SIZEOF_INT)
JEMALLOC_GENERATE_INT_ATOMICS(size_t, zu, LG_SIZEOF_PTR)
JEMALLOC_GENERATE_INT_ATOMICS(ssize_t, zd, LG_SIZEOF_PTR)
JEMALLOC_GENERATE_INT_ATOMICS(uint8_t, u8, 0)
JEMALLOC_GENERATE_INT_ATOMICS(uint32_t, u32, 2)
#ifdef JEMALLOC_ATOMIC_U64
JEMALLOC_GENERATE_INT_ATOMICS(uint64_t, u64, 3)
#endif
#undef ATOMIC_INLINE
#endif /* JEMALLOC_INTERNAL_ATOMIC_H */

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#ifndef JEMALLOC_INTERNAL_ATOMIC_C11_H
#define JEMALLOC_INTERNAL_ATOMIC_C11_H
#include <stdatomic.h>
#define ATOMIC_INIT(...) ATOMIC_VAR_INIT(__VA_ARGS__)
#define atomic_memory_order_t memory_order
#define atomic_memory_order_relaxed memory_order_relaxed
#define atomic_memory_order_acquire memory_order_acquire
#define atomic_memory_order_release memory_order_release
#define atomic_memory_order_acq_rel memory_order_acq_rel
#define atomic_memory_order_seq_cst memory_order_seq_cst
#define atomic_fence atomic_thread_fence
#define JEMALLOC_GENERATE_ATOMICS(type, short_type, \
/* unused */ lg_size) \
typedef _Atomic(type) atomic_##short_type##_t; \
\
ATOMIC_INLINE type \
atomic_load_##short_type(const atomic_##short_type##_t *a, \
atomic_memory_order_t mo) { \
/* \
* A strict interpretation of the C standard prevents \
* atomic_load from taking a const argument, but it's \
* convenient for our purposes. This cast is a workaround. \
*/ \
atomic_##short_type##_t* a_nonconst = \
(atomic_##short_type##_t*)a; \
return atomic_load_explicit(a_nonconst, mo); \
} \
\
ATOMIC_INLINE void \
atomic_store_##short_type(atomic_##short_type##_t *a, \
type val, atomic_memory_order_t mo) { \
atomic_store_explicit(a, val, mo); \
} \
\
ATOMIC_INLINE type \
atomic_exchange_##short_type(atomic_##short_type##_t *a, type val, \
atomic_memory_order_t mo) { \
return atomic_exchange_explicit(a, val, mo); \
} \
\
ATOMIC_INLINE bool \
atomic_compare_exchange_weak_##short_type(atomic_##short_type##_t *a, \
type *expected, type desired, atomic_memory_order_t success_mo, \
atomic_memory_order_t failure_mo) { \
return atomic_compare_exchange_weak_explicit(a, expected, \
desired, success_mo, failure_mo); \
} \
\
ATOMIC_INLINE bool \
atomic_compare_exchange_strong_##short_type(atomic_##short_type##_t *a, \
type *expected, type desired, atomic_memory_order_t success_mo, \
atomic_memory_order_t failure_mo) { \
return atomic_compare_exchange_strong_explicit(a, expected, \
desired, success_mo, failure_mo); \
}
/*
* Integral types have some special operations available that non-integral ones
* lack.
*/
#define JEMALLOC_GENERATE_INT_ATOMICS(type, short_type, \
/* unused */ lg_size) \
JEMALLOC_GENERATE_ATOMICS(type, short_type, /* unused */ lg_size) \
\
ATOMIC_INLINE type \
atomic_fetch_add_##short_type(atomic_##short_type##_t *a, \
type val, atomic_memory_order_t mo) { \
return atomic_fetch_add_explicit(a, val, mo); \
} \
\
ATOMIC_INLINE type \
atomic_fetch_sub_##short_type(atomic_##short_type##_t *a, \
type val, atomic_memory_order_t mo) { \
return atomic_fetch_sub_explicit(a, val, mo); \
} \
ATOMIC_INLINE type \
atomic_fetch_and_##short_type(atomic_##short_type##_t *a, \
type val, atomic_memory_order_t mo) { \
return atomic_fetch_and_explicit(a, val, mo); \
} \
ATOMIC_INLINE type \
atomic_fetch_or_##short_type(atomic_##short_type##_t *a, \
type val, atomic_memory_order_t mo) { \
return atomic_fetch_or_explicit(a, val, mo); \
} \
ATOMIC_INLINE type \
atomic_fetch_xor_##short_type(atomic_##short_type##_t *a, \
type val, atomic_memory_order_t mo) { \
return atomic_fetch_xor_explicit(a, val, mo); \
}
#endif /* JEMALLOC_INTERNAL_ATOMIC_C11_H */

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#ifndef JEMALLOC_INTERNAL_ATOMIC_GCC_ATOMIC_H
#define JEMALLOC_INTERNAL_ATOMIC_GCC_ATOMIC_H
#include "jemalloc/internal/assert.h"
#define ATOMIC_INIT(...) {__VA_ARGS__}
typedef enum {
atomic_memory_order_relaxed,
atomic_memory_order_acquire,
atomic_memory_order_release,
atomic_memory_order_acq_rel,
atomic_memory_order_seq_cst
} atomic_memory_order_t;
ATOMIC_INLINE int
atomic_enum_to_builtin(atomic_memory_order_t mo) {
switch (mo) {
case atomic_memory_order_relaxed:
return __ATOMIC_RELAXED;
case atomic_memory_order_acquire:
return __ATOMIC_ACQUIRE;
case atomic_memory_order_release:
return __ATOMIC_RELEASE;
case atomic_memory_order_acq_rel:
return __ATOMIC_ACQ_REL;
case atomic_memory_order_seq_cst:
return __ATOMIC_SEQ_CST;
}
/* Can't happen; the switch is exhaustive. */
not_reached();
}
ATOMIC_INLINE void
atomic_fence(atomic_memory_order_t mo) {
__atomic_thread_fence(atomic_enum_to_builtin(mo));
}
#define JEMALLOC_GENERATE_ATOMICS(type, short_type, \
/* unused */ lg_size) \
typedef struct { \
type repr; \
} atomic_##short_type##_t; \
\
ATOMIC_INLINE type \
atomic_load_##short_type(const atomic_##short_type##_t *a, \
atomic_memory_order_t mo) { \
type result; \
__atomic_load(&a->repr, &result, atomic_enum_to_builtin(mo)); \
return result; \
} \
\
ATOMIC_INLINE void \
atomic_store_##short_type(atomic_##short_type##_t *a, type val, \
atomic_memory_order_t mo) { \
__atomic_store(&a->repr, &val, atomic_enum_to_builtin(mo)); \
} \
\
ATOMIC_INLINE type \
atomic_exchange_##short_type(atomic_##short_type##_t *a, type val, \
atomic_memory_order_t mo) { \
type result; \
__atomic_exchange(&a->repr, &val, &result, \
atomic_enum_to_builtin(mo)); \
return result; \
} \
\
ATOMIC_INLINE bool \
atomic_compare_exchange_weak_##short_type(atomic_##short_type##_t *a, \
UNUSED type *expected, type desired, \
atomic_memory_order_t success_mo, \
atomic_memory_order_t failure_mo) { \
return __atomic_compare_exchange(&a->repr, expected, &desired, \
true, atomic_enum_to_builtin(success_mo), \
atomic_enum_to_builtin(failure_mo)); \
} \
\
ATOMIC_INLINE bool \
atomic_compare_exchange_strong_##short_type(atomic_##short_type##_t *a, \
UNUSED type *expected, type desired, \
atomic_memory_order_t success_mo, \
atomic_memory_order_t failure_mo) { \
return __atomic_compare_exchange(&a->repr, expected, &desired, \
false, \
atomic_enum_to_builtin(success_mo), \
atomic_enum_to_builtin(failure_mo)); \
}
#define JEMALLOC_GENERATE_INT_ATOMICS(type, short_type, \
/* unused */ lg_size) \
JEMALLOC_GENERATE_ATOMICS(type, short_type, /* unused */ lg_size) \
\
ATOMIC_INLINE type \
atomic_fetch_add_##short_type(atomic_##short_type##_t *a, type val, \
atomic_memory_order_t mo) { \
return __atomic_fetch_add(&a->repr, val, \
atomic_enum_to_builtin(mo)); \
} \
\
ATOMIC_INLINE type \
atomic_fetch_sub_##short_type(atomic_##short_type##_t *a, type val, \
atomic_memory_order_t mo) { \
return __atomic_fetch_sub(&a->repr, val, \
atomic_enum_to_builtin(mo)); \
} \
\
ATOMIC_INLINE type \
atomic_fetch_and_##short_type(atomic_##short_type##_t *a, type val, \
atomic_memory_order_t mo) { \
return __atomic_fetch_and(&a->repr, val, \
atomic_enum_to_builtin(mo)); \
} \
\
ATOMIC_INLINE type \
atomic_fetch_or_##short_type(atomic_##short_type##_t *a, type val, \
atomic_memory_order_t mo) { \
return __atomic_fetch_or(&a->repr, val, \
atomic_enum_to_builtin(mo)); \
} \
\
ATOMIC_INLINE type \
atomic_fetch_xor_##short_type(atomic_##short_type##_t *a, type val, \
atomic_memory_order_t mo) { \
return __atomic_fetch_xor(&a->repr, val, \
atomic_enum_to_builtin(mo)); \
}
#endif /* JEMALLOC_INTERNAL_ATOMIC_GCC_ATOMIC_H */

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#ifndef JEMALLOC_INTERNAL_ATOMIC_GCC_SYNC_H
#define JEMALLOC_INTERNAL_ATOMIC_GCC_SYNC_H
#define ATOMIC_INIT(...) {__VA_ARGS__}
typedef enum {
atomic_memory_order_relaxed,
atomic_memory_order_acquire,
atomic_memory_order_release,
atomic_memory_order_acq_rel,
atomic_memory_order_seq_cst
} atomic_memory_order_t;
ATOMIC_INLINE void
atomic_fence(atomic_memory_order_t mo) {
/* Easy cases first: no barrier, and full barrier. */
if (mo == atomic_memory_order_relaxed) {
asm volatile("" ::: "memory");
return;
}
if (mo == atomic_memory_order_seq_cst) {
asm volatile("" ::: "memory");
__sync_synchronize();
asm volatile("" ::: "memory");
return;
}
asm volatile("" ::: "memory");
# if defined(__i386__) || defined(__x86_64__)
/* This is implicit on x86. */
# elif defined(__ppc64__)
asm volatile("lwsync");
# elif defined(__ppc__)
asm volatile("sync");
# elif defined(__sparc__) && defined(__arch64__)
if (mo == atomic_memory_order_acquire) {
asm volatile("membar #LoadLoad | #LoadStore");
} else if (mo == atomic_memory_order_release) {
asm volatile("membar #LoadStore | #StoreStore");
} else {
asm volatile("membar #LoadLoad | #LoadStore | #StoreStore");
}
# else
__sync_synchronize();
# endif
asm volatile("" ::: "memory");
}
/*
* A correct implementation of seq_cst loads and stores on weakly ordered
* architectures could do either of the following:
* 1. store() is weak-fence -> store -> strong fence, load() is load ->
* strong-fence.
* 2. store() is strong-fence -> store, load() is strong-fence -> load ->
* weak-fence.
* The tricky thing is, load() and store() above can be the load or store
* portions of a gcc __sync builtin, so we have to follow GCC's lead, which
* means going with strategy 2.
* On strongly ordered architectures, the natural strategy is to stick a strong
* fence after seq_cst stores, and have naked loads. So we want the strong
* fences in different places on different architectures.
* atomic_pre_sc_load_fence and atomic_post_sc_store_fence allow us to
* accomplish this.
*/
ATOMIC_INLINE void
atomic_pre_sc_load_fence() {
# if defined(__i386__) || defined(__x86_64__) || \
(defined(__sparc__) && defined(__arch64__))
atomic_fence(atomic_memory_order_relaxed);
# else
atomic_fence(atomic_memory_order_seq_cst);
# endif
}
ATOMIC_INLINE void
atomic_post_sc_store_fence() {
# if defined(__i386__) || defined(__x86_64__) || \
(defined(__sparc__) && defined(__arch64__))
atomic_fence(atomic_memory_order_seq_cst);
# else
atomic_fence(atomic_memory_order_relaxed);
# endif
}
#define JEMALLOC_GENERATE_ATOMICS(type, short_type, \
/* unused */ lg_size) \
typedef struct { \
type volatile repr; \
} atomic_##short_type##_t; \
\
ATOMIC_INLINE type \
atomic_load_##short_type(const atomic_##short_type##_t *a, \
atomic_memory_order_t mo) { \
if (mo == atomic_memory_order_seq_cst) { \
atomic_pre_sc_load_fence(); \
} \
type result = a->repr; \
if (mo != atomic_memory_order_relaxed) { \
atomic_fence(atomic_memory_order_acquire); \
} \
return result; \
} \
\
ATOMIC_INLINE void \
atomic_store_##short_type(atomic_##short_type##_t *a, \
type val, atomic_memory_order_t mo) { \
if (mo != atomic_memory_order_relaxed) { \
atomic_fence(atomic_memory_order_release); \
} \
a->repr = val; \
if (mo == atomic_memory_order_seq_cst) { \
atomic_post_sc_store_fence(); \
} \
} \
\
ATOMIC_INLINE type \
atomic_exchange_##short_type(atomic_##short_type##_t *a, type val, \
atomic_memory_order_t mo) { \
/* \
* Because of FreeBSD, we care about gcc 4.2, which doesn't have\
* an atomic exchange builtin. We fake it with a CAS loop. \
*/ \
while (true) { \
type old = a->repr; \
if (__sync_bool_compare_and_swap(&a->repr, old, val)) { \
return old; \
} \
} \
} \
\
ATOMIC_INLINE bool \
atomic_compare_exchange_weak_##short_type(atomic_##short_type##_t *a, \
type *expected, type desired, \
atomic_memory_order_t success_mo, \
atomic_memory_order_t failure_mo) { \
type prev = __sync_val_compare_and_swap(&a->repr, *expected, \
desired); \
if (prev == *expected) { \
return true; \
} else { \
*expected = prev; \
return false; \
} \
} \
ATOMIC_INLINE bool \
atomic_compare_exchange_strong_##short_type(atomic_##short_type##_t *a, \
type *expected, type desired, \
atomic_memory_order_t success_mo, \
atomic_memory_order_t failure_mo) { \
type prev = __sync_val_compare_and_swap(&a->repr, *expected, \
desired); \
if (prev == *expected) { \
return true; \
} else { \
*expected = prev; \
return false; \
} \
}
#define JEMALLOC_GENERATE_INT_ATOMICS(type, short_type, \
/* unused */ lg_size) \
JEMALLOC_GENERATE_ATOMICS(type, short_type, /* unused */ lg_size) \
\
ATOMIC_INLINE type \
atomic_fetch_add_##short_type(atomic_##short_type##_t *a, type val, \
atomic_memory_order_t mo) { \
return __sync_fetch_and_add(&a->repr, val); \
} \
\
ATOMIC_INLINE type \
atomic_fetch_sub_##short_type(atomic_##short_type##_t *a, type val, \
atomic_memory_order_t mo) { \
return __sync_fetch_and_sub(&a->repr, val); \
} \
\
ATOMIC_INLINE type \
atomic_fetch_and_##short_type(atomic_##short_type##_t *a, type val, \
atomic_memory_order_t mo) { \
return __sync_fetch_and_and(&a->repr, val); \
} \
\
ATOMIC_INLINE type \
atomic_fetch_or_##short_type(atomic_##short_type##_t *a, type val, \
atomic_memory_order_t mo) { \
return __sync_fetch_and_or(&a->repr, val); \
} \
\
ATOMIC_INLINE type \
atomic_fetch_xor_##short_type(atomic_##short_type##_t *a, type val, \
atomic_memory_order_t mo) { \
return __sync_fetch_and_xor(&a->repr, val); \
}
#endif /* JEMALLOC_INTERNAL_ATOMIC_GCC_SYNC_H */

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#ifndef JEMALLOC_INTERNAL_ATOMIC_MSVC_H
#define JEMALLOC_INTERNAL_ATOMIC_MSVC_H
#define ATOMIC_INIT(...) {__VA_ARGS__}
typedef enum {
atomic_memory_order_relaxed,
atomic_memory_order_acquire,
atomic_memory_order_release,
atomic_memory_order_acq_rel,
atomic_memory_order_seq_cst
} atomic_memory_order_t;
typedef char atomic_repr_0_t;
typedef short atomic_repr_1_t;
typedef long atomic_repr_2_t;
typedef __int64 atomic_repr_3_t;
ATOMIC_INLINE void
atomic_fence(atomic_memory_order_t mo) {
_ReadWriteBarrier();
# if defined(_M_ARM) || defined(_M_ARM64)
/* ARM needs a barrier for everything but relaxed. */
if (mo != atomic_memory_order_relaxed) {
MemoryBarrier();
}
# elif defined(_M_IX86) || defined (_M_X64)
/* x86 needs a barrier only for seq_cst. */
if (mo == atomic_memory_order_seq_cst) {
MemoryBarrier();
}
# else
# error "Don't know how to create atomics for this platform for MSVC."
# endif
_ReadWriteBarrier();
}
#define ATOMIC_INTERLOCKED_REPR(lg_size) atomic_repr_ ## lg_size ## _t
#define ATOMIC_CONCAT(a, b) ATOMIC_RAW_CONCAT(a, b)
#define ATOMIC_RAW_CONCAT(a, b) a ## b
#define ATOMIC_INTERLOCKED_NAME(base_name, lg_size) ATOMIC_CONCAT( \
base_name, ATOMIC_INTERLOCKED_SUFFIX(lg_size))
#define ATOMIC_INTERLOCKED_SUFFIX(lg_size) \
ATOMIC_CONCAT(ATOMIC_INTERLOCKED_SUFFIX_, lg_size)
#define ATOMIC_INTERLOCKED_SUFFIX_0 8
#define ATOMIC_INTERLOCKED_SUFFIX_1 16
#define ATOMIC_INTERLOCKED_SUFFIX_2
#define ATOMIC_INTERLOCKED_SUFFIX_3 64
#define JEMALLOC_GENERATE_ATOMICS(type, short_type, lg_size) \
typedef struct { \
ATOMIC_INTERLOCKED_REPR(lg_size) repr; \
} atomic_##short_type##_t; \
\
ATOMIC_INLINE type \
atomic_load_##short_type(const atomic_##short_type##_t *a, \
atomic_memory_order_t mo) { \
ATOMIC_INTERLOCKED_REPR(lg_size) ret = a->repr; \
if (mo != atomic_memory_order_relaxed) { \
atomic_fence(atomic_memory_order_acquire); \
} \
return (type) ret; \
} \
\
ATOMIC_INLINE void \
atomic_store_##short_type(atomic_##short_type##_t *a, \
type val, atomic_memory_order_t mo) { \
if (mo != atomic_memory_order_relaxed) { \
atomic_fence(atomic_memory_order_release); \
} \
a->repr = (ATOMIC_INTERLOCKED_REPR(lg_size)) val; \
if (mo == atomic_memory_order_seq_cst) { \
atomic_fence(atomic_memory_order_seq_cst); \
} \
} \
\
ATOMIC_INLINE type \
atomic_exchange_##short_type(atomic_##short_type##_t *a, type val, \
atomic_memory_order_t mo) { \
return (type)ATOMIC_INTERLOCKED_NAME(_InterlockedExchange, \
lg_size)(&a->repr, (ATOMIC_INTERLOCKED_REPR(lg_size))val); \
} \
\
ATOMIC_INLINE bool \
atomic_compare_exchange_weak_##short_type(atomic_##short_type##_t *a, \
type *expected, type desired, atomic_memory_order_t success_mo, \
atomic_memory_order_t failure_mo) { \
ATOMIC_INTERLOCKED_REPR(lg_size) e = \
(ATOMIC_INTERLOCKED_REPR(lg_size))*expected; \
ATOMIC_INTERLOCKED_REPR(lg_size) d = \
(ATOMIC_INTERLOCKED_REPR(lg_size))desired; \
ATOMIC_INTERLOCKED_REPR(lg_size) old = \
ATOMIC_INTERLOCKED_NAME(_InterlockedCompareExchange, \
lg_size)(&a->repr, d, e); \
if (old == e) { \
return true; \
} else { \
*expected = (type)old; \
return false; \
} \
} \
\
ATOMIC_INLINE bool \
atomic_compare_exchange_strong_##short_type(atomic_##short_type##_t *a, \
type *expected, type desired, atomic_memory_order_t success_mo, \
atomic_memory_order_t failure_mo) { \
/* We implement the weak version with strong semantics. */ \
return atomic_compare_exchange_weak_##short_type(a, expected, \
desired, success_mo, failure_mo); \
}
#define JEMALLOC_GENERATE_INT_ATOMICS(type, short_type, lg_size) \
JEMALLOC_GENERATE_ATOMICS(type, short_type, lg_size) \
\
ATOMIC_INLINE type \
atomic_fetch_add_##short_type(atomic_##short_type##_t *a, \
type val, atomic_memory_order_t mo) { \
return (type)ATOMIC_INTERLOCKED_NAME(_InterlockedExchangeAdd, \
lg_size)(&a->repr, (ATOMIC_INTERLOCKED_REPR(lg_size))val); \
} \
\
ATOMIC_INLINE type \
atomic_fetch_sub_##short_type(atomic_##short_type##_t *a, \
type val, atomic_memory_order_t mo) { \
/* \
* MSVC warns on negation of unsigned operands, but for us it \
* gives exactly the right semantics (MAX_TYPE + 1 - operand). \
*/ \
__pragma(warning(push)) \
__pragma(warning(disable: 4146)) \
return atomic_fetch_add_##short_type(a, -val, mo); \
__pragma(warning(pop)) \
} \
ATOMIC_INLINE type \
atomic_fetch_and_##short_type(atomic_##short_type##_t *a, \
type val, atomic_memory_order_t mo) { \
return (type)ATOMIC_INTERLOCKED_NAME(_InterlockedAnd, lg_size)( \
&a->repr, (ATOMIC_INTERLOCKED_REPR(lg_size))val); \
} \
ATOMIC_INLINE type \
atomic_fetch_or_##short_type(atomic_##short_type##_t *a, \
type val, atomic_memory_order_t mo) { \
return (type)ATOMIC_INTERLOCKED_NAME(_InterlockedOr, lg_size)( \
&a->repr, (ATOMIC_INTERLOCKED_REPR(lg_size))val); \
} \
ATOMIC_INLINE type \
atomic_fetch_xor_##short_type(atomic_##short_type##_t *a, \
type val, atomic_memory_order_t mo) { \
return (type)ATOMIC_INTERLOCKED_NAME(_InterlockedXor, lg_size)( \
&a->repr, (ATOMIC_INTERLOCKED_REPR(lg_size))val); \
}
#endif /* JEMALLOC_INTERNAL_ATOMIC_MSVC_H */

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#ifndef JEMALLOC_INTERNAL_BACKGROUND_THREAD_EXTERNS_H
#define JEMALLOC_INTERNAL_BACKGROUND_THREAD_EXTERNS_H
extern bool opt_background_thread;
extern size_t opt_max_background_threads;
extern malloc_mutex_t background_thread_lock;
extern atomic_b_t background_thread_enabled_state;
extern size_t n_background_threads;
extern size_t max_background_threads;
extern background_thread_info_t *background_thread_info;
bool background_thread_create(tsd_t *tsd, unsigned arena_ind);
bool background_threads_enable(tsd_t *tsd);
bool background_threads_disable(tsd_t *tsd);
void background_thread_interval_check(tsdn_t *tsdn, arena_t *arena,
arena_decay_t *decay, size_t npages_new);
void background_thread_prefork0(tsdn_t *tsdn);
void background_thread_prefork1(tsdn_t *tsdn);
void background_thread_postfork_parent(tsdn_t *tsdn);
void background_thread_postfork_child(tsdn_t *tsdn);
bool background_thread_stats_read(tsdn_t *tsdn,
background_thread_stats_t *stats);
void background_thread_ctl_init(tsdn_t *tsdn);
#ifdef JEMALLOC_PTHREAD_CREATE_WRAPPER
extern int pthread_create_wrapper(pthread_t *__restrict, const pthread_attr_t *,
void *(*)(void *), void *__restrict);
#endif
bool background_thread_boot0(void);
bool background_thread_boot1(tsdn_t *tsdn);
#endif /* JEMALLOC_INTERNAL_BACKGROUND_THREAD_EXTERNS_H */

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#ifndef JEMALLOC_INTERNAL_BACKGROUND_THREAD_INLINES_H
#define JEMALLOC_INTERNAL_BACKGROUND_THREAD_INLINES_H
JEMALLOC_ALWAYS_INLINE bool
background_thread_enabled(void) {
return atomic_load_b(&background_thread_enabled_state, ATOMIC_RELAXED);
}
JEMALLOC_ALWAYS_INLINE void
background_thread_enabled_set(tsdn_t *tsdn, bool state) {
malloc_mutex_assert_owner(tsdn, &background_thread_lock);
atomic_store_b(&background_thread_enabled_state, state, ATOMIC_RELAXED);
}
JEMALLOC_ALWAYS_INLINE background_thread_info_t *
arena_background_thread_info_get(arena_t *arena) {
unsigned arena_ind = arena_ind_get(arena);
return &background_thread_info[arena_ind % max_background_threads];
}
JEMALLOC_ALWAYS_INLINE background_thread_info_t *
background_thread_info_get(size_t ind) {
return &background_thread_info[ind % max_background_threads];
}
JEMALLOC_ALWAYS_INLINE uint64_t
background_thread_wakeup_time_get(background_thread_info_t *info) {
uint64_t next_wakeup = nstime_ns(&info->next_wakeup);
assert(atomic_load_b(&info->indefinite_sleep, ATOMIC_ACQUIRE) ==
(next_wakeup == BACKGROUND_THREAD_INDEFINITE_SLEEP));
return next_wakeup;
}
JEMALLOC_ALWAYS_INLINE void
background_thread_wakeup_time_set(tsdn_t *tsdn, background_thread_info_t *info,
uint64_t wakeup_time) {
malloc_mutex_assert_owner(tsdn, &info->mtx);
atomic_store_b(&info->indefinite_sleep,
wakeup_time == BACKGROUND_THREAD_INDEFINITE_SLEEP, ATOMIC_RELEASE);
nstime_init(&info->next_wakeup, wakeup_time);
}
JEMALLOC_ALWAYS_INLINE bool
background_thread_indefinite_sleep(background_thread_info_t *info) {
return atomic_load_b(&info->indefinite_sleep, ATOMIC_ACQUIRE);
}
JEMALLOC_ALWAYS_INLINE void
arena_background_thread_inactivity_check(tsdn_t *tsdn, arena_t *arena,
bool is_background_thread) {
if (!background_thread_enabled() || is_background_thread) {
return;
}
background_thread_info_t *info =
arena_background_thread_info_get(arena);
if (background_thread_indefinite_sleep(info)) {
background_thread_interval_check(tsdn, arena,
&arena->decay_dirty, 0);
}
}
#endif /* JEMALLOC_INTERNAL_BACKGROUND_THREAD_INLINES_H */

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#ifndef JEMALLOC_INTERNAL_BACKGROUND_THREAD_STRUCTS_H
#define JEMALLOC_INTERNAL_BACKGROUND_THREAD_STRUCTS_H
/* This file really combines "structs" and "types", but only transitionally. */
#if defined(JEMALLOC_BACKGROUND_THREAD) || defined(JEMALLOC_LAZY_LOCK)
# define JEMALLOC_PTHREAD_CREATE_WRAPPER
#endif
#define BACKGROUND_THREAD_INDEFINITE_SLEEP UINT64_MAX
#define MAX_BACKGROUND_THREAD_LIMIT MALLOCX_ARENA_LIMIT
#define DEFAULT_NUM_BACKGROUND_THREAD 4
typedef enum {
background_thread_stopped,
background_thread_started,
/* Thread waits on the global lock when paused (for arena_reset). */
background_thread_paused,
} background_thread_state_t;
struct background_thread_info_s {
#ifdef JEMALLOC_BACKGROUND_THREAD
/* Background thread is pthread specific. */
pthread_t thread;
pthread_cond_t cond;
#endif
malloc_mutex_t mtx;
background_thread_state_t state;
/* When true, it means no wakeup scheduled. */
atomic_b_t indefinite_sleep;
/* Next scheduled wakeup time (absolute time in ns). */
nstime_t next_wakeup;
/*
* Since the last background thread run, newly added number of pages
* that need to be purged by the next wakeup. This is adjusted on
* epoch advance, and is used to determine whether we should signal the
* background thread to wake up earlier.
*/
size_t npages_to_purge_new;
/* Stats: total number of runs since started. */
uint64_t tot_n_runs;
/* Stats: total sleep time since started. */
nstime_t tot_sleep_time;
};
typedef struct background_thread_info_s background_thread_info_t;
struct background_thread_stats_s {
size_t num_threads;
uint64_t num_runs;
nstime_t run_interval;
};
typedef struct background_thread_stats_s background_thread_stats_t;
#endif /* JEMALLOC_INTERNAL_BACKGROUND_THREAD_STRUCTS_H */

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#ifndef JEMALLOC_INTERNAL_BASE_EXTERNS_H
#define JEMALLOC_INTERNAL_BASE_EXTERNS_H
extern metadata_thp_mode_t opt_metadata_thp;
extern const char *metadata_thp_mode_names[];
base_t *b0get(void);
base_t *base_new(tsdn_t *tsdn, unsigned ind, extent_hooks_t *extent_hooks);
void base_delete(tsdn_t *tsdn, base_t *base);
extent_hooks_t *base_extent_hooks_get(base_t *base);
extent_hooks_t *base_extent_hooks_set(base_t *base,
extent_hooks_t *extent_hooks);
void *base_alloc(tsdn_t *tsdn, base_t *base, size_t size, size_t alignment);
extent_t *base_alloc_extent(tsdn_t *tsdn, base_t *base);
void base_stats_get(tsdn_t *tsdn, base_t *base, size_t *allocated,
size_t *resident, size_t *mapped, size_t *n_thp);
void base_prefork(tsdn_t *tsdn, base_t *base);
void base_postfork_parent(tsdn_t *tsdn, base_t *base);
void base_postfork_child(tsdn_t *tsdn, base_t *base);
bool base_boot(tsdn_t *tsdn);
#endif /* JEMALLOC_INTERNAL_BASE_EXTERNS_H */

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#ifndef JEMALLOC_INTERNAL_BASE_INLINES_H
#define JEMALLOC_INTERNAL_BASE_INLINES_H
static inline unsigned
base_ind_get(const base_t *base) {
return base->ind;
}
static inline bool
metadata_thp_enabled(void) {
return (opt_metadata_thp != metadata_thp_disabled);
}
#endif /* JEMALLOC_INTERNAL_BASE_INLINES_H */

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#ifndef JEMALLOC_INTERNAL_BASE_STRUCTS_H
#define JEMALLOC_INTERNAL_BASE_STRUCTS_H
#include "jemalloc/internal/jemalloc_internal_types.h"
#include "jemalloc/internal/mutex.h"
#include "jemalloc/internal/sc.h"
/* Embedded at the beginning of every block of base-managed virtual memory. */
struct base_block_s {
/* Total size of block's virtual memory mapping. */
size_t size;
/* Next block in list of base's blocks. */
base_block_t *next;
/* Tracks unused trailing space. */
extent_t extent;
};
struct base_s {
/* Associated arena's index within the arenas array. */
unsigned ind;
/*
* User-configurable extent hook functions. Points to an
* extent_hooks_t.
*/
atomic_p_t extent_hooks;
/* Protects base_alloc() and base_stats_get() operations. */
malloc_mutex_t mtx;
/* Using THP when true (metadata_thp auto mode). */
bool auto_thp_switched;
/*
* Most recent size class in the series of increasingly large base
* extents. Logarithmic spacing between subsequent allocations ensures
* that the total number of distinct mappings remains small.
*/
pszind_t pind_last;
/* Serial number generation state. */
size_t extent_sn_next;
/* Chain of all blocks associated with base. */
base_block_t *blocks;
/* Heap of extents that track unused trailing space within blocks. */
extent_heap_t avail[SC_NSIZES];
/* Stats, only maintained if config_stats. */
size_t allocated;
size_t resident;
size_t mapped;
/* Number of THP regions touched. */
size_t n_thp;
};
#endif /* JEMALLOC_INTERNAL_BASE_STRUCTS_H */

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#ifndef JEMALLOC_INTERNAL_BASE_TYPES_H
#define JEMALLOC_INTERNAL_BASE_TYPES_H
typedef struct base_block_s base_block_t;
typedef struct base_s base_t;
#define METADATA_THP_DEFAULT metadata_thp_disabled
/*
* In auto mode, arenas switch to huge pages for the base allocator on the
* second base block. a0 switches to thp on the 5th block (after 20 megabytes
* of metadata), since more metadata (e.g. rtree nodes) come from a0's base.
*/
#define BASE_AUTO_THP_THRESHOLD 2
#define BASE_AUTO_THP_THRESHOLD_A0 5
typedef enum {
metadata_thp_disabled = 0,
/*
* Lazily enable hugepage for metadata. To avoid high RSS caused by THP
* + low usage arena (i.e. THP becomes a significant percentage), the
* "auto" option only starts using THP after a base allocator used up
* the first THP region. Starting from the second hugepage (in a single
* arena), "auto" behaves the same as "always", i.e. madvise hugepage
* right away.
*/
metadata_thp_auto = 1,
metadata_thp_always = 2,
metadata_thp_mode_limit = 3
} metadata_thp_mode_t;
#endif /* JEMALLOC_INTERNAL_BASE_TYPES_H */

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#ifndef JEMALLOC_INTERNAL_BIN_H
#define JEMALLOC_INTERNAL_BIN_H
#include "jemalloc/internal/bin_stats.h"
#include "jemalloc/internal/bin_types.h"
#include "jemalloc/internal/extent_types.h"
#include "jemalloc/internal/extent_structs.h"
#include "jemalloc/internal/mutex.h"
#include "jemalloc/internal/sc.h"
/*
* A bin contains a set of extents that are currently being used for slab
* allocations.
*/
/*
* Read-only information associated with each element of arena_t's bins array
* is stored separately, partly to reduce memory usage (only one copy, rather
* than one per arena), but mainly to avoid false cacheline sharing.
*
* Each slab has the following layout:
*
* /--------------------\
* | region 0 |
* |--------------------|
* | region 1 |
* |--------------------|
* | ... |
* | ... |
* | ... |
* |--------------------|
* | region nregs-1 |
* \--------------------/
*/
typedef struct bin_info_s bin_info_t;
struct bin_info_s {
/* Size of regions in a slab for this bin's size class. */
size_t reg_size;
/* Total size of a slab for this bin's size class. */
size_t slab_size;
/* Total number of regions in a slab for this bin's size class. */
uint32_t nregs;
/* Number of sharded bins in each arena for this size class. */
uint32_t n_shards;
/*
* Metadata used to manipulate bitmaps for slabs associated with this
* bin.
*/
bitmap_info_t bitmap_info;
};
extern bin_info_t bin_infos[SC_NBINS];
typedef struct bin_s bin_t;
struct bin_s {
/* All operations on bin_t fields require lock ownership. */
malloc_mutex_t lock;
/*
* Current slab being used to service allocations of this bin's size
* class. slabcur is independent of slabs_{nonfull,full}; whenever
* slabcur is reassigned, the previous slab must be deallocated or
* inserted into slabs_{nonfull,full}.
*/
extent_t *slabcur;
/*
* Heap of non-full slabs. This heap is used to assure that new
* allocations come from the non-full slab that is oldest/lowest in
* memory.
*/
extent_heap_t slabs_nonfull;
/* List used to track full slabs. */
extent_list_t slabs_full;
/* Bin statistics. */
bin_stats_t stats;
};
/* A set of sharded bins of the same size class. */
typedef struct bins_s bins_t;
struct bins_s {
/* Sharded bins. Dynamically sized. */
bin_t *bin_shards;
};
void bin_shard_sizes_boot(unsigned bin_shards[SC_NBINS]);
bool bin_update_shard_size(unsigned bin_shards[SC_NBINS], size_t start_size,
size_t end_size, size_t nshards);
void bin_boot(sc_data_t *sc_data, unsigned bin_shard_sizes[SC_NBINS]);
/* Initializes a bin to empty. Returns true on error. */
bool bin_init(bin_t *bin);
/* Forking. */
void bin_prefork(tsdn_t *tsdn, bin_t *bin);
void bin_postfork_parent(tsdn_t *tsdn, bin_t *bin);
void bin_postfork_child(tsdn_t *tsdn, bin_t *bin);
/* Stats. */
static inline void
bin_stats_merge(tsdn_t *tsdn, bin_stats_t *dst_bin_stats, bin_t *bin) {
malloc_mutex_lock(tsdn, &bin->lock);
malloc_mutex_prof_accum(tsdn, &dst_bin_stats->mutex_data, &bin->lock);
dst_bin_stats->nmalloc += bin->stats.nmalloc;
dst_bin_stats->ndalloc += bin->stats.ndalloc;
dst_bin_stats->nrequests += bin->stats.nrequests;
dst_bin_stats->curregs += bin->stats.curregs;
dst_bin_stats->nfills += bin->stats.nfills;
dst_bin_stats->nflushes += bin->stats.nflushes;
dst_bin_stats->nslabs += bin->stats.nslabs;
dst_bin_stats->reslabs += bin->stats.reslabs;
dst_bin_stats->curslabs += bin->stats.curslabs;
dst_bin_stats->nonfull_slabs += bin->stats.nonfull_slabs;
malloc_mutex_unlock(tsdn, &bin->lock);
}
#endif /* JEMALLOC_INTERNAL_BIN_H */

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#ifndef JEMALLOC_INTERNAL_BIN_STATS_H
#define JEMALLOC_INTERNAL_BIN_STATS_H
#include "jemalloc/internal/mutex_prof.h"
typedef struct bin_stats_s bin_stats_t;
struct bin_stats_s {
/*
* Total number of allocation/deallocation requests served directly by
* the bin. Note that tcache may allocate an object, then recycle it
* many times, resulting many increments to nrequests, but only one
* each to nmalloc and ndalloc.
*/
uint64_t nmalloc;
uint64_t ndalloc;
/*
* Number of allocation requests that correspond to the size of this
* bin. This includes requests served by tcache, though tcache only
* periodically merges into this counter.
*/
uint64_t nrequests;
/*
* Current number of regions of this size class, including regions
* currently cached by tcache.
*/
size_t curregs;
/* Number of tcache fills from this bin. */
uint64_t nfills;
/* Number of tcache flushes to this bin. */
uint64_t nflushes;
/* Total number of slabs created for this bin's size class. */
uint64_t nslabs;
/*
* Total number of slabs reused by extracting them from the slabs heap
* for this bin's size class.
*/
uint64_t reslabs;
/* Current number of slabs in this bin. */
size_t curslabs;
/* Current size of nonfull slabs heap in this bin. */
size_t nonfull_slabs;
mutex_prof_data_t mutex_data;
};
#endif /* JEMALLOC_INTERNAL_BIN_STATS_H */

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#ifndef JEMALLOC_INTERNAL_BIN_TYPES_H
#define JEMALLOC_INTERNAL_BIN_TYPES_H
#include "jemalloc/internal/sc.h"
#define BIN_SHARDS_MAX (1 << EXTENT_BITS_BINSHARD_WIDTH)
#define N_BIN_SHARDS_DEFAULT 1
/* Used in TSD static initializer only. Real init in arena_bind(). */
#define TSD_BINSHARDS_ZERO_INITIALIZER {{UINT8_MAX}}
typedef struct tsd_binshards_s tsd_binshards_t;
struct tsd_binshards_s {
uint8_t binshard[SC_NBINS];
};
#endif /* JEMALLOC_INTERNAL_BIN_TYPES_H */

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#ifndef JEMALLOC_INTERNAL_BIT_UTIL_H
#define JEMALLOC_INTERNAL_BIT_UTIL_H
#include "jemalloc/internal/assert.h"
#define BIT_UTIL_INLINE static inline
/* Sanity check. */
#if !defined(JEMALLOC_INTERNAL_FFSLL) || !defined(JEMALLOC_INTERNAL_FFSL) \
|| !defined(JEMALLOC_INTERNAL_FFS)
# error JEMALLOC_INTERNAL_FFS{,L,LL} should have been defined by configure
#endif
BIT_UTIL_INLINE unsigned
ffs_llu(unsigned long long bitmap) {
return JEMALLOC_INTERNAL_FFSLL(bitmap);
}
BIT_UTIL_INLINE unsigned
ffs_lu(unsigned long bitmap) {
return JEMALLOC_INTERNAL_FFSL(bitmap);
}
BIT_UTIL_INLINE unsigned
ffs_u(unsigned bitmap) {
return JEMALLOC_INTERNAL_FFS(bitmap);
}
#ifdef JEMALLOC_INTERNAL_POPCOUNTL
BIT_UTIL_INLINE unsigned
popcount_lu(unsigned long bitmap) {
return JEMALLOC_INTERNAL_POPCOUNTL(bitmap);
}
#endif
/*
* Clears first unset bit in bitmap, and returns
* place of bit. bitmap *must not* be 0.
*/
BIT_UTIL_INLINE size_t
cfs_lu(unsigned long* bitmap) {
size_t bit = ffs_lu(*bitmap) - 1;
*bitmap ^= ZU(1) << bit;
return bit;
}
BIT_UTIL_INLINE unsigned
ffs_zu(size_t bitmap) {
#if LG_SIZEOF_PTR == LG_SIZEOF_INT
return ffs_u(bitmap);
#elif LG_SIZEOF_PTR == LG_SIZEOF_LONG
return ffs_lu(bitmap);
#elif LG_SIZEOF_PTR == LG_SIZEOF_LONG_LONG
return ffs_llu(bitmap);
#else
#error No implementation for size_t ffs()
#endif
}
BIT_UTIL_INLINE unsigned
ffs_u64(uint64_t bitmap) {
#if LG_SIZEOF_LONG == 3
return ffs_lu(bitmap);
#elif LG_SIZEOF_LONG_LONG == 3
return ffs_llu(bitmap);
#else
#error No implementation for 64-bit ffs()
#endif
}
BIT_UTIL_INLINE unsigned
ffs_u32(uint32_t bitmap) {
#if LG_SIZEOF_INT == 2
return ffs_u(bitmap);
#else
#error No implementation for 32-bit ffs()
#endif
return ffs_u(bitmap);
}
BIT_UTIL_INLINE uint64_t
pow2_ceil_u64(uint64_t x) {
#if (defined(__amd64__) || defined(__x86_64__) || defined(JEMALLOC_HAVE_BUILTIN_CLZ))
if(unlikely(x <= 1)) {
return x;
}
size_t msb_on_index;
#if (defined(__amd64__) || defined(__x86_64__))
asm ("bsrq %1, %0"
: "=r"(msb_on_index) // Outputs.
: "r"(x-1) // Inputs.
);
#elif (defined(JEMALLOC_HAVE_BUILTIN_CLZ))
msb_on_index = (63 ^ __builtin_clzll(x - 1));
#endif
assert(msb_on_index < 63);
return 1ULL << (msb_on_index + 1);
#else
x--;
x |= x >> 1;
x |= x >> 2;
x |= x >> 4;
x |= x >> 8;
x |= x >> 16;
x |= x >> 32;
x++;
return x;
#endif
}
BIT_UTIL_INLINE uint32_t
pow2_ceil_u32(uint32_t x) {
#if ((defined(__i386__) || defined(JEMALLOC_HAVE_BUILTIN_CLZ)) && (!defined(__s390__)))
if(unlikely(x <= 1)) {
return x;
}
size_t msb_on_index;
#if (defined(__i386__))
asm ("bsr %1, %0"
: "=r"(msb_on_index) // Outputs.
: "r"(x-1) // Inputs.
);
#elif (defined(JEMALLOC_HAVE_BUILTIN_CLZ))
msb_on_index = (31 ^ __builtin_clz(x - 1));
#endif
assert(msb_on_index < 31);
return 1U << (msb_on_index + 1);
#else
x--;
x |= x >> 1;
x |= x >> 2;
x |= x >> 4;
x |= x >> 8;
x |= x >> 16;
x++;
return x;
#endif
}
/* Compute the smallest power of 2 that is >= x. */
BIT_UTIL_INLINE size_t
pow2_ceil_zu(size_t x) {
#if (LG_SIZEOF_PTR == 3)
return pow2_ceil_u64(x);
#else
return pow2_ceil_u32(x);
#endif
}
#if (defined(__i386__) || defined(__amd64__) || defined(__x86_64__))
BIT_UTIL_INLINE unsigned
lg_floor(size_t x) {
size_t ret;
assert(x != 0);
asm ("bsr %1, %0"
: "=r"(ret) // Outputs.
: "r"(x) // Inputs.
);
assert(ret < UINT_MAX);
return (unsigned)ret;
}
#elif (defined(_MSC_VER))
BIT_UTIL_INLINE unsigned
lg_floor(size_t x) {
unsigned long ret;
assert(x != 0);
#if (LG_SIZEOF_PTR == 3)
_BitScanReverse64(&ret, x);
#elif (LG_SIZEOF_PTR == 2)
_BitScanReverse(&ret, x);
#else
# error "Unsupported type size for lg_floor()"
#endif
assert(ret < UINT_MAX);
return (unsigned)ret;
}
#elif (defined(JEMALLOC_HAVE_BUILTIN_CLZ))
BIT_UTIL_INLINE unsigned
lg_floor(size_t x) {
assert(x != 0);
#if (LG_SIZEOF_PTR == LG_SIZEOF_INT)
return ((8 << LG_SIZEOF_PTR) - 1) - __builtin_clz(x);
#elif (LG_SIZEOF_PTR == LG_SIZEOF_LONG)
return ((8 << LG_SIZEOF_PTR) - 1) - __builtin_clzl(x);
#else
# error "Unsupported type size for lg_floor()"
#endif
}
#else
BIT_UTIL_INLINE unsigned
lg_floor(size_t x) {
assert(x != 0);
x |= (x >> 1);
x |= (x >> 2);
x |= (x >> 4);
x |= (x >> 8);
x |= (x >> 16);
#if (LG_SIZEOF_PTR == 3)
x |= (x >> 32);
#endif
if (x == SIZE_T_MAX) {
return (8 << LG_SIZEOF_PTR) - 1;
}
x++;
return ffs_zu(x) - 2;
}
#endif
BIT_UTIL_INLINE unsigned
lg_ceil(size_t x) {
return lg_floor(x) + ((x & (x - 1)) == 0 ? 0 : 1);
}
#undef BIT_UTIL_INLINE
/* A compile-time version of lg_floor and lg_ceil. */
#define LG_FLOOR_1(x) 0
#define LG_FLOOR_2(x) (x < (1ULL << 1) ? LG_FLOOR_1(x) : 1 + LG_FLOOR_1(x >> 1))
#define LG_FLOOR_4(x) (x < (1ULL << 2) ? LG_FLOOR_2(x) : 2 + LG_FLOOR_2(x >> 2))
#define LG_FLOOR_8(x) (x < (1ULL << 4) ? LG_FLOOR_4(x) : 4 + LG_FLOOR_4(x >> 4))
#define LG_FLOOR_16(x) (x < (1ULL << 8) ? LG_FLOOR_8(x) : 8 + LG_FLOOR_8(x >> 8))
#define LG_FLOOR_32(x) (x < (1ULL << 16) ? LG_FLOOR_16(x) : 16 + LG_FLOOR_16(x >> 16))
#define LG_FLOOR_64(x) (x < (1ULL << 32) ? LG_FLOOR_32(x) : 32 + LG_FLOOR_32(x >> 32))
#if LG_SIZEOF_PTR == 2
# define LG_FLOOR(x) LG_FLOOR_32((x))
#else
# define LG_FLOOR(x) LG_FLOOR_64((x))
#endif
#define LG_CEIL(x) (LG_FLOOR(x) + (((x) & ((x) - 1)) == 0 ? 0 : 1))
#endif /* JEMALLOC_INTERNAL_BIT_UTIL_H */

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#ifndef JEMALLOC_INTERNAL_BITMAP_H
#define JEMALLOC_INTERNAL_BITMAP_H
#include "jemalloc/internal/arena_types.h"
#include "jemalloc/internal/bit_util.h"
#include "jemalloc/internal/sc.h"
typedef unsigned long bitmap_t;
#define LG_SIZEOF_BITMAP LG_SIZEOF_LONG
/* Maximum bitmap bit count is 2^LG_BITMAP_MAXBITS. */
#if LG_SLAB_MAXREGS > LG_CEIL(SC_NSIZES)
/* Maximum bitmap bit count is determined by maximum regions per slab. */
# define LG_BITMAP_MAXBITS LG_SLAB_MAXREGS
#else
/* Maximum bitmap bit count is determined by number of extent size classes. */
# define LG_BITMAP_MAXBITS LG_CEIL(SC_NSIZES)
#endif
#define BITMAP_MAXBITS (ZU(1) << LG_BITMAP_MAXBITS)
/* Number of bits per group. */
#define LG_BITMAP_GROUP_NBITS (LG_SIZEOF_BITMAP + 3)
#define BITMAP_GROUP_NBITS (1U << LG_BITMAP_GROUP_NBITS)
#define BITMAP_GROUP_NBITS_MASK (BITMAP_GROUP_NBITS-1)
/*
* Do some analysis on how big the bitmap is before we use a tree. For a brute
* force linear search, if we would have to call ffs_lu() more than 2^3 times,
* use a tree instead.
*/
#if LG_BITMAP_MAXBITS - LG_BITMAP_GROUP_NBITS > 3
# define BITMAP_USE_TREE
#endif
/* Number of groups required to store a given number of bits. */
#define BITMAP_BITS2GROUPS(nbits) \
(((nbits) + BITMAP_GROUP_NBITS_MASK) >> LG_BITMAP_GROUP_NBITS)
/*
* Number of groups required at a particular level for a given number of bits.
*/
#define BITMAP_GROUPS_L0(nbits) \
BITMAP_BITS2GROUPS(nbits)
#define BITMAP_GROUPS_L1(nbits) \
BITMAP_BITS2GROUPS(BITMAP_BITS2GROUPS(nbits))
#define BITMAP_GROUPS_L2(nbits) \
BITMAP_BITS2GROUPS(BITMAP_BITS2GROUPS(BITMAP_BITS2GROUPS((nbits))))
#define BITMAP_GROUPS_L3(nbits) \
BITMAP_BITS2GROUPS(BITMAP_BITS2GROUPS(BITMAP_BITS2GROUPS( \
BITMAP_BITS2GROUPS((nbits)))))
#define BITMAP_GROUPS_L4(nbits) \
BITMAP_BITS2GROUPS(BITMAP_BITS2GROUPS(BITMAP_BITS2GROUPS( \
BITMAP_BITS2GROUPS(BITMAP_BITS2GROUPS((nbits))))))
/*
* Assuming the number of levels, number of groups required for a given number
* of bits.
*/
#define BITMAP_GROUPS_1_LEVEL(nbits) \
BITMAP_GROUPS_L0(nbits)
#define BITMAP_GROUPS_2_LEVEL(nbits) \
(BITMAP_GROUPS_1_LEVEL(nbits) + BITMAP_GROUPS_L1(nbits))
#define BITMAP_GROUPS_3_LEVEL(nbits) \
(BITMAP_GROUPS_2_LEVEL(nbits) + BITMAP_GROUPS_L2(nbits))
#define BITMAP_GROUPS_4_LEVEL(nbits) \
(BITMAP_GROUPS_3_LEVEL(nbits) + BITMAP_GROUPS_L3(nbits))
#define BITMAP_GROUPS_5_LEVEL(nbits) \
(BITMAP_GROUPS_4_LEVEL(nbits) + BITMAP_GROUPS_L4(nbits))
/*
* Maximum number of groups required to support LG_BITMAP_MAXBITS.
*/
#ifdef BITMAP_USE_TREE
#if LG_BITMAP_MAXBITS <= LG_BITMAP_GROUP_NBITS
# define BITMAP_GROUPS(nbits) BITMAP_GROUPS_1_LEVEL(nbits)
# define BITMAP_GROUPS_MAX BITMAP_GROUPS_1_LEVEL(BITMAP_MAXBITS)
#elif LG_BITMAP_MAXBITS <= LG_BITMAP_GROUP_NBITS * 2
# define BITMAP_GROUPS(nbits) BITMAP_GROUPS_2_LEVEL(nbits)
# define BITMAP_GROUPS_MAX BITMAP_GROUPS_2_LEVEL(BITMAP_MAXBITS)
#elif LG_BITMAP_MAXBITS <= LG_BITMAP_GROUP_NBITS * 3
# define BITMAP_GROUPS(nbits) BITMAP_GROUPS_3_LEVEL(nbits)
# define BITMAP_GROUPS_MAX BITMAP_GROUPS_3_LEVEL(BITMAP_MAXBITS)
#elif LG_BITMAP_MAXBITS <= LG_BITMAP_GROUP_NBITS * 4
# define BITMAP_GROUPS(nbits) BITMAP_GROUPS_4_LEVEL(nbits)
# define BITMAP_GROUPS_MAX BITMAP_GROUPS_4_LEVEL(BITMAP_MAXBITS)
#elif LG_BITMAP_MAXBITS <= LG_BITMAP_GROUP_NBITS * 5
# define BITMAP_GROUPS(nbits) BITMAP_GROUPS_5_LEVEL(nbits)
# define BITMAP_GROUPS_MAX BITMAP_GROUPS_5_LEVEL(BITMAP_MAXBITS)
#else
# error "Unsupported bitmap size"
#endif
/*
* Maximum number of levels possible. This could be statically computed based
* on LG_BITMAP_MAXBITS:
*
* #define BITMAP_MAX_LEVELS \
* (LG_BITMAP_MAXBITS / LG_SIZEOF_BITMAP) \
* + !!(LG_BITMAP_MAXBITS % LG_SIZEOF_BITMAP)
*
* However, that would not allow the generic BITMAP_INFO_INITIALIZER() macro, so
* instead hardcode BITMAP_MAX_LEVELS to the largest number supported by the
* various cascading macros. The only additional cost this incurs is some
* unused trailing entries in bitmap_info_t structures; the bitmaps themselves
* are not impacted.
*/
#define BITMAP_MAX_LEVELS 5
#define BITMAP_INFO_INITIALIZER(nbits) { \
/* nbits. */ \
nbits, \
/* nlevels. */ \
(BITMAP_GROUPS_L0(nbits) > BITMAP_GROUPS_L1(nbits)) + \
(BITMAP_GROUPS_L1(nbits) > BITMAP_GROUPS_L2(nbits)) + \
(BITMAP_GROUPS_L2(nbits) > BITMAP_GROUPS_L3(nbits)) + \
(BITMAP_GROUPS_L3(nbits) > BITMAP_GROUPS_L4(nbits)) + 1, \
/* levels. */ \
{ \
{0}, \
{BITMAP_GROUPS_L0(nbits)}, \
{BITMAP_GROUPS_L1(nbits) + BITMAP_GROUPS_L0(nbits)}, \
{BITMAP_GROUPS_L2(nbits) + BITMAP_GROUPS_L1(nbits) + \
BITMAP_GROUPS_L0(nbits)}, \
{BITMAP_GROUPS_L3(nbits) + BITMAP_GROUPS_L2(nbits) + \
BITMAP_GROUPS_L1(nbits) + BITMAP_GROUPS_L0(nbits)}, \
{BITMAP_GROUPS_L4(nbits) + BITMAP_GROUPS_L3(nbits) + \
BITMAP_GROUPS_L2(nbits) + BITMAP_GROUPS_L1(nbits) \
+ BITMAP_GROUPS_L0(nbits)} \
} \
}
#else /* BITMAP_USE_TREE */
#define BITMAP_GROUPS(nbits) BITMAP_BITS2GROUPS(nbits)
#define BITMAP_GROUPS_MAX BITMAP_BITS2GROUPS(BITMAP_MAXBITS)
#define BITMAP_INFO_INITIALIZER(nbits) { \
/* nbits. */ \
nbits, \
/* ngroups. */ \
BITMAP_BITS2GROUPS(nbits) \
}
#endif /* BITMAP_USE_TREE */
typedef struct bitmap_level_s {
/* Offset of this level's groups within the array of groups. */
size_t group_offset;
} bitmap_level_t;
typedef struct bitmap_info_s {
/* Logical number of bits in bitmap (stored at bottom level). */
size_t nbits;
#ifdef BITMAP_USE_TREE
/* Number of levels necessary for nbits. */
unsigned nlevels;
/*
* Only the first (nlevels+1) elements are used, and levels are ordered
* bottom to top (e.g. the bottom level is stored in levels[0]).
*/
bitmap_level_t levels[BITMAP_MAX_LEVELS+1];
#else /* BITMAP_USE_TREE */
/* Number of groups necessary for nbits. */
size_t ngroups;
#endif /* BITMAP_USE_TREE */
} bitmap_info_t;
void bitmap_info_init(bitmap_info_t *binfo, size_t nbits);
void bitmap_init(bitmap_t *bitmap, const bitmap_info_t *binfo, bool fill);
size_t bitmap_size(const bitmap_info_t *binfo);
static inline bool
bitmap_full(bitmap_t *bitmap, const bitmap_info_t *binfo) {
#ifdef BITMAP_USE_TREE
size_t rgoff = binfo->levels[binfo->nlevels].group_offset - 1;
bitmap_t rg = bitmap[rgoff];
/* The bitmap is full iff the root group is 0. */
return (rg == 0);
#else
size_t i;
for (i = 0; i < binfo->ngroups; i++) {
if (bitmap[i] != 0) {
return false;
}
}
return true;
#endif
}
static inline bool
bitmap_get(bitmap_t *bitmap, const bitmap_info_t *binfo, size_t bit) {
size_t goff;
bitmap_t g;
assert(bit < binfo->nbits);
goff = bit >> LG_BITMAP_GROUP_NBITS;
g = bitmap[goff];
return !(g & (ZU(1) << (bit & BITMAP_GROUP_NBITS_MASK)));
}
static inline void
bitmap_set(bitmap_t *bitmap, const bitmap_info_t *binfo, size_t bit) {
size_t goff;
bitmap_t *gp;
bitmap_t g;
assert(bit < binfo->nbits);
assert(!bitmap_get(bitmap, binfo, bit));
goff = bit >> LG_BITMAP_GROUP_NBITS;
gp = &bitmap[goff];
g = *gp;
assert(g & (ZU(1) << (bit & BITMAP_GROUP_NBITS_MASK)));
g ^= ZU(1) << (bit & BITMAP_GROUP_NBITS_MASK);
*gp = g;
assert(bitmap_get(bitmap, binfo, bit));
#ifdef BITMAP_USE_TREE
/* Propagate group state transitions up the tree. */
if (g == 0) {
unsigned i;
for (i = 1; i < binfo->nlevels; i++) {
bit = goff;
goff = bit >> LG_BITMAP_GROUP_NBITS;
gp = &bitmap[binfo->levels[i].group_offset + goff];
g = *gp;
assert(g & (ZU(1) << (bit & BITMAP_GROUP_NBITS_MASK)));
g ^= ZU(1) << (bit & BITMAP_GROUP_NBITS_MASK);
*gp = g;
if (g != 0) {
break;
}
}
}
#endif
}
/* ffu: find first unset >= bit. */
static inline size_t
bitmap_ffu(const bitmap_t *bitmap, const bitmap_info_t *binfo, size_t min_bit) {
assert(min_bit < binfo->nbits);
#ifdef BITMAP_USE_TREE
size_t bit = 0;
for (unsigned level = binfo->nlevels; level--;) {
size_t lg_bits_per_group = (LG_BITMAP_GROUP_NBITS * (level +
1));
bitmap_t group = bitmap[binfo->levels[level].group_offset + (bit
>> lg_bits_per_group)];
unsigned group_nmask = (unsigned)(((min_bit > bit) ? (min_bit -
bit) : 0) >> (lg_bits_per_group - LG_BITMAP_GROUP_NBITS));
assert(group_nmask <= BITMAP_GROUP_NBITS);
bitmap_t group_mask = ~((1LU << group_nmask) - 1);
bitmap_t group_masked = group & group_mask;
if (group_masked == 0LU) {
if (group == 0LU) {
return binfo->nbits;
}
/*
* min_bit was preceded by one or more unset bits in
* this group, but there are no other unset bits in this
* group. Try again starting at the first bit of the
* next sibling. This will recurse at most once per
* non-root level.
*/
size_t sib_base = bit + (ZU(1) << lg_bits_per_group);
assert(sib_base > min_bit);
assert(sib_base > bit);
if (sib_base >= binfo->nbits) {
return binfo->nbits;
}
return bitmap_ffu(bitmap, binfo, sib_base);
}
bit += ((size_t)(ffs_lu(group_masked) - 1)) <<
(lg_bits_per_group - LG_BITMAP_GROUP_NBITS);
}
assert(bit >= min_bit);
assert(bit < binfo->nbits);
return bit;
#else
size_t i = min_bit >> LG_BITMAP_GROUP_NBITS;
bitmap_t g = bitmap[i] & ~((1LU << (min_bit & BITMAP_GROUP_NBITS_MASK))
- 1);
size_t bit;
do {
bit = ffs_lu(g);
if (bit != 0) {
return (i << LG_BITMAP_GROUP_NBITS) + (bit - 1);
}
i++;
g = bitmap[i];
} while (i < binfo->ngroups);
return binfo->nbits;
#endif
}
/* sfu: set first unset. */
static inline size_t
bitmap_sfu(bitmap_t *bitmap, const bitmap_info_t *binfo) {
size_t bit;
bitmap_t g;
unsigned i;
assert(!bitmap_full(bitmap, binfo));
#ifdef BITMAP_USE_TREE
i = binfo->nlevels - 1;
g = bitmap[binfo->levels[i].group_offset];
bit = ffs_lu(g) - 1;
while (i > 0) {
i--;
g = bitmap[binfo->levels[i].group_offset + bit];
bit = (bit << LG_BITMAP_GROUP_NBITS) + (ffs_lu(g) - 1);
}
#else
i = 0;
g = bitmap[0];
while ((bit = ffs_lu(g)) == 0) {
i++;
g = bitmap[i];
}
bit = (i << LG_BITMAP_GROUP_NBITS) + (bit - 1);
#endif
bitmap_set(bitmap, binfo, bit);
return bit;
}
static inline void
bitmap_unset(bitmap_t *bitmap, const bitmap_info_t *binfo, size_t bit) {
size_t goff;
bitmap_t *gp;
bitmap_t g;
UNUSED bool propagate;
assert(bit < binfo->nbits);
assert(bitmap_get(bitmap, binfo, bit));
goff = bit >> LG_BITMAP_GROUP_NBITS;
gp = &bitmap[goff];
g = *gp;
propagate = (g == 0);
assert((g & (ZU(1) << (bit & BITMAP_GROUP_NBITS_MASK))) == 0);
g ^= ZU(1) << (bit & BITMAP_GROUP_NBITS_MASK);
*gp = g;
assert(!bitmap_get(bitmap, binfo, bit));
#ifdef BITMAP_USE_TREE
/* Propagate group state transitions up the tree. */
if (propagate) {
unsigned i;
for (i = 1; i < binfo->nlevels; i++) {
bit = goff;
goff = bit >> LG_BITMAP_GROUP_NBITS;
gp = &bitmap[binfo->levels[i].group_offset + goff];
g = *gp;
propagate = (g == 0);
assert((g & (ZU(1) << (bit & BITMAP_GROUP_NBITS_MASK)))
== 0);
g ^= ZU(1) << (bit & BITMAP_GROUP_NBITS_MASK);
*gp = g;
if (!propagate) {
break;
}
}
}
#endif /* BITMAP_USE_TREE */
}
#endif /* JEMALLOC_INTERNAL_BITMAP_H */

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#ifndef JEMALLOC_INTERNAL_CACHE_BIN_H
#define JEMALLOC_INTERNAL_CACHE_BIN_H
#include "jemalloc/internal/ql.h"
/*
* The cache_bins are the mechanism that the tcache and the arena use to
* communicate. The tcache fills from and flushes to the arena by passing a
* cache_bin_t to fill/flush. When the arena needs to pull stats from the
* tcaches associated with it, it does so by iterating over its
* cache_bin_array_descriptor_t objects and reading out per-bin stats it
* contains. This makes it so that the arena need not know about the existence
* of the tcache at all.
*/
/*
* The count of the number of cached allocations in a bin. We make this signed
* so that negative numbers can encode "invalid" states (e.g. a low water mark
* of -1 for a cache that has been depleted).
*/
typedef int32_t cache_bin_sz_t;
typedef struct cache_bin_stats_s cache_bin_stats_t;
struct cache_bin_stats_s {
/*
* Number of allocation requests that corresponded to the size of this
* bin.
*/
uint64_t nrequests;
};
/*
* Read-only information associated with each element of tcache_t's tbins array
* is stored separately, mainly to reduce memory usage.
*/
typedef struct cache_bin_info_s cache_bin_info_t;
struct cache_bin_info_s {
/* Upper limit on ncached. */
cache_bin_sz_t ncached_max;
};
typedef struct cache_bin_s cache_bin_t;
struct cache_bin_s {
/* Min # cached since last GC. */
cache_bin_sz_t low_water;
/* # of cached objects. */
cache_bin_sz_t ncached;
/*
* ncached and stats are both modified frequently. Let's keep them
* close so that they have a higher chance of being on the same
* cacheline, thus less write-backs.
*/
cache_bin_stats_t tstats;
/*
* Stack of available objects.
*
* To make use of adjacent cacheline prefetch, the items in the avail
* stack goes to higher address for newer allocations. avail points
* just above the available space, which means that
* avail[-ncached, ... -1] are available items and the lowest item will
* be allocated first.
*/
void **avail;
};
typedef struct cache_bin_array_descriptor_s cache_bin_array_descriptor_t;
struct cache_bin_array_descriptor_s {
/*
* The arena keeps a list of the cache bins associated with it, for
* stats collection.
*/
ql_elm(cache_bin_array_descriptor_t) link;
/* Pointers to the tcache bins. */
cache_bin_t *bins_small;
cache_bin_t *bins_large;
};
static inline void
cache_bin_array_descriptor_init(cache_bin_array_descriptor_t *descriptor,
cache_bin_t *bins_small, cache_bin_t *bins_large) {
ql_elm_new(descriptor, link);
descriptor->bins_small = bins_small;
descriptor->bins_large = bins_large;
}
JEMALLOC_ALWAYS_INLINE void *
cache_bin_alloc_easy(cache_bin_t *bin, bool *success) {
void *ret;
bin->ncached--;
/*
* Check for both bin->ncached == 0 and ncached < low_water
* in a single branch.
*/
if (unlikely(bin->ncached <= bin->low_water)) {
bin->low_water = bin->ncached;
if (bin->ncached == -1) {
bin->ncached = 0;
*success = false;
return NULL;
}
}
/*
* success (instead of ret) should be checked upon the return of this
* function. We avoid checking (ret == NULL) because there is never a
* null stored on the avail stack (which is unknown to the compiler),
* and eagerly checking ret would cause pipeline stall (waiting for the
* cacheline).
*/
*success = true;
ret = *(bin->avail - (bin->ncached + 1));
return ret;
}
JEMALLOC_ALWAYS_INLINE bool
cache_bin_dalloc_easy(cache_bin_t *bin, cache_bin_info_t *bin_info, void *ptr) {
if (unlikely(bin->ncached == bin_info->ncached_max)) {
return false;
}
assert(bin->ncached < bin_info->ncached_max);
bin->ncached++;
*(bin->avail - bin->ncached) = ptr;
return true;
}
#endif /* JEMALLOC_INTERNAL_CACHE_BIN_H */

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#ifndef JEMALLOC_INTERNAL_CKH_H
#define JEMALLOC_INTERNAL_CKH_H
#include "jemalloc/internal/tsd.h"
/* Cuckoo hashing implementation. Skip to the end for the interface. */
/******************************************************************************/
/* INTERNAL DEFINITIONS -- IGNORE */
/******************************************************************************/
/* Maintain counters used to get an idea of performance. */
/* #define CKH_COUNT */
/* Print counter values in ckh_delete() (requires CKH_COUNT). */
/* #define CKH_VERBOSE */
/*
* There are 2^LG_CKH_BUCKET_CELLS cells in each hash table bucket. Try to fit
* one bucket per L1 cache line.
*/
#define LG_CKH_BUCKET_CELLS (LG_CACHELINE - LG_SIZEOF_PTR - 1)
/* Typedefs to allow easy function pointer passing. */
typedef void ckh_hash_t (const void *, size_t[2]);
typedef bool ckh_keycomp_t (const void *, const void *);
/* Hash table cell. */
typedef struct {
const void *key;
const void *data;
} ckhc_t;
/* The hash table itself. */
typedef struct {
#ifdef CKH_COUNT
/* Counters used to get an idea of performance. */
uint64_t ngrows;
uint64_t nshrinks;
uint64_t nshrinkfails;
uint64_t ninserts;
uint64_t nrelocs;
#endif
/* Used for pseudo-random number generation. */
uint64_t prng_state;
/* Total number of items. */
size_t count;
/*
* Minimum and current number of hash table buckets. There are
* 2^LG_CKH_BUCKET_CELLS cells per bucket.
*/
unsigned lg_minbuckets;
unsigned lg_curbuckets;
/* Hash and comparison functions. */
ckh_hash_t *hash;
ckh_keycomp_t *keycomp;
/* Hash table with 2^lg_curbuckets buckets. */
ckhc_t *tab;
} ckh_t;
/******************************************************************************/
/* BEGIN PUBLIC API */
/******************************************************************************/
/* Lifetime management. Minitems is the initial capacity. */
bool ckh_new(tsd_t *tsd, ckh_t *ckh, size_t minitems, ckh_hash_t *hash,
ckh_keycomp_t *keycomp);
void ckh_delete(tsd_t *tsd, ckh_t *ckh);
/* Get the number of elements in the set. */
size_t ckh_count(ckh_t *ckh);
/*
* To iterate over the elements in the table, initialize *tabind to 0 and call
* this function until it returns true. Each call that returns false will
* update *key and *data to the next element in the table, assuming the pointers
* are non-NULL.
*/
bool ckh_iter(ckh_t *ckh, size_t *tabind, void **key, void **data);
/*
* Basic hash table operations -- insert, removal, lookup. For ckh_remove and
* ckh_search, key or data can be NULL. The hash-table only stores pointers to
* the key and value, and doesn't do any lifetime management.
*/
bool ckh_insert(tsd_t *tsd, ckh_t *ckh, const void *key, const void *data);
bool ckh_remove(tsd_t *tsd, ckh_t *ckh, const void *searchkey, void **key,
void **data);
bool ckh_search(ckh_t *ckh, const void *searchkey, void **key, void **data);
/* Some useful hash and comparison functions for strings and pointers. */
void ckh_string_hash(const void *key, size_t r_hash[2]);
bool ckh_string_keycomp(const void *k1, const void *k2);
void ckh_pointer_hash(const void *key, size_t r_hash[2]);
bool ckh_pointer_keycomp(const void *k1, const void *k2);
#endif /* JEMALLOC_INTERNAL_CKH_H */

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#ifndef JEMALLOC_INTERNAL_CTL_H
#define JEMALLOC_INTERNAL_CTL_H
#include "jemalloc/internal/jemalloc_internal_types.h"
#include "jemalloc/internal/malloc_io.h"
#include "jemalloc/internal/mutex_prof.h"
#include "jemalloc/internal/ql.h"
#include "jemalloc/internal/sc.h"
#include "jemalloc/internal/stats.h"
/* Maximum ctl tree depth. */
#define CTL_MAX_DEPTH 7
typedef struct ctl_node_s {
bool named;
} ctl_node_t;
typedef struct ctl_named_node_s {
ctl_node_t node;
const char *name;
/* If (nchildren == 0), this is a terminal node. */
size_t nchildren;
const ctl_node_t *children;
int (*ctl)(tsd_t *, const size_t *, size_t, void *, size_t *, void *,
size_t);
} ctl_named_node_t;
typedef struct ctl_indexed_node_s {
struct ctl_node_s node;
const ctl_named_node_t *(*index)(tsdn_t *, const size_t *, size_t,
size_t);
} ctl_indexed_node_t;
typedef struct ctl_arena_stats_s {
arena_stats_t astats;
/* Aggregate stats for small size classes, based on bin stats. */
size_t allocated_small;
uint64_t nmalloc_small;
uint64_t ndalloc_small;
uint64_t nrequests_small;
uint64_t nfills_small;
uint64_t nflushes_small;
bin_stats_t bstats[SC_NBINS];
arena_stats_large_t lstats[SC_NSIZES - SC_NBINS];
arena_stats_extents_t estats[SC_NPSIZES];
} ctl_arena_stats_t;
typedef struct ctl_stats_s {
size_t allocated;
size_t active;
size_t metadata;
size_t metadata_thp;
size_t resident;
size_t mapped;
size_t retained;
background_thread_stats_t background_thread;
mutex_prof_data_t mutex_prof_data[mutex_prof_num_global_mutexes];
} ctl_stats_t;
typedef struct ctl_arena_s ctl_arena_t;
struct ctl_arena_s {
unsigned arena_ind;
bool initialized;
ql_elm(ctl_arena_t) destroyed_link;
/* Basic stats, supported even if !config_stats. */
unsigned nthreads;
const char *dss;
ssize_t dirty_decay_ms;
ssize_t muzzy_decay_ms;
size_t pactive;
size_t pdirty;
size_t pmuzzy;
/* NULL if !config_stats. */
ctl_arena_stats_t *astats;
};
typedef struct ctl_arenas_s {
uint64_t epoch;
unsigned narenas;
ql_head(ctl_arena_t) destroyed;
/*
* Element 0 corresponds to merged stats for extant arenas (accessed via
* MALLCTL_ARENAS_ALL), element 1 corresponds to merged stats for
* destroyed arenas (accessed via MALLCTL_ARENAS_DESTROYED), and the
* remaining MALLOCX_ARENA_LIMIT elements correspond to arenas.
*/
ctl_arena_t *arenas[2 + MALLOCX_ARENA_LIMIT];
} ctl_arenas_t;
int ctl_byname(tsd_t *tsd, const char *name, void *oldp, size_t *oldlenp,
void *newp, size_t newlen);
int ctl_nametomib(tsd_t *tsd, const char *name, size_t *mibp, size_t *miblenp);
int ctl_bymib(tsd_t *tsd, const size_t *mib, size_t miblen, void *oldp,
size_t *oldlenp, void *newp, size_t newlen);
bool ctl_boot(void);
void ctl_prefork(tsdn_t *tsdn);
void ctl_postfork_parent(tsdn_t *tsdn);
void ctl_postfork_child(tsdn_t *tsdn);
#define xmallctl(name, oldp, oldlenp, newp, newlen) do { \
if (je_mallctl(name, oldp, oldlenp, newp, newlen) \
!= 0) { \
malloc_printf( \
"<jemalloc>: Failure in xmallctl(\"%s\", ...)\n", \
name); \
abort(); \
} \
} while (0)
#define xmallctlnametomib(name, mibp, miblenp) do { \
if (je_mallctlnametomib(name, mibp, miblenp) != 0) { \
malloc_printf("<jemalloc>: Failure in " \
"xmallctlnametomib(\"%s\", ...)\n", name); \
abort(); \
} \
} while (0)
#define xmallctlbymib(mib, miblen, oldp, oldlenp, newp, newlen) do { \
if (je_mallctlbymib(mib, miblen, oldp, oldlenp, newp, \
newlen) != 0) { \
malloc_write( \
"<jemalloc>: Failure in xmallctlbymib()\n"); \
abort(); \
} \
} while (0)
#endif /* JEMALLOC_INTERNAL_CTL_H */

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#ifndef JEMALLOC_INTERNAL_DIV_H
#define JEMALLOC_INTERNAL_DIV_H
#include "jemalloc/internal/assert.h"
/*
* This module does the division that computes the index of a region in a slab,
* given its offset relative to the base.
* That is, given a divisor d, an n = i * d (all integers), we'll return i.
* We do some pre-computation to do this more quickly than a CPU division
* instruction.
* We bound n < 2^32, and don't support dividing by one.
*/
typedef struct div_info_s div_info_t;
struct div_info_s {
uint32_t magic;
#ifdef JEMALLOC_DEBUG
size_t d;
#endif
};
void div_init(div_info_t *div_info, size_t divisor);
static inline size_t
div_compute(div_info_t *div_info, size_t n) {
assert(n <= (uint32_t)-1);
/*
* This generates, e.g. mov; imul; shr on x86-64. On a 32-bit machine,
* the compilers I tried were all smart enough to turn this into the
* appropriate "get the high 32 bits of the result of a multiply" (e.g.
* mul; mov edx eax; on x86, umull on arm, etc.).
*/
size_t i = ((uint64_t)n * (uint64_t)div_info->magic) >> 32;
#ifdef JEMALLOC_DEBUG
assert(i * div_info->d == n);
#endif
return i;
}
#endif /* JEMALLOC_INTERNAL_DIV_H */

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#ifndef JEMALLOC_INTERNAL_EMITTER_H
#define JEMALLOC_INTERNAL_EMITTER_H
#include "jemalloc/internal/ql.h"
typedef enum emitter_output_e emitter_output_t;
enum emitter_output_e {
emitter_output_json,
emitter_output_table
};
typedef enum emitter_justify_e emitter_justify_t;
enum emitter_justify_e {
emitter_justify_left,
emitter_justify_right,
/* Not for users; just to pass to internal functions. */
emitter_justify_none
};
typedef enum emitter_type_e emitter_type_t;
enum emitter_type_e {
emitter_type_bool,
emitter_type_int,
emitter_type_unsigned,
emitter_type_uint32,
emitter_type_uint64,
emitter_type_size,
emitter_type_ssize,
emitter_type_string,
/*
* A title is a column title in a table; it's just a string, but it's
* not quoted.
*/
emitter_type_title,
};
typedef struct emitter_col_s emitter_col_t;
struct emitter_col_s {
/* Filled in by the user. */
emitter_justify_t justify;
int width;
emitter_type_t type;
union {
bool bool_val;
int int_val;
unsigned unsigned_val;
uint32_t uint32_val;
uint32_t uint32_t_val;
uint64_t uint64_val;
uint64_t uint64_t_val;
size_t size_val;
ssize_t ssize_val;
const char *str_val;
};
/* Filled in by initialization. */
ql_elm(emitter_col_t) link;
};
typedef struct emitter_row_s emitter_row_t;
struct emitter_row_s {
ql_head(emitter_col_t) cols;
};
typedef struct emitter_s emitter_t;
struct emitter_s {
emitter_output_t output;
/* The output information. */
void (*write_cb)(void *, const char *);
void *cbopaque;
int nesting_depth;
/* True if we've already emitted a value at the given depth. */
bool item_at_depth;
/* True if we emitted a key and will emit corresponding value next. */
bool emitted_key;
};
/* Internal convenience function. Write to the emitter the given string. */
JEMALLOC_FORMAT_PRINTF(2, 3)
static inline void
emitter_printf(emitter_t *emitter, const char *format, ...) {
va_list ap;
va_start(ap, format);
malloc_vcprintf(emitter->write_cb, emitter->cbopaque, format, ap);
va_end(ap);
}
static inline const char * JEMALLOC_FORMAT_ARG(3)
emitter_gen_fmt(char *out_fmt, size_t out_size, const char *fmt_specifier,
emitter_justify_t justify, int width) {
size_t written;
fmt_specifier++;
if (justify == emitter_justify_none) {
written = malloc_snprintf(out_fmt, out_size,
"%%%s", fmt_specifier);
} else if (justify == emitter_justify_left) {
written = malloc_snprintf(out_fmt, out_size,
"%%-%d%s", width, fmt_specifier);
} else {
written = malloc_snprintf(out_fmt, out_size,
"%%%d%s", width, fmt_specifier);
}
/* Only happens in case of bad format string, which *we* choose. */
assert(written < out_size);
return out_fmt;
}
/*
* Internal. Emit the given value type in the relevant encoding (so that the
* bool true gets mapped to json "true", but the string "true" gets mapped to
* json "\"true\"", for instance.
*
* Width is ignored if justify is emitter_justify_none.
*/
static inline void
emitter_print_value(emitter_t *emitter, emitter_justify_t justify, int width,
emitter_type_t value_type, const void *value) {
size_t str_written;
#define BUF_SIZE 256
#define FMT_SIZE 10
/*
* We dynamically generate a format string to emit, to let us use the
* snprintf machinery. This is kinda hacky, but gets the job done
* quickly without having to think about the various snprintf edge
* cases.
*/
char fmt[FMT_SIZE];
char buf[BUF_SIZE];
#define EMIT_SIMPLE(type, format) \
emitter_printf(emitter, \
emitter_gen_fmt(fmt, FMT_SIZE, format, justify, width), \
*(const type *)value);
switch (value_type) {
case emitter_type_bool:
emitter_printf(emitter,
emitter_gen_fmt(fmt, FMT_SIZE, "%s", justify, width),
*(const bool *)value ? "true" : "false");
break;
case emitter_type_int:
EMIT_SIMPLE(int, "%d")
break;
case emitter_type_unsigned:
EMIT_SIMPLE(unsigned, "%u")
break;
case emitter_type_ssize:
EMIT_SIMPLE(ssize_t, "%zd")
break;
case emitter_type_size:
EMIT_SIMPLE(size_t, "%zu")
break;
case emitter_type_string:
str_written = malloc_snprintf(buf, BUF_SIZE, "\"%s\"",
*(const char *const *)value);
/*
* We control the strings we output; we shouldn't get anything
* anywhere near the fmt size.
*/
assert(str_written < BUF_SIZE);
emitter_printf(emitter,
emitter_gen_fmt(fmt, FMT_SIZE, "%s", justify, width), buf);
break;
case emitter_type_uint32:
EMIT_SIMPLE(uint32_t, "%" FMTu32)
break;
case emitter_type_uint64:
EMIT_SIMPLE(uint64_t, "%" FMTu64)
break;
case emitter_type_title:
EMIT_SIMPLE(char *const, "%s");
break;
default:
unreachable();
}
#undef BUF_SIZE
#undef FMT_SIZE
}
/* Internal functions. In json mode, tracks nesting state. */
static inline void
emitter_nest_inc(emitter_t *emitter) {
emitter->nesting_depth++;
emitter->item_at_depth = false;
}
static inline void
emitter_nest_dec(emitter_t *emitter) {
emitter->nesting_depth--;
emitter->item_at_depth = true;
}
static inline void
emitter_indent(emitter_t *emitter) {
int amount = emitter->nesting_depth;
const char *indent_str;
if (emitter->output == emitter_output_json) {
indent_str = "\t";
} else {
amount *= 2;
indent_str = " ";
}
for (int i = 0; i < amount; i++) {
emitter_printf(emitter, "%s", indent_str);
}
}
static inline void
emitter_json_key_prefix(emitter_t *emitter) {
if (emitter->emitted_key) {
emitter->emitted_key = false;
return;
}
emitter_printf(emitter, "%s\n", emitter->item_at_depth ? "," : "");
emitter_indent(emitter);
}
/******************************************************************************/
/* Public functions for emitter_t. */
static inline void
emitter_init(emitter_t *emitter, emitter_output_t emitter_output,
void (*write_cb)(void *, const char *), void *cbopaque) {
emitter->output = emitter_output;
emitter->write_cb = write_cb;
emitter->cbopaque = cbopaque;
emitter->item_at_depth = false;
emitter->emitted_key = false;
emitter->nesting_depth = 0;
}
/******************************************************************************/
/* JSON public API. */
/*
* Emits a key (e.g. as appears in an object). The next json entity emitted will
* be the corresponding value.
*/
static inline void
emitter_json_key(emitter_t *emitter, const char *json_key) {
if (emitter->output == emitter_output_json) {
emitter_json_key_prefix(emitter);
emitter_printf(emitter, "\"%s\": ", json_key);
emitter->emitted_key = true;
}
}
static inline void
emitter_json_value(emitter_t *emitter, emitter_type_t value_type,
const void *value) {
if (emitter->output == emitter_output_json) {
emitter_json_key_prefix(emitter);
emitter_print_value(emitter, emitter_justify_none, -1,
value_type, value);
emitter->item_at_depth = true;
}
}
/* Shorthand for calling emitter_json_key and then emitter_json_value. */
static inline void
emitter_json_kv(emitter_t *emitter, const char *json_key,
emitter_type_t value_type, const void *value) {
emitter_json_key(emitter, json_key);
emitter_json_value(emitter, value_type, value);
}
static inline void
emitter_json_array_begin(emitter_t *emitter) {
if (emitter->output == emitter_output_json) {
emitter_json_key_prefix(emitter);
emitter_printf(emitter, "[");
emitter_nest_inc(emitter);
}
}
/* Shorthand for calling emitter_json_key and then emitter_json_array_begin. */
static inline void
emitter_json_array_kv_begin(emitter_t *emitter, const char *json_key) {
emitter_json_key(emitter, json_key);
emitter_json_array_begin(emitter);
}
static inline void
emitter_json_array_end(emitter_t *emitter) {
if (emitter->output == emitter_output_json) {
assert(emitter->nesting_depth > 0);
emitter_nest_dec(emitter);
emitter_printf(emitter, "\n");
emitter_indent(emitter);
emitter_printf(emitter, "]");
}
}
static inline void
emitter_json_object_begin(emitter_t *emitter) {
if (emitter->output == emitter_output_json) {
emitter_json_key_prefix(emitter);
emitter_printf(emitter, "{");
emitter_nest_inc(emitter);
}
}
/* Shorthand for calling emitter_json_key and then emitter_json_object_begin. */
static inline void
emitter_json_object_kv_begin(emitter_t *emitter, const char *json_key) {
emitter_json_key(emitter, json_key);
emitter_json_object_begin(emitter);
}
static inline void
emitter_json_object_end(emitter_t *emitter) {
if (emitter->output == emitter_output_json) {
assert(emitter->nesting_depth > 0);
emitter_nest_dec(emitter);
emitter_printf(emitter, "\n");
emitter_indent(emitter);
emitter_printf(emitter, "}");
}
}
/******************************************************************************/
/* Table public API. */
static inline void
emitter_table_dict_begin(emitter_t *emitter, const char *table_key) {
if (emitter->output == emitter_output_table) {
emitter_indent(emitter);
emitter_printf(emitter, "%s\n", table_key);
emitter_nest_inc(emitter);
}
}
static inline void
emitter_table_dict_end(emitter_t *emitter) {
if (emitter->output == emitter_output_table) {
emitter_nest_dec(emitter);
}
}
static inline void
emitter_table_kv_note(emitter_t *emitter, const char *table_key,
emitter_type_t value_type, const void *value,
const char *table_note_key, emitter_type_t table_note_value_type,
const void *table_note_value) {
if (emitter->output == emitter_output_table) {
emitter_indent(emitter);
emitter_printf(emitter, "%s: ", table_key);
emitter_print_value(emitter, emitter_justify_none, -1,
value_type, value);
if (table_note_key != NULL) {
emitter_printf(emitter, " (%s: ", table_note_key);
emitter_print_value(emitter, emitter_justify_none, -1,
table_note_value_type, table_note_value);
emitter_printf(emitter, ")");
}
emitter_printf(emitter, "\n");
}
emitter->item_at_depth = true;
}
static inline void
emitter_table_kv(emitter_t *emitter, const char *table_key,
emitter_type_t value_type, const void *value) {
emitter_table_kv_note(emitter, table_key, value_type, value, NULL,
emitter_type_bool, NULL);
}
/* Write to the emitter the given string, but only in table mode. */
JEMALLOC_FORMAT_PRINTF(2, 3)
static inline void
emitter_table_printf(emitter_t *emitter, const char *format, ...) {
if (emitter->output == emitter_output_table) {
va_list ap;
va_start(ap, format);
malloc_vcprintf(emitter->write_cb, emitter->cbopaque, format, ap);
va_end(ap);
}
}
static inline void
emitter_table_row(emitter_t *emitter, emitter_row_t *row) {
if (emitter->output != emitter_output_table) {
return;
}
emitter_col_t *col;
ql_foreach(col, &row->cols, link) {
emitter_print_value(emitter, col->justify, col->width,
col->type, (const void *)&col->bool_val);
}
emitter_table_printf(emitter, "\n");
}
static inline void
emitter_row_init(emitter_row_t *row) {
ql_new(&row->cols);
}
static inline void
emitter_col_init(emitter_col_t *col, emitter_row_t *row) {
ql_elm_new(col, link);
ql_tail_insert(&row->cols, col, link);
}
/******************************************************************************/
/*
* Generalized public API. Emits using either JSON or table, according to
* settings in the emitter_t. */
/*
* Note emits a different kv pair as well, but only in table mode. Omits the
* note if table_note_key is NULL.
*/
static inline void
emitter_kv_note(emitter_t *emitter, const char *json_key, const char *table_key,
emitter_type_t value_type, const void *value,
const char *table_note_key, emitter_type_t table_note_value_type,
const void *table_note_value) {
if (emitter->output == emitter_output_json) {
emitter_json_key(emitter, json_key);
emitter_json_value(emitter, value_type, value);
} else {
emitter_table_kv_note(emitter, table_key, value_type, value,
table_note_key, table_note_value_type, table_note_value);
}
emitter->item_at_depth = true;
}
static inline void
emitter_kv(emitter_t *emitter, const char *json_key, const char *table_key,
emitter_type_t value_type, const void *value) {
emitter_kv_note(emitter, json_key, table_key, value_type, value, NULL,
emitter_type_bool, NULL);
}
static inline void
emitter_dict_begin(emitter_t *emitter, const char *json_key,
const char *table_header) {
if (emitter->output == emitter_output_json) {
emitter_json_key(emitter, json_key);
emitter_json_object_begin(emitter);
} else {
emitter_table_dict_begin(emitter, table_header);
}
}
static inline void
emitter_dict_end(emitter_t *emitter) {
if (emitter->output == emitter_output_json) {
emitter_json_object_end(emitter);
} else {
emitter_table_dict_end(emitter);
}
}
static inline void
emitter_begin(emitter_t *emitter) {
if (emitter->output == emitter_output_json) {
assert(emitter->nesting_depth == 0);
emitter_printf(emitter, "{");
emitter_nest_inc(emitter);
} else {
/*
* This guarantees that we always call write_cb at least once.
* This is useful if some invariant is established by each call
* to write_cb, but doesn't hold initially: e.g., some buffer
* holds a null-terminated string.
*/
emitter_printf(emitter, "%s", "");
}
}
static inline void
emitter_end(emitter_t *emitter) {
if (emitter->output == emitter_output_json) {
assert(emitter->nesting_depth == 1);
emitter_nest_dec(emitter);
emitter_printf(emitter, "\n}\n");
}
}
#endif /* JEMALLOC_INTERNAL_EMITTER_H */

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#ifndef JEMALLOC_INTERNAL_EXTENT_DSS_H
#define JEMALLOC_INTERNAL_EXTENT_DSS_H
typedef enum {
dss_prec_disabled = 0,
dss_prec_primary = 1,
dss_prec_secondary = 2,
dss_prec_limit = 3
} dss_prec_t;
#define DSS_PREC_DEFAULT dss_prec_secondary
#define DSS_DEFAULT "secondary"
extern const char *dss_prec_names[];
extern const char *opt_dss;
dss_prec_t extent_dss_prec_get(void);
bool extent_dss_prec_set(dss_prec_t dss_prec);
void *extent_alloc_dss(tsdn_t *tsdn, arena_t *arena, void *new_addr,
size_t size, size_t alignment, bool *zero, bool *commit);
bool extent_in_dss(void *addr);
bool extent_dss_mergeable(void *addr_a, void *addr_b);
void extent_dss_boot(void);
#endif /* JEMALLOC_INTERNAL_EXTENT_DSS_H */

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#ifndef JEMALLOC_INTERNAL_EXTENT_EXTERNS_H
#define JEMALLOC_INTERNAL_EXTENT_EXTERNS_H
#include "jemalloc/internal/mutex.h"
#include "jemalloc/internal/mutex_pool.h"
#include "jemalloc/internal/ph.h"
#include "jemalloc/internal/rtree.h"
extern size_t opt_lg_extent_max_active_fit;
extern rtree_t extents_rtree;
extern const extent_hooks_t extent_hooks_default;
extern mutex_pool_t extent_mutex_pool;
extent_t *extent_alloc(tsdn_t *tsdn, arena_t *arena);
void extent_dalloc(tsdn_t *tsdn, arena_t *arena, extent_t *extent);
extent_hooks_t *extent_hooks_get(arena_t *arena);
extent_hooks_t *extent_hooks_set(tsd_t *tsd, arena_t *arena,
extent_hooks_t *extent_hooks);
#ifdef JEMALLOC_JET
size_t extent_size_quantize_floor(size_t size);
size_t extent_size_quantize_ceil(size_t size);
#endif
ph_proto(, extent_avail_, extent_tree_t, extent_t)
ph_proto(, extent_heap_, extent_heap_t, extent_t)
bool extents_init(tsdn_t *tsdn, extents_t *extents, extent_state_t state,
bool delay_coalesce);
extent_state_t extents_state_get(const extents_t *extents);
size_t extents_npages_get(extents_t *extents);
/* Get the number of extents in the given page size index. */
size_t extents_nextents_get(extents_t *extents, pszind_t ind);
/* Get the sum total bytes of the extents in the given page size index. */
size_t extents_nbytes_get(extents_t *extents, pszind_t ind);
extent_t *extents_alloc(tsdn_t *tsdn, arena_t *arena,
extent_hooks_t **r_extent_hooks, extents_t *extents, void *new_addr,
size_t size, size_t pad, size_t alignment, bool slab, szind_t szind,
bool *zero, bool *commit);
void extents_dalloc(tsdn_t *tsdn, arena_t *arena,
extent_hooks_t **r_extent_hooks, extents_t *extents, extent_t *extent);
extent_t *extents_evict(tsdn_t *tsdn, arena_t *arena,
extent_hooks_t **r_extent_hooks, extents_t *extents, size_t npages_min);
void extents_prefork(tsdn_t *tsdn, extents_t *extents);
void extents_postfork_parent(tsdn_t *tsdn, extents_t *extents);
void extents_postfork_child(tsdn_t *tsdn, extents_t *extents);
extent_t *extent_alloc_wrapper(tsdn_t *tsdn, arena_t *arena,
extent_hooks_t **r_extent_hooks, void *new_addr, size_t size, size_t pad,
size_t alignment, bool slab, szind_t szind, bool *zero, bool *commit);
void extent_dalloc_gap(tsdn_t *tsdn, arena_t *arena, extent_t *extent);
void extent_dalloc_wrapper(tsdn_t *tsdn, arena_t *arena,
extent_hooks_t **r_extent_hooks, extent_t *extent);
void extent_destroy_wrapper(tsdn_t *tsdn, arena_t *arena,
extent_hooks_t **r_extent_hooks, extent_t *extent);
bool extent_commit_wrapper(tsdn_t *tsdn, arena_t *arena,
extent_hooks_t **r_extent_hooks, extent_t *extent, size_t offset,
size_t length);
bool extent_decommit_wrapper(tsdn_t *tsdn, arena_t *arena,
extent_hooks_t **r_extent_hooks, extent_t *extent, size_t offset,
size_t length);
bool extent_purge_lazy_wrapper(tsdn_t *tsdn, arena_t *arena,
extent_hooks_t **r_extent_hooks, extent_t *extent, size_t offset,
size_t length);
bool extent_purge_forced_wrapper(tsdn_t *tsdn, arena_t *arena,
extent_hooks_t **r_extent_hooks, extent_t *extent, size_t offset,
size_t length);
extent_t *extent_split_wrapper(tsdn_t *tsdn, arena_t *arena,
extent_hooks_t **r_extent_hooks, extent_t *extent, size_t size_a,
szind_t szind_a, bool slab_a, size_t size_b, szind_t szind_b, bool slab_b);
bool extent_merge_wrapper(tsdn_t *tsdn, arena_t *arena,
extent_hooks_t **r_extent_hooks, extent_t *a, extent_t *b);
bool extent_boot(void);
void extent_util_stats_get(tsdn_t *tsdn, const void *ptr,
size_t *nfree, size_t *nregs, size_t *size);
void extent_util_stats_verbose_get(tsdn_t *tsdn, const void *ptr,
size_t *nfree, size_t *nregs, size_t *size,
size_t *bin_nfree, size_t *bin_nregs, void **slabcur_addr);
#endif /* JEMALLOC_INTERNAL_EXTENT_EXTERNS_H */

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#ifndef JEMALLOC_INTERNAL_EXTENT_INLINES_H
#define JEMALLOC_INTERNAL_EXTENT_INLINES_H
#include "jemalloc/internal/mutex.h"
#include "jemalloc/internal/mutex_pool.h"
#include "jemalloc/internal/pages.h"
#include "jemalloc/internal/prng.h"
#include "jemalloc/internal/ql.h"
#include "jemalloc/internal/sc.h"
#include "jemalloc/internal/sz.h"
static inline void
extent_lock(tsdn_t *tsdn, extent_t *extent) {
assert(extent != NULL);
mutex_pool_lock(tsdn, &extent_mutex_pool, (uintptr_t)extent);
}
static inline void
extent_unlock(tsdn_t *tsdn, extent_t *extent) {
assert(extent != NULL);
mutex_pool_unlock(tsdn, &extent_mutex_pool, (uintptr_t)extent);
}
static inline void
extent_lock2(tsdn_t *tsdn, extent_t *extent1, extent_t *extent2) {
assert(extent1 != NULL && extent2 != NULL);
mutex_pool_lock2(tsdn, &extent_mutex_pool, (uintptr_t)extent1,
(uintptr_t)extent2);
}
static inline void
extent_unlock2(tsdn_t *tsdn, extent_t *extent1, extent_t *extent2) {
assert(extent1 != NULL && extent2 != NULL);
mutex_pool_unlock2(tsdn, &extent_mutex_pool, (uintptr_t)extent1,
(uintptr_t)extent2);
}
static inline unsigned
extent_arena_ind_get(const extent_t *extent) {
unsigned arena_ind = (unsigned)((extent->e_bits &
EXTENT_BITS_ARENA_MASK) >> EXTENT_BITS_ARENA_SHIFT);
assert(arena_ind < MALLOCX_ARENA_LIMIT);
return arena_ind;
}
static inline arena_t *
extent_arena_get(const extent_t *extent) {
unsigned arena_ind = extent_arena_ind_get(extent);
return (arena_t *)atomic_load_p(&arenas[arena_ind], ATOMIC_ACQUIRE);
}
static inline szind_t
extent_szind_get_maybe_invalid(const extent_t *extent) {
szind_t szind = (szind_t)((extent->e_bits & EXTENT_BITS_SZIND_MASK) >>
EXTENT_BITS_SZIND_SHIFT);
assert(szind <= SC_NSIZES);
return szind;
}
static inline szind_t
extent_szind_get(const extent_t *extent) {
szind_t szind = extent_szind_get_maybe_invalid(extent);
assert(szind < SC_NSIZES); /* Never call when "invalid". */
return szind;
}
static inline size_t
extent_usize_get(const extent_t *extent) {
return sz_index2size(extent_szind_get(extent));
}
static inline unsigned
extent_binshard_get(const extent_t *extent) {
unsigned binshard = (unsigned)((extent->e_bits &
EXTENT_BITS_BINSHARD_MASK) >> EXTENT_BITS_BINSHARD_SHIFT);
assert(binshard < bin_infos[extent_szind_get(extent)].n_shards);
return binshard;
}
static inline size_t
extent_sn_get(const extent_t *extent) {
return (size_t)((extent->e_bits & EXTENT_BITS_SN_MASK) >>
EXTENT_BITS_SN_SHIFT);
}
static inline extent_state_t
extent_state_get(const extent_t *extent) {
return (extent_state_t)((extent->e_bits & EXTENT_BITS_STATE_MASK) >>
EXTENT_BITS_STATE_SHIFT);
}
static inline bool
extent_zeroed_get(const extent_t *extent) {
return (bool)((extent->e_bits & EXTENT_BITS_ZEROED_MASK) >>
EXTENT_BITS_ZEROED_SHIFT);
}
static inline bool
extent_committed_get(const extent_t *extent) {
return (bool)((extent->e_bits & EXTENT_BITS_COMMITTED_MASK) >>
EXTENT_BITS_COMMITTED_SHIFT);
}
static inline bool
extent_dumpable_get(const extent_t *extent) {
return (bool)((extent->e_bits & EXTENT_BITS_DUMPABLE_MASK) >>
EXTENT_BITS_DUMPABLE_SHIFT);
}
static inline bool
extent_slab_get(const extent_t *extent) {
return (bool)((extent->e_bits & EXTENT_BITS_SLAB_MASK) >>
EXTENT_BITS_SLAB_SHIFT);
}
static inline unsigned
extent_nfree_get(const extent_t *extent) {
assert(extent_slab_get(extent));
return (unsigned)((extent->e_bits & EXTENT_BITS_NFREE_MASK) >>
EXTENT_BITS_NFREE_SHIFT);
}
static inline void *
extent_base_get(const extent_t *extent) {
assert(extent->e_addr == PAGE_ADDR2BASE(extent->e_addr) ||
!extent_slab_get(extent));
return PAGE_ADDR2BASE(extent->e_addr);
}
static inline void *
extent_addr_get(const extent_t *extent) {
assert(extent->e_addr == PAGE_ADDR2BASE(extent->e_addr) ||
!extent_slab_get(extent));
return extent->e_addr;
}
static inline size_t
extent_size_get(const extent_t *extent) {
return (extent->e_size_esn & EXTENT_SIZE_MASK);
}
static inline size_t
extent_esn_get(const extent_t *extent) {
return (extent->e_size_esn & EXTENT_ESN_MASK);
}
static inline size_t
extent_bsize_get(const extent_t *extent) {
return extent->e_bsize;
}
static inline void *
extent_before_get(const extent_t *extent) {
return (void *)((uintptr_t)extent_base_get(extent) - PAGE);
}
static inline void *
extent_last_get(const extent_t *extent) {
return (void *)((uintptr_t)extent_base_get(extent) +
extent_size_get(extent) - PAGE);
}
static inline void *
extent_past_get(const extent_t *extent) {
return (void *)((uintptr_t)extent_base_get(extent) +
extent_size_get(extent));
}
static inline arena_slab_data_t *
extent_slab_data_get(extent_t *extent) {
assert(extent_slab_get(extent));
return &extent->e_slab_data;
}
static inline const arena_slab_data_t *
extent_slab_data_get_const(const extent_t *extent) {
assert(extent_slab_get(extent));
return &extent->e_slab_data;
}
static inline prof_tctx_t *
extent_prof_tctx_get(const extent_t *extent) {
return (prof_tctx_t *)atomic_load_p(&extent->e_prof_tctx,
ATOMIC_ACQUIRE);
}
static inline nstime_t
extent_prof_alloc_time_get(const extent_t *extent) {
return extent->e_alloc_time;
}
static inline void
extent_arena_set(extent_t *extent, arena_t *arena) {
unsigned arena_ind = (arena != NULL) ? arena_ind_get(arena) : ((1U <<
MALLOCX_ARENA_BITS) - 1);
extent->e_bits = (extent->e_bits & ~EXTENT_BITS_ARENA_MASK) |
((uint64_t)arena_ind << EXTENT_BITS_ARENA_SHIFT);
}
static inline void
extent_binshard_set(extent_t *extent, unsigned binshard) {
/* The assertion assumes szind is set already. */
assert(binshard < bin_infos[extent_szind_get(extent)].n_shards);
extent->e_bits = (extent->e_bits & ~EXTENT_BITS_BINSHARD_MASK) |
((uint64_t)binshard << EXTENT_BITS_BINSHARD_SHIFT);
}
static inline void
extent_addr_set(extent_t *extent, void *addr) {
extent->e_addr = addr;
}
static inline void
extent_addr_randomize(tsdn_t *tsdn, extent_t *extent, size_t alignment) {
assert(extent_base_get(extent) == extent_addr_get(extent));
if (alignment < PAGE) {
unsigned lg_range = LG_PAGE -
lg_floor(CACHELINE_CEILING(alignment));
size_t r;
if (!tsdn_null(tsdn)) {
tsd_t *tsd = tsdn_tsd(tsdn);
r = (size_t)prng_lg_range_u64(
tsd_offset_statep_get(tsd), lg_range);
} else {
r = prng_lg_range_zu(
&extent_arena_get(extent)->offset_state,
lg_range, true);
}
uintptr_t random_offset = ((uintptr_t)r) << (LG_PAGE -
lg_range);
extent->e_addr = (void *)((uintptr_t)extent->e_addr +
random_offset);
assert(ALIGNMENT_ADDR2BASE(extent->e_addr, alignment) ==
extent->e_addr);
}
}
static inline void
extent_size_set(extent_t *extent, size_t size) {
assert((size & ~EXTENT_SIZE_MASK) == 0);
extent->e_size_esn = size | (extent->e_size_esn & ~EXTENT_SIZE_MASK);
}
static inline void
extent_esn_set(extent_t *extent, size_t esn) {
extent->e_size_esn = (extent->e_size_esn & ~EXTENT_ESN_MASK) | (esn &
EXTENT_ESN_MASK);
}
static inline void
extent_bsize_set(extent_t *extent, size_t bsize) {
extent->e_bsize = bsize;
}
static inline void
extent_szind_set(extent_t *extent, szind_t szind) {
assert(szind <= SC_NSIZES); /* SC_NSIZES means "invalid". */
extent->e_bits = (extent->e_bits & ~EXTENT_BITS_SZIND_MASK) |
((uint64_t)szind << EXTENT_BITS_SZIND_SHIFT);
}
static inline void
extent_nfree_set(extent_t *extent, unsigned nfree) {
assert(extent_slab_get(extent));
extent->e_bits = (extent->e_bits & ~EXTENT_BITS_NFREE_MASK) |
((uint64_t)nfree << EXTENT_BITS_NFREE_SHIFT);
}
static inline void
extent_nfree_binshard_set(extent_t *extent, unsigned nfree, unsigned binshard) {
/* The assertion assumes szind is set already. */
assert(binshard < bin_infos[extent_szind_get(extent)].n_shards);
extent->e_bits = (extent->e_bits &
(~EXTENT_BITS_NFREE_MASK & ~EXTENT_BITS_BINSHARD_MASK)) |
((uint64_t)binshard << EXTENT_BITS_BINSHARD_SHIFT) |
((uint64_t)nfree << EXTENT_BITS_NFREE_SHIFT);
}
static inline void
extent_nfree_inc(extent_t *extent) {
assert(extent_slab_get(extent));
extent->e_bits += ((uint64_t)1U << EXTENT_BITS_NFREE_SHIFT);
}
static inline void
extent_nfree_dec(extent_t *extent) {
assert(extent_slab_get(extent));
extent->e_bits -= ((uint64_t)1U << EXTENT_BITS_NFREE_SHIFT);
}
static inline void
extent_nfree_sub(extent_t *extent, uint64_t n) {
assert(extent_slab_get(extent));
extent->e_bits -= (n << EXTENT_BITS_NFREE_SHIFT);
}
static inline void
extent_sn_set(extent_t *extent, size_t sn) {
extent->e_bits = (extent->e_bits & ~EXTENT_BITS_SN_MASK) |
((uint64_t)sn << EXTENT_BITS_SN_SHIFT);
}
static inline void
extent_state_set(extent_t *extent, extent_state_t state) {
extent->e_bits = (extent->e_bits & ~EXTENT_BITS_STATE_MASK) |
((uint64_t)state << EXTENT_BITS_STATE_SHIFT);
}
static inline void
extent_zeroed_set(extent_t *extent, bool zeroed) {
extent->e_bits = (extent->e_bits & ~EXTENT_BITS_ZEROED_MASK) |
((uint64_t)zeroed << EXTENT_BITS_ZEROED_SHIFT);
}
static inline void
extent_committed_set(extent_t *extent, bool committed) {
extent->e_bits = (extent->e_bits & ~EXTENT_BITS_COMMITTED_MASK) |
((uint64_t)committed << EXTENT_BITS_COMMITTED_SHIFT);
}
static inline void
extent_dumpable_set(extent_t *extent, bool dumpable) {
extent->e_bits = (extent->e_bits & ~EXTENT_BITS_DUMPABLE_MASK) |
((uint64_t)dumpable << EXTENT_BITS_DUMPABLE_SHIFT);
}
static inline void
extent_slab_set(extent_t *extent, bool slab) {
extent->e_bits = (extent->e_bits & ~EXTENT_BITS_SLAB_MASK) |
((uint64_t)slab << EXTENT_BITS_SLAB_SHIFT);
}
static inline void
extent_prof_tctx_set(extent_t *extent, prof_tctx_t *tctx) {
atomic_store_p(&extent->e_prof_tctx, tctx, ATOMIC_RELEASE);
}
static inline void
extent_prof_alloc_time_set(extent_t *extent, nstime_t t) {
nstime_copy(&extent->e_alloc_time, &t);
}
static inline bool
extent_is_head_get(extent_t *extent) {
if (maps_coalesce) {
not_reached();
}
return (bool)((extent->e_bits & EXTENT_BITS_IS_HEAD_MASK) >>
EXTENT_BITS_IS_HEAD_SHIFT);
}
static inline void
extent_is_head_set(extent_t *extent, bool is_head) {
if (maps_coalesce) {
not_reached();
}
extent->e_bits = (extent->e_bits & ~EXTENT_BITS_IS_HEAD_MASK) |
((uint64_t)is_head << EXTENT_BITS_IS_HEAD_SHIFT);
}
static inline void
extent_init(extent_t *extent, arena_t *arena, void *addr, size_t size,
bool slab, szind_t szind, size_t sn, extent_state_t state, bool zeroed,
bool committed, bool dumpable, extent_head_state_t is_head) {
assert(addr == PAGE_ADDR2BASE(addr) || !slab);
extent_arena_set(extent, arena);
extent_addr_set(extent, addr);
extent_size_set(extent, size);
extent_slab_set(extent, slab);
extent_szind_set(extent, szind);
extent_sn_set(extent, sn);
extent_state_set(extent, state);
extent_zeroed_set(extent, zeroed);
extent_committed_set(extent, committed);
extent_dumpable_set(extent, dumpable);
ql_elm_new(extent, ql_link);
if (!maps_coalesce) {
extent_is_head_set(extent, (is_head == EXTENT_IS_HEAD) ? true :
false);
}
if (config_prof) {
extent_prof_tctx_set(extent, NULL);
}
}
static inline void
extent_binit(extent_t *extent, void *addr, size_t bsize, size_t sn) {
extent_arena_set(extent, NULL);
extent_addr_set(extent, addr);
extent_bsize_set(extent, bsize);
extent_slab_set(extent, false);
extent_szind_set(extent, SC_NSIZES);
extent_sn_set(extent, sn);
extent_state_set(extent, extent_state_active);
extent_zeroed_set(extent, true);
extent_committed_set(extent, true);
extent_dumpable_set(extent, true);
}
static inline void
extent_list_init(extent_list_t *list) {
ql_new(list);
}
static inline extent_t *
extent_list_first(const extent_list_t *list) {
return ql_first(list);
}
static inline extent_t *
extent_list_last(const extent_list_t *list) {
return ql_last(list, ql_link);
}
static inline void
extent_list_append(extent_list_t *list, extent_t *extent) {
ql_tail_insert(list, extent, ql_link);
}
static inline void
extent_list_prepend(extent_list_t *list, extent_t *extent) {
ql_head_insert(list, extent, ql_link);
}
static inline void
extent_list_replace(extent_list_t *list, extent_t *to_remove,
extent_t *to_insert) {
ql_after_insert(to_remove, to_insert, ql_link);
ql_remove(list, to_remove, ql_link);
}
static inline void
extent_list_remove(extent_list_t *list, extent_t *extent) {
ql_remove(list, extent, ql_link);
}
static inline int
extent_sn_comp(const extent_t *a, const extent_t *b) {
size_t a_sn = extent_sn_get(a);
size_t b_sn = extent_sn_get(b);
return (a_sn > b_sn) - (a_sn < b_sn);
}
static inline int
extent_esn_comp(const extent_t *a, const extent_t *b) {
size_t a_esn = extent_esn_get(a);
size_t b_esn = extent_esn_get(b);
return (a_esn > b_esn) - (a_esn < b_esn);
}
static inline int
extent_ad_comp(const extent_t *a, const extent_t *b) {
uintptr_t a_addr = (uintptr_t)extent_addr_get(a);
uintptr_t b_addr = (uintptr_t)extent_addr_get(b);
return (a_addr > b_addr) - (a_addr < b_addr);
}
static inline int
extent_ead_comp(const extent_t *a, const extent_t *b) {
uintptr_t a_eaddr = (uintptr_t)a;
uintptr_t b_eaddr = (uintptr_t)b;
return (a_eaddr > b_eaddr) - (a_eaddr < b_eaddr);
}
static inline int
extent_snad_comp(const extent_t *a, const extent_t *b) {
int ret;
ret = extent_sn_comp(a, b);
if (ret != 0) {
return ret;
}
ret = extent_ad_comp(a, b);
return ret;
}
static inline int
extent_esnead_comp(const extent_t *a, const extent_t *b) {
int ret;
ret = extent_esn_comp(a, b);
if (ret != 0) {
return ret;
}
ret = extent_ead_comp(a, b);
return ret;
}
#endif /* JEMALLOC_INTERNAL_EXTENT_INLINES_H */

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#ifndef JEMALLOC_INTERNAL_EXTENT_MMAP_EXTERNS_H
#define JEMALLOC_INTERNAL_EXTENT_MMAP_EXTERNS_H
extern bool opt_retain;
void *extent_alloc_mmap(void *new_addr, size_t size, size_t alignment,
bool *zero, bool *commit);
bool extent_dalloc_mmap(void *addr, size_t size);
#endif /* JEMALLOC_INTERNAL_EXTENT_MMAP_EXTERNS_H */

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#ifndef JEMALLOC_INTERNAL_EXTENT_STRUCTS_H
#define JEMALLOC_INTERNAL_EXTENT_STRUCTS_H
#include "jemalloc/internal/atomic.h"
#include "jemalloc/internal/bit_util.h"
#include "jemalloc/internal/bitmap.h"
#include "jemalloc/internal/mutex.h"
#include "jemalloc/internal/ql.h"
#include "jemalloc/internal/ph.h"
#include "jemalloc/internal/sc.h"
typedef enum {
extent_state_active = 0,
extent_state_dirty = 1,
extent_state_muzzy = 2,
extent_state_retained = 3
} extent_state_t;
/* Extent (span of pages). Use accessor functions for e_* fields. */
struct extent_s {
/*
* Bitfield containing several fields:
*
* a: arena_ind
* b: slab
* c: committed
* d: dumpable
* z: zeroed
* t: state
* i: szind
* f: nfree
* s: bin_shard
* n: sn
*
* nnnnnnnn ... nnnnnnss ssssffff ffffffii iiiiiitt zdcbaaaa aaaaaaaa
*
* arena_ind: Arena from which this extent came, or all 1 bits if
* unassociated.
*
* slab: The slab flag indicates whether the extent is used for a slab
* of small regions. This helps differentiate small size classes,
* and it indicates whether interior pointers can be looked up via
* iealloc().
*
* committed: The committed flag indicates whether physical memory is
* committed to the extent, whether explicitly or implicitly
* as on a system that overcommits and satisfies physical
* memory needs on demand via soft page faults.
*
* dumpable: The dumpable flag indicates whether or not we've set the
* memory in question to be dumpable. Note that this
* interacts somewhat subtly with user-specified extent hooks,
* since we don't know if *they* are fiddling with
* dumpability (in which case, we don't want to undo whatever
* they're doing). To deal with this scenario, we:
* - Make dumpable false only for memory allocated with the
* default hooks.
* - Only allow memory to go from non-dumpable to dumpable,
* and only once.
* - Never make the OS call to allow dumping when the
* dumpable bit is already set.
* These three constraints mean that we will never
* accidentally dump user memory that the user meant to set
* nondumpable with their extent hooks.
*
*
* zeroed: The zeroed flag is used by extent recycling code to track
* whether memory is zero-filled.
*
* state: The state flag is an extent_state_t.
*
* szind: The szind flag indicates usable size class index for
* allocations residing in this extent, regardless of whether the
* extent is a slab. Extent size and usable size often differ
* even for non-slabs, either due to sz_large_pad or promotion of
* sampled small regions.
*
* nfree: Number of free regions in slab.
*
* bin_shard: the shard of the bin from which this extent came.
*
* sn: Serial number (potentially non-unique).
*
* Serial numbers may wrap around if !opt_retain, but as long as
* comparison functions fall back on address comparison for equal
* serial numbers, stable (if imperfect) ordering is maintained.
*
* Serial numbers may not be unique even in the absence of
* wrap-around, e.g. when splitting an extent and assigning the same
* serial number to both resulting adjacent extents.
*/
uint64_t e_bits;
#define MASK(CURRENT_FIELD_WIDTH, CURRENT_FIELD_SHIFT) ((((((uint64_t)0x1U) << (CURRENT_FIELD_WIDTH)) - 1)) << (CURRENT_FIELD_SHIFT))
#define EXTENT_BITS_ARENA_WIDTH MALLOCX_ARENA_BITS
#define EXTENT_BITS_ARENA_SHIFT 0
#define EXTENT_BITS_ARENA_MASK MASK(EXTENT_BITS_ARENA_WIDTH, EXTENT_BITS_ARENA_SHIFT)
#define EXTENT_BITS_SLAB_WIDTH 1
#define EXTENT_BITS_SLAB_SHIFT (EXTENT_BITS_ARENA_WIDTH + EXTENT_BITS_ARENA_SHIFT)
#define EXTENT_BITS_SLAB_MASK MASK(EXTENT_BITS_SLAB_WIDTH, EXTENT_BITS_SLAB_SHIFT)
#define EXTENT_BITS_COMMITTED_WIDTH 1
#define EXTENT_BITS_COMMITTED_SHIFT (EXTENT_BITS_SLAB_WIDTH + EXTENT_BITS_SLAB_SHIFT)
#define EXTENT_BITS_COMMITTED_MASK MASK(EXTENT_BITS_COMMITTED_WIDTH, EXTENT_BITS_COMMITTED_SHIFT)
#define EXTENT_BITS_DUMPABLE_WIDTH 1
#define EXTENT_BITS_DUMPABLE_SHIFT (EXTENT_BITS_COMMITTED_WIDTH + EXTENT_BITS_COMMITTED_SHIFT)
#define EXTENT_BITS_DUMPABLE_MASK MASK(EXTENT_BITS_DUMPABLE_WIDTH, EXTENT_BITS_DUMPABLE_SHIFT)
#define EXTENT_BITS_ZEROED_WIDTH 1
#define EXTENT_BITS_ZEROED_SHIFT (EXTENT_BITS_DUMPABLE_WIDTH + EXTENT_BITS_DUMPABLE_SHIFT)
#define EXTENT_BITS_ZEROED_MASK MASK(EXTENT_BITS_ZEROED_WIDTH, EXTENT_BITS_ZEROED_SHIFT)
#define EXTENT_BITS_STATE_WIDTH 2
#define EXTENT_BITS_STATE_SHIFT (EXTENT_BITS_ZEROED_WIDTH + EXTENT_BITS_ZEROED_SHIFT)
#define EXTENT_BITS_STATE_MASK MASK(EXTENT_BITS_STATE_WIDTH, EXTENT_BITS_STATE_SHIFT)
#define EXTENT_BITS_SZIND_WIDTH LG_CEIL(SC_NSIZES)
#define EXTENT_BITS_SZIND_SHIFT (EXTENT_BITS_STATE_WIDTH + EXTENT_BITS_STATE_SHIFT)
#define EXTENT_BITS_SZIND_MASK MASK(EXTENT_BITS_SZIND_WIDTH, EXTENT_BITS_SZIND_SHIFT)
#define EXTENT_BITS_NFREE_WIDTH (LG_SLAB_MAXREGS + 1)
#define EXTENT_BITS_NFREE_SHIFT (EXTENT_BITS_SZIND_WIDTH + EXTENT_BITS_SZIND_SHIFT)
#define EXTENT_BITS_NFREE_MASK MASK(EXTENT_BITS_NFREE_WIDTH, EXTENT_BITS_NFREE_SHIFT)
#define EXTENT_BITS_BINSHARD_WIDTH 6
#define EXTENT_BITS_BINSHARD_SHIFT (EXTENT_BITS_NFREE_WIDTH + EXTENT_BITS_NFREE_SHIFT)
#define EXTENT_BITS_BINSHARD_MASK MASK(EXTENT_BITS_BINSHARD_WIDTH, EXTENT_BITS_BINSHARD_SHIFT)
#define EXTENT_BITS_IS_HEAD_WIDTH 1
#define EXTENT_BITS_IS_HEAD_SHIFT (EXTENT_BITS_BINSHARD_WIDTH + EXTENT_BITS_BINSHARD_SHIFT)
#define EXTENT_BITS_IS_HEAD_MASK MASK(EXTENT_BITS_IS_HEAD_WIDTH, EXTENT_BITS_IS_HEAD_SHIFT)
#define EXTENT_BITS_SN_SHIFT (EXTENT_BITS_IS_HEAD_WIDTH + EXTENT_BITS_IS_HEAD_SHIFT)
#define EXTENT_BITS_SN_MASK (UINT64_MAX << EXTENT_BITS_SN_SHIFT)
/* Pointer to the extent that this structure is responsible for. */
void *e_addr;
union {
/*
* Extent size and serial number associated with the extent
* structure (different than the serial number for the extent at
* e_addr).
*
* ssssssss [...] ssssssss ssssnnnn nnnnnnnn
*/
size_t e_size_esn;
#define EXTENT_SIZE_MASK ((size_t)~(PAGE-1))
#define EXTENT_ESN_MASK ((size_t)PAGE-1)
/* Base extent size, which may not be a multiple of PAGE. */
size_t e_bsize;
};
/*
* List linkage, used by a variety of lists:
* - bin_t's slabs_full
* - extents_t's LRU
* - stashed dirty extents
* - arena's large allocations
*/
ql_elm(extent_t) ql_link;
/*
* Linkage for per size class sn/address-ordered heaps, and
* for extent_avail
*/
phn(extent_t) ph_link;
union {
/* Small region slab metadata. */
arena_slab_data_t e_slab_data;
/* Profiling data, used for large objects. */
struct {
/* Time when this was allocated. */
nstime_t e_alloc_time;
/* Points to a prof_tctx_t. */
atomic_p_t e_prof_tctx;
};
};
};
typedef ql_head(extent_t) extent_list_t;
typedef ph(extent_t) extent_tree_t;
typedef ph(extent_t) extent_heap_t;
/* Quantized collection of extents, with built-in LRU queue. */
struct extents_s {
malloc_mutex_t mtx;
/*
* Quantized per size class heaps of extents.
*
* Synchronization: mtx.
*/
extent_heap_t heaps[SC_NPSIZES + 1];
atomic_zu_t nextents[SC_NPSIZES + 1];
atomic_zu_t nbytes[SC_NPSIZES + 1];
/*
* Bitmap for which set bits correspond to non-empty heaps.
*
* Synchronization: mtx.
*/
bitmap_t bitmap[BITMAP_GROUPS(SC_NPSIZES + 1)];
/*
* LRU of all extents in heaps.
*
* Synchronization: mtx.
*/
extent_list_t lru;
/*
* Page sum for all extents in heaps.
*
* The synchronization here is a little tricky. Modifications to npages
* must hold mtx, but reads need not (though, a reader who sees npages
* without holding the mutex can't assume anything about the rest of the
* state of the extents_t).
*/
atomic_zu_t npages;
/* All stored extents must be in the same state. */
extent_state_t state;
/*
* If true, delay coalescing until eviction; otherwise coalesce during
* deallocation.
*/
bool delay_coalesce;
};
/*
* The following two structs are for experimental purposes. See
* experimental_utilization_query_ctl and
* experimental_utilization_batch_query_ctl in src/ctl.c.
*/
struct extent_util_stats_s {
size_t nfree;
size_t nregs;
size_t size;
};
struct extent_util_stats_verbose_s {
void *slabcur_addr;
size_t nfree;
size_t nregs;
size_t size;
size_t bin_nfree;
size_t bin_nregs;
};
#endif /* JEMALLOC_INTERNAL_EXTENT_STRUCTS_H */

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#ifndef JEMALLOC_INTERNAL_EXTENT_TYPES_H
#define JEMALLOC_INTERNAL_EXTENT_TYPES_H
typedef struct extent_s extent_t;
typedef struct extents_s extents_t;
typedef struct extent_util_stats_s extent_util_stats_t;
typedef struct extent_util_stats_verbose_s extent_util_stats_verbose_t;
#define EXTENT_HOOKS_INITIALIZER NULL
/*
* When reuse (and split) an active extent, (1U << opt_lg_extent_max_active_fit)
* is the max ratio between the size of the active extent and the new extent.
*/
#define LG_EXTENT_MAX_ACTIVE_FIT_DEFAULT 6
typedef enum {
EXTENT_NOT_HEAD,
EXTENT_IS_HEAD /* Only relevant for Windows && opt.retain. */
} extent_head_state_t;
#endif /* JEMALLOC_INTERNAL_EXTENT_TYPES_H */

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#ifndef JEMALLOC_INTERNAL_HASH_H
#define JEMALLOC_INTERNAL_HASH_H
#include "jemalloc/internal/assert.h"
/*
* The following hash function is based on MurmurHash3, placed into the public
* domain by Austin Appleby. See https://github.com/aappleby/smhasher for
* details.
*/
/******************************************************************************/
/* Internal implementation. */
static inline uint32_t
hash_rotl_32(uint32_t x, int8_t r) {
return ((x << r) | (x >> (32 - r)));
}
static inline uint64_t
hash_rotl_64(uint64_t x, int8_t r) {
return ((x << r) | (x >> (64 - r)));
}
static inline uint32_t
hash_get_block_32(const uint32_t *p, int i) {
/* Handle unaligned read. */
if (unlikely((uintptr_t)p & (sizeof(uint32_t)-1)) != 0) {
uint32_t ret;
memcpy(&ret, (uint8_t *)(p + i), sizeof(uint32_t));
return ret;
}
return p[i];
}
static inline uint64_t
hash_get_block_64(const uint64_t *p, int i) {
/* Handle unaligned read. */
if (unlikely((uintptr_t)p & (sizeof(uint64_t)-1)) != 0) {
uint64_t ret;
memcpy(&ret, (uint8_t *)(p + i), sizeof(uint64_t));
return ret;
}
return p[i];
}
static inline uint32_t
hash_fmix_32(uint32_t h) {
h ^= h >> 16;
h *= 0x85ebca6b;
h ^= h >> 13;
h *= 0xc2b2ae35;
h ^= h >> 16;
return h;
}
static inline uint64_t
hash_fmix_64(uint64_t k) {
k ^= k >> 33;
k *= KQU(0xff51afd7ed558ccd);
k ^= k >> 33;
k *= KQU(0xc4ceb9fe1a85ec53);
k ^= k >> 33;
return k;
}
static inline uint32_t
hash_x86_32(const void *key, int len, uint32_t seed) {
const uint8_t *data = (const uint8_t *) key;
const int nblocks = len / 4;
uint32_t h1 = seed;
const uint32_t c1 = 0xcc9e2d51;
const uint32_t c2 = 0x1b873593;
/* body */
{
const uint32_t *blocks = (const uint32_t *) (data + nblocks*4);
int i;
for (i = -nblocks; i; i++) {
uint32_t k1 = hash_get_block_32(blocks, i);
k1 *= c1;
k1 = hash_rotl_32(k1, 15);
k1 *= c2;
h1 ^= k1;
h1 = hash_rotl_32(h1, 13);
h1 = h1*5 + 0xe6546b64;
}
}
/* tail */
{
const uint8_t *tail = (const uint8_t *) (data + nblocks*4);
uint32_t k1 = 0;
switch (len & 3) {
case 3: k1 ^= tail[2] << 16; JEMALLOC_FALLTHROUGH
case 2: k1 ^= tail[1] << 8; JEMALLOC_FALLTHROUGH
case 1: k1 ^= tail[0]; k1 *= c1; k1 = hash_rotl_32(k1, 15);
k1 *= c2; h1 ^= k1;
}
}
/* finalization */
h1 ^= len;
h1 = hash_fmix_32(h1);
return h1;
}
static inline void
hash_x86_128(const void *key, const int len, uint32_t seed,
uint64_t r_out[2]) {
const uint8_t * data = (const uint8_t *) key;
const int nblocks = len / 16;
uint32_t h1 = seed;
uint32_t h2 = seed;
uint32_t h3 = seed;
uint32_t h4 = seed;
const uint32_t c1 = 0x239b961b;
const uint32_t c2 = 0xab0e9789;
const uint32_t c3 = 0x38b34ae5;
const uint32_t c4 = 0xa1e38b93;
/* body */
{
const uint32_t *blocks = (const uint32_t *) (data + nblocks*16);
int i;
for (i = -nblocks; i; i++) {
uint32_t k1 = hash_get_block_32(blocks, i*4 + 0);
uint32_t k2 = hash_get_block_32(blocks, i*4 + 1);
uint32_t k3 = hash_get_block_32(blocks, i*4 + 2);
uint32_t k4 = hash_get_block_32(blocks, i*4 + 3);
k1 *= c1; k1 = hash_rotl_32(k1, 15); k1 *= c2; h1 ^= k1;
h1 = hash_rotl_32(h1, 19); h1 += h2;
h1 = h1*5 + 0x561ccd1b;
k2 *= c2; k2 = hash_rotl_32(k2, 16); k2 *= c3; h2 ^= k2;
h2 = hash_rotl_32(h2, 17); h2 += h3;
h2 = h2*5 + 0x0bcaa747;
k3 *= c3; k3 = hash_rotl_32(k3, 17); k3 *= c4; h3 ^= k3;
h3 = hash_rotl_32(h3, 15); h3 += h4;
h3 = h3*5 + 0x96cd1c35;
k4 *= c4; k4 = hash_rotl_32(k4, 18); k4 *= c1; h4 ^= k4;
h4 = hash_rotl_32(h4, 13); h4 += h1;
h4 = h4*5 + 0x32ac3b17;
}
}
/* tail */
{
const uint8_t *tail = (const uint8_t *) (data + nblocks*16);
uint32_t k1 = 0;
uint32_t k2 = 0;
uint32_t k3 = 0;
uint32_t k4 = 0;
switch (len & 15) {
case 15: k4 ^= tail[14] << 16; JEMALLOC_FALLTHROUGH
case 14: k4 ^= tail[13] << 8; JEMALLOC_FALLTHROUGH
case 13: k4 ^= tail[12] << 0;
k4 *= c4; k4 = hash_rotl_32(k4, 18); k4 *= c1; h4 ^= k4;
JEMALLOC_FALLTHROUGH
case 12: k3 ^= tail[11] << 24; JEMALLOC_FALLTHROUGH
case 11: k3 ^= tail[10] << 16; JEMALLOC_FALLTHROUGH
case 10: k3 ^= tail[ 9] << 8; JEMALLOC_FALLTHROUGH
case 9: k3 ^= tail[ 8] << 0;
k3 *= c3; k3 = hash_rotl_32(k3, 17); k3 *= c4; h3 ^= k3;
JEMALLOC_FALLTHROUGH
case 8: k2 ^= tail[ 7] << 24; JEMALLOC_FALLTHROUGH
case 7: k2 ^= tail[ 6] << 16; JEMALLOC_FALLTHROUGH
case 6: k2 ^= tail[ 5] << 8; JEMALLOC_FALLTHROUGH
case 5: k2 ^= tail[ 4] << 0;
k2 *= c2; k2 = hash_rotl_32(k2, 16); k2 *= c3; h2 ^= k2;
JEMALLOC_FALLTHROUGH
case 4: k1 ^= tail[ 3] << 24; JEMALLOC_FALLTHROUGH
case 3: k1 ^= tail[ 2] << 16; JEMALLOC_FALLTHROUGH
case 2: k1 ^= tail[ 1] << 8; JEMALLOC_FALLTHROUGH
case 1: k1 ^= tail[ 0] << 0;
k1 *= c1; k1 = hash_rotl_32(k1, 15); k1 *= c2; h1 ^= k1;
JEMALLOC_FALLTHROUGH
}
}
/* finalization */
h1 ^= len; h2 ^= len; h3 ^= len; h4 ^= len;
h1 += h2; h1 += h3; h1 += h4;
h2 += h1; h3 += h1; h4 += h1;
h1 = hash_fmix_32(h1);
h2 = hash_fmix_32(h2);
h3 = hash_fmix_32(h3);
h4 = hash_fmix_32(h4);
h1 += h2; h1 += h3; h1 += h4;
h2 += h1; h3 += h1; h4 += h1;
r_out[0] = (((uint64_t) h2) << 32) | h1;
r_out[1] = (((uint64_t) h4) << 32) | h3;
}
static inline void
hash_x64_128(const void *key, const int len, const uint32_t seed,
uint64_t r_out[2]) {
const uint8_t *data = (const uint8_t *) key;
const int nblocks = len / 16;
uint64_t h1 = seed;
uint64_t h2 = seed;
const uint64_t c1 = KQU(0x87c37b91114253d5);
const uint64_t c2 = KQU(0x4cf5ad432745937f);
/* body */
{
const uint64_t *blocks = (const uint64_t *) (data);
int i;
for (i = 0; i < nblocks; i++) {
uint64_t k1 = hash_get_block_64(blocks, i*2 + 0);
uint64_t k2 = hash_get_block_64(blocks, i*2 + 1);
k1 *= c1; k1 = hash_rotl_64(k1, 31); k1 *= c2; h1 ^= k1;
h1 = hash_rotl_64(h1, 27); h1 += h2;
h1 = h1*5 + 0x52dce729;
k2 *= c2; k2 = hash_rotl_64(k2, 33); k2 *= c1; h2 ^= k2;
h2 = hash_rotl_64(h2, 31); h2 += h1;
h2 = h2*5 + 0x38495ab5;
}
}
/* tail */
{
const uint8_t *tail = (const uint8_t*)(data + nblocks*16);
uint64_t k1 = 0;
uint64_t k2 = 0;
switch (len & 15) {
case 15: k2 ^= ((uint64_t)(tail[14])) << 48; JEMALLOC_FALLTHROUGH
case 14: k2 ^= ((uint64_t)(tail[13])) << 40; JEMALLOC_FALLTHROUGH
case 13: k2 ^= ((uint64_t)(tail[12])) << 32; JEMALLOC_FALLTHROUGH
case 12: k2 ^= ((uint64_t)(tail[11])) << 24; JEMALLOC_FALLTHROUGH
case 11: k2 ^= ((uint64_t)(tail[10])) << 16; JEMALLOC_FALLTHROUGH
case 10: k2 ^= ((uint64_t)(tail[ 9])) << 8; JEMALLOC_FALLTHROUGH
case 9: k2 ^= ((uint64_t)(tail[ 8])) << 0;
k2 *= c2; k2 = hash_rotl_64(k2, 33); k2 *= c1; h2 ^= k2;
JEMALLOC_FALLTHROUGH
case 8: k1 ^= ((uint64_t)(tail[ 7])) << 56; JEMALLOC_FALLTHROUGH
case 7: k1 ^= ((uint64_t)(tail[ 6])) << 48; JEMALLOC_FALLTHROUGH
case 6: k1 ^= ((uint64_t)(tail[ 5])) << 40; JEMALLOC_FALLTHROUGH
case 5: k1 ^= ((uint64_t)(tail[ 4])) << 32; JEMALLOC_FALLTHROUGH
case 4: k1 ^= ((uint64_t)(tail[ 3])) << 24; JEMALLOC_FALLTHROUGH
case 3: k1 ^= ((uint64_t)(tail[ 2])) << 16; JEMALLOC_FALLTHROUGH
case 2: k1 ^= ((uint64_t)(tail[ 1])) << 8; JEMALLOC_FALLTHROUGH
case 1: k1 ^= ((uint64_t)(tail[ 0])) << 0;
k1 *= c1; k1 = hash_rotl_64(k1, 31); k1 *= c2; h1 ^= k1;
}
}
/* finalization */
h1 ^= len; h2 ^= len;
h1 += h2;
h2 += h1;
h1 = hash_fmix_64(h1);
h2 = hash_fmix_64(h2);
h1 += h2;
h2 += h1;
r_out[0] = h1;
r_out[1] = h2;
}
/******************************************************************************/
/* API. */
static inline void
hash(const void *key, size_t len, const uint32_t seed, size_t r_hash[2]) {
assert(len <= INT_MAX); /* Unfortunate implementation limitation. */
#if (LG_SIZEOF_PTR == 3 && !defined(JEMALLOC_BIG_ENDIAN))
hash_x64_128(key, (int)len, seed, (uint64_t *)r_hash);
#else
{
uint64_t hashes[2];
hash_x86_128(key, (int)len, seed, hashes);
r_hash[0] = (size_t)hashes[0];
r_hash[1] = (size_t)hashes[1];
}
#endif
}
#endif /* JEMALLOC_INTERNAL_HASH_H */

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#ifndef JEMALLOC_INTERNAL_HOOK_H
#define JEMALLOC_INTERNAL_HOOK_H
#include "jemalloc/internal/tsd.h"
/*
* This API is *extremely* experimental, and may get ripped out, changed in API-
* and ABI-incompatible ways, be insufficiently or incorrectly documented, etc.
*
* It allows hooking the stateful parts of the API to see changes as they
* happen.
*
* Allocation hooks are called after the allocation is done, free hooks are
* called before the free is done, and expand hooks are called after the
* allocation is expanded.
*
* For realloc and rallocx, if the expansion happens in place, the expansion
* hook is called. If it is moved, then the alloc hook is called on the new
* location, and then the free hook is called on the old location (i.e. both
* hooks are invoked in between the alloc and the dalloc).
*
* If we return NULL from OOM, then usize might not be trustworthy. Calling
* realloc(NULL, size) only calls the alloc hook, and calling realloc(ptr, 0)
* only calls the free hook. (Calling realloc(NULL, 0) is treated as malloc(0),
* and only calls the alloc hook).
*
* Reentrancy:
* Reentrancy is guarded against from within the hook implementation. If you
* call allocator functions from within a hook, the hooks will not be invoked
* again.
* Threading:
* The installation of a hook synchronizes with all its uses. If you can
* prove the installation of a hook happens-before a jemalloc entry point,
* then the hook will get invoked (unless there's a racing removal).
*
* Hook insertion appears to be atomic at a per-thread level (i.e. if a thread
* allocates and has the alloc hook invoked, then a subsequent free on the
* same thread will also have the free hook invoked).
*
* The *removal* of a hook does *not* block until all threads are done with
* the hook. Hook authors have to be resilient to this, and need some
* out-of-band mechanism for cleaning up any dynamically allocated memory
* associated with their hook.
* Ordering:
* Order of hook execution is unspecified, and may be different than insertion
* order.
*/
#define HOOK_MAX 4
enum hook_alloc_e {
hook_alloc_malloc,
hook_alloc_posix_memalign,
hook_alloc_aligned_alloc,
hook_alloc_calloc,
hook_alloc_memalign,
hook_alloc_valloc,
hook_alloc_mallocx,
/* The reallocating functions have both alloc and dalloc variants */
hook_alloc_realloc,
hook_alloc_rallocx,
};
/*
* We put the enum typedef after the enum, since this file may get included by
* jemalloc_cpp.cpp, and C++ disallows enum forward declarations.
*/
typedef enum hook_alloc_e hook_alloc_t;
enum hook_dalloc_e {
hook_dalloc_free,
hook_dalloc_dallocx,
hook_dalloc_sdallocx,
/*
* The dalloc halves of reallocation (not called if in-place expansion
* happens).
*/
hook_dalloc_realloc,
hook_dalloc_rallocx,
};
typedef enum hook_dalloc_e hook_dalloc_t;
enum hook_expand_e {
hook_expand_realloc,
hook_expand_rallocx,
hook_expand_xallocx,
};
typedef enum hook_expand_e hook_expand_t;
typedef void (*hook_alloc)(
void *extra, hook_alloc_t type, void *result, uintptr_t result_raw,
uintptr_t args_raw[3]);
typedef void (*hook_dalloc)(
void *extra, hook_dalloc_t type, void *address, uintptr_t args_raw[3]);
typedef void (*hook_expand)(
void *extra, hook_expand_t type, void *address, size_t old_usize,
size_t new_usize, uintptr_t result_raw, uintptr_t args_raw[4]);
typedef struct hooks_s hooks_t;
struct hooks_s {
hook_alloc alloc_hook;
hook_dalloc dalloc_hook;
hook_expand expand_hook;
void *extra;
};
/*
* Begin implementation details; everything above this point might one day live
* in a public API. Everything below this point never will.
*/
/*
* The realloc pathways haven't gotten any refactoring love in a while, and it's
* fairly difficult to pass information from the entry point to the hooks. We
* put the informaiton the hooks will need into a struct to encapsulate
* everything.
*
* Much of these pathways are force-inlined, so that the compiler can avoid
* materializing this struct until we hit an extern arena function. For fairly
* goofy reasons, *many* of the realloc paths hit an extern arena function.
* These paths are cold enough that it doesn't matter; eventually, we should
* rewrite the realloc code to make the expand-in-place and the
* free-then-realloc paths more orthogonal, at which point we don't need to
* spread the hook logic all over the place.
*/
typedef struct hook_ralloc_args_s hook_ralloc_args_t;
struct hook_ralloc_args_s {
/* I.e. as opposed to rallocx. */
bool is_realloc;
/*
* The expand hook takes 4 arguments, even if only 3 are actually used;
* we add an extra one in case the user decides to memcpy without
* looking too closely at the hooked function.
*/
uintptr_t args[4];
};
/*
* Returns an opaque handle to be used when removing the hook. NULL means that
* we couldn't install the hook.
*/
bool hook_boot();
void *hook_install(tsdn_t *tsdn, hooks_t *hooks);
/* Uninstalls the hook with the handle previously returned from hook_install. */
void hook_remove(tsdn_t *tsdn, void *opaque);
/* Hooks */
void hook_invoke_alloc(hook_alloc_t type, void *result, uintptr_t result_raw,
uintptr_t args_raw[3]);
void hook_invoke_dalloc(hook_dalloc_t type, void *address,
uintptr_t args_raw[3]);
void hook_invoke_expand(hook_expand_t type, void *address, size_t old_usize,
size_t new_usize, uintptr_t result_raw, uintptr_t args_raw[4]);
#endif /* JEMALLOC_INTERNAL_HOOK_H */

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#ifndef JEMALLOC_INTERNAL_DECLS_H
#define JEMALLOC_INTERNAL_DECLS_H
#include <math.h>
#ifdef _WIN32
# include <windows.h>
# include "msvc_compat/windows_extra.h"
# ifdef _WIN64
# if LG_VADDR <= 32
# error Generate the headers using x64 vcargs
# endif
# else
# if LG_VADDR > 32
# undef LG_VADDR
# define LG_VADDR 32
# endif
# endif
#else
# include <sys/param.h>
# include <sys/mman.h>
# if !defined(__pnacl__) && !defined(__native_client__)
# include <sys/syscall.h>
# if !defined(SYS_write) && defined(__NR_write)
# define SYS_write __NR_write
# endif
# if defined(SYS_open) && defined(__aarch64__)
/* Android headers may define SYS_open to __NR_open even though
* __NR_open may not exist on AArch64 (superseded by __NR_openat). */
# undef SYS_open
# endif
# include <sys/uio.h>
# endif
# include <pthread.h>
# ifdef __FreeBSD__
# include <pthread_np.h>
# endif
# include <signal.h>
# ifdef JEMALLOC_OS_UNFAIR_LOCK
# include <os/lock.h>
# endif
# ifdef JEMALLOC_GLIBC_MALLOC_HOOK
# include <sched.h>
# endif
# include <errno.h>
# include <sys/time.h>
# include <time.h>
# ifdef JEMALLOC_HAVE_MACH_ABSOLUTE_TIME
# include <mach/mach_time.h>
# endif
#endif
#include <sys/types.h>
#include <limits.h>
#ifndef SIZE_T_MAX
# define SIZE_T_MAX SIZE_MAX
#endif
#ifndef SSIZE_MAX
# define SSIZE_MAX ((ssize_t)(SIZE_T_MAX >> 1))
#endif
#include <stdarg.h>
#include <stdbool.h>
#include <stdio.h>
#include <stdlib.h>
#include <stdint.h>
#include <stddef.h>
#ifndef offsetof
# define offsetof(type, member) ((size_t)&(((type *)NULL)->member))
#endif
#include <string.h>
#include <strings.h>
#include <ctype.h>
#ifdef _MSC_VER
# include <io.h>
typedef intptr_t ssize_t;
# define PATH_MAX 1024
# define STDERR_FILENO 2
# define __func__ __FUNCTION__
# ifdef JEMALLOC_HAS_RESTRICT
# define restrict __restrict
# endif
/* Disable warnings about deprecated system functions. */
# pragma warning(disable: 4996)
#if _MSC_VER < 1800
static int
isblank(int c) {
return (c == '\t' || c == ' ');
}
#endif
#else
# include <unistd.h>
#endif
#include <fcntl.h>
#endif /* JEMALLOC_INTERNAL_H */

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#ifndef JEMALLOC_INTERNAL_DEFS_H_
#define JEMALLOC_INTERNAL_DEFS_H_
/*
* If JEMALLOC_PREFIX is defined via --with-jemalloc-prefix, it will cause all
* public APIs to be prefixed. This makes it possible, with some care, to use
* multiple allocators simultaneously.
*/
#undef JEMALLOC_PREFIX
#undef JEMALLOC_CPREFIX
/*
* Define overrides for non-standard allocator-related functions if they are
* present on the system.
*/
#undef JEMALLOC_OVERRIDE___LIBC_CALLOC
#undef JEMALLOC_OVERRIDE___LIBC_FREE
#undef JEMALLOC_OVERRIDE___LIBC_MALLOC
#undef JEMALLOC_OVERRIDE___LIBC_MEMALIGN
#undef JEMALLOC_OVERRIDE___LIBC_REALLOC
#undef JEMALLOC_OVERRIDE___LIBC_VALLOC
#undef JEMALLOC_OVERRIDE___POSIX_MEMALIGN
/*
* JEMALLOC_PRIVATE_NAMESPACE is used as a prefix for all library-private APIs.
* For shared libraries, symbol visibility mechanisms prevent these symbols
* from being exported, but for static libraries, naming collisions are a real
* possibility.
*/
#undef JEMALLOC_PRIVATE_NAMESPACE
/*
* Hyper-threaded CPUs may need a special instruction inside spin loops in
* order to yield to another virtual CPU.
*/
#undef CPU_SPINWAIT
/* 1 if CPU_SPINWAIT is defined, 0 otherwise. */
#undef HAVE_CPU_SPINWAIT
/*
* Number of significant bits in virtual addresses. This may be less than the
* total number of bits in a pointer, e.g. on x64, for which the uppermost 16
* bits are the same as bit 47.
*/
#undef LG_VADDR
/* Defined if C11 atomics are available. */
#undef JEMALLOC_C11_ATOMICS
/* Defined if GCC __atomic atomics are available. */
#undef JEMALLOC_GCC_ATOMIC_ATOMICS
/* and the 8-bit variant support. */
#undef JEMALLOC_GCC_U8_ATOMIC_ATOMICS
/* Defined if GCC __sync atomics are available. */
#undef JEMALLOC_GCC_SYNC_ATOMICS
/* and the 8-bit variant support. */
#undef JEMALLOC_GCC_U8_SYNC_ATOMICS
/*
* Defined if __builtin_clz() and __builtin_clzl() are available.
*/
#undef JEMALLOC_HAVE_BUILTIN_CLZ
/*
* Defined if os_unfair_lock_*() functions are available, as provided by Darwin.
*/
#undef JEMALLOC_OS_UNFAIR_LOCK
/* Defined if syscall(2) is usable. */
#undef JEMALLOC_USE_SYSCALL
/*
* Defined if secure_getenv(3) is available.
*/
#undef JEMALLOC_HAVE_SECURE_GETENV
/*
* Defined if issetugid(2) is available.
*/
#undef JEMALLOC_HAVE_ISSETUGID
/* Defined if pthread_atfork(3) is available. */
#undef JEMALLOC_HAVE_PTHREAD_ATFORK
/* Defined if pthread_setname_np(3) is available. */
#undef JEMALLOC_HAVE_PTHREAD_SETNAME_NP
/*
* Defined if clock_gettime(CLOCK_MONOTONIC_COARSE, ...) is available.
*/
#undef JEMALLOC_HAVE_CLOCK_MONOTONIC_COARSE
/*
* Defined if clock_gettime(CLOCK_MONOTONIC, ...) is available.
*/
#undef JEMALLOC_HAVE_CLOCK_MONOTONIC
/*
* Defined if mach_absolute_time() is available.
*/
#undef JEMALLOC_HAVE_MACH_ABSOLUTE_TIME
/*
* Defined if _malloc_thread_cleanup() exists. At least in the case of
* FreeBSD, pthread_key_create() allocates, which if used during malloc
* bootstrapping will cause recursion into the pthreads library. Therefore, if
* _malloc_thread_cleanup() exists, use it as the basis for thread cleanup in
* malloc_tsd.
*/
#undef JEMALLOC_MALLOC_THREAD_CLEANUP
/*
* Defined if threaded initialization is known to be safe on this platform.
* Among other things, it must be possible to initialize a mutex without
* triggering allocation in order for threaded allocation to be safe.
*/
#undef JEMALLOC_THREADED_INIT
/*
* Defined if the pthreads implementation defines
* _pthread_mutex_init_calloc_cb(), in which case the function is used in order
* to avoid recursive allocation during mutex initialization.
*/
#undef JEMALLOC_MUTEX_INIT_CB
/* Non-empty if the tls_model attribute is supported. */
#undef JEMALLOC_TLS_MODEL
/*
* JEMALLOC_DEBUG enables assertions and other sanity checks, and disables
* inline functions.
*/
#undef JEMALLOC_DEBUG
/* JEMALLOC_STATS enables statistics calculation. */
#undef JEMALLOC_STATS
/* JEMALLOC_EXPERIMENTAL_SMALLOCX_API enables experimental smallocx API. */
#undef JEMALLOC_EXPERIMENTAL_SMALLOCX_API
/* JEMALLOC_PROF enables allocation profiling. */
#undef JEMALLOC_PROF
/* Use libunwind for profile backtracing if defined. */
#undef JEMALLOC_PROF_LIBUNWIND
/* Use libgcc for profile backtracing if defined. */
#undef JEMALLOC_PROF_LIBGCC
/* Use gcc intrinsics for profile backtracing if defined. */
#undef JEMALLOC_PROF_GCC
/*
* JEMALLOC_DSS enables use of sbrk(2) to allocate extents from the data storage
* segment (DSS).
*/
#undef JEMALLOC_DSS
/* Support memory filling (junk/zero). */
#undef JEMALLOC_FILL
/* Support utrace(2)-based tracing. */
#undef JEMALLOC_UTRACE
/* Support optional abort() on OOM. */
#undef JEMALLOC_XMALLOC
/* Support lazy locking (avoid locking unless a second thread is launched). */
#undef JEMALLOC_LAZY_LOCK
/*
* Minimum allocation alignment is 2^LG_QUANTUM bytes (ignoring tiny size
* classes).
*/
#undef LG_QUANTUM
/* One page is 2^LG_PAGE bytes. */
#undef LG_PAGE
/*
* One huge page is 2^LG_HUGEPAGE bytes. Note that this is defined even if the
* system does not explicitly support huge pages; system calls that require
* explicit huge page support are separately configured.
*/
#undef LG_HUGEPAGE
/*
* If defined, adjacent virtual memory mappings with identical attributes
* automatically coalesce, and they fragment when changes are made to subranges.
* This is the normal order of things for mmap()/munmap(), but on Windows
* VirtualAlloc()/VirtualFree() operations must be precisely matched, i.e.
* mappings do *not* coalesce/fragment.
*/
#undef JEMALLOC_MAPS_COALESCE
/*
* If defined, retain memory for later reuse by default rather than using e.g.
* munmap() to unmap freed extents. This is enabled on 64-bit Linux because
* common sequences of mmap()/munmap() calls will cause virtual memory map
* holes.
*/
#undef JEMALLOC_RETAIN
/* TLS is used to map arenas and magazine caches to threads. */
#undef JEMALLOC_TLS
/*
* Used to mark unreachable code to quiet "end of non-void" compiler warnings.
* Don't use this directly; instead use unreachable() from util.h
*/
#undef JEMALLOC_INTERNAL_UNREACHABLE
/*
* ffs*() functions to use for bitmapping. Don't use these directly; instead,
* use ffs_*() from util.h.
*/
#undef JEMALLOC_INTERNAL_FFSLL
#undef JEMALLOC_INTERNAL_FFSL
#undef JEMALLOC_INTERNAL_FFS
/*
* popcount*() functions to use for bitmapping.
*/
#undef JEMALLOC_INTERNAL_POPCOUNTL
#undef JEMALLOC_INTERNAL_POPCOUNT
/*
* If defined, explicitly attempt to more uniformly distribute large allocation
* pointer alignments across all cache indices.
*/
#undef JEMALLOC_CACHE_OBLIVIOUS
/*
* If defined, enable logging facilities. We make this a configure option to
* avoid taking extra branches everywhere.
*/
#undef JEMALLOC_LOG
/*
* If defined, use readlinkat() (instead of readlink()) to follow
* /etc/malloc_conf.
*/
#undef JEMALLOC_READLINKAT
/*
* Darwin (OS X) uses zones to work around Mach-O symbol override shortcomings.
*/
#undef JEMALLOC_ZONE
/*
* Methods for determining whether the OS overcommits.
* JEMALLOC_PROC_SYS_VM_OVERCOMMIT_MEMORY: Linux's
* /proc/sys/vm.overcommit_memory file.
* JEMALLOC_SYSCTL_VM_OVERCOMMIT: FreeBSD's vm.overcommit sysctl.
*/
#undef JEMALLOC_SYSCTL_VM_OVERCOMMIT
#undef JEMALLOC_PROC_SYS_VM_OVERCOMMIT_MEMORY
/* Defined if madvise(2) is available. */
#undef JEMALLOC_HAVE_MADVISE
/*
* Defined if transparent huge pages are supported via the MADV_[NO]HUGEPAGE
* arguments to madvise(2).
*/
#undef JEMALLOC_HAVE_MADVISE_HUGE
/*
* Methods for purging unused pages differ between operating systems.
*
* madvise(..., MADV_FREE) : This marks pages as being unused, such that they
* will be discarded rather than swapped out.
* madvise(..., MADV_DONTNEED) : If JEMALLOC_PURGE_MADVISE_DONTNEED_ZEROS is
* defined, this immediately discards pages,
* such that new pages will be demand-zeroed if
* the address region is later touched;
* otherwise this behaves similarly to
* MADV_FREE, though typically with higher
* system overhead.
*/
#undef JEMALLOC_PURGE_MADVISE_FREE
#undef JEMALLOC_PURGE_MADVISE_DONTNEED
#undef JEMALLOC_PURGE_MADVISE_DONTNEED_ZEROS
/* Defined if madvise(2) is available but MADV_FREE is not (x86 Linux only). */
#undef JEMALLOC_DEFINE_MADVISE_FREE
/*
* Defined if MADV_DO[NT]DUMP is supported as an argument to madvise.
*/
#undef JEMALLOC_MADVISE_DONTDUMP
/*
* Defined if transparent huge pages (THPs) are supported via the
* MADV_[NO]HUGEPAGE arguments to madvise(2), and THP support is enabled.
*/
#undef JEMALLOC_THP
/* Define if operating system has alloca.h header. */
#undef JEMALLOC_HAS_ALLOCA_H
/* C99 restrict keyword supported. */
#undef JEMALLOC_HAS_RESTRICT
/* For use by hash code. */
#undef JEMALLOC_BIG_ENDIAN
/* sizeof(int) == 2^LG_SIZEOF_INT. */
#undef LG_SIZEOF_INT
/* sizeof(long) == 2^LG_SIZEOF_LONG. */
#undef LG_SIZEOF_LONG
/* sizeof(long long) == 2^LG_SIZEOF_LONG_LONG. */
#undef LG_SIZEOF_LONG_LONG
/* sizeof(intmax_t) == 2^LG_SIZEOF_INTMAX_T. */
#undef LG_SIZEOF_INTMAX_T
/* glibc malloc hooks (__malloc_hook, __realloc_hook, __free_hook). */
#undef JEMALLOC_GLIBC_MALLOC_HOOK
/* glibc memalign hook. */
#undef JEMALLOC_GLIBC_MEMALIGN_HOOK
/* pthread support */
#undef JEMALLOC_HAVE_PTHREAD
/* dlsym() support */
#undef JEMALLOC_HAVE_DLSYM
/* Adaptive mutex support in pthreads. */
#undef JEMALLOC_HAVE_PTHREAD_MUTEX_ADAPTIVE_NP
/* GNU specific sched_getcpu support */
#undef JEMALLOC_HAVE_SCHED_GETCPU
/* GNU specific sched_setaffinity support */
#undef JEMALLOC_HAVE_SCHED_SETAFFINITY
/*
* If defined, all the features necessary for background threads are present.
*/
#undef JEMALLOC_BACKGROUND_THREAD
/*
* If defined, jemalloc symbols are not exported (doesn't work when
* JEMALLOC_PREFIX is not defined).
*/
#undef JEMALLOC_EXPORT
/* config.malloc_conf options string. */
#undef JEMALLOC_CONFIG_MALLOC_CONF
/* If defined, jemalloc takes the malloc/free/etc. symbol names. */
#undef JEMALLOC_IS_MALLOC
/*
* Defined if strerror_r returns char * if _GNU_SOURCE is defined.
*/
#undef JEMALLOC_STRERROR_R_RETURNS_CHAR_WITH_GNU_SOURCE
/* Performs additional safety checks when defined. */
#undef JEMALLOC_OPT_SAFETY_CHECKS
#endif /* JEMALLOC_INTERNAL_DEFS_H_ */

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#ifndef JEMALLOC_INTERNAL_EXTERNS_H
#define JEMALLOC_INTERNAL_EXTERNS_H
#include "jemalloc/internal/atomic.h"
#include "jemalloc/internal/tsd_types.h"
/* TSD checks this to set thread local slow state accordingly. */
extern bool malloc_slow;
/* Run-time options. */
extern bool opt_abort;
extern bool opt_abort_conf;
extern bool opt_confirm_conf;
extern const char *opt_junk;
extern bool opt_junk_alloc;
extern bool opt_junk_free;
extern bool opt_utrace;
extern bool opt_xmalloc;
extern bool opt_zero;
extern unsigned opt_narenas;
/* Number of CPUs. */
extern unsigned ncpus;
/* Number of arenas used for automatic multiplexing of threads and arenas. */
extern unsigned narenas_auto;
/* Base index for manual arenas. */
extern unsigned manual_arena_base;
/*
* Arenas that are used to service external requests. Not all elements of the
* arenas array are necessarily used; arenas are created lazily as needed.
*/
extern atomic_p_t arenas[];
void *a0malloc(size_t size);
void a0dalloc(void *ptr);
void *bootstrap_malloc(size_t size);
void *bootstrap_calloc(size_t num, size_t size);
void bootstrap_free(void *ptr);
void arena_set(unsigned ind, arena_t *arena);
unsigned narenas_total_get(void);
arena_t *arena_init(tsdn_t *tsdn, unsigned ind, extent_hooks_t *extent_hooks);
arena_tdata_t *arena_tdata_get_hard(tsd_t *tsd, unsigned ind);
arena_t *arena_choose_hard(tsd_t *tsd, bool internal);
void arena_migrate(tsd_t *tsd, unsigned oldind, unsigned newind);
void iarena_cleanup(tsd_t *tsd);
void arena_cleanup(tsd_t *tsd);
void arenas_tdata_cleanup(tsd_t *tsd);
void jemalloc_prefork(void);
void jemalloc_postfork_parent(void);
void jemalloc_postfork_child(void);
bool malloc_initialized(void);
void je_sdallocx_noflags(void *ptr, size_t size);
#endif /* JEMALLOC_INTERNAL_EXTERNS_H */

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#ifndef JEMALLOC_INTERNAL_INCLUDES_H
#define JEMALLOC_INTERNAL_INCLUDES_H
/*
* jemalloc can conceptually be broken into components (arena, tcache, etc.),
* but there are circular dependencies that cannot be broken without
* substantial performance degradation.
*
* Historically, we dealt with this by each header into four sections (types,
* structs, externs, and inlines), and included each header file multiple times
* in this file, picking out the portion we want on each pass using the
* following #defines:
* JEMALLOC_H_TYPES : Preprocessor-defined constants and psuedo-opaque data
* types.
* JEMALLOC_H_STRUCTS : Data structures.
* JEMALLOC_H_EXTERNS : Extern data declarations and function prototypes.
* JEMALLOC_H_INLINES : Inline functions.
*
* We're moving toward a world in which the dependencies are explicit; each file
* will #include the headers it depends on (rather than relying on them being
* implicitly available via this file including every header file in the
* project).
*
* We're now in an intermediate state: we've broken up the header files to avoid
* having to include each one multiple times, but have not yet moved the
* dependency information into the header files (i.e. we still rely on the
* ordering in this file to ensure all a header's dependencies are available in
* its translation unit). Each component is now broken up into multiple header
* files, corresponding to the sections above (e.g. instead of "foo.h", we now
* have "foo_types.h", "foo_structs.h", "foo_externs.h", "foo_inlines.h").
*
* Those files which have been converted to explicitly include their
* inter-component dependencies are now in the initial HERMETIC HEADERS
* section. All headers may still rely on jemalloc_preamble.h (which, by fiat,
* must be included first in every translation unit) for system headers and
* global jemalloc definitions, however.
*/
/******************************************************************************/
/* TYPES */
/******************************************************************************/
#include "jemalloc/internal/extent_types.h"
#include "jemalloc/internal/base_types.h"
#include "jemalloc/internal/arena_types.h"
#include "jemalloc/internal/tcache_types.h"
#include "jemalloc/internal/prof_types.h"
/******************************************************************************/
/* STRUCTS */
/******************************************************************************/
#include "jemalloc/internal/arena_structs_a.h"
#include "jemalloc/internal/extent_structs.h"
#include "jemalloc/internal/base_structs.h"
#include "jemalloc/internal/prof_structs.h"
#include "jemalloc/internal/arena_structs_b.h"
#include "jemalloc/internal/tcache_structs.h"
#include "jemalloc/internal/background_thread_structs.h"
/******************************************************************************/
/* EXTERNS */
/******************************************************************************/
#include "jemalloc/internal/jemalloc_internal_externs.h"
#include "jemalloc/internal/extent_externs.h"
#include "jemalloc/internal/base_externs.h"
#include "jemalloc/internal/arena_externs.h"
#include "jemalloc/internal/large_externs.h"
#include "jemalloc/internal/tcache_externs.h"
#include "jemalloc/internal/prof_externs.h"
#include "jemalloc/internal/background_thread_externs.h"
/******************************************************************************/
/* INLINES */
/******************************************************************************/
#include "jemalloc/internal/jemalloc_internal_inlines_a.h"
#include "jemalloc/internal/base_inlines.h"
/*
* Include portions of arena code interleaved with tcache code in order to
* resolve circular dependencies.
*/
#include "jemalloc/internal/prof_inlines_a.h"
#include "jemalloc/internal/arena_inlines_a.h"
#include "jemalloc/internal/extent_inlines.h"
#include "jemalloc/internal/jemalloc_internal_inlines_b.h"
#include "jemalloc/internal/tcache_inlines.h"
#include "jemalloc/internal/arena_inlines_b.h"
#include "jemalloc/internal/jemalloc_internal_inlines_c.h"
#include "jemalloc/internal/prof_inlines_b.h"
#include "jemalloc/internal/background_thread_inlines.h"
#endif /* JEMALLOC_INTERNAL_INCLUDES_H */

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#ifndef JEMALLOC_INTERNAL_INLINES_A_H
#define JEMALLOC_INTERNAL_INLINES_A_H
#include "jemalloc/internal/atomic.h"
#include "jemalloc/internal/bit_util.h"
#include "jemalloc/internal/jemalloc_internal_types.h"
#include "jemalloc/internal/sc.h"
#include "jemalloc/internal/ticker.h"
JEMALLOC_ALWAYS_INLINE malloc_cpuid_t
malloc_getcpu(void) {
assert(have_percpu_arena);
#if defined(_WIN32)
return GetCurrentProcessorNumber();
#elif defined(JEMALLOC_HAVE_SCHED_GETCPU)
return (malloc_cpuid_t)sched_getcpu();
#else
not_reached();
return -1;
#endif
}
/* Return the chosen arena index based on current cpu. */
JEMALLOC_ALWAYS_INLINE unsigned
percpu_arena_choose(void) {
assert(have_percpu_arena && PERCPU_ARENA_ENABLED(opt_percpu_arena));
malloc_cpuid_t cpuid = malloc_getcpu();
assert(cpuid >= 0);
unsigned arena_ind;
if ((opt_percpu_arena == percpu_arena) || ((unsigned)cpuid < ncpus /
2)) {
arena_ind = cpuid;
} else {
assert(opt_percpu_arena == per_phycpu_arena);
/* Hyper threads on the same physical CPU share arena. */
arena_ind = cpuid - ncpus / 2;
}
return arena_ind;
}
/* Return the limit of percpu auto arena range, i.e. arenas[0...ind_limit). */
JEMALLOC_ALWAYS_INLINE unsigned
percpu_arena_ind_limit(percpu_arena_mode_t mode) {
assert(have_percpu_arena && PERCPU_ARENA_ENABLED(mode));
if (mode == per_phycpu_arena && ncpus > 1) {
if (ncpus % 2) {
/* This likely means a misconfig. */
return ncpus / 2 + 1;
}
return ncpus / 2;
} else {
return ncpus;
}
}
static inline arena_tdata_t *
arena_tdata_get(tsd_t *tsd, unsigned ind, bool refresh_if_missing) {
arena_tdata_t *tdata;
arena_tdata_t *arenas_tdata = tsd_arenas_tdata_get(tsd);
if (unlikely(arenas_tdata == NULL)) {
/* arenas_tdata hasn't been initialized yet. */
return arena_tdata_get_hard(tsd, ind);
}
if (unlikely(ind >= tsd_narenas_tdata_get(tsd))) {
/*
* ind is invalid, cache is old (too small), or tdata to be
* initialized.
*/
return (refresh_if_missing ? arena_tdata_get_hard(tsd, ind) :
NULL);
}
tdata = &arenas_tdata[ind];
if (likely(tdata != NULL) || !refresh_if_missing) {
return tdata;
}
return arena_tdata_get_hard(tsd, ind);
}
static inline arena_t *
arena_get(tsdn_t *tsdn, unsigned ind, bool init_if_missing) {
arena_t *ret;
assert(ind < MALLOCX_ARENA_LIMIT);
ret = (arena_t *)atomic_load_p(&arenas[ind], ATOMIC_ACQUIRE);
if (unlikely(ret == NULL)) {
if (init_if_missing) {
ret = arena_init(tsdn, ind,
(extent_hooks_t *)&extent_hooks_default);
}
}
return ret;
}
static inline ticker_t *
decay_ticker_get(tsd_t *tsd, unsigned ind) {
arena_tdata_t *tdata;
tdata = arena_tdata_get(tsd, ind, true);
if (unlikely(tdata == NULL)) {
return NULL;
}
return &tdata->decay_ticker;
}
JEMALLOC_ALWAYS_INLINE cache_bin_t *
tcache_small_bin_get(tcache_t *tcache, szind_t binind) {
assert(binind < SC_NBINS);
return &tcache->bins_small[binind];
}
JEMALLOC_ALWAYS_INLINE cache_bin_t *
tcache_large_bin_get(tcache_t *tcache, szind_t binind) {
assert(binind >= SC_NBINS &&binind < nhbins);
return &tcache->bins_large[binind - SC_NBINS];
}
JEMALLOC_ALWAYS_INLINE bool
tcache_available(tsd_t *tsd) {
/*
* Thread specific auto tcache might be unavailable if: 1) during tcache
* initialization, or 2) disabled through thread.tcache.enabled mallctl
* or config options. This check covers all cases.
*/
if (likely(tsd_tcache_enabled_get(tsd))) {
/* Associated arena == NULL implies tcache init in progress. */
assert(tsd_tcachep_get(tsd)->arena == NULL ||
tcache_small_bin_get(tsd_tcachep_get(tsd), 0)->avail !=
NULL);
return true;
}
return false;
}
JEMALLOC_ALWAYS_INLINE tcache_t *
tcache_get(tsd_t *tsd) {
if (!tcache_available(tsd)) {
return NULL;
}
return tsd_tcachep_get(tsd);
}
static inline void
pre_reentrancy(tsd_t *tsd, arena_t *arena) {
/* arena is the current context. Reentry from a0 is not allowed. */
assert(arena != arena_get(tsd_tsdn(tsd), 0, false));
bool fast = tsd_fast(tsd);
assert(tsd_reentrancy_level_get(tsd) < INT8_MAX);
++*tsd_reentrancy_levelp_get(tsd);
if (fast) {
/* Prepare slow path for reentrancy. */
tsd_slow_update(tsd);
assert(tsd_state_get(tsd) == tsd_state_nominal_slow);
}
}
static inline void
post_reentrancy(tsd_t *tsd) {
int8_t *reentrancy_level = tsd_reentrancy_levelp_get(tsd);
assert(*reentrancy_level > 0);
if (--*reentrancy_level == 0) {
tsd_slow_update(tsd);
}
}
#endif /* JEMALLOC_INTERNAL_INLINES_A_H */

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#ifndef JEMALLOC_INTERNAL_INLINES_B_H
#define JEMALLOC_INTERNAL_INLINES_B_H
#include "jemalloc/internal/rtree.h"
/* Choose an arena based on a per-thread value. */
static inline arena_t *
arena_choose_impl(tsd_t *tsd, arena_t *arena, bool internal) {
arena_t *ret;
if (arena != NULL) {
return arena;
}
/* During reentrancy, arena 0 is the safest bet. */
if (unlikely(tsd_reentrancy_level_get(tsd) > 0)) {
return arena_get(tsd_tsdn(tsd), 0, true);
}
ret = internal ? tsd_iarena_get(tsd) : tsd_arena_get(tsd);
if (unlikely(ret == NULL)) {
ret = arena_choose_hard(tsd, internal);
assert(ret);
if (tcache_available(tsd)) {
tcache_t *tcache = tcache_get(tsd);
if (tcache->arena != NULL) {
/* See comments in tcache_data_init().*/
assert(tcache->arena ==
arena_get(tsd_tsdn(tsd), 0, false));
if (tcache->arena != ret) {
tcache_arena_reassociate(tsd_tsdn(tsd),
tcache, ret);
}
} else {
tcache_arena_associate(tsd_tsdn(tsd), tcache,
ret);
}
}
}
/*
* Note that for percpu arena, if the current arena is outside of the
* auto percpu arena range, (i.e. thread is assigned to a manually
* managed arena), then percpu arena is skipped.
*/
if (have_percpu_arena && PERCPU_ARENA_ENABLED(opt_percpu_arena) &&
!internal && (arena_ind_get(ret) <
percpu_arena_ind_limit(opt_percpu_arena)) && (ret->last_thd !=
tsd_tsdn(tsd))) {
unsigned ind = percpu_arena_choose();
if (arena_ind_get(ret) != ind) {
percpu_arena_update(tsd, ind);
ret = tsd_arena_get(tsd);
}
ret->last_thd = tsd_tsdn(tsd);
}
return ret;
}
static inline arena_t *
arena_choose(tsd_t *tsd, arena_t *arena) {
return arena_choose_impl(tsd, arena, false);
}
static inline arena_t *
arena_ichoose(tsd_t *tsd, arena_t *arena) {
return arena_choose_impl(tsd, arena, true);
}
static inline bool
arena_is_auto(arena_t *arena) {
assert(narenas_auto > 0);
return (arena_ind_get(arena) < manual_arena_base);
}
JEMALLOC_ALWAYS_INLINE extent_t *
iealloc(tsdn_t *tsdn, const void *ptr) {
rtree_ctx_t rtree_ctx_fallback;
rtree_ctx_t *rtree_ctx = tsdn_rtree_ctx(tsdn, &rtree_ctx_fallback);
return rtree_extent_read(tsdn, &extents_rtree, rtree_ctx,
(uintptr_t)ptr, true);
}
#endif /* JEMALLOC_INTERNAL_INLINES_B_H */

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#ifndef JEMALLOC_INTERNAL_INLINES_C_H
#define JEMALLOC_INTERNAL_INLINES_C_H
#include "jemalloc/internal/hook.h"
#include "jemalloc/internal/jemalloc_internal_types.h"
#include "jemalloc/internal/sz.h"
#include "jemalloc/internal/witness.h"
/*
* Translating the names of the 'i' functions:
* Abbreviations used in the first part of the function name (before
* alloc/dalloc) describe what that function accomplishes:
* a: arena (query)
* s: size (query, or sized deallocation)
* e: extent (query)
* p: aligned (allocates)
* vs: size (query, without knowing that the pointer is into the heap)
* r: rallocx implementation
* x: xallocx implementation
* Abbreviations used in the second part of the function name (after
* alloc/dalloc) describe the arguments it takes
* z: whether to return zeroed memory
* t: accepts a tcache_t * parameter
* m: accepts an arena_t * parameter
*/
JEMALLOC_ALWAYS_INLINE arena_t *
iaalloc(tsdn_t *tsdn, const void *ptr) {
assert(ptr != NULL);
return arena_aalloc(tsdn, ptr);
}
JEMALLOC_ALWAYS_INLINE size_t
isalloc(tsdn_t *tsdn, const void *ptr) {
assert(ptr != NULL);
return arena_salloc(tsdn, ptr);
}
JEMALLOC_ALWAYS_INLINE void *
iallocztm(tsdn_t *tsdn, size_t size, szind_t ind, bool zero, tcache_t *tcache,
bool is_internal, arena_t *arena, bool slow_path) {
void *ret;
assert(!is_internal || tcache == NULL);
assert(!is_internal || arena == NULL || arena_is_auto(arena));
if (!tsdn_null(tsdn) && tsd_reentrancy_level_get(tsdn_tsd(tsdn)) == 0) {
witness_assert_depth_to_rank(tsdn_witness_tsdp_get(tsdn),
WITNESS_RANK_CORE, 0);
}
ret = arena_malloc(tsdn, arena, size, ind, zero, tcache, slow_path);
if (config_stats && is_internal && likely(ret != NULL)) {
arena_internal_add(iaalloc(tsdn, ret), isalloc(tsdn, ret));
}
return ret;
}
JEMALLOC_ALWAYS_INLINE void *
ialloc(tsd_t *tsd, size_t size, szind_t ind, bool zero, bool slow_path) {
return iallocztm(tsd_tsdn(tsd), size, ind, zero, tcache_get(tsd), false,
NULL, slow_path);
}
JEMALLOC_ALWAYS_INLINE void *
ipallocztm(tsdn_t *tsdn, size_t usize, size_t alignment, bool zero,
tcache_t *tcache, bool is_internal, arena_t *arena) {
void *ret;
assert(usize != 0);
assert(usize == sz_sa2u(usize, alignment));
assert(!is_internal || tcache == NULL);
assert(!is_internal || arena == NULL || arena_is_auto(arena));
witness_assert_depth_to_rank(tsdn_witness_tsdp_get(tsdn),
WITNESS_RANK_CORE, 0);
ret = arena_palloc(tsdn, arena, usize, alignment, zero, tcache);
assert(ALIGNMENT_ADDR2BASE(ret, alignment) == ret);
if (config_stats && is_internal && likely(ret != NULL)) {
arena_internal_add(iaalloc(tsdn, ret), isalloc(tsdn, ret));
}
return ret;
}
JEMALLOC_ALWAYS_INLINE void *
ipalloct(tsdn_t *tsdn, size_t usize, size_t alignment, bool zero,
tcache_t *tcache, arena_t *arena) {
return ipallocztm(tsdn, usize, alignment, zero, tcache, false, arena);
}
JEMALLOC_ALWAYS_INLINE void *
ipalloc(tsd_t *tsd, size_t usize, size_t alignment, bool zero) {
return ipallocztm(tsd_tsdn(tsd), usize, alignment, zero,
tcache_get(tsd), false, NULL);
}
JEMALLOC_ALWAYS_INLINE size_t
ivsalloc(tsdn_t *tsdn, const void *ptr) {
return arena_vsalloc(tsdn, ptr);
}
JEMALLOC_ALWAYS_INLINE void
idalloctm(tsdn_t *tsdn, void *ptr, tcache_t *tcache, alloc_ctx_t *alloc_ctx,
bool is_internal, bool slow_path) {
assert(ptr != NULL);
assert(!is_internal || tcache == NULL);
assert(!is_internal || arena_is_auto(iaalloc(tsdn, ptr)));
witness_assert_depth_to_rank(tsdn_witness_tsdp_get(tsdn),
WITNESS_RANK_CORE, 0);
if (config_stats && is_internal) {
arena_internal_sub(iaalloc(tsdn, ptr), isalloc(tsdn, ptr));
}
if (!is_internal && !tsdn_null(tsdn) &&
tsd_reentrancy_level_get(tsdn_tsd(tsdn)) != 0) {
assert(tcache == NULL);
}
arena_dalloc(tsdn, ptr, tcache, alloc_ctx, slow_path);
}
JEMALLOC_ALWAYS_INLINE void
idalloc(tsd_t *tsd, void *ptr) {
idalloctm(tsd_tsdn(tsd), ptr, tcache_get(tsd), NULL, false, true);
}
JEMALLOC_ALWAYS_INLINE void
isdalloct(tsdn_t *tsdn, void *ptr, size_t size, tcache_t *tcache,
alloc_ctx_t *alloc_ctx, bool slow_path) {
witness_assert_depth_to_rank(tsdn_witness_tsdp_get(tsdn),
WITNESS_RANK_CORE, 0);
arena_sdalloc(tsdn, ptr, size, tcache, alloc_ctx, slow_path);
}
JEMALLOC_ALWAYS_INLINE void *
iralloct_realign(tsdn_t *tsdn, void *ptr, size_t oldsize, size_t size,
size_t alignment, bool zero, tcache_t *tcache, arena_t *arena,
hook_ralloc_args_t *hook_args) {
witness_assert_depth_to_rank(tsdn_witness_tsdp_get(tsdn),
WITNESS_RANK_CORE, 0);
void *p;
size_t usize, copysize;
usize = sz_sa2u(size, alignment);
if (unlikely(usize == 0 || usize > SC_LARGE_MAXCLASS)) {
return NULL;
}
p = ipalloct(tsdn, usize, alignment, zero, tcache, arena);
if (p == NULL) {
return NULL;
}
/*
* Copy at most size bytes (not size+extra), since the caller has no
* expectation that the extra bytes will be reliably preserved.
*/
copysize = (size < oldsize) ? size : oldsize;
memcpy(p, ptr, copysize);
hook_invoke_alloc(hook_args->is_realloc
? hook_alloc_realloc : hook_alloc_rallocx, p, (uintptr_t)p,
hook_args->args);
hook_invoke_dalloc(hook_args->is_realloc
? hook_dalloc_realloc : hook_dalloc_rallocx, ptr, hook_args->args);
isdalloct(tsdn, ptr, oldsize, tcache, NULL, true);
return p;
}
/*
* is_realloc threads through the knowledge of whether or not this call comes
* from je_realloc (as opposed to je_rallocx); this ensures that we pass the
* correct entry point into any hooks.
* Note that these functions are all force-inlined, so no actual bool gets
* passed-around anywhere.
*/
JEMALLOC_ALWAYS_INLINE void *
iralloct(tsdn_t *tsdn, void *ptr, size_t oldsize, size_t size, size_t alignment,
bool zero, tcache_t *tcache, arena_t *arena, hook_ralloc_args_t *hook_args)
{
assert(ptr != NULL);
assert(size != 0);
witness_assert_depth_to_rank(tsdn_witness_tsdp_get(tsdn),
WITNESS_RANK_CORE, 0);
if (alignment != 0 && ((uintptr_t)ptr & ((uintptr_t)alignment-1))
!= 0) {
/*
* Existing object alignment is inadequate; allocate new space
* and copy.
*/
return iralloct_realign(tsdn, ptr, oldsize, size, alignment,
zero, tcache, arena, hook_args);
}
return arena_ralloc(tsdn, arena, ptr, oldsize, size, alignment, zero,
tcache, hook_args);
}
JEMALLOC_ALWAYS_INLINE void *
iralloc(tsd_t *tsd, void *ptr, size_t oldsize, size_t size, size_t alignment,
bool zero, hook_ralloc_args_t *hook_args) {
return iralloct(tsd_tsdn(tsd), ptr, oldsize, size, alignment, zero,
tcache_get(tsd), NULL, hook_args);
}
JEMALLOC_ALWAYS_INLINE bool
ixalloc(tsdn_t *tsdn, void *ptr, size_t oldsize, size_t size, size_t extra,
size_t alignment, bool zero, size_t *newsize) {
assert(ptr != NULL);
assert(size != 0);
witness_assert_depth_to_rank(tsdn_witness_tsdp_get(tsdn),
WITNESS_RANK_CORE, 0);
if (alignment != 0 && ((uintptr_t)ptr & ((uintptr_t)alignment-1))
!= 0) {
/* Existing object alignment is inadequate. */
*newsize = oldsize;
return true;
}
return arena_ralloc_no_move(tsdn, ptr, oldsize, size, extra, zero,
newsize);
}
#endif /* JEMALLOC_INTERNAL_INLINES_C_H */

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#ifndef JEMALLOC_INTERNAL_MACROS_H
#define JEMALLOC_INTERNAL_MACROS_H
#ifdef JEMALLOC_DEBUG
# define JEMALLOC_ALWAYS_INLINE static inline
#else
# define JEMALLOC_ALWAYS_INLINE JEMALLOC_ATTR(always_inline) static inline
#endif
#ifdef _MSC_VER
# define inline _inline
#endif
#define UNUSED JEMALLOC_ATTR(unused)
#define ZU(z) ((size_t)z)
#define ZD(z) ((ssize_t)z)
#define QU(q) ((uint64_t)q)
#define QD(q) ((int64_t)q)
#define KZU(z) ZU(z##ULL)
#define KZD(z) ZD(z##LL)
#define KQU(q) QU(q##ULL)
#define KQD(q) QI(q##LL)
#ifndef __DECONST
# define __DECONST(type, var) ((type)(uintptr_t)(const void *)(var))
#endif
#if !defined(JEMALLOC_HAS_RESTRICT) || defined(__cplusplus)
# define restrict
#endif
/* Various function pointers are static and immutable except during testing. */
#ifdef JEMALLOC_JET
# define JET_MUTABLE
#else
# define JET_MUTABLE const
#endif
#define JEMALLOC_VA_ARGS_HEAD(head, ...) head
#define JEMALLOC_VA_ARGS_TAIL(head, ...) __VA_ARGS__
#if (defined(__GNUC__) || defined(__GNUG__)) && !defined(__clang__) \
&& defined(JEMALLOC_HAVE_ATTR) && (__GNUC__ >= 7)
#define JEMALLOC_FALLTHROUGH JEMALLOC_ATTR(fallthrough);
#else
#define JEMALLOC_FALLTHROUGH /* falls through */
#endif
/* Diagnostic suppression macros */
#if defined(_MSC_VER) && !defined(__clang__)
# define JEMALLOC_DIAGNOSTIC_PUSH __pragma(warning(push))
# define JEMALLOC_DIAGNOSTIC_POP __pragma(warning(pop))
# define JEMALLOC_DIAGNOSTIC_IGNORE(W) __pragma(warning(disable:W))
# define JEMALLOC_DIAGNOSTIC_IGNORE_MISSING_STRUCT_FIELD_INITIALIZERS
# define JEMALLOC_DIAGNOSTIC_IGNORE_TYPE_LIMITS
# define JEMALLOC_DIAGNOSTIC_IGNORE_ALLOC_SIZE_LARGER_THAN
# define JEMALLOC_DIAGNOSTIC_DISABLE_SPURIOUS
/* #pragma GCC diagnostic first appeared in gcc 4.6. */
#elif (defined(__GNUC__) && ((__GNUC__ > 4) || ((__GNUC__ == 4) && \
(__GNUC_MINOR__ > 5)))) || defined(__clang__)
/*
* The JEMALLOC_PRAGMA__ macro is an implementation detail of the GCC and Clang
* diagnostic suppression macros and should not be used anywhere else.
*/
# define JEMALLOC_PRAGMA__(X) _Pragma(#X)
# define JEMALLOC_DIAGNOSTIC_PUSH JEMALLOC_PRAGMA__(GCC diagnostic push)
# define JEMALLOC_DIAGNOSTIC_POP JEMALLOC_PRAGMA__(GCC diagnostic pop)
# define JEMALLOC_DIAGNOSTIC_IGNORE(W) \
JEMALLOC_PRAGMA__(GCC diagnostic ignored W)
/*
* The -Wmissing-field-initializers warning is buggy in GCC versions < 5.1 and
* all clang versions up to version 7 (currently trunk, unreleased). This macro
* suppresses the warning for the affected compiler versions only.
*/
# if ((defined(__GNUC__) && !defined(__clang__)) && (__GNUC__ < 5)) || \
defined(__clang__)
# define JEMALLOC_DIAGNOSTIC_IGNORE_MISSING_STRUCT_FIELD_INITIALIZERS \
JEMALLOC_DIAGNOSTIC_IGNORE("-Wmissing-field-initializers")
# else
# define JEMALLOC_DIAGNOSTIC_IGNORE_MISSING_STRUCT_FIELD_INITIALIZERS
# endif
# define JEMALLOC_DIAGNOSTIC_IGNORE_TYPE_LIMITS \
JEMALLOC_DIAGNOSTIC_IGNORE("-Wtype-limits")
# define JEMALLOC_DIAGNOSTIC_IGNORE_UNUSED_PARAMETER \
JEMALLOC_DIAGNOSTIC_IGNORE("-Wunused-parameter")
# if defined(__GNUC__) && !defined(__clang__) && (__GNUC__ >= 7)
# define JEMALLOC_DIAGNOSTIC_IGNORE_ALLOC_SIZE_LARGER_THAN \
JEMALLOC_DIAGNOSTIC_IGNORE("-Walloc-size-larger-than=")
# else
# define JEMALLOC_DIAGNOSTIC_IGNORE_ALLOC_SIZE_LARGER_THAN
# endif
# define JEMALLOC_DIAGNOSTIC_DISABLE_SPURIOUS \
JEMALLOC_DIAGNOSTIC_PUSH \
JEMALLOC_DIAGNOSTIC_IGNORE_UNUSED_PARAMETER
#else
# define JEMALLOC_DIAGNOSTIC_PUSH
# define JEMALLOC_DIAGNOSTIC_POP
# define JEMALLOC_DIAGNOSTIC_IGNORE(W)
# define JEMALLOC_DIAGNOSTIC_IGNORE_MISSING_STRUCT_FIELD_INITIALIZERS
# define JEMALLOC_DIAGNOSTIC_IGNORE_TYPE_LIMITS
# define JEMALLOC_DIAGNOSTIC_IGNORE_ALLOC_SIZE_LARGER_THAN
# define JEMALLOC_DIAGNOSTIC_DISABLE_SPURIOUS
#endif
/*
* Disables spurious diagnostics for all headers. Since these headers are not
* included by users directly, it does not affect their diagnostic settings.
*/
JEMALLOC_DIAGNOSTIC_DISABLE_SPURIOUS
#endif /* JEMALLOC_INTERNAL_MACROS_H */

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#ifndef JEMALLOC_INTERNAL_TYPES_H
#define JEMALLOC_INTERNAL_TYPES_H
#include "jemalloc/internal/quantum.h"
/* Page size index type. */
typedef unsigned pszind_t;
/* Size class index type. */
typedef unsigned szind_t;
/* Processor / core id type. */
typedef int malloc_cpuid_t;
/*
* Flags bits:
*
* a: arena
* t: tcache
* 0: unused
* z: zero
* n: alignment
*
* aaaaaaaa aaaatttt tttttttt 0znnnnnn
*/
#define MALLOCX_ARENA_BITS 12
#define MALLOCX_TCACHE_BITS 12
#define MALLOCX_LG_ALIGN_BITS 6
#define MALLOCX_ARENA_SHIFT 20
#define MALLOCX_TCACHE_SHIFT 8
#define MALLOCX_ARENA_MASK \
(((1 << MALLOCX_ARENA_BITS) - 1) << MALLOCX_ARENA_SHIFT)
/* NB: Arena index bias decreases the maximum number of arenas by 1. */
#define MALLOCX_ARENA_LIMIT ((1 << MALLOCX_ARENA_BITS) - 1)
#define MALLOCX_TCACHE_MASK \
(((1 << MALLOCX_TCACHE_BITS) - 1) << MALLOCX_TCACHE_SHIFT)
#define MALLOCX_TCACHE_MAX ((1 << MALLOCX_TCACHE_BITS) - 3)
#define MALLOCX_LG_ALIGN_MASK ((1 << MALLOCX_LG_ALIGN_BITS) - 1)
/* Use MALLOCX_ALIGN_GET() if alignment may not be specified in flags. */
#define MALLOCX_ALIGN_GET_SPECIFIED(flags) \
(ZU(1) << (flags & MALLOCX_LG_ALIGN_MASK))
#define MALLOCX_ALIGN_GET(flags) \
(MALLOCX_ALIGN_GET_SPECIFIED(flags) & (SIZE_T_MAX-1))
#define MALLOCX_ZERO_GET(flags) \
((bool)(flags & MALLOCX_ZERO))
#define MALLOCX_TCACHE_GET(flags) \
(((unsigned)((flags & MALLOCX_TCACHE_MASK) >> MALLOCX_TCACHE_SHIFT)) - 2)
#define MALLOCX_ARENA_GET(flags) \
(((unsigned)(((unsigned)flags) >> MALLOCX_ARENA_SHIFT)) - 1)
/* Smallest size class to support. */
#define TINY_MIN (1U << LG_TINY_MIN)
#define LONG ((size_t)(1U << LG_SIZEOF_LONG))
#define LONG_MASK (LONG - 1)
/* Return the smallest long multiple that is >= a. */
#define LONG_CEILING(a) \
(((a) + LONG_MASK) & ~LONG_MASK)
#define SIZEOF_PTR (1U << LG_SIZEOF_PTR)
#define PTR_MASK (SIZEOF_PTR - 1)
/* Return the smallest (void *) multiple that is >= a. */
#define PTR_CEILING(a) \
(((a) + PTR_MASK) & ~PTR_MASK)
/*
* Maximum size of L1 cache line. This is used to avoid cache line aliasing.
* In addition, this controls the spacing of cacheline-spaced size classes.
*
* CACHELINE cannot be based on LG_CACHELINE because __declspec(align()) can
* only handle raw constants.
*/
#define LG_CACHELINE 6
#define CACHELINE 64
#define CACHELINE_MASK (CACHELINE - 1)
/* Return the smallest cacheline multiple that is >= s. */
#define CACHELINE_CEILING(s) \
(((s) + CACHELINE_MASK) & ~CACHELINE_MASK)
/* Return the nearest aligned address at or below a. */
#define ALIGNMENT_ADDR2BASE(a, alignment) \
((void *)((uintptr_t)(a) & ((~(alignment)) + 1)))
/* Return the offset between a and the nearest aligned address at or below a. */
#define ALIGNMENT_ADDR2OFFSET(a, alignment) \
((size_t)((uintptr_t)(a) & (alignment - 1)))
/* Return the smallest alignment multiple that is >= s. */
#define ALIGNMENT_CEILING(s, alignment) \
(((s) + (alignment - 1)) & ((~(alignment)) + 1))
/* Declare a variable-length array. */
#if __STDC_VERSION__ < 199901L
# ifdef _MSC_VER
# include <malloc.h>
# define alloca _alloca
# else
# ifdef JEMALLOC_HAS_ALLOCA_H
# include <alloca.h>
# else
# include <stdlib.h>
# endif
# endif
# define VARIABLE_ARRAY(type, name, count) \
type *name = alloca(sizeof(type) * (count))
#else
# define VARIABLE_ARRAY(type, name, count) type name[(count)]
#endif
#endif /* JEMALLOC_INTERNAL_TYPES_H */

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#ifndef JEMALLOC_PREAMBLE_H
#define JEMALLOC_PREAMBLE_H
#include "jemalloc_internal_defs.h"
#include "jemalloc/internal/jemalloc_internal_decls.h"
#ifdef JEMALLOC_UTRACE
#include <sys/ktrace.h>
#endif
#define JEMALLOC_NO_DEMANGLE
#ifdef JEMALLOC_JET
# undef JEMALLOC_IS_MALLOC
# define JEMALLOC_N(n) jet_##n
# include "jemalloc/internal/public_namespace.h"
# define JEMALLOC_NO_RENAME
# include "../jemalloc@install_suffix@.h"
# undef JEMALLOC_NO_RENAME
#else
# define JEMALLOC_N(n) @private_namespace@##n
# include "../jemalloc@install_suffix@.h"
#endif
#if defined(JEMALLOC_OSATOMIC)
#include <libkern/OSAtomic.h>
#endif
#ifdef JEMALLOC_ZONE
#include <mach/mach_error.h>
#include <mach/mach_init.h>
#include <mach/vm_map.h>
#endif
#include "jemalloc/internal/jemalloc_internal_macros.h"
/*
* Note that the ordering matters here; the hook itself is name-mangled. We
* want the inclusion of hooks to happen early, so that we hook as much as
* possible.
*/
#ifndef JEMALLOC_NO_PRIVATE_NAMESPACE
# ifndef JEMALLOC_JET
# include "jemalloc/internal/private_namespace.h"
# else
# include "jemalloc/internal/private_namespace_jet.h"
# endif
#endif
#include "jemalloc/internal/test_hooks.h"
#ifdef JEMALLOC_DEFINE_MADVISE_FREE
# define JEMALLOC_MADV_FREE 8
#endif
static const bool config_debug =
#ifdef JEMALLOC_DEBUG
true
#else
false
#endif
;
static const bool have_dss =
#ifdef JEMALLOC_DSS
true
#else
false
#endif
;
static const bool have_madvise_huge =
#ifdef JEMALLOC_HAVE_MADVISE_HUGE
true
#else
false
#endif
;
static const bool config_fill =
#ifdef JEMALLOC_FILL
true
#else
false
#endif
;
static const bool config_lazy_lock =
#ifdef JEMALLOC_LAZY_LOCK
true
#else
false
#endif
;
static const char * const config_malloc_conf = JEMALLOC_CONFIG_MALLOC_CONF;
static const bool config_prof =
#ifdef JEMALLOC_PROF
true
#else
false
#endif
;
static const bool config_prof_libgcc =
#ifdef JEMALLOC_PROF_LIBGCC
true
#else
false
#endif
;
static const bool config_prof_libunwind =
#ifdef JEMALLOC_PROF_LIBUNWIND
true
#else
false
#endif
;
static const bool maps_coalesce =
#ifdef JEMALLOC_MAPS_COALESCE
true
#else
false
#endif
;
static const bool config_stats =
#ifdef JEMALLOC_STATS
true
#else
false
#endif
;
static const bool config_tls =
#ifdef JEMALLOC_TLS
true
#else
false
#endif
;
static const bool config_utrace =
#ifdef JEMALLOC_UTRACE
true
#else
false
#endif
;
static const bool config_xmalloc =
#ifdef JEMALLOC_XMALLOC
true
#else
false
#endif
;
static const bool config_cache_oblivious =
#ifdef JEMALLOC_CACHE_OBLIVIOUS
true
#else
false
#endif
;
/*
* Undocumented, for jemalloc development use only at the moment. See the note
* in jemalloc/internal/log.h.
*/
static const bool config_log =
#ifdef JEMALLOC_LOG
true
#else
false
#endif
;
/*
* Are extra safety checks enabled; things like checking the size of sized
* deallocations, double-frees, etc.
*/
static const bool config_opt_safety_checks =
#ifdef JEMALLOC_OPT_SAFETY_CHECKS
true
#elif defined(JEMALLOC_DEBUG)
/*
* This lets us only guard safety checks by one flag instead of two; fast
* checks can guard solely by config_opt_safety_checks and run in debug mode
* too.
*/
true
#else
false
#endif
;
#if defined(_WIN32) || defined(JEMALLOC_HAVE_SCHED_GETCPU)
/* Currently percpu_arena depends on sched_getcpu. */
#define JEMALLOC_PERCPU_ARENA
#endif
static const bool have_percpu_arena =
#ifdef JEMALLOC_PERCPU_ARENA
true
#else
false
#endif
;
/*
* Undocumented, and not recommended; the application should take full
* responsibility for tracking provenance.
*/
static const bool force_ivsalloc =
#ifdef JEMALLOC_FORCE_IVSALLOC
true
#else
false
#endif
;
static const bool have_background_thread =
#ifdef JEMALLOC_BACKGROUND_THREAD
true
#else
false
#endif
;
#endif /* JEMALLOC_PREAMBLE_H */

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#ifndef JEMALLOC_INTERNAL_LARGE_EXTERNS_H
#define JEMALLOC_INTERNAL_LARGE_EXTERNS_H
#include "jemalloc/internal/hook.h"
void *large_malloc(tsdn_t *tsdn, arena_t *arena, size_t usize, bool zero);
void *large_palloc(tsdn_t *tsdn, arena_t *arena, size_t usize, size_t alignment,
bool zero);
bool large_ralloc_no_move(tsdn_t *tsdn, extent_t *extent, size_t usize_min,
size_t usize_max, bool zero);
void *large_ralloc(tsdn_t *tsdn, arena_t *arena, void *ptr, size_t usize,
size_t alignment, bool zero, tcache_t *tcache,
hook_ralloc_args_t *hook_args);
typedef void (large_dalloc_junk_t)(void *, size_t);
extern large_dalloc_junk_t *JET_MUTABLE large_dalloc_junk;
typedef void (large_dalloc_maybe_junk_t)(void *, size_t);
extern large_dalloc_maybe_junk_t *JET_MUTABLE large_dalloc_maybe_junk;
void large_dalloc_prep_junked_locked(tsdn_t *tsdn, extent_t *extent);
void large_dalloc_finish(tsdn_t *tsdn, extent_t *extent);
void large_dalloc(tsdn_t *tsdn, extent_t *extent);
size_t large_salloc(tsdn_t *tsdn, const extent_t *extent);
prof_tctx_t *large_prof_tctx_get(tsdn_t *tsdn, const extent_t *extent);
void large_prof_tctx_set(tsdn_t *tsdn, extent_t *extent, prof_tctx_t *tctx);
void large_prof_tctx_reset(tsdn_t *tsdn, extent_t *extent);
nstime_t large_prof_alloc_time_get(const extent_t *extent);
void large_prof_alloc_time_set(extent_t *extent, nstime_t time);
#endif /* JEMALLOC_INTERNAL_LARGE_EXTERNS_H */

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#ifndef JEMALLOC_INTERNAL_LOG_H
#define JEMALLOC_INTERNAL_LOG_H
#include "jemalloc/internal/atomic.h"
#include "jemalloc/internal/malloc_io.h"
#include "jemalloc/internal/mutex.h"
#ifdef JEMALLOC_LOG
# define JEMALLOC_LOG_VAR_BUFSIZE 1000
#else
# define JEMALLOC_LOG_VAR_BUFSIZE 1
#endif
#define JEMALLOC_LOG_BUFSIZE 4096
/*
* The log malloc_conf option is a '|'-delimited list of log_var name segments
* which should be logged. The names are themselves hierarchical, with '.' as
* the delimiter (a "segment" is just a prefix in the log namespace). So, if
* you have:
*
* log("arena", "log msg for arena"); // 1
* log("arena.a", "log msg for arena.a"); // 2
* log("arena.b", "log msg for arena.b"); // 3
* log("arena.a.a", "log msg for arena.a.a"); // 4
* log("extent.a", "log msg for extent.a"); // 5
* log("extent.b", "log msg for extent.b"); // 6
*
* And your malloc_conf option is "log=arena.a|extent", then lines 2, 4, 5, and
* 6 will print at runtime. You can enable logging from all log vars by
* writing "log=.".
*
* None of this should be regarded as a stable API for right now. It's intended
* as a debugging interface, to let us keep around some of our printf-debugging
* statements.
*/
extern char log_var_names[JEMALLOC_LOG_VAR_BUFSIZE];
extern atomic_b_t log_init_done;
typedef struct log_var_s log_var_t;
struct log_var_s {
/*
* Lowest bit is "inited", second lowest is "enabled". Putting them in
* a single word lets us avoid any fences on weak architectures.
*/
atomic_u_t state;
const char *name;
};
#define LOG_NOT_INITIALIZED 0U
#define LOG_INITIALIZED_NOT_ENABLED 1U
#define LOG_ENABLED 2U
#define LOG_VAR_INIT(name_str) {ATOMIC_INIT(LOG_NOT_INITIALIZED), name_str}
/*
* Returns the value we should assume for state (which is not necessarily
* accurate; if logging is done before logging has finished initializing, then
* we default to doing the safe thing by logging everything).
*/
unsigned log_var_update_state(log_var_t *log_var);
/* We factor out the metadata management to allow us to test more easily. */
#define log_do_begin(log_var) \
if (config_log) { \
unsigned log_state = atomic_load_u(&(log_var).state, \
ATOMIC_RELAXED); \
if (unlikely(log_state == LOG_NOT_INITIALIZED)) { \
log_state = log_var_update_state(&(log_var)); \
assert(log_state != LOG_NOT_INITIALIZED); \
} \
if (log_state == LOG_ENABLED) { \
{
/* User code executes here. */
#define log_do_end(log_var) \
} \
} \
}
/*
* MSVC has some preprocessor bugs in its expansion of __VA_ARGS__ during
* preprocessing. To work around this, we take all potential extra arguments in
* a var-args functions. Since a varargs macro needs at least one argument in
* the "...", we accept the format string there, and require that the first
* argument in this "..." is a const char *.
*/
static inline void
log_impl_varargs(const char *name, ...) {
char buf[JEMALLOC_LOG_BUFSIZE];
va_list ap;
va_start(ap, name);
const char *format = va_arg(ap, const char *);
size_t dst_offset = 0;
dst_offset += malloc_snprintf(buf, JEMALLOC_LOG_BUFSIZE, "%s: ", name);
dst_offset += malloc_vsnprintf(buf + dst_offset,
JEMALLOC_LOG_BUFSIZE - dst_offset, format, ap);
dst_offset += malloc_snprintf(buf + dst_offset,
JEMALLOC_LOG_BUFSIZE - dst_offset, "\n");
va_end(ap);
malloc_write(buf);
}
/* Call as log("log.var.str", "format_string %d", arg_for_format_string); */
#define LOG(log_var_str, ...) \
do { \
static log_var_t log_var = LOG_VAR_INIT(log_var_str); \
log_do_begin(log_var) \
log_impl_varargs((log_var).name, __VA_ARGS__); \
log_do_end(log_var) \
} while (0)
#endif /* JEMALLOC_INTERNAL_LOG_H */

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#ifndef JEMALLOC_INTERNAL_MALLOC_IO_H
#define JEMALLOC_INTERNAL_MALLOC_IO_H
#ifdef _WIN32
# ifdef _WIN64
# define FMT64_PREFIX "ll"
# define FMTPTR_PREFIX "ll"
# else
# define FMT64_PREFIX "ll"
# define FMTPTR_PREFIX ""
# endif
# define FMTd32 "d"
# define FMTu32 "u"
# define FMTx32 "x"
# define FMTd64 FMT64_PREFIX "d"
# define FMTu64 FMT64_PREFIX "u"
# define FMTx64 FMT64_PREFIX "x"
# define FMTdPTR FMTPTR_PREFIX "d"
# define FMTuPTR FMTPTR_PREFIX "u"
# define FMTxPTR FMTPTR_PREFIX "x"
#else
# include <inttypes.h>
# define FMTd32 PRId32
# define FMTu32 PRIu32
# define FMTx32 PRIx32
# define FMTd64 PRId64
# define FMTu64 PRIu64
# define FMTx64 PRIx64
# define FMTdPTR PRIdPTR
# define FMTuPTR PRIuPTR
# define FMTxPTR PRIxPTR
#endif
/* Size of stack-allocated buffer passed to buferror(). */
#define BUFERROR_BUF 64
/*
* Size of stack-allocated buffer used by malloc_{,v,vc}printf(). This must be
* large enough for all possible uses within jemalloc.
*/
#define MALLOC_PRINTF_BUFSIZE 4096
int buferror(int err, char *buf, size_t buflen);
uintmax_t malloc_strtoumax(const char *restrict nptr, char **restrict endptr,
int base);
void malloc_write(const char *s);
/*
* malloc_vsnprintf() supports a subset of snprintf(3) that avoids floating
* point math.
*/
size_t malloc_vsnprintf(char *str, size_t size, const char *format,
va_list ap);
size_t malloc_snprintf(char *str, size_t size, const char *format, ...)
JEMALLOC_FORMAT_PRINTF(3, 4);
/*
* The caller can set write_cb to null to choose to print with the
* je_malloc_message hook.
*/
void malloc_vcprintf(void (*write_cb)(void *, const char *), void *cbopaque,
const char *format, va_list ap);
void malloc_cprintf(void (*write_cb)(void *, const char *), void *cbopaque,
const char *format, ...) JEMALLOC_FORMAT_PRINTF(3, 4);
void malloc_printf(const char *format, ...) JEMALLOC_FORMAT_PRINTF(1, 2);
static inline ssize_t
malloc_write_fd(int fd, const void *buf, size_t count) {
#if defined(JEMALLOC_USE_SYSCALL) && defined(SYS_write)
/*
* Use syscall(2) rather than write(2) when possible in order to avoid
* the possibility of memory allocation within libc. This is necessary
* on FreeBSD; most operating systems do not have this problem though.
*
* syscall() returns long or int, depending on platform, so capture the
* result in the widest plausible type to avoid compiler warnings.
*/
long result = syscall(SYS_write, fd, buf, count);
#else
ssize_t result = (ssize_t)write(fd, buf,
#ifdef _WIN32
(unsigned int)
#endif
count);
#endif
return (ssize_t)result;
}
static inline ssize_t
malloc_read_fd(int fd, void *buf, size_t count) {
#if defined(JEMALLOC_USE_SYSCALL) && defined(SYS_read)
long result = syscall(SYS_read, fd, buf, count);
#else
ssize_t result = read(fd, buf,
#ifdef _WIN32
(unsigned int)
#endif
count);
#endif
return (ssize_t)result;
}
#endif /* JEMALLOC_INTERNAL_MALLOC_IO_H */

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#ifndef JEMALLOC_INTERNAL_MUTEX_H
#define JEMALLOC_INTERNAL_MUTEX_H
#include "jemalloc/internal/atomic.h"
#include "jemalloc/internal/mutex_prof.h"
#include "jemalloc/internal/tsd.h"
#include "jemalloc/internal/witness.h"
typedef enum {
/* Can only acquire one mutex of a given witness rank at a time. */
malloc_mutex_rank_exclusive,
/*
* Can acquire multiple mutexes of the same witness rank, but in
* address-ascending order only.
*/
malloc_mutex_address_ordered
} malloc_mutex_lock_order_t;
typedef struct malloc_mutex_s malloc_mutex_t;
struct malloc_mutex_s {
union {
struct {
/*
* prof_data is defined first to reduce cacheline
* bouncing: the data is not touched by the mutex holder
* during unlocking, while might be modified by
* contenders. Having it before the mutex itself could
* avoid prefetching a modified cacheline (for the
* unlocking thread).
*/
mutex_prof_data_t prof_data;
#ifdef _WIN32
# if _WIN32_WINNT >= 0x0600
SRWLOCK lock;
# else
CRITICAL_SECTION lock;
# endif
#elif (defined(JEMALLOC_OS_UNFAIR_LOCK))
os_unfair_lock lock;
#elif (defined(JEMALLOC_MUTEX_INIT_CB))
pthread_mutex_t lock;
malloc_mutex_t *postponed_next;
#else
pthread_mutex_t lock;
#endif
/*
* Hint flag to avoid exclusive cache line contention
* during spin waiting
*/
atomic_b_t locked;
};
/*
* We only touch witness when configured w/ debug. However we
* keep the field in a union when !debug so that we don't have
* to pollute the code base with #ifdefs, while avoid paying the
* memory cost.
*/
#if !defined(JEMALLOC_DEBUG)
witness_t witness;
malloc_mutex_lock_order_t lock_order;
#endif
};
#if defined(JEMALLOC_DEBUG)
witness_t witness;
malloc_mutex_lock_order_t lock_order;
#endif
};
/*
* Based on benchmark results, a fixed spin with this amount of retries works
* well for our critical sections.
*/
#define MALLOC_MUTEX_MAX_SPIN 250
#ifdef _WIN32
# if _WIN32_WINNT >= 0x0600
# define MALLOC_MUTEX_LOCK(m) AcquireSRWLockExclusive(&(m)->lock)
# define MALLOC_MUTEX_UNLOCK(m) ReleaseSRWLockExclusive(&(m)->lock)
# define MALLOC_MUTEX_TRYLOCK(m) (!TryAcquireSRWLockExclusive(&(m)->lock))
# else
# define MALLOC_MUTEX_LOCK(m) EnterCriticalSection(&(m)->lock)
# define MALLOC_MUTEX_UNLOCK(m) LeaveCriticalSection(&(m)->lock)
# define MALLOC_MUTEX_TRYLOCK(m) (!TryEnterCriticalSection(&(m)->lock))
# endif
#elif (defined(JEMALLOC_OS_UNFAIR_LOCK))
# define MALLOC_MUTEX_LOCK(m) os_unfair_lock_lock(&(m)->lock)
# define MALLOC_MUTEX_UNLOCK(m) os_unfair_lock_unlock(&(m)->lock)
# define MALLOC_MUTEX_TRYLOCK(m) (!os_unfair_lock_trylock(&(m)->lock))
#else
# define MALLOC_MUTEX_LOCK(m) pthread_mutex_lock(&(m)->lock)
# define MALLOC_MUTEX_UNLOCK(m) pthread_mutex_unlock(&(m)->lock)
# define MALLOC_MUTEX_TRYLOCK(m) (pthread_mutex_trylock(&(m)->lock) != 0)
#endif
#define LOCK_PROF_DATA_INITIALIZER \
{NSTIME_ZERO_INITIALIZER, NSTIME_ZERO_INITIALIZER, 0, 0, 0, \
ATOMIC_INIT(0), 0, NULL, 0}
#ifdef _WIN32
# define MALLOC_MUTEX_INITIALIZER
#elif (defined(JEMALLOC_OS_UNFAIR_LOCK))
# if defined(JEMALLOC_DEBUG)
# define MALLOC_MUTEX_INITIALIZER \
{{{LOCK_PROF_DATA_INITIALIZER, OS_UNFAIR_LOCK_INIT, ATOMIC_INIT(false)}}, \
WITNESS_INITIALIZER("mutex", WITNESS_RANK_OMIT), 0}
# else
# define MALLOC_MUTEX_INITIALIZER \
{{{LOCK_PROF_DATA_INITIALIZER, OS_UNFAIR_LOCK_INIT, ATOMIC_INIT(false)}}, \
WITNESS_INITIALIZER("mutex", WITNESS_RANK_OMIT)}
# endif
#elif (defined(JEMALLOC_MUTEX_INIT_CB))
# if (defined(JEMALLOC_DEBUG))
# define MALLOC_MUTEX_INITIALIZER \
{{{LOCK_PROF_DATA_INITIALIZER, PTHREAD_MUTEX_INITIALIZER, NULL, ATOMIC_INIT(false)}}, \
WITNESS_INITIALIZER("mutex", WITNESS_RANK_OMIT), 0}
# else
# define MALLOC_MUTEX_INITIALIZER \
{{{LOCK_PROF_DATA_INITIALIZER, PTHREAD_MUTEX_INITIALIZER, NULL, ATOMIC_INIT(false)}}, \
WITNESS_INITIALIZER("mutex", WITNESS_RANK_OMIT)}
# endif
#else
# define MALLOC_MUTEX_TYPE PTHREAD_MUTEX_DEFAULT
# if defined(JEMALLOC_DEBUG)
# define MALLOC_MUTEX_INITIALIZER \
{{{LOCK_PROF_DATA_INITIALIZER, PTHREAD_MUTEX_INITIALIZER, ATOMIC_INIT(false)}}, \
WITNESS_INITIALIZER("mutex", WITNESS_RANK_OMIT), 0}
# else
# define MALLOC_MUTEX_INITIALIZER \
{{{LOCK_PROF_DATA_INITIALIZER, PTHREAD_MUTEX_INITIALIZER, ATOMIC_INIT(false)}}, \
WITNESS_INITIALIZER("mutex", WITNESS_RANK_OMIT)}
# endif
#endif
#ifdef JEMALLOC_LAZY_LOCK
extern bool isthreaded;
#else
# undef isthreaded /* Undo private_namespace.h definition. */
# define isthreaded true
#endif
bool malloc_mutex_init(malloc_mutex_t *mutex, const char *name,
witness_rank_t rank, malloc_mutex_lock_order_t lock_order);
void malloc_mutex_prefork(tsdn_t *tsdn, malloc_mutex_t *mutex);
void malloc_mutex_postfork_parent(tsdn_t *tsdn, malloc_mutex_t *mutex);
void malloc_mutex_postfork_child(tsdn_t *tsdn, malloc_mutex_t *mutex);
bool malloc_mutex_boot(void);
void malloc_mutex_prof_data_reset(tsdn_t *tsdn, malloc_mutex_t *mutex);
void malloc_mutex_lock_slow(malloc_mutex_t *mutex);
static inline void
malloc_mutex_lock_final(malloc_mutex_t *mutex) {
MALLOC_MUTEX_LOCK(mutex);
atomic_store_b(&mutex->locked, true, ATOMIC_RELAXED);
}
static inline bool
malloc_mutex_trylock_final(malloc_mutex_t *mutex) {
return MALLOC_MUTEX_TRYLOCK(mutex);
}
static inline void
mutex_owner_stats_update(tsdn_t *tsdn, malloc_mutex_t *mutex) {
if (config_stats) {
mutex_prof_data_t *data = &mutex->prof_data;
data->n_lock_ops++;
if (data->prev_owner != tsdn) {
data->prev_owner = tsdn;
data->n_owner_switches++;
}
}
}
/* Trylock: return false if the lock is successfully acquired. */
static inline bool
malloc_mutex_trylock(tsdn_t *tsdn, malloc_mutex_t *mutex) {
witness_assert_not_owner(tsdn_witness_tsdp_get(tsdn), &mutex->witness);
if (isthreaded) {
if (malloc_mutex_trylock_final(mutex)) {
atomic_store_b(&mutex->locked, true, ATOMIC_RELAXED);
return true;
}
mutex_owner_stats_update(tsdn, mutex);
}
witness_lock(tsdn_witness_tsdp_get(tsdn), &mutex->witness);
return false;
}
/* Aggregate lock prof data. */
static inline void
malloc_mutex_prof_merge(mutex_prof_data_t *sum, mutex_prof_data_t *data) {
nstime_add(&sum->tot_wait_time, &data->tot_wait_time);
if (nstime_compare(&sum->max_wait_time, &data->max_wait_time) < 0) {
nstime_copy(&sum->max_wait_time, &data->max_wait_time);
}
sum->n_wait_times += data->n_wait_times;
sum->n_spin_acquired += data->n_spin_acquired;
if (sum->max_n_thds < data->max_n_thds) {
sum->max_n_thds = data->max_n_thds;
}
uint32_t cur_n_waiting_thds = atomic_load_u32(&sum->n_waiting_thds,
ATOMIC_RELAXED);
uint32_t new_n_waiting_thds = cur_n_waiting_thds + atomic_load_u32(
&data->n_waiting_thds, ATOMIC_RELAXED);
atomic_store_u32(&sum->n_waiting_thds, new_n_waiting_thds,
ATOMIC_RELAXED);
sum->n_owner_switches += data->n_owner_switches;
sum->n_lock_ops += data->n_lock_ops;
}
static inline void
malloc_mutex_lock(tsdn_t *tsdn, malloc_mutex_t *mutex) {
witness_assert_not_owner(tsdn_witness_tsdp_get(tsdn), &mutex->witness);
if (isthreaded) {
if (malloc_mutex_trylock_final(mutex)) {
malloc_mutex_lock_slow(mutex);
atomic_store_b(&mutex->locked, true, ATOMIC_RELAXED);
}
mutex_owner_stats_update(tsdn, mutex);
}
witness_lock(tsdn_witness_tsdp_get(tsdn), &mutex->witness);
}
static inline void
malloc_mutex_unlock(tsdn_t *tsdn, malloc_mutex_t *mutex) {
atomic_store_b(&mutex->locked, false, ATOMIC_RELAXED);
witness_unlock(tsdn_witness_tsdp_get(tsdn), &mutex->witness);
if (isthreaded) {
MALLOC_MUTEX_UNLOCK(mutex);
}
}
static inline void
malloc_mutex_assert_owner(tsdn_t *tsdn, malloc_mutex_t *mutex) {
witness_assert_owner(tsdn_witness_tsdp_get(tsdn), &mutex->witness);
}
static inline void
malloc_mutex_assert_not_owner(tsdn_t *tsdn, malloc_mutex_t *mutex) {
witness_assert_not_owner(tsdn_witness_tsdp_get(tsdn), &mutex->witness);
}
/* Copy the prof data from mutex for processing. */
static inline void
malloc_mutex_prof_read(tsdn_t *tsdn, mutex_prof_data_t *data,
malloc_mutex_t *mutex) {
mutex_prof_data_t *source = &mutex->prof_data;
/* Can only read holding the mutex. */
malloc_mutex_assert_owner(tsdn, mutex);
/*
* Not *really* allowed (we shouldn't be doing non-atomic loads of
* atomic data), but the mutex protection makes this safe, and writing
* a member-for-member copy is tedious for this situation.
*/
*data = *source;
/* n_wait_thds is not reported (modified w/o locking). */
atomic_store_u32(&data->n_waiting_thds, 0, ATOMIC_RELAXED);
}
static inline void
malloc_mutex_prof_accum(tsdn_t *tsdn, mutex_prof_data_t *data,
malloc_mutex_t *mutex) {
mutex_prof_data_t *source = &mutex->prof_data;
/* Can only read holding the mutex. */
malloc_mutex_assert_owner(tsdn, mutex);
nstime_add(&data->tot_wait_time, &source->tot_wait_time);
if (nstime_compare(&source->max_wait_time, &data->max_wait_time) > 0) {
nstime_copy(&data->max_wait_time, &source->max_wait_time);
}
data->n_wait_times += source->n_wait_times;
data->n_spin_acquired += source->n_spin_acquired;
if (data->max_n_thds < source->max_n_thds) {
data->max_n_thds = source->max_n_thds;
}
/* n_wait_thds is not reported. */
atomic_store_u32(&data->n_waiting_thds, 0, ATOMIC_RELAXED);
data->n_owner_switches += source->n_owner_switches;
data->n_lock_ops += source->n_lock_ops;
}
#endif /* JEMALLOC_INTERNAL_MUTEX_H */

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#ifndef JEMALLOC_INTERNAL_MUTEX_POOL_H
#define JEMALLOC_INTERNAL_MUTEX_POOL_H
#include "jemalloc/internal/hash.h"
#include "jemalloc/internal/mutex.h"
#include "jemalloc/internal/witness.h"
/* We do mod reductions by this value, so it should be kept a power of 2. */
#define MUTEX_POOL_SIZE 256
typedef struct mutex_pool_s mutex_pool_t;
struct mutex_pool_s {
malloc_mutex_t mutexes[MUTEX_POOL_SIZE];
};
bool mutex_pool_init(mutex_pool_t *pool, const char *name, witness_rank_t rank);
/* Internal helper - not meant to be called outside this module. */
static inline malloc_mutex_t *
mutex_pool_mutex(mutex_pool_t *pool, uintptr_t key) {
size_t hash_result[2];
hash(&key, sizeof(key), 0xd50dcc1b, hash_result);
return &pool->mutexes[hash_result[0] % MUTEX_POOL_SIZE];
}
static inline void
mutex_pool_assert_not_held(tsdn_t *tsdn, mutex_pool_t *pool) {
for (int i = 0; i < MUTEX_POOL_SIZE; i++) {
malloc_mutex_assert_not_owner(tsdn, &pool->mutexes[i]);
}
}
/*
* Note that a mutex pool doesn't work exactly the way an embdedded mutex would.
* You're not allowed to acquire mutexes in the pool one at a time. You have to
* acquire all the mutexes you'll need in a single function call, and then
* release them all in a single function call.
*/
static inline void
mutex_pool_lock(tsdn_t *tsdn, mutex_pool_t *pool, uintptr_t key) {
mutex_pool_assert_not_held(tsdn, pool);
malloc_mutex_t *mutex = mutex_pool_mutex(pool, key);
malloc_mutex_lock(tsdn, mutex);
}
static inline void
mutex_pool_unlock(tsdn_t *tsdn, mutex_pool_t *pool, uintptr_t key) {
malloc_mutex_t *mutex = mutex_pool_mutex(pool, key);
malloc_mutex_unlock(tsdn, mutex);
mutex_pool_assert_not_held(tsdn, pool);
}
static inline void
mutex_pool_lock2(tsdn_t *tsdn, mutex_pool_t *pool, uintptr_t key1,
uintptr_t key2) {
mutex_pool_assert_not_held(tsdn, pool);
malloc_mutex_t *mutex1 = mutex_pool_mutex(pool, key1);
malloc_mutex_t *mutex2 = mutex_pool_mutex(pool, key2);
if ((uintptr_t)mutex1 < (uintptr_t)mutex2) {
malloc_mutex_lock(tsdn, mutex1);
malloc_mutex_lock(tsdn, mutex2);
} else if ((uintptr_t)mutex1 == (uintptr_t)mutex2) {
malloc_mutex_lock(tsdn, mutex1);
} else {
malloc_mutex_lock(tsdn, mutex2);
malloc_mutex_lock(tsdn, mutex1);
}
}
static inline void
mutex_pool_unlock2(tsdn_t *tsdn, mutex_pool_t *pool, uintptr_t key1,
uintptr_t key2) {
malloc_mutex_t *mutex1 = mutex_pool_mutex(pool, key1);
malloc_mutex_t *mutex2 = mutex_pool_mutex(pool, key2);
if (mutex1 == mutex2) {
malloc_mutex_unlock(tsdn, mutex1);
} else {
malloc_mutex_unlock(tsdn, mutex1);
malloc_mutex_unlock(tsdn, mutex2);
}
mutex_pool_assert_not_held(tsdn, pool);
}
static inline void
mutex_pool_assert_owner(tsdn_t *tsdn, mutex_pool_t *pool, uintptr_t key) {
malloc_mutex_assert_owner(tsdn, mutex_pool_mutex(pool, key));
}
#endif /* JEMALLOC_INTERNAL_MUTEX_POOL_H */

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#ifndef JEMALLOC_INTERNAL_MUTEX_PROF_H
#define JEMALLOC_INTERNAL_MUTEX_PROF_H
#include "jemalloc/internal/atomic.h"
#include "jemalloc/internal/nstime.h"
#include "jemalloc/internal/tsd_types.h"
#define MUTEX_PROF_GLOBAL_MUTEXES \
OP(background_thread) \
OP(ctl) \
OP(prof)
typedef enum {
#define OP(mtx) global_prof_mutex_##mtx,
MUTEX_PROF_GLOBAL_MUTEXES
#undef OP
mutex_prof_num_global_mutexes
} mutex_prof_global_ind_t;
#define MUTEX_PROF_ARENA_MUTEXES \
OP(large) \
OP(extent_avail) \
OP(extents_dirty) \
OP(extents_muzzy) \
OP(extents_retained) \
OP(decay_dirty) \
OP(decay_muzzy) \
OP(base) \
OP(tcache_list)
typedef enum {
#define OP(mtx) arena_prof_mutex_##mtx,
MUTEX_PROF_ARENA_MUTEXES
#undef OP
mutex_prof_num_arena_mutexes
} mutex_prof_arena_ind_t;
/*
* The forth parameter is a boolean value that is true for derived rate counters
* and false for real ones.
*/
#define MUTEX_PROF_UINT64_COUNTERS \
OP(num_ops, uint64_t, "n_lock_ops", false, num_ops) \
OP(num_ops_ps, uint64_t, "(#/sec)", true, num_ops) \
OP(num_wait, uint64_t, "n_waiting", false, num_wait) \
OP(num_wait_ps, uint64_t, "(#/sec)", true, num_wait) \
OP(num_spin_acq, uint64_t, "n_spin_acq", false, num_spin_acq) \
OP(num_spin_acq_ps, uint64_t, "(#/sec)", true, num_spin_acq) \
OP(num_owner_switch, uint64_t, "n_owner_switch", false, num_owner_switch) \
OP(num_owner_switch_ps, uint64_t, "(#/sec)", true, num_owner_switch) \
OP(total_wait_time, uint64_t, "total_wait_ns", false, total_wait_time) \
OP(total_wait_time_ps, uint64_t, "(#/sec)", true, total_wait_time) \
OP(max_wait_time, uint64_t, "max_wait_ns", false, max_wait_time)
#define MUTEX_PROF_UINT32_COUNTERS \
OP(max_num_thds, uint32_t, "max_n_thds", false, max_num_thds)
#define MUTEX_PROF_COUNTERS \
MUTEX_PROF_UINT64_COUNTERS \
MUTEX_PROF_UINT32_COUNTERS
#define OP(counter, type, human, derived, base_counter) mutex_counter_##counter,
#define COUNTER_ENUM(counter_list, t) \
typedef enum { \
counter_list \
mutex_prof_num_##t##_counters \
} mutex_prof_##t##_counter_ind_t;
COUNTER_ENUM(MUTEX_PROF_UINT64_COUNTERS, uint64_t)
COUNTER_ENUM(MUTEX_PROF_UINT32_COUNTERS, uint32_t)
#undef COUNTER_ENUM
#undef OP
typedef struct {
/*
* Counters touched on the slow path, i.e. when there is lock
* contention. We update them once we have the lock.
*/
/* Total time (in nano seconds) spent waiting on this mutex. */
nstime_t tot_wait_time;
/* Max time (in nano seconds) spent on a single lock operation. */
nstime_t max_wait_time;
/* # of times have to wait for this mutex (after spinning). */
uint64_t n_wait_times;
/* # of times acquired the mutex through local spinning. */
uint64_t n_spin_acquired;
/* Max # of threads waiting for the mutex at the same time. */
uint32_t max_n_thds;
/* Current # of threads waiting on the lock. Atomic synced. */
atomic_u32_t n_waiting_thds;
/*
* Data touched on the fast path. These are modified right after we
* grab the lock, so it's placed closest to the end (i.e. right before
* the lock) so that we have a higher chance of them being on the same
* cacheline.
*/
/* # of times the mutex holder is different than the previous one. */
uint64_t n_owner_switches;
/* Previous mutex holder, to facilitate n_owner_switches. */
tsdn_t *prev_owner;
/* # of lock() operations in total. */
uint64_t n_lock_ops;
} mutex_prof_data_t;
#endif /* JEMALLOC_INTERNAL_MUTEX_PROF_H */

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#ifndef JEMALLOC_INTERNAL_NSTIME_H
#define JEMALLOC_INTERNAL_NSTIME_H
/* Maximum supported number of seconds (~584 years). */
#define NSTIME_SEC_MAX KQU(18446744072)
#define NSTIME_ZERO_INITIALIZER {0}
typedef struct {
uint64_t ns;
} nstime_t;
void nstime_init(nstime_t *time, uint64_t ns);
void nstime_init2(nstime_t *time, uint64_t sec, uint64_t nsec);
uint64_t nstime_ns(const nstime_t *time);
uint64_t nstime_sec(const nstime_t *time);
uint64_t nstime_msec(const nstime_t *time);
uint64_t nstime_nsec(const nstime_t *time);
void nstime_copy(nstime_t *time, const nstime_t *source);
int nstime_compare(const nstime_t *a, const nstime_t *b);
void nstime_add(nstime_t *time, const nstime_t *addend);
void nstime_iadd(nstime_t *time, uint64_t addend);
void nstime_subtract(nstime_t *time, const nstime_t *subtrahend);
void nstime_isubtract(nstime_t *time, uint64_t subtrahend);
void nstime_imultiply(nstime_t *time, uint64_t multiplier);
void nstime_idivide(nstime_t *time, uint64_t divisor);
uint64_t nstime_divide(const nstime_t *time, const nstime_t *divisor);
typedef bool (nstime_monotonic_t)(void);
extern nstime_monotonic_t *JET_MUTABLE nstime_monotonic;
typedef bool (nstime_update_t)(nstime_t *);
extern nstime_update_t *JET_MUTABLE nstime_update;
#endif /* JEMALLOC_INTERNAL_NSTIME_H */

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#ifndef JEMALLOC_INTERNAL_PAGES_EXTERNS_H
#define JEMALLOC_INTERNAL_PAGES_EXTERNS_H
/* Page size. LG_PAGE is determined by the configure script. */
#ifdef PAGE_MASK
# undef PAGE_MASK
#endif
#define PAGE ((size_t)(1U << LG_PAGE))
#define PAGE_MASK ((size_t)(PAGE - 1))
/* Return the page base address for the page containing address a. */
#define PAGE_ADDR2BASE(a) \
((void *)((uintptr_t)(a) & ~PAGE_MASK))
/* Return the smallest pagesize multiple that is >= s. */
#define PAGE_CEILING(s) \
(((s) + PAGE_MASK) & ~PAGE_MASK)
/* Huge page size. LG_HUGEPAGE is determined by the configure script. */
#define HUGEPAGE ((size_t)(1U << LG_HUGEPAGE))
#define HUGEPAGE_MASK ((size_t)(HUGEPAGE - 1))
/* Return the huge page base address for the huge page containing address a. */
#define HUGEPAGE_ADDR2BASE(a) \
((void *)((uintptr_t)(a) & ~HUGEPAGE_MASK))
/* Return the smallest pagesize multiple that is >= s. */
#define HUGEPAGE_CEILING(s) \
(((s) + HUGEPAGE_MASK) & ~HUGEPAGE_MASK)
/* PAGES_CAN_PURGE_LAZY is defined if lazy purging is supported. */
#if defined(_WIN32) || defined(JEMALLOC_PURGE_MADVISE_FREE)
# define PAGES_CAN_PURGE_LAZY
#endif
/*
* PAGES_CAN_PURGE_FORCED is defined if forced purging is supported.
*
* The only supported way to hard-purge on Windows is to decommit and then
* re-commit, but doing so is racy, and if re-commit fails it's a pain to
* propagate the "poisoned" memory state. Since we typically decommit as the
* next step after purging on Windows anyway, there's no point in adding such
* complexity.
*/
#if !defined(_WIN32) && ((defined(JEMALLOC_PURGE_MADVISE_DONTNEED) && \
defined(JEMALLOC_PURGE_MADVISE_DONTNEED_ZEROS)) || \
defined(JEMALLOC_MAPS_COALESCE))
# define PAGES_CAN_PURGE_FORCED
#endif
static const bool pages_can_purge_lazy =
#ifdef PAGES_CAN_PURGE_LAZY
true
#else
false
#endif
;
static const bool pages_can_purge_forced =
#ifdef PAGES_CAN_PURGE_FORCED
true
#else
false
#endif
;
typedef enum {
thp_mode_default = 0, /* Do not change hugepage settings. */
thp_mode_always = 1, /* Always set MADV_HUGEPAGE. */
thp_mode_never = 2, /* Always set MADV_NOHUGEPAGE. */
thp_mode_names_limit = 3, /* Used for option processing. */
thp_mode_not_supported = 3 /* No THP support detected. */
} thp_mode_t;
#define THP_MODE_DEFAULT thp_mode_default
extern thp_mode_t opt_thp;
extern thp_mode_t init_system_thp_mode; /* Initial system wide state. */
extern const char *thp_mode_names[];
void *pages_map(void *addr, size_t size, size_t alignment, bool *commit);
void pages_unmap(void *addr, size_t size);
bool pages_commit(void *addr, size_t size);
bool pages_decommit(void *addr, size_t size);
bool pages_purge_lazy(void *addr, size_t size);
bool pages_purge_forced(void *addr, size_t size);
bool pages_huge(void *addr, size_t size);
bool pages_nohuge(void *addr, size_t size);
bool pages_dontdump(void *addr, size_t size);
bool pages_dodump(void *addr, size_t size);
bool pages_boot(void);
void pages_set_thp_state (void *ptr, size_t size);
#endif /* JEMALLOC_INTERNAL_PAGES_EXTERNS_H */

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/*
* A Pairing Heap implementation.
*
* "The Pairing Heap: A New Form of Self-Adjusting Heap"
* https://www.cs.cmu.edu/~sleator/papers/pairing-heaps.pdf
*
* With auxiliary twopass list, described in a follow on paper.
*
* "Pairing Heaps: Experiments and Analysis"
* http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.106.2988&rep=rep1&type=pdf
*
*******************************************************************************
*/
#ifndef PH_H_
#define PH_H_
/* Node structure. */
#define phn(a_type) \
struct { \
a_type *phn_prev; \
a_type *phn_next; \
a_type *phn_lchild; \
}
/* Root structure. */
#define ph(a_type) \
struct { \
a_type *ph_root; \
}
/* Internal utility macros. */
#define phn_lchild_get(a_type, a_field, a_phn) \
(a_phn->a_field.phn_lchild)
#define phn_lchild_set(a_type, a_field, a_phn, a_lchild) do { \
a_phn->a_field.phn_lchild = a_lchild; \
} while (0)
#define phn_next_get(a_type, a_field, a_phn) \
(a_phn->a_field.phn_next)
#define phn_prev_set(a_type, a_field, a_phn, a_prev) do { \
a_phn->a_field.phn_prev = a_prev; \
} while (0)
#define phn_prev_get(a_type, a_field, a_phn) \
(a_phn->a_field.phn_prev)
#define phn_next_set(a_type, a_field, a_phn, a_next) do { \
a_phn->a_field.phn_next = a_next; \
} while (0)
#define phn_merge_ordered(a_type, a_field, a_phn0, a_phn1, a_cmp) do { \
a_type *phn0child; \
\
assert(a_phn0 != NULL); \
assert(a_phn1 != NULL); \
assert(a_cmp(a_phn0, a_phn1) <= 0); \
\
phn_prev_set(a_type, a_field, a_phn1, a_phn0); \
phn0child = phn_lchild_get(a_type, a_field, a_phn0); \
phn_next_set(a_type, a_field, a_phn1, phn0child); \
if (phn0child != NULL) { \
phn_prev_set(a_type, a_field, phn0child, a_phn1); \
} \
phn_lchild_set(a_type, a_field, a_phn0, a_phn1); \
} while (0)
#define phn_merge(a_type, a_field, a_phn0, a_phn1, a_cmp, r_phn) do { \
if (a_phn0 == NULL) { \
r_phn = a_phn1; \
} else if (a_phn1 == NULL) { \
r_phn = a_phn0; \
} else if (a_cmp(a_phn0, a_phn1) < 0) { \
phn_merge_ordered(a_type, a_field, a_phn0, a_phn1, \
a_cmp); \
r_phn = a_phn0; \
} else { \
phn_merge_ordered(a_type, a_field, a_phn1, a_phn0, \
a_cmp); \
r_phn = a_phn1; \
} \
} while (0)
#define ph_merge_siblings(a_type, a_field, a_phn, a_cmp, r_phn) do { \
a_type *head = NULL; \
a_type *tail = NULL; \
a_type *phn0 = a_phn; \
a_type *phn1 = phn_next_get(a_type, a_field, phn0); \
\
/* \
* Multipass merge, wherein the first two elements of a FIFO \
* are repeatedly merged, and each result is appended to the \
* singly linked FIFO, until the FIFO contains only a single \
* element. We start with a sibling list but no reference to \
* its tail, so we do a single pass over the sibling list to \
* populate the FIFO. \
*/ \
if (phn1 != NULL) { \
a_type *phnrest = phn_next_get(a_type, a_field, phn1); \
if (phnrest != NULL) { \
phn_prev_set(a_type, a_field, phnrest, NULL); \
} \
phn_prev_set(a_type, a_field, phn0, NULL); \
phn_next_set(a_type, a_field, phn0, NULL); \
phn_prev_set(a_type, a_field, phn1, NULL); \
phn_next_set(a_type, a_field, phn1, NULL); \
phn_merge(a_type, a_field, phn0, phn1, a_cmp, phn0); \
head = tail = phn0; \
phn0 = phnrest; \
while (phn0 != NULL) { \
phn1 = phn_next_get(a_type, a_field, phn0); \
if (phn1 != NULL) { \
phnrest = phn_next_get(a_type, a_field, \
phn1); \
if (phnrest != NULL) { \
phn_prev_set(a_type, a_field, \
phnrest, NULL); \
} \
phn_prev_set(a_type, a_field, phn0, \
NULL); \
phn_next_set(a_type, a_field, phn0, \
NULL); \
phn_prev_set(a_type, a_field, phn1, \
NULL); \
phn_next_set(a_type, a_field, phn1, \
NULL); \
phn_merge(a_type, a_field, phn0, phn1, \
a_cmp, phn0); \
phn_next_set(a_type, a_field, tail, \
phn0); \
tail = phn0; \
phn0 = phnrest; \
} else { \
phn_next_set(a_type, a_field, tail, \
phn0); \
tail = phn0; \
phn0 = NULL; \
} \
} \
phn0 = head; \
phn1 = phn_next_get(a_type, a_field, phn0); \
if (phn1 != NULL) { \
while (true) { \
head = phn_next_get(a_type, a_field, \
phn1); \
assert(phn_prev_get(a_type, a_field, \
phn0) == NULL); \
phn_next_set(a_type, a_field, phn0, \
NULL); \
assert(phn_prev_get(a_type, a_field, \
phn1) == NULL); \
phn_next_set(a_type, a_field, phn1, \
NULL); \
phn_merge(a_type, a_field, phn0, phn1, \
a_cmp, phn0); \
if (head == NULL) { \
break; \
} \
phn_next_set(a_type, a_field, tail, \
phn0); \
tail = phn0; \
phn0 = head; \
phn1 = phn_next_get(a_type, a_field, \
phn0); \
} \
} \
} \
r_phn = phn0; \
} while (0)
#define ph_merge_aux(a_type, a_field, a_ph, a_cmp) do { \
a_type *phn = phn_next_get(a_type, a_field, a_ph->ph_root); \
if (phn != NULL) { \
phn_prev_set(a_type, a_field, a_ph->ph_root, NULL); \
phn_next_set(a_type, a_field, a_ph->ph_root, NULL); \
phn_prev_set(a_type, a_field, phn, NULL); \
ph_merge_siblings(a_type, a_field, phn, a_cmp, phn); \
assert(phn_next_get(a_type, a_field, phn) == NULL); \
phn_merge(a_type, a_field, a_ph->ph_root, phn, a_cmp, \
a_ph->ph_root); \
} \
} while (0)
#define ph_merge_children(a_type, a_field, a_phn, a_cmp, r_phn) do { \
a_type *lchild = phn_lchild_get(a_type, a_field, a_phn); \
if (lchild == NULL) { \
r_phn = NULL; \
} else { \
ph_merge_siblings(a_type, a_field, lchild, a_cmp, \
r_phn); \
} \
} while (0)
/*
* The ph_proto() macro generates function prototypes that correspond to the
* functions generated by an equivalently parameterized call to ph_gen().
*/
#define ph_proto(a_attr, a_prefix, a_ph_type, a_type) \
a_attr void a_prefix##new(a_ph_type *ph); \
a_attr bool a_prefix##empty(a_ph_type *ph); \
a_attr a_type *a_prefix##first(a_ph_type *ph); \
a_attr a_type *a_prefix##any(a_ph_type *ph); \
a_attr void a_prefix##insert(a_ph_type *ph, a_type *phn); \
a_attr a_type *a_prefix##remove_first(a_ph_type *ph); \
a_attr a_type *a_prefix##remove_any(a_ph_type *ph); \
a_attr void a_prefix##remove(a_ph_type *ph, a_type *phn);
/*
* The ph_gen() macro generates a type-specific pairing heap implementation,
* based on the above cpp macros.
*/
#define ph_gen(a_attr, a_prefix, a_ph_type, a_type, a_field, a_cmp) \
a_attr void \
a_prefix##new(a_ph_type *ph) { \
memset(ph, 0, sizeof(ph(a_type))); \
} \
a_attr bool \
a_prefix##empty(a_ph_type *ph) { \
return (ph->ph_root == NULL); \
} \
a_attr a_type * \
a_prefix##first(a_ph_type *ph) { \
if (ph->ph_root == NULL) { \
return NULL; \
} \
ph_merge_aux(a_type, a_field, ph, a_cmp); \
return ph->ph_root; \
} \
a_attr a_type * \
a_prefix##any(a_ph_type *ph) { \
if (ph->ph_root == NULL) { \
return NULL; \
} \
a_type *aux = phn_next_get(a_type, a_field, ph->ph_root); \
if (aux != NULL) { \
return aux; \
} \
return ph->ph_root; \
} \
a_attr void \
a_prefix##insert(a_ph_type *ph, a_type *phn) { \
memset(&phn->a_field, 0, sizeof(phn(a_type))); \
\
/* \
* Treat the root as an aux list during insertion, and lazily \
* merge during a_prefix##remove_first(). For elements that \
* are inserted, then removed via a_prefix##remove() before the \
* aux list is ever processed, this makes insert/remove \
* constant-time, whereas eager merging would make insert \
* O(log n). \
*/ \
if (ph->ph_root == NULL) { \
ph->ph_root = phn; \
} else { \
phn_next_set(a_type, a_field, phn, phn_next_get(a_type, \
a_field, ph->ph_root)); \
if (phn_next_get(a_type, a_field, ph->ph_root) != \
NULL) { \
phn_prev_set(a_type, a_field, \
phn_next_get(a_type, a_field, ph->ph_root), \
phn); \
} \
phn_prev_set(a_type, a_field, phn, ph->ph_root); \
phn_next_set(a_type, a_field, ph->ph_root, phn); \
} \
} \
a_attr a_type * \
a_prefix##remove_first(a_ph_type *ph) { \
a_type *ret; \
\
if (ph->ph_root == NULL) { \
return NULL; \
} \
ph_merge_aux(a_type, a_field, ph, a_cmp); \
\
ret = ph->ph_root; \
\
ph_merge_children(a_type, a_field, ph->ph_root, a_cmp, \
ph->ph_root); \
\
return ret; \
} \
a_attr a_type * \
a_prefix##remove_any(a_ph_type *ph) { \
/* \
* Remove the most recently inserted aux list element, or the \
* root if the aux list is empty. This has the effect of \
* behaving as a LIFO (and insertion/removal is therefore \
* constant-time) if a_prefix##[remove_]first() are never \
* called. \
*/ \
if (ph->ph_root == NULL) { \
return NULL; \
} \
a_type *ret = phn_next_get(a_type, a_field, ph->ph_root); \
if (ret != NULL) { \
a_type *aux = phn_next_get(a_type, a_field, ret); \
phn_next_set(a_type, a_field, ph->ph_root, aux); \
if (aux != NULL) { \
phn_prev_set(a_type, a_field, aux, \
ph->ph_root); \
} \
return ret; \
} \
ret = ph->ph_root; \
ph_merge_children(a_type, a_field, ph->ph_root, a_cmp, \
ph->ph_root); \
return ret; \
} \
a_attr void \
a_prefix##remove(a_ph_type *ph, a_type *phn) { \
a_type *replace, *parent; \
\
if (ph->ph_root == phn) { \
/* \
* We can delete from aux list without merging it, but \
* we need to merge if we are dealing with the root \
* node and it has children. \
*/ \
if (phn_lchild_get(a_type, a_field, phn) == NULL) { \
ph->ph_root = phn_next_get(a_type, a_field, \
phn); \
if (ph->ph_root != NULL) { \
phn_prev_set(a_type, a_field, \
ph->ph_root, NULL); \
} \
return; \
} \
ph_merge_aux(a_type, a_field, ph, a_cmp); \
if (ph->ph_root == phn) { \
ph_merge_children(a_type, a_field, ph->ph_root, \
a_cmp, ph->ph_root); \
return; \
} \
} \
\
/* Get parent (if phn is leftmost child) before mutating. */ \
if ((parent = phn_prev_get(a_type, a_field, phn)) != NULL) { \
if (phn_lchild_get(a_type, a_field, parent) != phn) { \
parent = NULL; \
} \
} \
/* Find a possible replacement node, and link to parent. */ \
ph_merge_children(a_type, a_field, phn, a_cmp, replace); \
/* Set next/prev for sibling linked list. */ \
if (replace != NULL) { \
if (parent != NULL) { \
phn_prev_set(a_type, a_field, replace, parent); \
phn_lchild_set(a_type, a_field, parent, \
replace); \
} else { \
phn_prev_set(a_type, a_field, replace, \
phn_prev_get(a_type, a_field, phn)); \
if (phn_prev_get(a_type, a_field, phn) != \
NULL) { \
phn_next_set(a_type, a_field, \
phn_prev_get(a_type, a_field, phn), \
replace); \
} \
} \
phn_next_set(a_type, a_field, replace, \
phn_next_get(a_type, a_field, phn)); \
if (phn_next_get(a_type, a_field, phn) != NULL) { \
phn_prev_set(a_type, a_field, \
phn_next_get(a_type, a_field, phn), \
replace); \
} \
} else { \
if (parent != NULL) { \
a_type *next = phn_next_get(a_type, a_field, \
phn); \
phn_lchild_set(a_type, a_field, parent, next); \
if (next != NULL) { \
phn_prev_set(a_type, a_field, next, \
parent); \
} \
} else { \
assert(phn_prev_get(a_type, a_field, phn) != \
NULL); \
phn_next_set(a_type, a_field, \
phn_prev_get(a_type, a_field, phn), \
phn_next_get(a_type, a_field, phn)); \
} \
if (phn_next_get(a_type, a_field, phn) != NULL) { \
phn_prev_set(a_type, a_field, \
phn_next_get(a_type, a_field, phn), \
phn_prev_get(a_type, a_field, phn)); \
} \
} \
}
#endif /* PH_H_ */

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#!/bin/sh
for symbol in `cat "$@"` ; do
echo "#define ${symbol} JEMALLOC_N(${symbol})"
done

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#!/bin/sh
#
# Generate private_symbols[_jet].awk.
#
# Usage: private_symbols.sh <sym_prefix> <sym>*
#
# <sym_prefix> is typically "" or "_".
sym_prefix=$1
shift
cat <<EOF
#!/usr/bin/env awk -f
BEGIN {
sym_prefix = "${sym_prefix}"
split("\\
EOF
for public_sym in "$@" ; do
cat <<EOF
${sym_prefix}${public_sym} \\
EOF
done
cat <<"EOF"
", exported_symbol_names)
# Store exported symbol names as keys in exported_symbols.
for (i in exported_symbol_names) {
exported_symbols[exported_symbol_names[i]] = 1
}
}
# Process 'nm -a <c_source.o>' output.
#
# Handle lines like:
# 0000000000000008 D opt_junk
# 0000000000007574 T malloc_initialized
(NF == 3 && $2 ~ /^[ABCDGRSTVW]$/ && !($3 in exported_symbols) && $3 ~ /^[A-Za-z0-9_]+$/) {
print substr($3, 1+length(sym_prefix), length($3)-length(sym_prefix))
}
# Process 'dumpbin /SYMBOLS <c_source.obj>' output.
#
# Handle lines like:
# 353 00008098 SECT4 notype External | opt_junk
# 3F1 00000000 SECT7 notype () External | malloc_initialized
($3 ~ /^SECT[0-9]+/ && $(NF-2) == "External" && !($NF in exported_symbols)) {
print $NF
}
EOF

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#ifndef JEMALLOC_INTERNAL_PRNG_H
#define JEMALLOC_INTERNAL_PRNG_H
#include "jemalloc/internal/atomic.h"
#include "jemalloc/internal/bit_util.h"
/*
* Simple linear congruential pseudo-random number generator:
*
* prng(y) = (a*x + c) % m
*
* where the following constants ensure maximal period:
*
* a == Odd number (relatively prime to 2^n), and (a-1) is a multiple of 4.
* c == Odd number (relatively prime to 2^n).
* m == 2^32
*
* See Knuth's TAOCP 3rd Ed., Vol. 2, pg. 17 for details on these constraints.
*
* This choice of m has the disadvantage that the quality of the bits is
* proportional to bit position. For example, the lowest bit has a cycle of 2,
* the next has a cycle of 4, etc. For this reason, we prefer to use the upper
* bits.
*/
/******************************************************************************/
/* INTERNAL DEFINITIONS -- IGNORE */
/******************************************************************************/
#define PRNG_A_32 UINT32_C(1103515241)
#define PRNG_C_32 UINT32_C(12347)
#define PRNG_A_64 UINT64_C(6364136223846793005)
#define PRNG_C_64 UINT64_C(1442695040888963407)
JEMALLOC_ALWAYS_INLINE uint32_t
prng_state_next_u32(uint32_t state) {
return (state * PRNG_A_32) + PRNG_C_32;
}
JEMALLOC_ALWAYS_INLINE uint64_t
prng_state_next_u64(uint64_t state) {
return (state * PRNG_A_64) + PRNG_C_64;
}
JEMALLOC_ALWAYS_INLINE size_t
prng_state_next_zu(size_t state) {
#if LG_SIZEOF_PTR == 2
return (state * PRNG_A_32) + PRNG_C_32;
#elif LG_SIZEOF_PTR == 3
return (state * PRNG_A_64) + PRNG_C_64;
#else
#error Unsupported pointer size
#endif
}
/******************************************************************************/
/* BEGIN PUBLIC API */
/******************************************************************************/
/*
* The prng_lg_range functions give a uniform int in the half-open range [0,
* 2**lg_range). If atomic is true, they do so safely from multiple threads.
* Multithreaded 64-bit prngs aren't supported.
*/
JEMALLOC_ALWAYS_INLINE uint32_t
prng_lg_range_u32(atomic_u32_t *state, unsigned lg_range, bool atomic) {
uint32_t ret, state0, state1;
assert(lg_range > 0);
assert(lg_range <= 32);
state0 = atomic_load_u32(state, ATOMIC_RELAXED);
if (atomic) {
do {
state1 = prng_state_next_u32(state0);
} while (!atomic_compare_exchange_weak_u32(state, &state0,
state1, ATOMIC_RELAXED, ATOMIC_RELAXED));
} else {
state1 = prng_state_next_u32(state0);
atomic_store_u32(state, state1, ATOMIC_RELAXED);
}
ret = state1 >> (32 - lg_range);
return ret;
}
JEMALLOC_ALWAYS_INLINE uint64_t
prng_lg_range_u64(uint64_t *state, unsigned lg_range) {
uint64_t ret, state1;
assert(lg_range > 0);
assert(lg_range <= 64);
state1 = prng_state_next_u64(*state);
*state = state1;
ret = state1 >> (64 - lg_range);
return ret;
}
JEMALLOC_ALWAYS_INLINE size_t
prng_lg_range_zu(atomic_zu_t *state, unsigned lg_range, bool atomic) {
size_t ret, state0, state1;
assert(lg_range > 0);
assert(lg_range <= ZU(1) << (3 + LG_SIZEOF_PTR));
state0 = atomic_load_zu(state, ATOMIC_RELAXED);
if (atomic) {
do {
state1 = prng_state_next_zu(state0);
} while (atomic_compare_exchange_weak_zu(state, &state0,
state1, ATOMIC_RELAXED, ATOMIC_RELAXED));
} else {
state1 = prng_state_next_zu(state0);
atomic_store_zu(state, state1, ATOMIC_RELAXED);
}
ret = state1 >> ((ZU(1) << (3 + LG_SIZEOF_PTR)) - lg_range);
return ret;
}
/*
* The prng_range functions behave like the prng_lg_range, but return a result
* in [0, range) instead of [0, 2**lg_range).
*/
JEMALLOC_ALWAYS_INLINE uint32_t
prng_range_u32(atomic_u32_t *state, uint32_t range, bool atomic) {
uint32_t ret;
unsigned lg_range;
assert(range > 1);
/* Compute the ceiling of lg(range). */
lg_range = ffs_u32(pow2_ceil_u32(range)) - 1;
/* Generate a result in [0..range) via repeated trial. */
do {
ret = prng_lg_range_u32(state, lg_range, atomic);
} while (ret >= range);
return ret;
}
JEMALLOC_ALWAYS_INLINE uint64_t
prng_range_u64(uint64_t *state, uint64_t range) {
uint64_t ret;
unsigned lg_range;
assert(range > 1);
/* Compute the ceiling of lg(range). */
lg_range = ffs_u64(pow2_ceil_u64(range)) - 1;
/* Generate a result in [0..range) via repeated trial. */
do {
ret = prng_lg_range_u64(state, lg_range);
} while (ret >= range);
return ret;
}
JEMALLOC_ALWAYS_INLINE size_t
prng_range_zu(atomic_zu_t *state, size_t range, bool atomic) {
size_t ret;
unsigned lg_range;
assert(range > 1);
/* Compute the ceiling of lg(range). */
lg_range = ffs_u64(pow2_ceil_u64(range)) - 1;
/* Generate a result in [0..range) via repeated trial. */
do {
ret = prng_lg_range_zu(state, lg_range, atomic);
} while (ret >= range);
return ret;
}
#endif /* JEMALLOC_INTERNAL_PRNG_H */

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#ifndef JEMALLOC_INTERNAL_PROF_EXTERNS_H
#define JEMALLOC_INTERNAL_PROF_EXTERNS_H
#include "jemalloc/internal/mutex.h"
extern malloc_mutex_t bt2gctx_mtx;
extern bool opt_prof;
extern bool opt_prof_active;
extern bool opt_prof_thread_active_init;
extern size_t opt_lg_prof_sample; /* Mean bytes between samples. */
extern ssize_t opt_lg_prof_interval; /* lg(prof_interval). */
extern bool opt_prof_gdump; /* High-water memory dumping. */
extern bool opt_prof_final; /* Final profile dumping. */
extern bool opt_prof_leak; /* Dump leak summary at exit. */
extern bool opt_prof_accum; /* Report cumulative bytes. */
extern bool opt_prof_log; /* Turn logging on at boot. */
extern char opt_prof_prefix[
/* Minimize memory bloat for non-prof builds. */
#ifdef JEMALLOC_PROF
PATH_MAX +
#endif
1];
/* Accessed via prof_active_[gs]et{_unlocked,}(). */
extern bool prof_active;
/* Accessed via prof_gdump_[gs]et{_unlocked,}(). */
extern bool prof_gdump_val;
/*
* Profile dump interval, measured in bytes allocated. Each arena triggers a
* profile dump when it reaches this threshold. The effect is that the
* interval between profile dumps averages prof_interval, though the actual
* interval between dumps will tend to be sporadic, and the interval will be a
* maximum of approximately (prof_interval * narenas).
*/
extern uint64_t prof_interval;
/*
* Initialized as opt_lg_prof_sample, and potentially modified during profiling
* resets.
*/
extern size_t lg_prof_sample;
void prof_alloc_rollback(tsd_t *tsd, prof_tctx_t *tctx, bool updated);
void prof_malloc_sample_object(tsdn_t *tsdn, const void *ptr, size_t usize,
prof_tctx_t *tctx);
void prof_free_sampled_object(tsd_t *tsd, const void *ptr, size_t usize,
prof_tctx_t *tctx);
void bt_init(prof_bt_t *bt, void **vec);
void prof_backtrace(prof_bt_t *bt);
prof_tctx_t *prof_lookup(tsd_t *tsd, prof_bt_t *bt);
#ifdef JEMALLOC_JET
size_t prof_tdata_count(void);
size_t prof_bt_count(void);
#endif
typedef int (prof_dump_open_t)(bool, const char *);
extern prof_dump_open_t *JET_MUTABLE prof_dump_open;
typedef bool (prof_dump_header_t)(tsdn_t *, bool, const prof_cnt_t *);
extern prof_dump_header_t *JET_MUTABLE prof_dump_header;
#ifdef JEMALLOC_JET
void prof_cnt_all(uint64_t *curobjs, uint64_t *curbytes, uint64_t *accumobjs,
uint64_t *accumbytes);
#endif
bool prof_accum_init(tsdn_t *tsdn, prof_accum_t *prof_accum);
void prof_idump(tsdn_t *tsdn);
bool prof_mdump(tsd_t *tsd, const char *filename);
void prof_gdump(tsdn_t *tsdn);
prof_tdata_t *prof_tdata_init(tsd_t *tsd);
prof_tdata_t *prof_tdata_reinit(tsd_t *tsd, prof_tdata_t *tdata);
void prof_reset(tsd_t *tsd, size_t lg_sample);
void prof_tdata_cleanup(tsd_t *tsd);
bool prof_active_get(tsdn_t *tsdn);
bool prof_active_set(tsdn_t *tsdn, bool active);
const char *prof_thread_name_get(tsd_t *tsd);
int prof_thread_name_set(tsd_t *tsd, const char *thread_name);
bool prof_thread_active_get(tsd_t *tsd);
bool prof_thread_active_set(tsd_t *tsd, bool active);
bool prof_thread_active_init_get(tsdn_t *tsdn);
bool prof_thread_active_init_set(tsdn_t *tsdn, bool active_init);
bool prof_gdump_get(tsdn_t *tsdn);
bool prof_gdump_set(tsdn_t *tsdn, bool active);
void prof_boot0(void);
void prof_boot1(void);
bool prof_boot2(tsd_t *tsd);
void prof_prefork0(tsdn_t *tsdn);
void prof_prefork1(tsdn_t *tsdn);
void prof_postfork_parent(tsdn_t *tsdn);
void prof_postfork_child(tsdn_t *tsdn);
void prof_sample_threshold_update(prof_tdata_t *tdata);
bool prof_log_start(tsdn_t *tsdn, const char *filename);
bool prof_log_stop(tsdn_t *tsdn);
#ifdef JEMALLOC_JET
size_t prof_log_bt_count(void);
size_t prof_log_alloc_count(void);
size_t prof_log_thr_count(void);
bool prof_log_is_logging(void);
bool prof_log_rep_check(void);
void prof_log_dummy_set(bool new_value);
#endif
#endif /* JEMALLOC_INTERNAL_PROF_EXTERNS_H */

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#ifndef JEMALLOC_INTERNAL_PROF_INLINES_A_H
#define JEMALLOC_INTERNAL_PROF_INLINES_A_H
#include "jemalloc/internal/mutex.h"
static inline bool
prof_accum_add(tsdn_t *tsdn, prof_accum_t *prof_accum,
uint64_t accumbytes) {
cassert(config_prof);
bool overflow;
uint64_t a0, a1;
/*
* If the application allocates fast enough (and/or if idump is slow
* enough), extreme overflow here (a1 >= prof_interval * 2) can cause
* idump trigger coalescing. This is an intentional mechanism that
* avoids rate-limiting allocation.
*/
#ifdef JEMALLOC_ATOMIC_U64
a0 = atomic_load_u64(&prof_accum->accumbytes, ATOMIC_RELAXED);
do {
a1 = a0 + accumbytes;
assert(a1 >= a0);
overflow = (a1 >= prof_interval);
if (overflow) {
a1 %= prof_interval;
}
} while (!atomic_compare_exchange_weak_u64(&prof_accum->accumbytes, &a0,
a1, ATOMIC_RELAXED, ATOMIC_RELAXED));
#else
malloc_mutex_lock(tsdn, &prof_accum->mtx);
a0 = prof_accum->accumbytes;
a1 = a0 + accumbytes;
overflow = (a1 >= prof_interval);
if (overflow) {
a1 %= prof_interval;
}
prof_accum->accumbytes = a1;
malloc_mutex_unlock(tsdn, &prof_accum->mtx);
#endif
return overflow;
}
static inline void
prof_accum_cancel(tsdn_t *tsdn, prof_accum_t *prof_accum,
size_t usize) {
cassert(config_prof);
/*
* Cancel out as much of the excessive prof_accumbytes increase as
* possible without underflowing. Interval-triggered dumps occur
* slightly more often than intended as a result of incomplete
* canceling.
*/
uint64_t a0, a1;
#ifdef JEMALLOC_ATOMIC_U64
a0 = atomic_load_u64(&prof_accum->accumbytes, ATOMIC_RELAXED);
do {
a1 = (a0 >= SC_LARGE_MINCLASS - usize)
? a0 - (SC_LARGE_MINCLASS - usize) : 0;
} while (!atomic_compare_exchange_weak_u64(&prof_accum->accumbytes, &a0,
a1, ATOMIC_RELAXED, ATOMIC_RELAXED));
#else
malloc_mutex_lock(tsdn, &prof_accum->mtx);
a0 = prof_accum->accumbytes;
a1 = (a0 >= SC_LARGE_MINCLASS - usize)
? a0 - (SC_LARGE_MINCLASS - usize) : 0;
prof_accum->accumbytes = a1;
malloc_mutex_unlock(tsdn, &prof_accum->mtx);
#endif
}
JEMALLOC_ALWAYS_INLINE bool
prof_active_get_unlocked(void) {
/*
* Even if opt_prof is true, sampling can be temporarily disabled by
* setting prof_active to false. No locking is used when reading
* prof_active in the fast path, so there are no guarantees regarding
* how long it will take for all threads to notice state changes.
*/
return prof_active;
}
#endif /* JEMALLOC_INTERNAL_PROF_INLINES_A_H */

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#ifndef JEMALLOC_INTERNAL_PROF_INLINES_B_H
#define JEMALLOC_INTERNAL_PROF_INLINES_B_H
#include "jemalloc/internal/safety_check.h"
#include "jemalloc/internal/sz.h"
JEMALLOC_ALWAYS_INLINE bool
prof_gdump_get_unlocked(void) {
/*
* No locking is used when reading prof_gdump_val in the fast path, so
* there are no guarantees regarding how long it will take for all
* threads to notice state changes.
*/
return prof_gdump_val;
}
JEMALLOC_ALWAYS_INLINE prof_tdata_t *
prof_tdata_get(tsd_t *tsd, bool create) {
prof_tdata_t *tdata;
cassert(config_prof);
tdata = tsd_prof_tdata_get(tsd);
if (create) {
if (unlikely(tdata == NULL)) {
if (tsd_nominal(tsd)) {
tdata = prof_tdata_init(tsd);
tsd_prof_tdata_set(tsd, tdata);
}
} else if (unlikely(tdata->expired)) {
tdata = prof_tdata_reinit(tsd, tdata);
tsd_prof_tdata_set(tsd, tdata);
}
assert(tdata == NULL || tdata->attached);
}
return tdata;
}
JEMALLOC_ALWAYS_INLINE prof_tctx_t *
prof_tctx_get(tsdn_t *tsdn, const void *ptr, alloc_ctx_t *alloc_ctx) {
cassert(config_prof);
assert(ptr != NULL);
return arena_prof_tctx_get(tsdn, ptr, alloc_ctx);
}
JEMALLOC_ALWAYS_INLINE void
prof_tctx_set(tsdn_t *tsdn, const void *ptr, size_t usize,
alloc_ctx_t *alloc_ctx, prof_tctx_t *tctx) {
cassert(config_prof);
assert(ptr != NULL);
arena_prof_tctx_set(tsdn, ptr, usize, alloc_ctx, tctx);
}
JEMALLOC_ALWAYS_INLINE void
prof_tctx_reset(tsdn_t *tsdn, const void *ptr, prof_tctx_t *tctx) {
cassert(config_prof);
assert(ptr != NULL);
arena_prof_tctx_reset(tsdn, ptr, tctx);
}
JEMALLOC_ALWAYS_INLINE nstime_t
prof_alloc_time_get(tsdn_t *tsdn, const void *ptr, alloc_ctx_t *alloc_ctx) {
cassert(config_prof);
assert(ptr != NULL);
return arena_prof_alloc_time_get(tsdn, ptr, alloc_ctx);
}
JEMALLOC_ALWAYS_INLINE void
prof_alloc_time_set(tsdn_t *tsdn, const void *ptr, alloc_ctx_t *alloc_ctx,
nstime_t t) {
cassert(config_prof);
assert(ptr != NULL);
arena_prof_alloc_time_set(tsdn, ptr, alloc_ctx, t);
}
JEMALLOC_ALWAYS_INLINE bool
prof_sample_check(tsd_t *tsd, size_t usize, bool update) {
ssize_t check = update ? 0 : usize;
int64_t bytes_until_sample = tsd_bytes_until_sample_get(tsd);
if (update) {
bytes_until_sample -= usize;
if (tsd_nominal(tsd)) {
tsd_bytes_until_sample_set(tsd, bytes_until_sample);
}
}
if (likely(bytes_until_sample >= check)) {
return true;
}
return false;
}
JEMALLOC_ALWAYS_INLINE bool
prof_sample_accum_update(tsd_t *tsd, size_t usize, bool update,
prof_tdata_t **tdata_out) {
prof_tdata_t *tdata;
cassert(config_prof);
/* Fastpath: no need to load tdata */
if (likely(prof_sample_check(tsd, usize, update))) {
return true;
}
bool booted = tsd_prof_tdata_get(tsd);
tdata = prof_tdata_get(tsd, true);
if (unlikely((uintptr_t)tdata <= (uintptr_t)PROF_TDATA_STATE_MAX)) {
tdata = NULL;
}
if (tdata_out != NULL) {
*tdata_out = tdata;
}
if (unlikely(tdata == NULL)) {
return true;
}
/*
* If this was the first creation of tdata, then
* prof_tdata_get() reset bytes_until_sample, so decrement and
* check it again
*/
if (!booted && prof_sample_check(tsd, usize, update)) {
return true;
}
if (tsd_reentrancy_level_get(tsd) > 0) {
return true;
}
/* Compute new sample threshold. */
if (update) {
prof_sample_threshold_update(tdata);
}
return !tdata->active;
}
JEMALLOC_ALWAYS_INLINE prof_tctx_t *
prof_alloc_prep(tsd_t *tsd, size_t usize, bool prof_active, bool update) {
prof_tctx_t *ret;
prof_tdata_t *tdata;
prof_bt_t bt;
assert(usize == sz_s2u(usize));
if (!prof_active || likely(prof_sample_accum_update(tsd, usize, update,
&tdata))) {
ret = (prof_tctx_t *)(uintptr_t)1U;
} else {
bt_init(&bt, tdata->vec);
prof_backtrace(&bt);
ret = prof_lookup(tsd, &bt);
}
return ret;
}
JEMALLOC_ALWAYS_INLINE void
prof_malloc(tsdn_t *tsdn, const void *ptr, size_t usize, alloc_ctx_t *alloc_ctx,
prof_tctx_t *tctx) {
cassert(config_prof);
assert(ptr != NULL);
assert(usize == isalloc(tsdn, ptr));
if (unlikely((uintptr_t)tctx > (uintptr_t)1U)) {
prof_malloc_sample_object(tsdn, ptr, usize, tctx);
} else {
prof_tctx_set(tsdn, ptr, usize, alloc_ctx,
(prof_tctx_t *)(uintptr_t)1U);
}
}
JEMALLOC_ALWAYS_INLINE void
prof_realloc(tsd_t *tsd, const void *ptr, size_t usize, prof_tctx_t *tctx,
bool prof_active, bool updated, const void *old_ptr, size_t old_usize,
prof_tctx_t *old_tctx) {
bool sampled, old_sampled, moved;
cassert(config_prof);
assert(ptr != NULL || (uintptr_t)tctx <= (uintptr_t)1U);
if (prof_active && !updated && ptr != NULL) {
assert(usize == isalloc(tsd_tsdn(tsd), ptr));
if (prof_sample_accum_update(tsd, usize, true, NULL)) {
/*
* Don't sample. The usize passed to prof_alloc_prep()
* was larger than what actually got allocated, so a
* backtrace was captured for this allocation, even
* though its actual usize was insufficient to cross the
* sample threshold.
*/
prof_alloc_rollback(tsd, tctx, true);
tctx = (prof_tctx_t *)(uintptr_t)1U;
}
}
sampled = ((uintptr_t)tctx > (uintptr_t)1U);
old_sampled = ((uintptr_t)old_tctx > (uintptr_t)1U);
moved = (ptr != old_ptr);
if (unlikely(sampled)) {
prof_malloc_sample_object(tsd_tsdn(tsd), ptr, usize, tctx);
} else if (moved) {
prof_tctx_set(tsd_tsdn(tsd), ptr, usize, NULL,
(prof_tctx_t *)(uintptr_t)1U);
} else if (unlikely(old_sampled)) {
/*
* prof_tctx_set() would work for the !moved case as well, but
* prof_tctx_reset() is slightly cheaper, and the proper thing
* to do here in the presence of explicit knowledge re: moved
* state.
*/
prof_tctx_reset(tsd_tsdn(tsd), ptr, tctx);
} else {
assert((uintptr_t)prof_tctx_get(tsd_tsdn(tsd), ptr, NULL) ==
(uintptr_t)1U);
}
/*
* The prof_free_sampled_object() call must come after the
* prof_malloc_sample_object() call, because tctx and old_tctx may be
* the same, in which case reversing the call order could cause the tctx
* to be prematurely destroyed as a side effect of momentarily zeroed
* counters.
*/
if (unlikely(old_sampled)) {
prof_free_sampled_object(tsd, ptr, old_usize, old_tctx);
}
}
JEMALLOC_ALWAYS_INLINE void
prof_free(tsd_t *tsd, const void *ptr, size_t usize, alloc_ctx_t *alloc_ctx) {
prof_tctx_t *tctx = prof_tctx_get(tsd_tsdn(tsd), ptr, alloc_ctx);
cassert(config_prof);
assert(usize == isalloc(tsd_tsdn(tsd), ptr));
if (unlikely((uintptr_t)tctx > (uintptr_t)1U)) {
prof_free_sampled_object(tsd, ptr, usize, tctx);
}
}
#endif /* JEMALLOC_INTERNAL_PROF_INLINES_B_H */

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#ifndef JEMALLOC_INTERNAL_PROF_STRUCTS_H
#define JEMALLOC_INTERNAL_PROF_STRUCTS_H
#include "jemalloc/internal/ckh.h"
#include "jemalloc/internal/mutex.h"
#include "jemalloc/internal/prng.h"
#include "jemalloc/internal/rb.h"
struct prof_bt_s {
/* Backtrace, stored as len program counters. */
void **vec;
unsigned len;
};
#ifdef JEMALLOC_PROF_LIBGCC
/* Data structure passed to libgcc _Unwind_Backtrace() callback functions. */
typedef struct {
prof_bt_t *bt;
unsigned max;
} prof_unwind_data_t;
#endif
struct prof_accum_s {
#ifndef JEMALLOC_ATOMIC_U64
malloc_mutex_t mtx;
uint64_t accumbytes;
#else
atomic_u64_t accumbytes;
#endif
};
struct prof_cnt_s {
/* Profiling counters. */
uint64_t curobjs;
uint64_t curbytes;
uint64_t accumobjs;
uint64_t accumbytes;
};
typedef enum {
prof_tctx_state_initializing,
prof_tctx_state_nominal,
prof_tctx_state_dumping,
prof_tctx_state_purgatory /* Dumper must finish destroying. */
} prof_tctx_state_t;
struct prof_tctx_s {
/* Thread data for thread that performed the allocation. */
prof_tdata_t *tdata;
/*
* Copy of tdata->thr_{uid,discrim}, necessary because tdata may be
* defunct during teardown.
*/
uint64_t thr_uid;
uint64_t thr_discrim;
/* Profiling counters, protected by tdata->lock. */
prof_cnt_t cnts;
/* Associated global context. */
prof_gctx_t *gctx;
/*
* UID that distinguishes multiple tctx's created by the same thread,
* but coexisting in gctx->tctxs. There are two ways that such
* coexistence can occur:
* - A dumper thread can cause a tctx to be retained in the purgatory
* state.
* - Although a single "producer" thread must create all tctx's which
* share the same thr_uid, multiple "consumers" can each concurrently
* execute portions of prof_tctx_destroy(). prof_tctx_destroy() only
* gets called once each time cnts.cur{objs,bytes} drop to 0, but this
* threshold can be hit again before the first consumer finishes
* executing prof_tctx_destroy().
*/
uint64_t tctx_uid;
/* Linkage into gctx's tctxs. */
rb_node(prof_tctx_t) tctx_link;
/*
* True during prof_alloc_prep()..prof_malloc_sample_object(), prevents
* sample vs destroy race.
*/
bool prepared;
/* Current dump-related state, protected by gctx->lock. */
prof_tctx_state_t state;
/*
* Copy of cnts snapshotted during early dump phase, protected by
* dump_mtx.
*/
prof_cnt_t dump_cnts;
};
typedef rb_tree(prof_tctx_t) prof_tctx_tree_t;
struct prof_gctx_s {
/* Protects nlimbo, cnt_summed, and tctxs. */
malloc_mutex_t *lock;
/*
* Number of threads that currently cause this gctx to be in a state of
* limbo due to one of:
* - Initializing this gctx.
* - Initializing per thread counters associated with this gctx.
* - Preparing to destroy this gctx.
* - Dumping a heap profile that includes this gctx.
* nlimbo must be 1 (single destroyer) in order to safely destroy the
* gctx.
*/
unsigned nlimbo;
/*
* Tree of profile counters, one for each thread that has allocated in
* this context.
*/
prof_tctx_tree_t tctxs;
/* Linkage for tree of contexts to be dumped. */
rb_node(prof_gctx_t) dump_link;
/* Temporary storage for summation during dump. */
prof_cnt_t cnt_summed;
/* Associated backtrace. */
prof_bt_t bt;
/* Backtrace vector, variable size, referred to by bt. */
void *vec[1];
};
typedef rb_tree(prof_gctx_t) prof_gctx_tree_t;
struct prof_tdata_s {
malloc_mutex_t *lock;
/* Monotonically increasing unique thread identifier. */
uint64_t thr_uid;
/*
* Monotonically increasing discriminator among tdata structures
* associated with the same thr_uid.
*/
uint64_t thr_discrim;
/* Included in heap profile dumps if non-NULL. */
char *thread_name;
bool attached;
bool expired;
rb_node(prof_tdata_t) tdata_link;
/*
* Counter used to initialize prof_tctx_t's tctx_uid. No locking is
* necessary when incrementing this field, because only one thread ever
* does so.
*/
uint64_t tctx_uid_next;
/*
* Hash of (prof_bt_t *)-->(prof_tctx_t *). Each thread tracks
* backtraces for which it has non-zero allocation/deallocation counters
* associated with thread-specific prof_tctx_t objects. Other threads
* may write to prof_tctx_t contents when freeing associated objects.
*/
ckh_t bt2tctx;
/* Sampling state. */
uint64_t prng_state;
/* State used to avoid dumping while operating on prof internals. */
bool enq;
bool enq_idump;
bool enq_gdump;
/*
* Set to true during an early dump phase for tdata's which are
* currently being dumped. New threads' tdata's have this initialized
* to false so that they aren't accidentally included in later dump
* phases.
*/
bool dumping;
/*
* True if profiling is active for this tdata's thread
* (thread.prof.active mallctl).
*/
bool active;
/* Temporary storage for summation during dump. */
prof_cnt_t cnt_summed;
/* Backtrace vector, used for calls to prof_backtrace(). */
void *vec[PROF_BT_MAX];
};
typedef rb_tree(prof_tdata_t) prof_tdata_tree_t;
#endif /* JEMALLOC_INTERNAL_PROF_STRUCTS_H */

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#ifndef JEMALLOC_INTERNAL_PROF_TYPES_H
#define JEMALLOC_INTERNAL_PROF_TYPES_H
typedef struct prof_bt_s prof_bt_t;
typedef struct prof_accum_s prof_accum_t;
typedef struct prof_cnt_s prof_cnt_t;
typedef struct prof_tctx_s prof_tctx_t;
typedef struct prof_gctx_s prof_gctx_t;
typedef struct prof_tdata_s prof_tdata_t;
/* Option defaults. */
#ifdef JEMALLOC_PROF
# define PROF_PREFIX_DEFAULT "jeprof"
#else
# define PROF_PREFIX_DEFAULT ""
#endif
#define LG_PROF_SAMPLE_DEFAULT 19
#define LG_PROF_INTERVAL_DEFAULT -1
/*
* Hard limit on stack backtrace depth. The version of prof_backtrace() that
* is based on __builtin_return_address() necessarily has a hard-coded number
* of backtrace frame handlers, and should be kept in sync with this setting.
*/
#define PROF_BT_MAX 128
/* Initial hash table size. */
#define PROF_CKH_MINITEMS 64
/* Size of memory buffer to use when writing dump files. */
#define PROF_DUMP_BUFSIZE 65536
/* Size of stack-allocated buffer used by prof_printf(). */
#define PROF_PRINTF_BUFSIZE 128
/*
* Number of mutexes shared among all gctx's. No space is allocated for these
* unless profiling is enabled, so it's okay to over-provision.
*/
#define PROF_NCTX_LOCKS 1024
/*
* Number of mutexes shared among all tdata's. No space is allocated for these
* unless profiling is enabled, so it's okay to over-provision.
*/
#define PROF_NTDATA_LOCKS 256
/*
* prof_tdata pointers close to NULL are used to encode state information that
* is used for cleaning up during thread shutdown.
*/
#define PROF_TDATA_STATE_REINCARNATED ((prof_tdata_t *)(uintptr_t)1)
#define PROF_TDATA_STATE_PURGATORY ((prof_tdata_t *)(uintptr_t)2)
#define PROF_TDATA_STATE_MAX PROF_TDATA_STATE_PURGATORY
#endif /* JEMALLOC_INTERNAL_PROF_TYPES_H */

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#!/bin/sh
for nm in `cat $1` ; do
n=`echo ${nm} |tr ':' ' ' |awk '{print $1}'`
echo "#define je_${n} JEMALLOC_N(${n})"
done

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#!/bin/sh
for nm in `cat $1` ; do
n=`echo ${nm} |tr ':' ' ' |awk '{print $1}'`
echo "#undef je_${n}"
done

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#ifndef JEMALLOC_INTERNAL_QL_H
#define JEMALLOC_INTERNAL_QL_H
#include "jemalloc/internal/qr.h"
/* List definitions. */
#define ql_head(a_type) \
struct { \
a_type *qlh_first; \
}
#define ql_head_initializer(a_head) {NULL}
#define ql_elm(a_type) qr(a_type)
/* List functions. */
#define ql_new(a_head) do { \
(a_head)->qlh_first = NULL; \
} while (0)
#define ql_elm_new(a_elm, a_field) qr_new((a_elm), a_field)
#define ql_first(a_head) ((a_head)->qlh_first)
#define ql_last(a_head, a_field) \
((ql_first(a_head) != NULL) \
? qr_prev(ql_first(a_head), a_field) : NULL)
#define ql_next(a_head, a_elm, a_field) \
((ql_last(a_head, a_field) != (a_elm)) \
? qr_next((a_elm), a_field) : NULL)
#define ql_prev(a_head, a_elm, a_field) \
((ql_first(a_head) != (a_elm)) ? qr_prev((a_elm), a_field) \
: NULL)
#define ql_before_insert(a_head, a_qlelm, a_elm, a_field) do { \
qr_before_insert((a_qlelm), (a_elm), a_field); \
if (ql_first(a_head) == (a_qlelm)) { \
ql_first(a_head) = (a_elm); \
} \
} while (0)
#define ql_after_insert(a_qlelm, a_elm, a_field) \
qr_after_insert((a_qlelm), (a_elm), a_field)
#define ql_head_insert(a_head, a_elm, a_field) do { \
if (ql_first(a_head) != NULL) { \
qr_before_insert(ql_first(a_head), (a_elm), a_field); \
} \
ql_first(a_head) = (a_elm); \
} while (0)
#define ql_tail_insert(a_head, a_elm, a_field) do { \
if (ql_first(a_head) != NULL) { \
qr_before_insert(ql_first(a_head), (a_elm), a_field); \
} \
ql_first(a_head) = qr_next((a_elm), a_field); \
} while (0)
#define ql_remove(a_head, a_elm, a_field) do { \
if (ql_first(a_head) == (a_elm)) { \
ql_first(a_head) = qr_next(ql_first(a_head), a_field); \
} \
if (ql_first(a_head) != (a_elm)) { \
qr_remove((a_elm), a_field); \
} else { \
ql_first(a_head) = NULL; \
} \
} while (0)
#define ql_head_remove(a_head, a_type, a_field) do { \
a_type *t = ql_first(a_head); \
ql_remove((a_head), t, a_field); \
} while (0)
#define ql_tail_remove(a_head, a_type, a_field) do { \
a_type *t = ql_last(a_head, a_field); \
ql_remove((a_head), t, a_field); \
} while (0)
#define ql_foreach(a_var, a_head, a_field) \
qr_foreach((a_var), ql_first(a_head), a_field)
#define ql_reverse_foreach(a_var, a_head, a_field) \
qr_reverse_foreach((a_var), ql_first(a_head), a_field)
#endif /* JEMALLOC_INTERNAL_QL_H */

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#ifndef JEMALLOC_INTERNAL_QR_H
#define JEMALLOC_INTERNAL_QR_H
/* Ring definitions. */
#define qr(a_type) \
struct { \
a_type *qre_next; \
a_type *qre_prev; \
}
/* Ring functions. */
#define qr_new(a_qr, a_field) do { \
(a_qr)->a_field.qre_next = (a_qr); \
(a_qr)->a_field.qre_prev = (a_qr); \
} while (0)
#define qr_next(a_qr, a_field) ((a_qr)->a_field.qre_next)
#define qr_prev(a_qr, a_field) ((a_qr)->a_field.qre_prev)
#define qr_before_insert(a_qrelm, a_qr, a_field) do { \
(a_qr)->a_field.qre_prev = (a_qrelm)->a_field.qre_prev; \
(a_qr)->a_field.qre_next = (a_qrelm); \
(a_qr)->a_field.qre_prev->a_field.qre_next = (a_qr); \
(a_qrelm)->a_field.qre_prev = (a_qr); \
} while (0)
#define qr_after_insert(a_qrelm, a_qr, a_field) do { \
(a_qr)->a_field.qre_next = (a_qrelm)->a_field.qre_next; \
(a_qr)->a_field.qre_prev = (a_qrelm); \
(a_qr)->a_field.qre_next->a_field.qre_prev = (a_qr); \
(a_qrelm)->a_field.qre_next = (a_qr); \
} while (0)
#define qr_meld(a_qr_a, a_qr_b, a_type, a_field) do { \
a_type *t; \
(a_qr_a)->a_field.qre_prev->a_field.qre_next = (a_qr_b); \
(a_qr_b)->a_field.qre_prev->a_field.qre_next = (a_qr_a); \
t = (a_qr_a)->a_field.qre_prev; \
(a_qr_a)->a_field.qre_prev = (a_qr_b)->a_field.qre_prev; \
(a_qr_b)->a_field.qre_prev = t; \
} while (0)
/*
* qr_meld() and qr_split() are functionally equivalent, so there's no need to
* have two copies of the code.
*/
#define qr_split(a_qr_a, a_qr_b, a_type, a_field) \
qr_meld((a_qr_a), (a_qr_b), a_type, a_field)
#define qr_remove(a_qr, a_field) do { \
(a_qr)->a_field.qre_prev->a_field.qre_next \
= (a_qr)->a_field.qre_next; \
(a_qr)->a_field.qre_next->a_field.qre_prev \
= (a_qr)->a_field.qre_prev; \
(a_qr)->a_field.qre_next = (a_qr); \
(a_qr)->a_field.qre_prev = (a_qr); \
} while (0)
#define qr_foreach(var, a_qr, a_field) \
for ((var) = (a_qr); \
(var) != NULL; \
(var) = (((var)->a_field.qre_next != (a_qr)) \
? (var)->a_field.qre_next : NULL))
#define qr_reverse_foreach(var, a_qr, a_field) \
for ((var) = ((a_qr) != NULL) ? qr_prev(a_qr, a_field) : NULL; \
(var) != NULL; \
(var) = (((var) != (a_qr)) \
? (var)->a_field.qre_prev : NULL))
#endif /* JEMALLOC_INTERNAL_QR_H */

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#ifndef JEMALLOC_INTERNAL_QUANTUM_H
#define JEMALLOC_INTERNAL_QUANTUM_H
/*
* Minimum allocation alignment is 2^LG_QUANTUM bytes (ignoring tiny size
* classes).
*/
#ifndef LG_QUANTUM
# if (defined(__i386__) || defined(_M_IX86))
# define LG_QUANTUM 4
# endif
# ifdef __ia64__
# define LG_QUANTUM 4
# endif
# ifdef __alpha__
# define LG_QUANTUM 4
# endif
# if (defined(__sparc64__) || defined(__sparcv9) || defined(__sparc_v9__))
# define LG_QUANTUM 4
# endif
# if (defined(__amd64__) || defined(__x86_64__) || defined(_M_X64))
# define LG_QUANTUM 4
# endif
# ifdef __arm__
# define LG_QUANTUM 3
# endif
# ifdef __aarch64__
# define LG_QUANTUM 4
# endif
# ifdef __hppa__
# define LG_QUANTUM 4
# endif
# ifdef __m68k__
# define LG_QUANTUM 3
# endif
# ifdef __mips__
# define LG_QUANTUM 3
# endif
# ifdef __nios2__
# define LG_QUANTUM 3
# endif
# ifdef __or1k__
# define LG_QUANTUM 3
# endif
# ifdef __powerpc__
# define LG_QUANTUM 4
# endif
# if defined(__riscv) || defined(__riscv__)
# define LG_QUANTUM 4
# endif
# ifdef __s390__
# define LG_QUANTUM 4
# endif
# if (defined (__SH3E__) || defined(__SH4_SINGLE__) || defined(__SH4__) || \
defined(__SH4_SINGLE_ONLY__))
# define LG_QUANTUM 4
# endif
# ifdef __tile__
# define LG_QUANTUM 4
# endif
# ifdef __le32__
# define LG_QUANTUM 4
# endif
# ifndef LG_QUANTUM
# error "Unknown minimum alignment for architecture; specify via "
"--with-lg-quantum"
# endif
#endif
#define QUANTUM ((size_t)(1U << LG_QUANTUM))
#define QUANTUM_MASK (QUANTUM - 1)
/* Return the smallest quantum multiple that is >= a. */
#define QUANTUM_CEILING(a) \
(((a) + QUANTUM_MASK) & ~QUANTUM_MASK)
#endif /* JEMALLOC_INTERNAL_QUANTUM_H */

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#ifndef JEMALLOC_INTERNAL_RTREE_H
#define JEMALLOC_INTERNAL_RTREE_H
#include "jemalloc/internal/atomic.h"
#include "jemalloc/internal/mutex.h"
#include "jemalloc/internal/rtree_tsd.h"
#include "jemalloc/internal/sc.h"
#include "jemalloc/internal/tsd.h"
/*
* This radix tree implementation is tailored to the singular purpose of
* associating metadata with extents that are currently owned by jemalloc.
*
*******************************************************************************
*/
/* Number of high insignificant bits. */
#define RTREE_NHIB ((1U << (LG_SIZEOF_PTR+3)) - LG_VADDR)
/* Number of low insigificant bits. */
#define RTREE_NLIB LG_PAGE
/* Number of significant bits. */
#define RTREE_NSB (LG_VADDR - RTREE_NLIB)
/* Number of levels in radix tree. */
#if RTREE_NSB <= 10
# define RTREE_HEIGHT 1
#elif RTREE_NSB <= 36
# define RTREE_HEIGHT 2
#elif RTREE_NSB <= 52
# define RTREE_HEIGHT 3
#else
# error Unsupported number of significant virtual address bits
#endif
/* Use compact leaf representation if virtual address encoding allows. */
#if RTREE_NHIB >= LG_CEIL(SC_NSIZES)
# define RTREE_LEAF_COMPACT
#endif
/* Needed for initialization only. */
#define RTREE_LEAFKEY_INVALID ((uintptr_t)1)
typedef struct rtree_node_elm_s rtree_node_elm_t;
struct rtree_node_elm_s {
atomic_p_t child; /* (rtree_{node,leaf}_elm_t *) */
};
struct rtree_leaf_elm_s {
#ifdef RTREE_LEAF_COMPACT
/*
* Single pointer-width field containing all three leaf element fields.
* For example, on a 64-bit x64 system with 48 significant virtual
* memory address bits, the index, extent, and slab fields are packed as
* such:
*
* x: index
* e: extent
* b: slab
*
* 00000000 xxxxxxxx eeeeeeee [...] eeeeeeee eeee000b
*/
atomic_p_t le_bits;
#else
atomic_p_t le_extent; /* (extent_t *) */
atomic_u_t le_szind; /* (szind_t) */
atomic_b_t le_slab; /* (bool) */
#endif
};
typedef struct rtree_level_s rtree_level_t;
struct rtree_level_s {
/* Number of key bits distinguished by this level. */
unsigned bits;
/*
* Cumulative number of key bits distinguished by traversing to
* corresponding tree level.
*/
unsigned cumbits;
};
typedef struct rtree_s rtree_t;
struct rtree_s {
malloc_mutex_t init_lock;
/* Number of elements based on rtree_levels[0].bits. */
#if RTREE_HEIGHT > 1
rtree_node_elm_t root[1U << (RTREE_NSB/RTREE_HEIGHT)];
#else
rtree_leaf_elm_t root[1U << (RTREE_NSB/RTREE_HEIGHT)];
#endif
};
/*
* Split the bits into one to three partitions depending on number of
* significant bits. It the number of bits does not divide evenly into the
* number of levels, place one remainder bit per level starting at the leaf
* level.
*/
static const rtree_level_t rtree_levels[] = {
#if RTREE_HEIGHT == 1
{RTREE_NSB, RTREE_NHIB + RTREE_NSB}
#elif RTREE_HEIGHT == 2
{RTREE_NSB/2, RTREE_NHIB + RTREE_NSB/2},
{RTREE_NSB/2 + RTREE_NSB%2, RTREE_NHIB + RTREE_NSB}
#elif RTREE_HEIGHT == 3
{RTREE_NSB/3, RTREE_NHIB + RTREE_NSB/3},
{RTREE_NSB/3 + RTREE_NSB%3/2,
RTREE_NHIB + RTREE_NSB/3*2 + RTREE_NSB%3/2},
{RTREE_NSB/3 + RTREE_NSB%3 - RTREE_NSB%3/2, RTREE_NHIB + RTREE_NSB}
#else
# error Unsupported rtree height
#endif
};
bool rtree_new(rtree_t *rtree, bool zeroed);
typedef rtree_node_elm_t *(rtree_node_alloc_t)(tsdn_t *, rtree_t *, size_t);
extern rtree_node_alloc_t *JET_MUTABLE rtree_node_alloc;
typedef rtree_leaf_elm_t *(rtree_leaf_alloc_t)(tsdn_t *, rtree_t *, size_t);
extern rtree_leaf_alloc_t *JET_MUTABLE rtree_leaf_alloc;
typedef void (rtree_node_dalloc_t)(tsdn_t *, rtree_t *, rtree_node_elm_t *);
extern rtree_node_dalloc_t *JET_MUTABLE rtree_node_dalloc;
typedef void (rtree_leaf_dalloc_t)(tsdn_t *, rtree_t *, rtree_leaf_elm_t *);
extern rtree_leaf_dalloc_t *JET_MUTABLE rtree_leaf_dalloc;
#ifdef JEMALLOC_JET
void rtree_delete(tsdn_t *tsdn, rtree_t *rtree);
#endif
rtree_leaf_elm_t *rtree_leaf_elm_lookup_hard(tsdn_t *tsdn, rtree_t *rtree,
rtree_ctx_t *rtree_ctx, uintptr_t key, bool dependent, bool init_missing);
JEMALLOC_ALWAYS_INLINE uintptr_t
rtree_leafkey(uintptr_t key) {
unsigned ptrbits = ZU(1) << (LG_SIZEOF_PTR+3);
unsigned cumbits = (rtree_levels[RTREE_HEIGHT-1].cumbits -
rtree_levels[RTREE_HEIGHT-1].bits);
unsigned maskbits = ptrbits - cumbits;
uintptr_t mask = ~((ZU(1) << maskbits) - 1);
return (key & mask);
}
JEMALLOC_ALWAYS_INLINE size_t
rtree_cache_direct_map(uintptr_t key) {
unsigned ptrbits = ZU(1) << (LG_SIZEOF_PTR+3);
unsigned cumbits = (rtree_levels[RTREE_HEIGHT-1].cumbits -
rtree_levels[RTREE_HEIGHT-1].bits);
unsigned maskbits = ptrbits - cumbits;
return (size_t)((key >> maskbits) & (RTREE_CTX_NCACHE - 1));
}
JEMALLOC_ALWAYS_INLINE uintptr_t
rtree_subkey(uintptr_t key, unsigned level) {
unsigned ptrbits = ZU(1) << (LG_SIZEOF_PTR+3);
unsigned cumbits = rtree_levels[level].cumbits;
unsigned shiftbits = ptrbits - cumbits;
unsigned maskbits = rtree_levels[level].bits;
uintptr_t mask = (ZU(1) << maskbits) - 1;
return ((key >> shiftbits) & mask);
}
/*
* Atomic getters.
*
* dependent: Reading a value on behalf of a pointer to a valid allocation
* is guaranteed to be a clean read even without synchronization,
* because the rtree update became visible in memory before the
* pointer came into existence.
* !dependent: An arbitrary read, e.g. on behalf of ivsalloc(), may not be
* dependent on a previous rtree write, which means a stale read
* could result if synchronization were omitted here.
*/
# ifdef RTREE_LEAF_COMPACT
JEMALLOC_ALWAYS_INLINE uintptr_t
rtree_leaf_elm_bits_read(tsdn_t *tsdn, rtree_t *rtree,
rtree_leaf_elm_t *elm, bool dependent) {
return (uintptr_t)atomic_load_p(&elm->le_bits, dependent
? ATOMIC_RELAXED : ATOMIC_ACQUIRE);
}
JEMALLOC_ALWAYS_INLINE extent_t *
rtree_leaf_elm_bits_extent_get(uintptr_t bits) {
# ifdef __aarch64__
/*
* aarch64 doesn't sign extend the highest virtual address bit to set
* the higher ones. Instead, the high bits gets zeroed.
*/
uintptr_t high_bit_mask = ((uintptr_t)1 << LG_VADDR) - 1;
/* Mask off the slab bit. */
uintptr_t low_bit_mask = ~(uintptr_t)1;
uintptr_t mask = high_bit_mask & low_bit_mask;
return (extent_t *)(bits & mask);
# else
/* Restore sign-extended high bits, mask slab bit. */
return (extent_t *)((uintptr_t)((intptr_t)(bits << RTREE_NHIB) >>
RTREE_NHIB) & ~((uintptr_t)0x1));
# endif
}
JEMALLOC_ALWAYS_INLINE szind_t
rtree_leaf_elm_bits_szind_get(uintptr_t bits) {
return (szind_t)(bits >> LG_VADDR);
}
JEMALLOC_ALWAYS_INLINE bool
rtree_leaf_elm_bits_slab_get(uintptr_t bits) {
return (bool)(bits & (uintptr_t)0x1);
}
# endif
JEMALLOC_ALWAYS_INLINE extent_t *
rtree_leaf_elm_extent_read(tsdn_t *tsdn, rtree_t *rtree,
rtree_leaf_elm_t *elm, bool dependent) {
#ifdef RTREE_LEAF_COMPACT
uintptr_t bits = rtree_leaf_elm_bits_read(tsdn, rtree, elm, dependent);
return rtree_leaf_elm_bits_extent_get(bits);
#else
extent_t *extent = (extent_t *)atomic_load_p(&elm->le_extent, dependent
? ATOMIC_RELAXED : ATOMIC_ACQUIRE);
return extent;
#endif
}
JEMALLOC_ALWAYS_INLINE szind_t
rtree_leaf_elm_szind_read(tsdn_t *tsdn, rtree_t *rtree,
rtree_leaf_elm_t *elm, bool dependent) {
#ifdef RTREE_LEAF_COMPACT
uintptr_t bits = rtree_leaf_elm_bits_read(tsdn, rtree, elm, dependent);
return rtree_leaf_elm_bits_szind_get(bits);
#else
return (szind_t)atomic_load_u(&elm->le_szind, dependent ? ATOMIC_RELAXED
: ATOMIC_ACQUIRE);
#endif
}
JEMALLOC_ALWAYS_INLINE bool
rtree_leaf_elm_slab_read(tsdn_t *tsdn, rtree_t *rtree,
rtree_leaf_elm_t *elm, bool dependent) {
#ifdef RTREE_LEAF_COMPACT
uintptr_t bits = rtree_leaf_elm_bits_read(tsdn, rtree, elm, dependent);
return rtree_leaf_elm_bits_slab_get(bits);
#else
return atomic_load_b(&elm->le_slab, dependent ? ATOMIC_RELAXED :
ATOMIC_ACQUIRE);
#endif
}
static inline void
rtree_leaf_elm_extent_write(tsdn_t *tsdn, rtree_t *rtree,
rtree_leaf_elm_t *elm, extent_t *extent) {
#ifdef RTREE_LEAF_COMPACT
uintptr_t old_bits = rtree_leaf_elm_bits_read(tsdn, rtree, elm, true);
uintptr_t bits = ((uintptr_t)rtree_leaf_elm_bits_szind_get(old_bits) <<
LG_VADDR) | ((uintptr_t)extent & (((uintptr_t)0x1 << LG_VADDR) - 1))
| ((uintptr_t)rtree_leaf_elm_bits_slab_get(old_bits));
atomic_store_p(&elm->le_bits, (void *)bits, ATOMIC_RELEASE);
#else
atomic_store_p(&elm->le_extent, extent, ATOMIC_RELEASE);
#endif
}
static inline void
rtree_leaf_elm_szind_write(tsdn_t *tsdn, rtree_t *rtree,
rtree_leaf_elm_t *elm, szind_t szind) {
assert(szind <= SC_NSIZES);
#ifdef RTREE_LEAF_COMPACT
uintptr_t old_bits = rtree_leaf_elm_bits_read(tsdn, rtree, elm,
true);
uintptr_t bits = ((uintptr_t)szind << LG_VADDR) |
((uintptr_t)rtree_leaf_elm_bits_extent_get(old_bits) &
(((uintptr_t)0x1 << LG_VADDR) - 1)) |
((uintptr_t)rtree_leaf_elm_bits_slab_get(old_bits));
atomic_store_p(&elm->le_bits, (void *)bits, ATOMIC_RELEASE);
#else
atomic_store_u(&elm->le_szind, szind, ATOMIC_RELEASE);
#endif
}
static inline void
rtree_leaf_elm_slab_write(tsdn_t *tsdn, rtree_t *rtree,
rtree_leaf_elm_t *elm, bool slab) {
#ifdef RTREE_LEAF_COMPACT
uintptr_t old_bits = rtree_leaf_elm_bits_read(tsdn, rtree, elm,
true);
uintptr_t bits = ((uintptr_t)rtree_leaf_elm_bits_szind_get(old_bits) <<
LG_VADDR) | ((uintptr_t)rtree_leaf_elm_bits_extent_get(old_bits) &
(((uintptr_t)0x1 << LG_VADDR) - 1)) | ((uintptr_t)slab);
atomic_store_p(&elm->le_bits, (void *)bits, ATOMIC_RELEASE);
#else
atomic_store_b(&elm->le_slab, slab, ATOMIC_RELEASE);
#endif
}
static inline void
rtree_leaf_elm_write(tsdn_t *tsdn, rtree_t *rtree,
rtree_leaf_elm_t *elm, extent_t *extent, szind_t szind, bool slab) {
#ifdef RTREE_LEAF_COMPACT
uintptr_t bits = ((uintptr_t)szind << LG_VADDR) |
((uintptr_t)extent & (((uintptr_t)0x1 << LG_VADDR) - 1)) |
((uintptr_t)slab);
atomic_store_p(&elm->le_bits, (void *)bits, ATOMIC_RELEASE);
#else
rtree_leaf_elm_slab_write(tsdn, rtree, elm, slab);
rtree_leaf_elm_szind_write(tsdn, rtree, elm, szind);
/*
* Write extent last, since the element is atomically considered valid
* as soon as the extent field is non-NULL.
*/
rtree_leaf_elm_extent_write(tsdn, rtree, elm, extent);
#endif
}
static inline void
rtree_leaf_elm_szind_slab_update(tsdn_t *tsdn, rtree_t *rtree,
rtree_leaf_elm_t *elm, szind_t szind, bool slab) {
assert(!slab || szind < SC_NBINS);
/*
* The caller implicitly assures that it is the only writer to the szind
* and slab fields, and that the extent field cannot currently change.
*/
rtree_leaf_elm_slab_write(tsdn, rtree, elm, slab);
rtree_leaf_elm_szind_write(tsdn, rtree, elm, szind);
}
JEMALLOC_ALWAYS_INLINE rtree_leaf_elm_t *
rtree_leaf_elm_lookup(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx,
uintptr_t key, bool dependent, bool init_missing) {
assert(key != 0);
assert(!dependent || !init_missing);
size_t slot = rtree_cache_direct_map(key);
uintptr_t leafkey = rtree_leafkey(key);
assert(leafkey != RTREE_LEAFKEY_INVALID);
/* Fast path: L1 direct mapped cache. */
if (likely(rtree_ctx->cache[slot].leafkey == leafkey)) {
rtree_leaf_elm_t *leaf = rtree_ctx->cache[slot].leaf;
assert(leaf != NULL);
uintptr_t subkey = rtree_subkey(key, RTREE_HEIGHT-1);
return &leaf[subkey];
}
/*
* Search the L2 LRU cache. On hit, swap the matching element into the
* slot in L1 cache, and move the position in L2 up by 1.
*/
#define RTREE_CACHE_CHECK_L2(i) do { \
if (likely(rtree_ctx->l2_cache[i].leafkey == leafkey)) { \
rtree_leaf_elm_t *leaf = rtree_ctx->l2_cache[i].leaf; \
assert(leaf != NULL); \
if (i > 0) { \
/* Bubble up by one. */ \
rtree_ctx->l2_cache[i].leafkey = \
rtree_ctx->l2_cache[i - 1].leafkey; \
rtree_ctx->l2_cache[i].leaf = \
rtree_ctx->l2_cache[i - 1].leaf; \
rtree_ctx->l2_cache[i - 1].leafkey = \
rtree_ctx->cache[slot].leafkey; \
rtree_ctx->l2_cache[i - 1].leaf = \
rtree_ctx->cache[slot].leaf; \
} else { \
rtree_ctx->l2_cache[0].leafkey = \
rtree_ctx->cache[slot].leafkey; \
rtree_ctx->l2_cache[0].leaf = \
rtree_ctx->cache[slot].leaf; \
} \
rtree_ctx->cache[slot].leafkey = leafkey; \
rtree_ctx->cache[slot].leaf = leaf; \
uintptr_t subkey = rtree_subkey(key, RTREE_HEIGHT-1); \
return &leaf[subkey]; \
} \
} while (0)
/* Check the first cache entry. */
RTREE_CACHE_CHECK_L2(0);
/* Search the remaining cache elements. */
for (unsigned i = 1; i < RTREE_CTX_NCACHE_L2; i++) {
RTREE_CACHE_CHECK_L2(i);
}
#undef RTREE_CACHE_CHECK_L2
return rtree_leaf_elm_lookup_hard(tsdn, rtree, rtree_ctx, key,
dependent, init_missing);
}
static inline bool
rtree_write(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx, uintptr_t key,
extent_t *extent, szind_t szind, bool slab) {
/* Use rtree_clear() to set the extent to NULL. */
assert(extent != NULL);
rtree_leaf_elm_t *elm = rtree_leaf_elm_lookup(tsdn, rtree, rtree_ctx,
key, false, true);
if (elm == NULL) {
return true;
}
assert(rtree_leaf_elm_extent_read(tsdn, rtree, elm, false) == NULL);
rtree_leaf_elm_write(tsdn, rtree, elm, extent, szind, slab);
return false;
}
JEMALLOC_ALWAYS_INLINE rtree_leaf_elm_t *
rtree_read(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx, uintptr_t key,
bool dependent) {
rtree_leaf_elm_t *elm = rtree_leaf_elm_lookup(tsdn, rtree, rtree_ctx,
key, dependent, false);
if (!dependent && elm == NULL) {
return NULL;
}
assert(elm != NULL);
return elm;
}
JEMALLOC_ALWAYS_INLINE extent_t *
rtree_extent_read(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx,
uintptr_t key, bool dependent) {
rtree_leaf_elm_t *elm = rtree_read(tsdn, rtree, rtree_ctx, key,
dependent);
if (!dependent && elm == NULL) {
return NULL;
}
return rtree_leaf_elm_extent_read(tsdn, rtree, elm, dependent);
}
JEMALLOC_ALWAYS_INLINE szind_t
rtree_szind_read(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx,
uintptr_t key, bool dependent) {
rtree_leaf_elm_t *elm = rtree_read(tsdn, rtree, rtree_ctx, key,
dependent);
if (!dependent && elm == NULL) {
return SC_NSIZES;
}
return rtree_leaf_elm_szind_read(tsdn, rtree, elm, dependent);
}
/*
* rtree_slab_read() is intentionally omitted because slab is always read in
* conjunction with szind, which makes rtree_szind_slab_read() a better choice.
*/
JEMALLOC_ALWAYS_INLINE bool
rtree_extent_szind_read(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx,
uintptr_t key, bool dependent, extent_t **r_extent, szind_t *r_szind) {
rtree_leaf_elm_t *elm = rtree_read(tsdn, rtree, rtree_ctx, key,
dependent);
if (!dependent && elm == NULL) {
return true;
}
*r_extent = rtree_leaf_elm_extent_read(tsdn, rtree, elm, dependent);
*r_szind = rtree_leaf_elm_szind_read(tsdn, rtree, elm, dependent);
return false;
}
/*
* Try to read szind_slab from the L1 cache. Returns true on a hit,
* and fills in r_szind and r_slab. Otherwise returns false.
*
* Key is allowed to be NULL in order to save an extra branch on the
* fastpath. returns false in this case.
*/
JEMALLOC_ALWAYS_INLINE bool
rtree_szind_slab_read_fast(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx,
uintptr_t key, szind_t *r_szind, bool *r_slab) {
rtree_leaf_elm_t *elm;
size_t slot = rtree_cache_direct_map(key);
uintptr_t leafkey = rtree_leafkey(key);
assert(leafkey != RTREE_LEAFKEY_INVALID);
if (likely(rtree_ctx->cache[slot].leafkey == leafkey)) {
rtree_leaf_elm_t *leaf = rtree_ctx->cache[slot].leaf;
assert(leaf != NULL);
uintptr_t subkey = rtree_subkey(key, RTREE_HEIGHT-1);
elm = &leaf[subkey];
#ifdef RTREE_LEAF_COMPACT
uintptr_t bits = rtree_leaf_elm_bits_read(tsdn, rtree,
elm, true);
*r_szind = rtree_leaf_elm_bits_szind_get(bits);
*r_slab = rtree_leaf_elm_bits_slab_get(bits);
#else
*r_szind = rtree_leaf_elm_szind_read(tsdn, rtree, elm, true);
*r_slab = rtree_leaf_elm_slab_read(tsdn, rtree, elm, true);
#endif
return true;
} else {
return false;
}
}
JEMALLOC_ALWAYS_INLINE bool
rtree_szind_slab_read(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx,
uintptr_t key, bool dependent, szind_t *r_szind, bool *r_slab) {
rtree_leaf_elm_t *elm = rtree_read(tsdn, rtree, rtree_ctx, key,
dependent);
if (!dependent && elm == NULL) {
return true;
}
#ifdef RTREE_LEAF_COMPACT
uintptr_t bits = rtree_leaf_elm_bits_read(tsdn, rtree, elm, dependent);
*r_szind = rtree_leaf_elm_bits_szind_get(bits);
*r_slab = rtree_leaf_elm_bits_slab_get(bits);
#else
*r_szind = rtree_leaf_elm_szind_read(tsdn, rtree, elm, dependent);
*r_slab = rtree_leaf_elm_slab_read(tsdn, rtree, elm, dependent);
#endif
return false;
}
static inline void
rtree_szind_slab_update(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx,
uintptr_t key, szind_t szind, bool slab) {
assert(!slab || szind < SC_NBINS);
rtree_leaf_elm_t *elm = rtree_read(tsdn, rtree, rtree_ctx, key, true);
rtree_leaf_elm_szind_slab_update(tsdn, rtree, elm, szind, slab);
}
static inline void
rtree_clear(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx,
uintptr_t key) {
rtree_leaf_elm_t *elm = rtree_read(tsdn, rtree, rtree_ctx, key, true);
assert(rtree_leaf_elm_extent_read(tsdn, rtree, elm, false) !=
NULL);
rtree_leaf_elm_write(tsdn, rtree, elm, NULL, SC_NSIZES, false);
}
#endif /* JEMALLOC_INTERNAL_RTREE_H */

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#ifndef JEMALLOC_INTERNAL_RTREE_CTX_H
#define JEMALLOC_INTERNAL_RTREE_CTX_H
/*
* Number of leafkey/leaf pairs to cache in L1 and L2 level respectively. Each
* entry supports an entire leaf, so the cache hit rate is typically high even
* with a small number of entries. In rare cases extent activity will straddle
* the boundary between two leaf nodes. Furthermore, an arena may use a
* combination of dss and mmap. Note that as memory usage grows past the amount
* that this cache can directly cover, the cache will become less effective if
* locality of reference is low, but the consequence is merely cache misses
* while traversing the tree nodes.
*
* The L1 direct mapped cache offers consistent and low cost on cache hit.
* However collision could affect hit rate negatively. This is resolved by
* combining with a L2 LRU cache, which requires linear search and re-ordering
* on access but suffers no collision. Note that, the cache will itself suffer
* cache misses if made overly large, plus the cost of linear search in the LRU
* cache.
*/
#define RTREE_CTX_LG_NCACHE 4
#define RTREE_CTX_NCACHE (1 << RTREE_CTX_LG_NCACHE)
#define RTREE_CTX_NCACHE_L2 8
/*
* Zero initializer required for tsd initialization only. Proper initialization
* done via rtree_ctx_data_init().
*/
#define RTREE_CTX_ZERO_INITIALIZER {{{0, 0}}, {{0, 0}}}
typedef struct rtree_leaf_elm_s rtree_leaf_elm_t;
typedef struct rtree_ctx_cache_elm_s rtree_ctx_cache_elm_t;
struct rtree_ctx_cache_elm_s {
uintptr_t leafkey;
rtree_leaf_elm_t *leaf;
};
typedef struct rtree_ctx_s rtree_ctx_t;
struct rtree_ctx_s {
/* Direct mapped cache. */
rtree_ctx_cache_elm_t cache[RTREE_CTX_NCACHE];
/* L2 LRU cache. */
rtree_ctx_cache_elm_t l2_cache[RTREE_CTX_NCACHE_L2];
};
void rtree_ctx_data_init(rtree_ctx_t *ctx);
#endif /* JEMALLOC_INTERNAL_RTREE_CTX_H */

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#ifndef JEMALLOC_INTERNAL_SAFETY_CHECK_H
#define JEMALLOC_INTERNAL_SAFETY_CHECK_H
void safety_check_fail(const char *format, ...);
/* Can set to NULL for a default. */
void safety_check_set_abort(void (*abort_fn)());
JEMALLOC_ALWAYS_INLINE void
safety_check_set_redzone(void *ptr, size_t usize, size_t bumped_usize) {
assert(usize < bumped_usize);
for (size_t i = usize; i < bumped_usize && i < usize + 32; ++i) {
*((unsigned char *)ptr + i) = 0xBC;
}
}
JEMALLOC_ALWAYS_INLINE void
safety_check_verify_redzone(const void *ptr, size_t usize, size_t bumped_usize)
{
for (size_t i = usize; i < bumped_usize && i < usize + 32; ++i) {
if (unlikely(*((unsigned char *)ptr + i) != 0xBC)) {
safety_check_fail("Use after free error\n");
}
}
}
#endif /*JEMALLOC_INTERNAL_SAFETY_CHECK_H */

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#ifndef JEMALLOC_INTERNAL_SC_H
#define JEMALLOC_INTERNAL_SC_H
#include "jemalloc/internal/jemalloc_internal_types.h"
/*
* Size class computations:
*
* These are a little tricky; we'll first start by describing how things
* generally work, and then describe some of the details.
*
* Ignore the first few size classes for a moment. We can then split all the
* remaining size classes into groups. The size classes in a group are spaced
* such that they cover allocation request sizes in a power-of-2 range. The
* power of two is called the base of the group, and the size classes in it
* satisfy allocations in the half-open range (base, base * 2]. There are
* SC_NGROUP size classes in each group, equally spaced in the range, so that
* each one covers allocations for base / SC_NGROUP possible allocation sizes.
* We call that value (base / SC_NGROUP) the delta of the group. Each size class
* is delta larger than the one before it (including the initial size class in a
* group, which is delta larger than base, the largest size class in the
* previous group).
* To make the math all work out nicely, we require that SC_NGROUP is a power of
* two, and define it in terms of SC_LG_NGROUP. We'll often talk in terms of
* lg_base and lg_delta. For each of these groups then, we have that
* lg_delta == lg_base - SC_LG_NGROUP.
* The size classes in a group with a given lg_base and lg_delta (which, recall,
* can be computed from lg_base for these groups) are therefore:
* base + 1 * delta
* which covers allocations in (base, base + 1 * delta]
* base + 2 * delta
* which covers allocations in (base + 1 * delta, base + 2 * delta].
* base + 3 * delta
* which covers allocations in (base + 2 * delta, base + 3 * delta].
* ...
* base + SC_NGROUP * delta ( == 2 * base)
* which covers allocations in (base + (SC_NGROUP - 1) * delta, 2 * base].
* (Note that currently SC_NGROUP is always 4, so the "..." is empty in
* practice.)
* Note that the last size class in the group is the next power of two (after
* base), so that we've set up the induction correctly for the next group's
* selection of delta.
*
* Now, let's start considering the first few size classes. Two extra constants
* come into play here: LG_QUANTUM and SC_LG_TINY_MIN. LG_QUANTUM ensures
* correct platform alignment; all objects of size (1 << LG_QUANTUM) or larger
* are at least (1 << LG_QUANTUM) aligned; this can be used to ensure that we
* never return improperly aligned memory, by making (1 << LG_QUANTUM) equal the
* highest required alignment of a platform. For allocation sizes smaller than
* (1 << LG_QUANTUM) though, we can be more relaxed (since we don't support
* platforms with types with alignment larger than their size). To allow such
* allocations (without wasting space unnecessarily), we introduce tiny size
* classes; one per power of two, up until we hit the quantum size. There are
* therefore LG_QUANTUM - SC_LG_TINY_MIN such size classes.
*
* Next, we have a size class of size (1 << LG_QUANTUM). This can't be the
* start of a group in the sense we described above (covering a power of two
* range) since, if we divided into it to pick a value of delta, we'd get a
* delta smaller than (1 << LG_QUANTUM) for sizes >= (1 << LG_QUANTUM), which
* is against the rules.
*
* The first base we can divide by SC_NGROUP while still being at least
* (1 << LG_QUANTUM) is SC_NGROUP * (1 << LG_QUANTUM). We can get there by
* having SC_NGROUP size classes, spaced (1 << LG_QUANTUM) apart. These size
* classes are:
* 1 * (1 << LG_QUANTUM)
* 2 * (1 << LG_QUANTUM)
* 3 * (1 << LG_QUANTUM)
* ... (although, as above, this "..." is empty in practice)
* SC_NGROUP * (1 << LG_QUANTUM).
*
* There are SC_NGROUP of these size classes, so we can regard it as a sort of
* pseudo-group, even though it spans multiple powers of 2, is divided
* differently, and both starts and ends on a power of 2 (as opposed to just
* ending). SC_NGROUP is itself a power of two, so the first group after the
* pseudo-group has the power-of-two base SC_NGROUP * (1 << LG_QUANTUM), for a
* lg_base of LG_QUANTUM + SC_LG_NGROUP. We can divide this base into SC_NGROUP
* sizes without violating our LG_QUANTUM requirements, so we can safely set
* lg_delta = lg_base - SC_LG_GROUP (== LG_QUANTUM).
*
* So, in order, the size classes are:
*
* Tiny size classes:
* - Count: LG_QUANTUM - SC_LG_TINY_MIN.
* - Sizes:
* 1 << SC_LG_TINY_MIN
* 1 << (SC_LG_TINY_MIN + 1)
* 1 << (SC_LG_TINY_MIN + 2)
* ...
* 1 << (LG_QUANTUM - 1)
*
* Initial pseudo-group:
* - Count: SC_NGROUP
* - Sizes:
* 1 * (1 << LG_QUANTUM)
* 2 * (1 << LG_QUANTUM)
* 3 * (1 << LG_QUANTUM)
* ...
* SC_NGROUP * (1 << LG_QUANTUM)
*
* Regular group 0:
* - Count: SC_NGROUP
* - Sizes:
* (relative to lg_base of LG_QUANTUM + SC_LG_NGROUP and lg_delta of
* lg_base - SC_LG_NGROUP)
* (1 << lg_base) + 1 * (1 << lg_delta)
* (1 << lg_base) + 2 * (1 << lg_delta)
* (1 << lg_base) + 3 * (1 << lg_delta)
* ...
* (1 << lg_base) + SC_NGROUP * (1 << lg_delta) [ == (1 << (lg_base + 1)) ]
*
* Regular group 1:
* - Count: SC_NGROUP
* - Sizes:
* (relative to lg_base of LG_QUANTUM + SC_LG_NGROUP + 1 and lg_delta of
* lg_base - SC_LG_NGROUP)
* (1 << lg_base) + 1 * (1 << lg_delta)
* (1 << lg_base) + 2 * (1 << lg_delta)
* (1 << lg_base) + 3 * (1 << lg_delta)
* ...
* (1 << lg_base) + SC_NGROUP * (1 << lg_delta) [ == (1 << (lg_base + 1)) ]
*
* ...
*
* Regular group N:
* - Count: SC_NGROUP
* - Sizes:
* (relative to lg_base of LG_QUANTUM + SC_LG_NGROUP + N and lg_delta of
* lg_base - SC_LG_NGROUP)
* (1 << lg_base) + 1 * (1 << lg_delta)
* (1 << lg_base) + 2 * (1 << lg_delta)
* (1 << lg_base) + 3 * (1 << lg_delta)
* ...
* (1 << lg_base) + SC_NGROUP * (1 << lg_delta) [ == (1 << (lg_base + 1)) ]
*
*
* Representation of metadata:
* To make the math easy, we'll mostly work in lg quantities. We record lg_base,
* lg_delta, and ndelta (i.e. number of deltas above the base) on a
* per-size-class basis, and maintain the invariant that, across all size
* classes, size == (1 << lg_base) + ndelta * (1 << lg_delta).
*
* For regular groups (i.e. those with lg_base >= LG_QUANTUM + SC_LG_NGROUP),
* lg_delta is lg_base - SC_LG_NGROUP, and ndelta goes from 1 to SC_NGROUP.
*
* For the initial tiny size classes (if any), lg_base is lg(size class size).
* lg_delta is lg_base for the first size class, and lg_base - 1 for all
* subsequent ones. ndelta is always 0.
*
* For the pseudo-group, if there are no tiny size classes, then we set
* lg_base == LG_QUANTUM, lg_delta == LG_QUANTUM, and have ndelta range from 0
* to SC_NGROUP - 1. (Note that delta == base, so base + (SC_NGROUP - 1) * delta
* is just SC_NGROUP * base, or (1 << (SC_LG_NGROUP + LG_QUANTUM)), so we do
* indeed get a power of two that way). If there *are* tiny size classes, then
* the first size class needs to have lg_delta relative to the largest tiny size
* class. We therefore set lg_base == LG_QUANTUM - 1,
* lg_delta == LG_QUANTUM - 1, and ndelta == 1, keeping the rest of the
* pseudo-group the same.
*
*
* Other terminology:
* "Small" size classes mean those that are allocated out of bins, which is the
* same as those that are slab allocated.
* "Large" size classes are those that are not small. The cutoff for counting as
* large is page size * group size.
*/
/*
* Size class N + (1 << SC_LG_NGROUP) twice the size of size class N.
*/
#define SC_LG_NGROUP 2
#define SC_LG_TINY_MIN 3
#if SC_LG_TINY_MIN == 0
/* The div module doesn't support division by 1, which this would require. */
#error "Unsupported LG_TINY_MIN"
#endif
/*
* The definitions below are all determined by the above settings and system
* characteristics.
*/
#define SC_NGROUP (1ULL << SC_LG_NGROUP)
#define SC_PTR_BITS ((1ULL << LG_SIZEOF_PTR) * 8)
#define SC_NTINY (LG_QUANTUM - SC_LG_TINY_MIN)
#define SC_LG_TINY_MAXCLASS (LG_QUANTUM > SC_LG_TINY_MIN ? LG_QUANTUM - 1 : -1)
#define SC_NPSEUDO SC_NGROUP
#define SC_LG_FIRST_REGULAR_BASE (LG_QUANTUM + SC_LG_NGROUP)
/*
* We cap allocations to be less than 2 ** (ptr_bits - 1), so the highest base
* we need is 2 ** (ptr_bits - 2). (This also means that the last group is 1
* size class shorter than the others).
* We could probably save some space in arenas by capping this at LG_VADDR size.
*/
#define SC_LG_BASE_MAX (SC_PTR_BITS - 2)
#define SC_NREGULAR (SC_NGROUP * \
(SC_LG_BASE_MAX - SC_LG_FIRST_REGULAR_BASE + 1) - 1)
#define SC_NSIZES (SC_NTINY + SC_NPSEUDO + SC_NREGULAR)
/* The number of size classes that are a multiple of the page size. */
#define SC_NPSIZES ( \
/* Start with all the size classes. */ \
SC_NSIZES \
/* Subtract out those groups with too small a base. */ \
- (LG_PAGE - 1 - SC_LG_FIRST_REGULAR_BASE) * SC_NGROUP \
/* And the pseudo-group. */ \
- SC_NPSEUDO \
/* And the tiny group. */ \
- SC_NTINY \
/* Sizes where ndelta*delta is not a multiple of the page size. */ \
- (SC_LG_NGROUP * SC_NGROUP))
/*
* Note that the last line is computed as the sum of the second column in the
* following table:
* lg(base) | count of sizes to exclude
* ------------------------------|-----------------------------
* LG_PAGE - 1 | SC_NGROUP - 1
* LG_PAGE | SC_NGROUP - 1
* LG_PAGE + 1 | SC_NGROUP - 2
* LG_PAGE + 2 | SC_NGROUP - 4
* ... | ...
* LG_PAGE + (SC_LG_NGROUP - 1) | SC_NGROUP - (SC_NGROUP / 2)
*/
/*
* We declare a size class is binnable if size < page size * group. Or, in other
* words, lg(size) < lg(page size) + lg(group size).
*/
#define SC_NBINS ( \
/* Sub-regular size classes. */ \
SC_NTINY + SC_NPSEUDO \
/* Groups with lg_regular_min_base <= lg_base <= lg_base_max */ \
+ SC_NGROUP * (LG_PAGE + SC_LG_NGROUP - SC_LG_FIRST_REGULAR_BASE) \
/* Last SC of the last group hits the bound exactly; exclude it. */ \
- 1)
/*
* The size2index_tab lookup table uses uint8_t to encode each bin index, so we
* cannot support more than 256 small size classes.
*/
#if (SC_NBINS > 256)
# error "Too many small size classes"
#endif
/* The largest size class in the lookup table. */
#define SC_LOOKUP_MAXCLASS ((size_t)1 << 12)
/* Internal, only used for the definition of SC_SMALL_MAXCLASS. */
#define SC_SMALL_MAX_BASE ((size_t)1 << (LG_PAGE + SC_LG_NGROUP - 1))
#define SC_SMALL_MAX_DELTA ((size_t)1 << (LG_PAGE - 1))
/* The largest size class allocated out of a slab. */
#define SC_SMALL_MAXCLASS (SC_SMALL_MAX_BASE \
+ (SC_NGROUP - 1) * SC_SMALL_MAX_DELTA)
/* The smallest size class not allocated out of a slab. */
#define SC_LARGE_MINCLASS ((size_t)1ULL << (LG_PAGE + SC_LG_NGROUP))
#define SC_LG_LARGE_MINCLASS (LG_PAGE + SC_LG_NGROUP)
/* Internal; only used for the definition of SC_LARGE_MAXCLASS. */
#define SC_MAX_BASE ((size_t)1 << (SC_PTR_BITS - 2))
#define SC_MAX_DELTA ((size_t)1 << (SC_PTR_BITS - 2 - SC_LG_NGROUP))
/* The largest size class supported. */
#define SC_LARGE_MAXCLASS (SC_MAX_BASE + (SC_NGROUP - 1) * SC_MAX_DELTA)
typedef struct sc_s sc_t;
struct sc_s {
/* Size class index, or -1 if not a valid size class. */
int index;
/* Lg group base size (no deltas added). */
int lg_base;
/* Lg delta to previous size class. */
int lg_delta;
/* Delta multiplier. size == 1<<lg_base + ndelta<<lg_delta */
int ndelta;
/*
* True if the size class is a multiple of the page size, false
* otherwise.
*/
bool psz;
/*
* True if the size class is a small, bin, size class. False otherwise.
*/
bool bin;
/* The slab page count if a small bin size class, 0 otherwise. */
int pgs;
/* Same as lg_delta if a lookup table size class, 0 otherwise. */
int lg_delta_lookup;
};
typedef struct sc_data_s sc_data_t;
struct sc_data_s {
/* Number of tiny size classes. */
unsigned ntiny;
/* Number of bins supported by the lookup table. */
int nlbins;
/* Number of small size class bins. */
int nbins;
/* Number of size classes. */
int nsizes;
/* Number of bits required to store NSIZES. */
int lg_ceil_nsizes;
/* Number of size classes that are a multiple of (1U << LG_PAGE). */
unsigned npsizes;
/* Lg of maximum tiny size class (or -1, if none). */
int lg_tiny_maxclass;
/* Maximum size class included in lookup table. */
size_t lookup_maxclass;
/* Maximum small size class. */
size_t small_maxclass;
/* Lg of minimum large size class. */
int lg_large_minclass;
/* The minimum large size class. */
size_t large_minclass;
/* Maximum (large) size class. */
size_t large_maxclass;
/* True if the sc_data_t has been initialized (for debugging only). */
bool initialized;
sc_t sc[SC_NSIZES];
};
void sc_data_init(sc_data_t *data);
/*
* Updates slab sizes in [begin, end] to be pgs pages in length, if possible.
* Otherwise, does its best to accomodate the request.
*/
void sc_data_update_slab_size(sc_data_t *data, size_t begin, size_t end,
int pgs);
void sc_boot(sc_data_t *data);
#endif /* JEMALLOC_INTERNAL_SC_H */

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