diff --git a/configure.ac b/configure.ac
index 50a52015..51a81210 100644
--- a/configure.ac
+++ b/configure.ac
@@ -1,3332 +1,3332 @@
# Configure.ac script for Libgcrypt
# Copyright (C) 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2006,
# 2007, 2008, 2009, 2011 Free Software Foundation, Inc.
# Copyright (C) 2012-2021 g10 Code GmbH
#
# This file is part of Libgcrypt.
#
# Libgcrypt is free software; you can redistribute it and/or modify
# it under the terms of the GNU Lesser General Public License as
# published by the Free Software Foundation; either version 2.1 of
# the License, or (at your option) any later version.
#
# Libgcrypt is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU Lesser General Public License for more details.
#
# You should have received a copy of the GNU Lesser General Public
# License along with this program; if not, see .
# (Process this file with autoconf to produce a configure script.)
AC_REVISION($Revision$)
AC_PREREQ([2.60])
min_automake_version="1.14"
# To build a release you need to create a tag with the version number
# (git tag -s libgcrypt-n.m.k) and run "./autogen.sh --force". Please
# bump the version number immediately after the release and do another
# commit and push so that the git magic is able to work. See below
# for the LT versions.
m4_define([mym4_package],[libgcrypt])
m4_define([mym4_major], [1])
m4_define([mym4_minor], [9])
m4_define([mym4_micro], [4])
# Below is m4 magic to extract and compute the git revision number,
# the decimalized short revision number, a beta version string and a
# flag indicating a development version (mym4_isbeta). Note that the
# m4 processing is done by autoconf and not during the configure run.
m4_define([mym4_verslist], m4_split(m4_esyscmd([./autogen.sh --find-version] \
mym4_package mym4_major mym4_minor mym4_micro),[:]))
m4_define([mym4_isbeta], m4_argn(2, mym4_verslist))
m4_define([mym4_version], m4_argn(4, mym4_verslist))
m4_define([mym4_revision], m4_argn(7, mym4_verslist))
m4_define([mym4_revision_dec], m4_argn(8, mym4_verslist))
m4_esyscmd([echo ]mym4_version[>VERSION])
AC_INIT([mym4_package],[mym4_version],[https://bugs.gnupg.org])
# LT Version numbers, remember to change them just *before* a release.
# (Code changed: REVISION++)
# (Interfaces added/removed/changed: CURRENT++, REVISION=0)
# (Interfaces added: AGE++)
# (Interfaces removed: AGE=0)
#
# (Interfaces removed: CURRENT++, AGE=0, REVISION=0)
# (Interfaces added: CURRENT++, AGE++, REVISION=0)
# (No interfaces changed: REVISION++)
LIBGCRYPT_LT_CURRENT=23
LIBGCRYPT_LT_AGE=3
LIBGCRYPT_LT_REVISION=3
################################################
AC_SUBST(LIBGCRYPT_LT_CURRENT)
AC_SUBST(LIBGCRYPT_LT_AGE)
AC_SUBST(LIBGCRYPT_LT_REVISION)
# If the API is changed in an incompatible way: increment the next counter.
#
# 1.6: ABI and API change but the change is to most users irrelevant
# and thus the API version number has not been incremented.
LIBGCRYPT_CONFIG_API_VERSION=1
# If you change the required gpg-error version, please remove
# unnecessary error code defines in src/gcrypt-int.h.
NEED_GPG_ERROR_VERSION=1.27
AC_CONFIG_AUX_DIR([build-aux])
AC_CONFIG_SRCDIR([src/libgcrypt.vers])
AM_INIT_AUTOMAKE([serial-tests dist-bzip2])
AC_CONFIG_HEADER(config.h)
AC_CONFIG_MACRO_DIR([m4])
AC_CONFIG_LIBOBJ_DIR([compat])
AC_CANONICAL_HOST
AM_MAINTAINER_MODE
AM_SILENT_RULES
AC_ARG_VAR(SYSROOT,[locate config scripts also below that directory])
AH_TOP([
#ifndef _GCRYPT_CONFIG_H_INCLUDED
#define _GCRYPT_CONFIG_H_INCLUDED
/* Enable gpg-error's strerror macro for W32CE. */
#define GPG_ERR_ENABLE_ERRNO_MACROS 1
])
AH_BOTTOM([
#define _GCRYPT_IN_LIBGCRYPT 1
/* Add .note.gnu.property section for Intel CET in assembler sources
when CET is enabled. */
#if defined(__ASSEMBLER__) && defined(__CET__)
# include
#endif
/* If the configure check for endianness has been disabled, get it from
OS macros. This is intended for making fat binary builds on OS X. */
#ifdef DISABLED_ENDIAN_CHECK
# if defined(__BIG_ENDIAN__)
# define WORDS_BIGENDIAN 1
# elif defined(__LITTLE_ENDIAN__)
# undef WORDS_BIGENDIAN
# else
# error "No endianness found"
# endif
#endif /*DISABLED_ENDIAN_CHECK*/
/* We basically use the original Camellia source. Make sure the symbols
properly prefixed. */
#define CAMELLIA_EXT_SYM_PREFIX _gcry_
#endif /*_GCRYPT_CONFIG_H_INCLUDED*/
])
AH_VERBATIM([_REENTRANT],
[/* To allow the use of Libgcrypt in multithreaded programs we have to use
special features from the library. */
#ifndef _REENTRANT
# define _REENTRANT 1
#endif
])
######################
## Basic checks. ### (we need some results later on (e.g. $GCC)
######################
AC_PROG_MAKE_SET
missing_dir=`cd $ac_aux_dir && pwd`
AM_MISSING_PROG(ACLOCAL, aclocal, $missing_dir)
AM_MISSING_PROG(AUTOCONF, autoconf, $missing_dir)
AM_MISSING_PROG(AUTOMAKE, automake, $missing_dir)
AM_MISSING_PROG(AUTOHEADER, autoheader, $missing_dir)
# AM_MISSING_PROG(MAKEINFO, makeinfo, $missing_dir)
AC_PROG_CC
AC_PROG_CPP
AM_PROG_CC_C_O
AM_PROG_AS
AC_SEARCH_LIBS([strerror],[cposix])
AC_PROG_INSTALL
AC_PROG_AWK
AC_USE_SYSTEM_EXTENSIONS
# Taken from mpfr-4.0.1, then modified for LDADD_FOR_TESTS_KLUDGE
dnl Under Linux, make sure that the old dtags are used if LD_LIBRARY_PATH
dnl is defined. The issue is that with the new dtags, LD_LIBRARY_PATH has
dnl the precedence over the run path, so that if a compatible MPFR library
dnl is installed in some directory from $LD_LIBRARY_PATH, then the tested
dnl MPFR library will be this library instead of the MPFR library from the
dnl build tree. Other OS with the same issue might be added later.
dnl
dnl References:
dnl https://bugs.debian.org/cgi-bin/bugreport.cgi?bug=859732
dnl http://lists.gnu.org/archive/html/libtool/2017-05/msg00000.html
dnl
dnl We need to check whether --disable-new-dtags is supported as alternate
dnl linkers may be used (e.g., with tcc: CC=tcc LD=tcc).
dnl
case $host in
*-*-linux*)
if test -n "$LD_LIBRARY_PATH"; then
saved_LDFLAGS="$LDFLAGS"
LDADD_FOR_TESTS_KLUDGE="-Wl,--disable-new-dtags"
LDFLAGS="$LDFLAGS $LDADD_FOR_TESTS_KLUDGE"
AC_MSG_CHECKING(whether --disable-new-dtags is supported by the linker)
AC_LINK_IFELSE([AC_LANG_SOURCE([[
int main (void) { return 0; }
]])],
[AC_MSG_RESULT(yes (use it since LD_LIBRARY_PATH is set))],
[AC_MSG_RESULT(no)
LDADD_FOR_TESTS_KLUDGE=""
])
LDFLAGS="$saved_LDFLAGS"
fi
;;
esac
AC_SUBST([LDADD_FOR_TESTS_KLUDGE])
VERSION_NUMBER=m4_esyscmd(printf "0x%02x%02x%02x" mym4_major \
mym4_minor mym4_micro)
AC_SUBST(VERSION_NUMBER)
# We need to compile and run a program on the build machine.
AX_CC_FOR_BUILD
LT_PREREQ([2.2.6])
LT_INIT([win32-dll disable-static])
LT_LANG([Windows Resource])
##########################
## General definitions. ##
##########################
# Used by libgcrypt-config
LIBGCRYPT_CONFIG_LIBS="-lgcrypt"
LIBGCRYPT_CONFIG_CFLAGS=""
LIBGCRYPT_CONFIG_HOST="$host"
# Definitions for symmetric ciphers.
available_ciphers="arcfour blowfish cast5 des aes twofish serpent rfc2268 seed"
available_ciphers="$available_ciphers camellia idea salsa20 gost28147 chacha20"
available_ciphers="$available_ciphers sm4"
enabled_ciphers=""
# Definitions for public-key ciphers.
available_pubkey_ciphers="dsa elgamal rsa ecc"
enabled_pubkey_ciphers=""
# Definitions for message digests.
available_digests="crc gostr3411-94 md2 md4 md5 rmd160 sha1 sha256 sha512"
available_digests="$available_digests sha3 tiger whirlpool stribog blake2"
available_digests="$available_digests sm3"
enabled_digests=""
# Definitions for kdfs (optional ones)
available_kdfs="s2k pkdf2 scrypt"
enabled_kdfs=""
# Definitions for random modules.
available_random_modules="getentropy linux egd unix"
auto_random_modules="$available_random_modules"
# Supported thread backends.
LIBGCRYPT_THREAD_MODULES=""
# Other definitions.
have_w32_system=no
have_w32ce_system=no
have_pthread=no
# Setup some stuff depending on host.
case "${host}" in
*-*-mingw32*)
ac_cv_have_dev_random=no
have_w32_system=yes
case "${host}" in
*-mingw32ce*)
have_w32ce_system=yes
available_random_modules="w32ce"
;;
*)
available_random_modules="w32"
;;
esac
AC_DEFINE(USE_ONLY_8DOT3,1,
[set this to limit filenames to the 8.3 format])
AC_DEFINE(HAVE_DRIVE_LETTERS,1,
[defined if we must run on a stupid file system])
AC_DEFINE(HAVE_DOSISH_SYSTEM,1,
[defined if we run on some of the PCDOS like systems
(DOS, Windoze. OS/2) with special properties like
no file modes])
;;
i?86-emx-os2 | i?86-*-os2*emx)
# OS/2 with the EMX environment
ac_cv_have_dev_random=no
AC_DEFINE(HAVE_DRIVE_LETTERS)
AC_DEFINE(HAVE_DOSISH_SYSTEM)
;;
i?86-*-msdosdjgpp*)
# DOS with the DJGPP environment
ac_cv_have_dev_random=no
AC_DEFINE(HAVE_DRIVE_LETTERS)
AC_DEFINE(HAVE_DOSISH_SYSTEM)
;;
*-*-hpux*)
if test -z "$GCC" ; then
CFLAGS="$CFLAGS -Ae -D_HPUX_SOURCE"
fi
;;
*-dec-osf4*)
if test -z "$GCC" ; then
# Suppress all warnings
# to get rid of the unsigned/signed char mismatch warnings.
CFLAGS="$CFLAGS -w"
fi
;;
m68k-atari-mint)
;;
*-apple-darwin*)
AC_DEFINE(_DARWIN_C_SOURCE, 1,
Expose all libc features (__DARWIN_C_FULL).)
AC_DEFINE(USE_POSIX_SPAWN_FOR_TESTS, 1,
[defined if we use posix_spawn in test program])
AC_CHECK_HEADERS(spawn.h)
;;
*)
;;
esac
if test "$have_w32_system" = yes; then
AC_DEFINE(HAVE_W32_SYSTEM,1, [Defined if we run on a W32 API based system])
if test "$have_w32ce_system" = yes; then
AC_DEFINE(HAVE_W32CE_SYSTEM,1,[Defined if we run on WindowsCE])
fi
fi
AM_CONDITIONAL(HAVE_W32_SYSTEM, test "$have_w32_system" = yes)
AM_CONDITIONAL(HAVE_W32CE_SYSTEM, test "$have_w32ce_system" = yes)
# A printable OS Name is sometimes useful.
case "${host}" in
*-*-mingw32ce*)
PRINTABLE_OS_NAME="W32CE"
;;
*-*-mingw32*)
PRINTABLE_OS_NAME="W32"
;;
i?86-emx-os2 | i?86-*-os2*emx )
PRINTABLE_OS_NAME="OS/2"
;;
i?86-*-msdosdjgpp*)
PRINTABLE_OS_NAME="MSDOS/DJGPP"
;;
*-linux*)
PRINTABLE_OS_NAME="GNU/Linux"
;;
*)
PRINTABLE_OS_NAME=`uname -s || echo "Unknown"`
;;
esac
NAME_OF_DEV_RANDOM="/dev/random"
NAME_OF_DEV_URANDOM="/dev/urandom"
AC_ARG_ENABLE(endian-check,
AS_HELP_STRING([--disable-endian-check],
[disable the endian check and trust the OS provided macros]),
endiancheck=$enableval,endiancheck=yes)
if test x"$endiancheck" = xyes ; then
AC_C_BIGENDIAN
else
AC_DEFINE(DISABLED_ENDIAN_CHECK,1,[configure did not test for endianness])
fi
AC_CHECK_SIZEOF(unsigned short, 2)
AC_CHECK_SIZEOF(unsigned int, 4)
AC_CHECK_SIZEOF(unsigned long, 4)
AC_CHECK_SIZEOF(unsigned long long, 0)
AC_CHECK_SIZEOF(void *, 0)
AC_TYPE_UINTPTR_T
if test "$ac_cv_sizeof_unsigned_short" = "0" \
|| test "$ac_cv_sizeof_unsigned_int" = "0" \
|| test "$ac_cv_sizeof_unsigned_long" = "0"; then
AC_MSG_WARN([Hmmm, something is wrong with the sizes - using defaults]);
fi
# Ensure that we have UINT64_C before we bother to check for uint64_t
AC_CACHE_CHECK([for UINT64_C],[gnupg_cv_uint64_c_works],
AC_COMPILE_IFELSE([AC_LANG_PROGRAM([[#include ]],
[[uint64_t foo=UINT64_C(42);]])],
gnupg_cv_uint64_c_works=yes,gnupg_cv_uint64_c_works=no))
if test "$gnupg_cv_uint64_c_works" = "yes" ; then
AC_CHECK_SIZEOF(uint64_t)
fi
# Do we have any 64-bit data types?
if test "$ac_cv_sizeof_unsigned_int" != "8" \
&& test "$ac_cv_sizeof_unsigned_long" != "8" \
&& test "$ac_cv_sizeof_unsigned_long_long" != "8" \
&& test "$ac_cv_sizeof_uint64_t" != "8"; then
AC_MSG_ERROR([[
***
*** No 64-bit integer type available.
*** It is not possible to build Libgcrypt on this platform.
***]])
fi
# If not specified otherwise, all available algorithms will be
# included.
default_ciphers="$available_ciphers"
default_pubkey_ciphers="$available_pubkey_ciphers"
default_digests="$available_digests"
default_kdfs="$available_kdfs"
# Blacklist MD2 by default
default_digests=`echo $default_digests | sed -e 's/md2//g'`
# Substitutions to set generated files in a Emacs buffer to read-only.
AC_SUBST(emacs_local_vars_begin, ['Local Variables:'])
AC_SUBST(emacs_local_vars_read_only, ['buffer-read-only: t'])
AC_SUBST(emacs_local_vars_end, ['End:'])
############################
## Command line switches. ##
############################
# Implementation of the --enable-ciphers switch.
AC_ARG_ENABLE(ciphers,
AS_HELP_STRING([--enable-ciphers=ciphers],
[select the symmetric ciphers to include]),
[enabled_ciphers=`echo $enableval | tr ',:' ' ' | tr '[A-Z]' '[a-z]'`],
[enabled_ciphers=""])
if test "x$enabled_ciphers" = "x" \
-o "$enabled_ciphers" = "yes" \
-o "$enabled_ciphers" = "no"; then
enabled_ciphers=$default_ciphers
fi
AC_MSG_CHECKING([which symmetric ciphers to include])
for cipher in $enabled_ciphers; do
LIST_MEMBER($cipher, $available_ciphers)
if test "$found" = "0"; then
AC_MSG_ERROR([unsupported cipher "$cipher" specified])
fi
done
AC_MSG_RESULT([$enabled_ciphers])
# Implementation of the --enable-pubkey-ciphers switch.
AC_ARG_ENABLE(pubkey-ciphers,
AS_HELP_STRING([--enable-pubkey-ciphers=ciphers],
[select the public-key ciphers to include]),
[enabled_pubkey_ciphers=`echo $enableval | tr ',:' ' ' | tr '[A-Z]' '[a-z]'`],
[enabled_pubkey_ciphers=""])
if test "x$enabled_pubkey_ciphers" = "x" \
-o "$enabled_pubkey_ciphers" = "yes" \
-o "$enabled_pubkey_ciphers" = "no"; then
enabled_pubkey_ciphers=$default_pubkey_ciphers
fi
AC_MSG_CHECKING([which public-key ciphers to include])
for cipher in $enabled_pubkey_ciphers; do
LIST_MEMBER($cipher, $available_pubkey_ciphers)
if test "$found" = "0"; then
AC_MSG_ERROR([unsupported public-key cipher specified])
fi
done
AC_MSG_RESULT([$enabled_pubkey_ciphers])
# Implementation of the --enable-digests switch.
AC_ARG_ENABLE(digests,
AS_HELP_STRING([--enable-digests=digests],
[select the message digests to include]),
[enabled_digests=`echo $enableval | tr ',:' ' ' | tr '[A-Z]' '[a-z]'`],
[enabled_digests=""])
if test "x$enabled_digests" = "x" \
-o "$enabled_digests" = "yes" \
-o "$enabled_digests" = "no"; then
enabled_digests=$default_digests
fi
AC_MSG_CHECKING([which message digests to include])
for digest in $enabled_digests; do
LIST_MEMBER($digest, $available_digests)
if test "$found" = "0"; then
AC_MSG_ERROR([unsupported message digest specified])
fi
done
AC_MSG_RESULT([$enabled_digests])
# Implementation of the --enable-kdfs switch.
AC_ARG_ENABLE(kdfs,
AS_HELP_STRING([--enable-kfds=kdfs],
[select the KDFs to include]),
[enabled_kdfs=`echo $enableval | tr ',:' ' ' | tr '[A-Z]' '[a-z]'`],
[enabled_kdfs=""])
if test "x$enabled_kdfs" = "x" \
-o "$enabled_kdfs" = "yes" \
-o "$enabled_kdfs" = "no"; then
enabled_kdfs=$default_kdfs
fi
AC_MSG_CHECKING([which key derivation functions to include])
for kdf in $enabled_kdfs; do
LIST_MEMBER($kdf, $available_kdfs)
if test "$found" = "0"; then
AC_MSG_ERROR([unsupported key derivation function specified])
fi
done
AC_MSG_RESULT([$enabled_kdfs])
# Implementation of the --enable-random switch.
AC_ARG_ENABLE(random,
AS_HELP_STRING([--enable-random=name],
[select which random number generator to use]),
[random=`echo $enableval | tr '[A-Z]' '[a-z]'`],
[])
if test "x$random" = "x" -o "$random" = "yes" -o "$random" = "no"; then
random=default
fi
AC_MSG_CHECKING([which random module to use])
if test "$random" != "default" -a "$random" != "auto"; then
LIST_MEMBER($random, $available_random_modules)
if test "$found" = "0"; then
AC_MSG_ERROR([unsupported random module specified])
fi
fi
AC_MSG_RESULT($random)
# Implementation of the --disable-dev-random switch.
AC_MSG_CHECKING([whether use of /dev/random is requested])
AC_ARG_ENABLE(dev-random,
[ --disable-dev-random disable the use of dev random],
try_dev_random=$enableval, try_dev_random=yes)
AC_MSG_RESULT($try_dev_random)
# Implementation of the --with-egd-socket switch.
AC_ARG_WITH(egd-socket,
[ --with-egd-socket=NAME Use NAME for the EGD socket)],
egd_socket_name="$withval", egd_socket_name="" )
AC_DEFINE_UNQUOTED(EGD_SOCKET_NAME, "$egd_socket_name",
[Define if you don't want the default EGD socket name.
For details see cipher/rndegd.c])
# Implementation of the --enable-random-daemon
AC_MSG_CHECKING([whether the experimental random daemon is requested])
AC_ARG_ENABLE([random-daemon],
AS_HELP_STRING([--enable-random-daemon],
- [Build and support the experimental gcryptrnd]),
+ [Build the experimental gcryptrnd]),
[use_random_daemon=$enableval],
[use_random_daemon=no])
AC_MSG_RESULT($use_random_daemon)
if test x$use_random_daemon = xyes ; then
AC_DEFINE(USE_RANDOM_DAEMON,1,
[Define to support the experimental random daemon])
fi
AM_CONDITIONAL(USE_RANDOM_DAEMON, test x$use_random_daemon = xyes)
# Implementation of --disable-asm.
AC_MSG_CHECKING([whether MPI and cipher assembler modules are requested])
AC_ARG_ENABLE([asm],
AS_HELP_STRING([--disable-asm],
[Disable MPI and cipher assembler modules]),
[try_asm_modules=$enableval],
[try_asm_modules=yes])
AC_MSG_RESULT($try_asm_modules)
if test "$try_asm_modules" != yes ; then
AC_DEFINE(ASM_DISABLED,1,[Defined if --disable-asm was used to configure])
fi
# Implementation of the --enable-m-guard switch.
AC_MSG_CHECKING([whether memory guard is requested])
AC_ARG_ENABLE(m-guard,
AS_HELP_STRING([--enable-m-guard],
[Enable memory guard facility]),
[use_m_guard=$enableval], [use_m_guard=no])
AC_MSG_RESULT($use_m_guard)
if test "$use_m_guard" = yes ; then
AC_DEFINE(M_GUARD,1,[Define to use the (obsolete) malloc guarding feature])
fi
# Implementation of the --enable-large-data-tests switch.
AC_MSG_CHECKING([whether to run large data tests])
AC_ARG_ENABLE(large-data-tests,
AS_HELP_STRING([--enable-large-data-tests],
[Enable the real long ruinning large data tests]),
large_data_tests=$enableval,large_data_tests=no)
AC_MSG_RESULT($large_data_tests)
AC_SUBST(RUN_LARGE_DATA_TESTS, $large_data_tests)
# Implementation of --enable-force-soft-hwfeatures
AC_MSG_CHECKING([whether 'soft' HW feature bits are forced on])
AC_ARG_ENABLE([force-soft-hwfeatures],
AS_HELP_STRING([--enable-force-soft-hwfeatures],
[Enable forcing 'soft' HW feature bits on]),
[force_soft_hwfeatures=$enableval],
[force_soft_hwfeatures=no])
AC_MSG_RESULT($force_soft_hwfeatures)
# Implementation of the --with-capabilities switch.
# Check whether we want to use Linux capabilities
AC_MSG_CHECKING([whether use of capabilities is requested])
AC_ARG_WITH(capabilities,
AS_HELP_STRING([--with-capabilities],
[Use linux capabilities [default=no]]),
[use_capabilities="$withval"],[use_capabilities=no])
AC_MSG_RESULT($use_capabilities)
# Implementation of the --enable-hmac-binary-check.
AC_MSG_CHECKING([whether a HMAC binary check is requested])
AC_ARG_ENABLE(hmac-binary-check,
AS_HELP_STRING([--enable-hmac-binary-check],
[Enable library integrity check]),
[use_hmac_binary_check="$enableval"],
[use_hmac_binary_check=no])
AC_MSG_RESULT($use_hmac_binary_check)
if test "$use_hmac_binary_check" = no ; then
DEF_HMAC_BINARY_CHECK=''
else
AC_DEFINE(ENABLE_HMAC_BINARY_CHECK,1,
[Define to support an HMAC based integrity check])
AC_CHECK_TOOL(OBJCOPY, [objcopy])
if test "$use_hmac_binary_check" != yes ; then
DEF_HMAC_BINARY_CHECK=-DKEY_FOR_BINARY_CHECK="'\"$use_hmac_binary_check\"'"
fi
fi
AM_CONDITIONAL(USE_HMAC_BINARY_CHECK, test "x$use_hmac_binary_check" != xno)
AC_SUBST(DEF_HMAC_BINARY_CHECK)
# Implementation of the --with-fips-module-version.
AC_ARG_WITH(fips-module-version,
[ --with-fips-module-version=VERSION)],
fips_module_version="$withval", fips_module_version="" )
AC_DEFINE_UNQUOTED(FIPS_MODULE_VERSION, "$fips_module_version",
[Define FIPS module version for certification])
# Implementation of the --disable-jent-support switch.
AC_MSG_CHECKING([whether jitter entropy support is requested])
AC_ARG_ENABLE(jent-support,
AS_HELP_STRING([--disable-jent-support],
[Disable support for the Jitter entropy collector]),
jentsupport=$enableval,jentsupport=yes)
AC_MSG_RESULT($jentsupport)
# Implementation of the --disable-padlock-support switch.
AC_MSG_CHECKING([whether padlock support is requested])
AC_ARG_ENABLE(padlock-support,
AS_HELP_STRING([--disable-padlock-support],
[Disable support for the PadLock Engine of VIA processors]),
padlocksupport=$enableval,padlocksupport=yes)
AC_MSG_RESULT($padlocksupport)
# Implementation of the --disable-aesni-support switch.
AC_MSG_CHECKING([whether AESNI support is requested])
AC_ARG_ENABLE(aesni-support,
AS_HELP_STRING([--disable-aesni-support],
[Disable support for the Intel AES-NI instructions]),
aesnisupport=$enableval,aesnisupport=yes)
AC_MSG_RESULT($aesnisupport)
# Implementation of the --disable-shaext-support switch.
AC_MSG_CHECKING([whether SHAEXT support is requested])
AC_ARG_ENABLE(shaext-support,
AS_HELP_STRING([--disable-shaext-support],
[Disable support for the Intel SHAEXT instructions]),
shaextsupport=$enableval,shaextsupport=yes)
AC_MSG_RESULT($shaextsupport)
# Implementation of the --disable-pclmul-support switch.
AC_MSG_CHECKING([whether PCLMUL support is requested])
AC_ARG_ENABLE(pclmul-support,
AS_HELP_STRING([--disable-pclmul-support],
[Disable support for the Intel PCLMUL instructions]),
pclmulsupport=$enableval,pclmulsupport=yes)
AC_MSG_RESULT($pclmulsupport)
# Implementation of the --disable-sse41-support switch.
AC_MSG_CHECKING([whether SSE4.1 support is requested])
AC_ARG_ENABLE(sse41-support,
AS_HELP_STRING([--disable-sse41-support],
[Disable support for the Intel SSE4.1 instructions]),
sse41support=$enableval,sse41support=yes)
AC_MSG_RESULT($sse41support)
# Implementation of the --disable-drng-support switch.
AC_MSG_CHECKING([whether DRNG support is requested])
AC_ARG_ENABLE(drng-support,
AS_HELP_STRING([--disable-drng-support],
[Disable support for the Intel DRNG (RDRAND instruction)]),
drngsupport=$enableval,drngsupport=yes)
AC_MSG_RESULT($drngsupport)
# Implementation of the --disable-avx-support switch.
AC_MSG_CHECKING([whether AVX support is requested])
AC_ARG_ENABLE(avx-support,
AS_HELP_STRING([--disable-avx-support],
[Disable support for the Intel AVX instructions]),
avxsupport=$enableval,avxsupport=yes)
AC_MSG_RESULT($avxsupport)
# Implementation of the --disable-avx2-support switch.
AC_MSG_CHECKING([whether AVX2 support is requested])
AC_ARG_ENABLE(avx2-support,
AS_HELP_STRING([--disable-avx2-support],
[Disable support for the Intel AVX2 instructions]),
avx2support=$enableval,avx2support=yes)
AC_MSG_RESULT($avx2support)
# Implementation of the --disable-neon-support switch.
AC_MSG_CHECKING([whether NEON support is requested])
AC_ARG_ENABLE(neon-support,
AS_HELP_STRING([--disable-neon-support],
[Disable support for the ARM NEON instructions]),
neonsupport=$enableval,neonsupport=yes)
AC_MSG_RESULT($neonsupport)
# Implementation of the --disable-arm-crypto-support switch.
AC_MSG_CHECKING([whether ARMv8 Crypto Extension support is requested])
AC_ARG_ENABLE(arm-crypto-support,
AS_HELP_STRING([--disable-arm-crypto-support],
[Disable support for the ARMv8 Crypto Extension instructions]),
armcryptosupport=$enableval,armcryptosupport=yes)
AC_MSG_RESULT($armcryptosupport)
# Implementation of the --disable-ppc-crypto-support switch.
AC_MSG_CHECKING([whether PPC crypto support is requested])
AC_ARG_ENABLE(ppc-crypto-support,
AS_HELP_STRING([--disable-ppc-crypto-support],
[Disable support for the PPC crypto instructions introduced in POWER 8 (PowerISA 2.07)]),
ppccryptosupport=$enableval,ppccryptosupport=yes)
AC_MSG_RESULT($ppccryptosupport)
# Implementation of the --disable-O-flag-munging switch.
AC_MSG_CHECKING([whether a -O flag munging is requested])
AC_ARG_ENABLE([O-flag-munging],
AS_HELP_STRING([--disable-O-flag-munging],
[Disable modification of the cc -O flag]),
[enable_o_flag_munging=$enableval],
[enable_o_flag_munging=yes])
AC_MSG_RESULT($enable_o_flag_munging)
AM_CONDITIONAL(ENABLE_O_FLAG_MUNGING, test "$enable_o_flag_munging" = "yes")
# Implementation of the --disable-instrumentation-munging switch.
AC_MSG_CHECKING([whether a instrumentation (-fprofile, -fsanitize) munging is requested])
AC_ARG_ENABLE([instrumentation-munging],
AS_HELP_STRING([--disable-instrumentation-munging],
[Disable modification of the cc instrumentation options]),
[enable_instrumentation_munging=$enableval],
[enable_instrumentation_munging=yes])
AC_MSG_RESULT($enable_instrumentation_munging)
AM_CONDITIONAL(ENABLE_INSTRUMENTATION_MUNGING,
test "$enable_instrumentation_munging" = "yes")
# Implementation of the --disable-amd64-as-feature-detection switch.
AC_MSG_CHECKING([whether to enable AMD64 as(1) feature detection])
AC_ARG_ENABLE(amd64-as-feature-detection,
AS_HELP_STRING([--disable-amd64-as-feature-detection],
[Disable the auto-detection of AMD64 as(1) features]),
amd64_as_feature_detection=$enableval,
amd64_as_feature_detection=yes)
AC_MSG_RESULT($amd64_as_feature_detection)
AC_DEFINE_UNQUOTED(PRINTABLE_OS_NAME, "$PRINTABLE_OS_NAME",
[A human readable text with the name of the OS])
# For some systems we know that we have ld_version scripts.
# Use it then as default.
have_ld_version_script=no
case "${host}" in
*-*-linux*)
have_ld_version_script=yes
;;
*-*-gnu*)
have_ld_version_script=yes
;;
esac
AC_ARG_ENABLE([ld-version-script],
AS_HELP_STRING([--enable-ld-version-script],
[enable/disable use of linker version script.
(default is system dependent)]),
[have_ld_version_script=$enableval],
[ : ] )
AM_CONDITIONAL(HAVE_LD_VERSION_SCRIPT, test "$have_ld_version_script" = "yes")
AC_DEFINE_UNQUOTED(NAME_OF_DEV_RANDOM, "$NAME_OF_DEV_RANDOM",
[defined to the name of the strong random device])
AC_DEFINE_UNQUOTED(NAME_OF_DEV_URANDOM, "$NAME_OF_DEV_URANDOM",
[defined to the name of the weaker random device])
###############################
#### Checks for libraries. ####
###############################
#
# gpg-error is required.
#
AM_PATH_GPG_ERROR("$NEED_GPG_ERROR_VERSION")
if test "x$GPG_ERROR_LIBS" = "x"; then
AC_MSG_ERROR([libgpg-error is needed.
See ftp://ftp.gnupg.org/gcrypt/libgpg-error/ .])
fi
AC_DEFINE(GPG_ERR_SOURCE_DEFAULT, GPG_ERR_SOURCE_GCRYPT,
[The default error source for libgcrypt.])
#
# Check whether the GNU Pth library is available. We require this
# to build the optional gcryptrnd program.
#
AC_ARG_WITH(pth-prefix,
AS_HELP_STRING([--with-pth-prefix=PFX],
[prefix where GNU Pth is installed (optional)]),
pth_config_prefix="$withval", pth_config_prefix="")
if test x$pth_config_prefix != x ; then
PTH_CONFIG="$pth_config_prefix/bin/pth-config"
fi
if test "$use_random_daemon" = "yes"; then
AC_PATH_PROG(PTH_CONFIG, pth-config, no)
if test "$PTH_CONFIG" = "no"; then
AC_MSG_WARN([[
***
*** To build the Libgcrypt's random number daemon
*** we need the support of the GNU Portable Threads Library.
*** Download it from ftp://ftp.gnu.org/gnu/pth/
*** On a Debian GNU/Linux system you might want to try
*** apt-get install libpth-dev
***]])
else
GNUPG_PTH_VERSION_CHECK([1.3.7])
if test $have_pth = yes; then
PTH_CFLAGS=`$PTH_CONFIG --cflags`
PTH_LIBS=`$PTH_CONFIG --ldflags`
PTH_LIBS="$PTH_LIBS `$PTH_CONFIG --libs --all`"
AC_DEFINE(USE_GNU_PTH, 1,
[Defined if the GNU Portable Thread Library should be used])
AC_DEFINE(HAVE_PTH, 1,
[Defined if the GNU Pth is available])
fi
fi
fi
AC_SUBST(PTH_CFLAGS)
AC_SUBST(PTH_LIBS)
#
# Check whether pthreads is available
#
if test "$have_w32_system" != yes; then
AC_CHECK_LIB(pthread,pthread_create,have_pthread=yes)
if test "$have_pthread" = yes; then
AC_DEFINE(HAVE_PTHREAD, 1 ,[Define if we have pthread.])
fi
fi
# Solaris needs -lsocket and -lnsl. Unisys system includes
# gethostbyname in libsocket but needs libnsl for socket.
AC_SEARCH_LIBS(setsockopt, [socket], ,
[AC_SEARCH_LIBS(setsockopt, [socket], , , [-lnsl])])
AC_SEARCH_LIBS(setsockopt, [nsl])
##################################
#### Checks for header files. ####
##################################
AC_HEADER_STDC
AC_CHECK_HEADERS(unistd.h sys/auxv.h)
##########################################
#### Checks for typedefs, structures, ####
#### and compiler characteristics. ####
##########################################
AC_C_CONST
AC_C_INLINE
AC_TYPE_SIZE_T
AC_TYPE_PID_T
AC_CHECK_TYPES([byte, ushort, u16, u32, u64])
gl_TYPE_SOCKLEN_T
#
# Check for __builtin_bswap32 intrinsic.
#
AC_CACHE_CHECK(for __builtin_bswap32,
[gcry_cv_have_builtin_bswap32],
[gcry_cv_have_builtin_bswap32=no
AC_LINK_IFELSE([AC_LANG_PROGRAM([],
[int x = 0; int y = __builtin_bswap32(x); return y;])],
[gcry_cv_have_builtin_bswap32=yes])])
if test "$gcry_cv_have_builtin_bswap32" = "yes" ; then
AC_DEFINE(HAVE_BUILTIN_BSWAP32,1,
[Defined if compiler has '__builtin_bswap32' intrinsic])
fi
#
# Check for __builtin_bswap64 intrinsic.
#
AC_CACHE_CHECK(for __builtin_bswap64,
[gcry_cv_have_builtin_bswap64],
[gcry_cv_have_builtin_bswap64=no
AC_LINK_IFELSE([AC_LANG_PROGRAM([],
[long long x = 0; long long y = __builtin_bswap64(x); return y;])],
[gcry_cv_have_builtin_bswap64=yes])])
if test "$gcry_cv_have_builtin_bswap64" = "yes" ; then
AC_DEFINE(HAVE_BUILTIN_BSWAP64,1,
[Defined if compiler has '__builtin_bswap64' intrinsic])
fi
#
# Check for __builtin_ctz intrinsic.
#
AC_CACHE_CHECK(for __builtin_ctz,
[gcry_cv_have_builtin_ctz],
[gcry_cv_have_builtin_ctz=no
AC_LINK_IFELSE([AC_LANG_PROGRAM([],
[unsigned int x = 0; int y = __builtin_ctz(x); return y;])],
[gcry_cv_have_builtin_ctz=yes])])
if test "$gcry_cv_have_builtin_ctz" = "yes" ; then
AC_DEFINE(HAVE_BUILTIN_CTZ, 1,
[Defined if compiler has '__builtin_ctz' intrinsic])
fi
#
# Check for __builtin_ctzl intrinsic.
#
AC_CACHE_CHECK(for __builtin_ctzl,
[gcry_cv_have_builtin_ctzl],
[gcry_cv_have_builtin_ctzl=no
AC_LINK_IFELSE([AC_LANG_PROGRAM([],
[unsigned long x = 0; long y = __builtin_ctzl(x); return y;])],
[gcry_cv_have_builtin_ctzl=yes])])
if test "$gcry_cv_have_builtin_ctzl" = "yes" ; then
AC_DEFINE(HAVE_BUILTIN_CTZL, 1,
[Defined if compiler has '__builtin_ctzl' intrinsic])
fi
#
# Check for __builtin_clz intrinsic.
#
AC_CACHE_CHECK(for __builtin_clz,
[gcry_cv_have_builtin_clz],
[gcry_cv_have_builtin_clz=no
AC_LINK_IFELSE([AC_LANG_PROGRAM([],
[unsigned int x = 0; int y = __builtin_clz(x); return y;])],
[gcry_cv_have_builtin_clz=yes])])
if test "$gcry_cv_have_builtin_clz" = "yes" ; then
AC_DEFINE(HAVE_BUILTIN_CLZ, 1,
[Defined if compiler has '__builtin_clz' intrinsic])
fi
#
# Check for __builtin_clzl intrinsic.
#
AC_CACHE_CHECK(for __builtin_clzl,
[gcry_cv_have_builtin_clzl],
[gcry_cv_have_builtin_clzl=no
AC_LINK_IFELSE([AC_LANG_PROGRAM([],
[unsigned long x = 0; long y = __builtin_clzl(x); return y;])],
[gcry_cv_have_builtin_clzl=yes])])
if test "$gcry_cv_have_builtin_clzl" = "yes" ; then
AC_DEFINE(HAVE_BUILTIN_CLZL, 1,
[Defined if compiler has '__builtin_clzl' intrinsic])
fi
#
# Check for __sync_synchronize intrinsic.
#
AC_CACHE_CHECK(for __sync_synchronize,
[gcry_cv_have_sync_synchronize],
[gcry_cv_have_sync_synchronize=no
AC_LINK_IFELSE([AC_LANG_PROGRAM([],
[__sync_synchronize(); return 0;])],
[gcry_cv_have_sync_synchronize=yes])])
if test "$gcry_cv_have_sync_synchronize" = "yes" ; then
AC_DEFINE(HAVE_SYNC_SYNCHRONIZE, 1,
[Defined if compiler has '__sync_synchronize' intrinsic])
fi
#
# Check for VLA support (variable length arrays).
#
AC_CACHE_CHECK(whether the variable length arrays are supported,
[gcry_cv_have_vla],
[gcry_cv_have_vla=no
AC_COMPILE_IFELSE([AC_LANG_SOURCE(
[[void f1(char *, int);
char foo(int i) {
char b[(i < 0 ? 0 : i) + 1];
f1(b, sizeof b); return b[0];}]])],
[gcry_cv_have_vla=yes])])
if test "$gcry_cv_have_vla" = "yes" ; then
AC_DEFINE(HAVE_VLA,1, [Defined if variable length arrays are supported])
fi
#
# Check for ELF visibility support.
#
AC_CACHE_CHECK(whether the visibility attribute is supported,
gcry_cv_visibility_attribute,
[gcry_cv_visibility_attribute=no
AC_LANG_CONFTEST([AC_LANG_SOURCE(
[[int foo __attribute__ ((visibility ("hidden"))) = 1;
int bar __attribute__ ((visibility ("protected"))) = 1;
]])])
if ${CC-cc} -Werror -S conftest.c -o conftest.s \
1>&AS_MESSAGE_LOG_FD 2>&AS_MESSAGE_LOG_FD ; then
if grep '\.hidden.*foo' conftest.s >/dev/null 2>&1 ; then
if grep '\.protected.*bar' conftest.s >/dev/null 2>&1; then
gcry_cv_visibility_attribute=yes
fi
fi
fi
])
if test "$gcry_cv_visibility_attribute" = "yes"; then
AC_CACHE_CHECK(for broken visibility attribute,
gcry_cv_broken_visibility_attribute,
[gcry_cv_broken_visibility_attribute=yes
AC_LANG_CONFTEST([AC_LANG_SOURCE(
[[int foo (int x);
int bar (int x) __asm__ ("foo")
__attribute__ ((visibility ("hidden")));
int bar (int x) { return x; }
]])])
if ${CC-cc} -Werror -S conftest.c -o conftest.s \
1>&AS_MESSAGE_LOG_FD 2>&AS_MESSAGE_LOG_FD ; then
if grep '\.hidden@<:@ _@:>@foo' conftest.s >/dev/null 2>&1;
then
gcry_cv_broken_visibility_attribute=no
fi
fi
])
fi
if test "$gcry_cv_visibility_attribute" = "yes"; then
AC_CACHE_CHECK(for broken alias attribute,
gcry_cv_broken_alias_attribute,
[gcry_cv_broken_alias_attribute=yes
AC_LANG_CONFTEST([AC_LANG_SOURCE(
[[extern int foo (int x) __asm ("xyzzy");
int bar (int x) { return x; }
extern __typeof (bar) foo __attribute ((weak, alias ("bar")));
extern int dfoo;
extern __typeof (dfoo) dfoo __asm ("abccb");
int dfoo = 1;
]])])
if ${CC-cc} -Werror -S conftest.c -o conftest.s \
1>&AS_MESSAGE_LOG_FD 2>&AS_MESSAGE_LOG_FD ; then
if grep 'xyzzy' conftest.s >/dev/null 2>&1 && \
grep 'abccb' conftest.s >/dev/null 2>&1; then
gcry_cv_broken_alias_attribute=no
fi
fi
])
fi
if test "$gcry_cv_visibility_attribute" = "yes"; then
AC_CACHE_CHECK(if gcc supports -fvisibility=hidden,
gcry_cv_gcc_has_f_visibility,
[gcry_cv_gcc_has_f_visibility=no
_gcc_cflags_save=$CFLAGS
CFLAGS="-fvisibility=hidden"
AC_COMPILE_IFELSE([AC_LANG_PROGRAM([],[])],
gcry_cv_gcc_has_f_visibility=yes)
CFLAGS=$_gcc_cflags_save;
])
fi
if test "$gcry_cv_visibility_attribute" = "yes" \
&& test "$gcry_cv_broken_visibility_attribute" != "yes" \
&& test "$gcry_cv_broken_alias_attribute" != "yes" \
&& test "$gcry_cv_gcc_has_f_visibility" = "yes"
then
AC_DEFINE(GCRY_USE_VISIBILITY, 1,
[Define to use the GNU C visibility attribute.])
CFLAGS="$CFLAGS -fvisibility=hidden"
fi
# Following attribute tests depend on warnings to cause compile to fail,
# so set -Werror temporarily.
_gcc_cflags_save=$CFLAGS
CFLAGS="$CFLAGS -Werror"
#
# Check whether the compiler supports the GCC style aligned attribute
#
AC_CACHE_CHECK([whether the GCC style aligned attribute is supported],
[gcry_cv_gcc_attribute_aligned],
[gcry_cv_gcc_attribute_aligned=no
AC_COMPILE_IFELSE([AC_LANG_SOURCE(
[[struct { int a; } foo __attribute__ ((aligned (16)));]])],
[gcry_cv_gcc_attribute_aligned=yes])])
if test "$gcry_cv_gcc_attribute_aligned" = "yes" ; then
AC_DEFINE(HAVE_GCC_ATTRIBUTE_ALIGNED,1,
[Defined if a GCC style "__attribute__ ((aligned (n))" is supported])
fi
#
# Check whether the compiler supports the GCC style packed attribute
#
AC_CACHE_CHECK([whether the GCC style packed attribute is supported],
[gcry_cv_gcc_attribute_packed],
[gcry_cv_gcc_attribute_packed=no
AC_COMPILE_IFELSE([AC_LANG_SOURCE(
[[struct foolong_s { long b; } __attribute__ ((packed));
struct foo_s { char a; struct foolong_s b; }
__attribute__ ((packed));
enum bar {
FOO = 1 / (sizeof(struct foo_s) == (sizeof(char) + sizeof(long))),
};]])],
[gcry_cv_gcc_attribute_packed=yes])])
if test "$gcry_cv_gcc_attribute_packed" = "yes" ; then
AC_DEFINE(HAVE_GCC_ATTRIBUTE_PACKED,1,
[Defined if a GCC style "__attribute__ ((packed))" is supported])
fi
#
# Check whether the compiler supports the GCC style may_alias attribute
#
AC_CACHE_CHECK([whether the GCC style may_alias attribute is supported],
[gcry_cv_gcc_attribute_may_alias],
[gcry_cv_gcc_attribute_may_alias=no
AC_COMPILE_IFELSE([AC_LANG_SOURCE(
[[typedef struct foo_s { int a; }
__attribute__ ((may_alias)) foo_t;]])],
[gcry_cv_gcc_attribute_may_alias=yes])])
if test "$gcry_cv_gcc_attribute_may_alias" = "yes" ; then
AC_DEFINE(HAVE_GCC_ATTRIBUTE_MAY_ALIAS,1,
[Defined if a GCC style "__attribute__ ((may_alias))" is supported])
fi
# Restore flags.
CFLAGS=$_gcc_cflags_save;
#
# Check whether the compiler supports 'asm' or '__asm__' keyword for
# assembler blocks.
#
AC_CACHE_CHECK([whether 'asm' assembler keyword is supported],
[gcry_cv_have_asm],
[gcry_cv_have_asm=no
AC_COMPILE_IFELSE([AC_LANG_SOURCE(
[[void a(void) { asm("":::"memory"); }]])],
[gcry_cv_have_asm=yes])])
AC_CACHE_CHECK([whether '__asm__' assembler keyword is supported],
[gcry_cv_have___asm__],
[gcry_cv_have___asm__=no
AC_COMPILE_IFELSE([AC_LANG_SOURCE(
[[void a(void) { __asm__("":::"memory"); }]])],
[gcry_cv_have___asm__=yes])])
if test "$gcry_cv_have_asm" = "no" ; then
if test "$gcry_cv_have___asm__" = "yes" ; then
AC_DEFINE(asm,__asm__,
[Define to supported assembler block keyword, if plain 'asm' was not
supported])
fi
fi
#
# Check whether the compiler supports inline assembly memory barrier.
#
if test "$gcry_cv_have_asm" = "no" ; then
if test "$gcry_cv_have___asm__" = "yes" ; then
AC_CACHE_CHECK([whether inline assembly memory barrier is supported],
[gcry_cv_have_asm_volatile_memory],
[gcry_cv_have_asm_volatile_memory=no
AC_COMPILE_IFELSE([AC_LANG_SOURCE(
[[void a(int x)
{
__asm__ volatile("":::"memory");
__asm__ volatile("":"+r"(x)::"memory");
}]])],
[gcry_cv_have_asm_volatile_memory=yes])])
fi
else
AC_CACHE_CHECK([whether inline assembly memory barrier is supported],
[gcry_cv_have_asm_volatile_memory],
[gcry_cv_have_asm_volatile_memory=no
AC_COMPILE_IFELSE([AC_LANG_SOURCE(
[[void a(int x)
{
asm volatile("":::"memory");
asm volatile("":"+r"(x)::"memory"); }]])],
[gcry_cv_have_asm_volatile_memory=yes])])
fi
if test "$gcry_cv_have_asm_volatile_memory" = "yes" ; then
AC_DEFINE(HAVE_GCC_ASM_VOLATILE_MEMORY,1,
[Define if inline asm memory barrier is supported])
fi
#
# Check whether GCC assembler supports features needed for our ARM
# implementations. This needs to be done before setting up the
# assembler stuff.
#
AC_CACHE_CHECK([whether GCC assembler is compatible for ARM assembly implementations],
[gcry_cv_gcc_arm_platform_as_ok],
[if test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_arm_platform_as_ok="n/a"
else
gcry_cv_gcc_arm_platform_as_ok=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[__asm__(
/* Test if assembler supports UAL syntax. */
".syntax unified\n\t"
".arm\n\t" /* our assembly code is in ARM mode */
".text\n\t"
/* Following causes error if assembler ignored '.syntax unified'. */
"asmfunc:\n\t"
"add %r0, %r0, %r4, ror #12;\n\t"
/* Test if '.type' and '.size' are supported. */
".size asmfunc,.-asmfunc;\n\t"
".type asmfunc,%function;\n\t"
);]], [ asmfunc(); ] )],
[gcry_cv_gcc_arm_platform_as_ok=yes])
fi])
if test "$gcry_cv_gcc_arm_platform_as_ok" = "yes" ; then
AC_DEFINE(HAVE_COMPATIBLE_GCC_ARM_PLATFORM_AS,1,
[Defined if underlying assembler is compatible with ARM assembly implementations])
fi
#
# Check whether GCC assembler supports features needed for our ARMv8/Aarch64
# implementations. This needs to be done before setting up the
# assembler stuff.
#
AC_CACHE_CHECK([whether GCC assembler is compatible for ARMv8/Aarch64 assembly implementations],
[gcry_cv_gcc_aarch64_platform_as_ok],
[if test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_aarch64_platform_as_ok="n/a"
else
gcry_cv_gcc_aarch64_platform_as_ok=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[__asm__(
".text\n\t"
"asmfunc:\n\t"
"eor x0, x0, x30, ror #12;\n\t"
"add x0, x0, x30, asr #12;\n\t"
"eor v0.16b, v0.16b, v31.16b;\n\t"
);]], [ asmfunc(); ] )],
[gcry_cv_gcc_aarch64_platform_as_ok=yes])
fi])
if test "$gcry_cv_gcc_aarch64_platform_as_ok" = "yes" ; then
AC_DEFINE(HAVE_COMPATIBLE_GCC_AARCH64_PLATFORM_AS,1,
[Defined if underlying assembler is compatible with ARMv8/Aarch64 assembly implementations])
fi
#
# Check whether GCC assembler supports for CFI directives.
#
AC_CACHE_CHECK([whether GCC assembler supports for CFI directives],
[gcry_cv_gcc_asm_cfi_directives],
[gcry_cv_gcc_asm_cfi_directives=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[__asm__(
".text\n\t"
"ac_test:\n\t"
".cfi_startproc\n\t"
".cfi_remember_state\n\t"
".cfi_adjust_cfa_offset 8\n\t"
".cfi_rel_offset 0, 8\n\t"
".cfi_def_cfa_register 1\n\t"
".cfi_register 2, 3\n\t"
".cfi_restore 2\n\t"
".cfi_escape 0x0f, 0x02, 0x11, 0x00\n\t"
".cfi_restore_state\n\t"
".long 0\n\t"
".cfi_endproc\n\t"
);]])],
[gcry_cv_gcc_asm_cfi_directives=yes])])
if test "$gcry_cv_gcc_asm_cfi_directives" = "yes" ; then
AC_DEFINE(HAVE_GCC_ASM_CFI_DIRECTIVES,1,
[Defined if underlying assembler supports for CFI directives])
fi
#
# Check whether GCC assembler supports for ELF directives.
#
AC_CACHE_CHECK([whether GCC assembler supports for ELF directives],
[gcry_cv_gcc_asm_elf_directives],
[gcry_cv_gcc_asm_elf_directives=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[__asm__(
/* Test if ELF directives '.type' and '.size' are supported. */
".text\n\t"
"asmfunc:\n\t"
".size asmfunc,.-asmfunc;\n\t"
".type asmfunc,STT_FUNC;\n\t"
);]])],
[gcry_cv_gcc_asm_elf_directives=yes])])
if test "$gcry_cv_gcc_asm_elf_directives" = "yes" ; then
AC_DEFINE(HAVE_GCC_ASM_ELF_DIRECTIVES,1,
[Defined if underlying assembler supports for ELF directives])
fi
#
# Check whether underscores in symbols are required. This needs to be
# done before setting up the assembler stuff.
#
GNUPG_SYS_SYMBOL_UNDERSCORE()
#################################
#### ####
#### Setup assembler stuff. ####
#### Define mpi_cpu_arch. ####
#### ####
#################################
AC_ARG_ENABLE(mpi-path,
AS_HELP_STRING([--enable-mpi-path=EXTRA_PATH],
[prepend EXTRA_PATH to list of CPU specific optimizations]),
mpi_extra_path="$enableval",mpi_extra_path="")
AC_MSG_CHECKING(architecture and mpi assembler functions)
if test -f $srcdir/mpi/config.links ; then
. $srcdir/mpi/config.links
AC_CONFIG_LINKS("$mpi_ln_list")
ac_cv_mpi_sflags="$mpi_sflags"
AC_MSG_RESULT($mpi_cpu_arch)
else
AC_MSG_RESULT(failed)
AC_MSG_ERROR([mpi/config.links missing!])
fi
MPI_SFLAGS="$ac_cv_mpi_sflags"
AC_SUBST(MPI_SFLAGS)
AM_CONDITIONAL(MPI_MOD_ASM_MPIH_ADD1, test "$mpi_mod_asm_mpih_add1" = yes)
AM_CONDITIONAL(MPI_MOD_ASM_MPIH_SUB1, test "$mpi_mod_asm_mpih_sub1" = yes)
AM_CONDITIONAL(MPI_MOD_ASM_MPIH_MUL1, test "$mpi_mod_asm_mpih_mul1" = yes)
AM_CONDITIONAL(MPI_MOD_ASM_MPIH_MUL2, test "$mpi_mod_asm_mpih_mul2" = yes)
AM_CONDITIONAL(MPI_MOD_ASM_MPIH_MUL3, test "$mpi_mod_asm_mpih_mul3" = yes)
AM_CONDITIONAL(MPI_MOD_ASM_MPIH_LSHIFT, test "$mpi_mod_asm_mpih_lshift" = yes)
AM_CONDITIONAL(MPI_MOD_ASM_MPIH_RSHIFT, test "$mpi_mod_asm_mpih_rshift" = yes)
AM_CONDITIONAL(MPI_MOD_ASM_UDIV, test "$mpi_mod_asm_udiv" = yes)
AM_CONDITIONAL(MPI_MOD_ASM_UDIV_QRNND, test "$mpi_mod_asm_udiv_qrnnd" = yes)
AM_CONDITIONAL(MPI_MOD_C_MPIH_ADD1, test "$mpi_mod_c_mpih_add1" = yes)
AM_CONDITIONAL(MPI_MOD_C_MPIH_SUB1, test "$mpi_mod_c_mpih_sub1" = yes)
AM_CONDITIONAL(MPI_MOD_C_MPIH_MUL1, test "$mpi_mod_c_mpih_mul1" = yes)
AM_CONDITIONAL(MPI_MOD_C_MPIH_MUL2, test "$mpi_mod_c_mpih_mul2" = yes)
AM_CONDITIONAL(MPI_MOD_C_MPIH_MUL3, test "$mpi_mod_c_mpih_mul3" = yes)
AM_CONDITIONAL(MPI_MOD_C_MPIH_LSHIFT, test "$mpi_mod_c_mpih_lshift" = yes)
AM_CONDITIONAL(MPI_MOD_C_MPIH_RSHIFT, test "$mpi_mod_c_mpih_rshift" = yes)
AM_CONDITIONAL(MPI_MOD_C_UDIV, test "$mpi_mod_c_udiv" = yes)
AM_CONDITIONAL(MPI_MOD_C_UDIV_QRNND, test "$mpi_mod_c_udiv_qrnnd" = yes)
# Reset non applicable feature flags.
if test "$mpi_cpu_arch" != "x86" ; then
aesnisupport="n/a"
shaextsupport="n/a"
pclmulsupport="n/a"
sse41support="n/a"
avxsupport="n/a"
avx2support="n/a"
padlocksupport="n/a"
drngsupport="n/a"
fi
if test "$mpi_cpu_arch" != "arm" ; then
if test "$mpi_cpu_arch" != "aarch64" ; then
neonsupport="n/a"
armcryptosupport="n/a"
fi
fi
if test "$mpi_cpu_arch" != "ppc"; then
ppccryptosupport="n/a"
fi
#############################################
#### ####
#### Platform specific compiler checks. ####
#### ####
#############################################
# Following tests depend on warnings to cause compile to fail, so set -Werror
# temporarily.
_gcc_cflags_save=$CFLAGS
CFLAGS="$CFLAGS -Werror"
#
# Check whether compiler supports 'ms_abi' function attribute.
#
AC_CACHE_CHECK([whether compiler supports 'ms_abi' function attribute],
[gcry_cv_gcc_attribute_ms_abi],
[gcry_cv_gcc_attribute_ms_abi=no
AC_COMPILE_IFELSE([AC_LANG_SOURCE(
[[int __attribute__ ((ms_abi)) proto(int);]])],
[gcry_cv_gcc_attribute_ms_abi=yes])])
if test "$gcry_cv_gcc_attribute_ms_abi" = "yes" ; then
AC_DEFINE(HAVE_GCC_ATTRIBUTE_MS_ABI,1,
[Defined if compiler supports "__attribute__ ((ms_abi))" function attribute])
fi
#
# Check whether compiler supports 'sysv_abi' function attribute.
#
AC_CACHE_CHECK([whether compiler supports 'sysv_abi' function attribute],
[gcry_cv_gcc_attribute_sysv_abi],
[gcry_cv_gcc_attribute_sysv_abi=no
AC_COMPILE_IFELSE([AC_LANG_SOURCE(
[[int __attribute__ ((sysv_abi)) proto(int);]])],
[gcry_cv_gcc_attribute_sysv_abi=yes])])
if test "$gcry_cv_gcc_attribute_sysv_abi" = "yes" ; then
AC_DEFINE(HAVE_GCC_ATTRIBUTE_SYSV_ABI,1,
[Defined if compiler supports "__attribute__ ((sysv_abi))" function attribute])
fi
#
# Check whether default calling convention is 'ms_abi'.
#
if test "$gcry_cv_gcc_attribute_ms_abi" = "yes" ; then
AC_CACHE_CHECK([whether default calling convention is 'ms_abi'],
[gcry_cv_gcc_default_abi_is_ms_abi],
[gcry_cv_gcc_default_abi_is_ms_abi=no
AC_COMPILE_IFELSE([AC_LANG_SOURCE(
[[void *test(void) {
void *(*def_func)(void) = test;
void *__attribute__((ms_abi))(*msabi_func)(void);
/* warning on SysV abi targets, passes on Windows based targets */
msabi_func = def_func;
return msabi_func;
}]])],
[gcry_cv_gcc_default_abi_is_ms_abi=yes])])
if test "$gcry_cv_gcc_default_abi_is_ms_abi" = "yes" ; then
AC_DEFINE(HAVE_GCC_DEFAULT_ABI_IS_MS_ABI,1,
[Defined if default calling convention is 'ms_abi'])
fi
fi
#
# Check whether default calling convention is 'sysv_abi'.
#
if test "$gcry_cv_gcc_attribute_sysv_abi" = "yes" ; then
AC_CACHE_CHECK([whether default calling convention is 'sysv_abi'],
[gcry_cv_gcc_default_abi_is_sysv_abi],
[gcry_cv_gcc_default_abi_is_sysv_abi=no
AC_COMPILE_IFELSE([AC_LANG_SOURCE(
[[void *test(void) {
void *(*def_func)(void) = test;
void *__attribute__((sysv_abi))(*sysvabi_func)(void);
/* warning on MS ABI targets, passes on SysV ABI targets */
sysvabi_func = def_func;
return sysvabi_func;
}]])],
[gcry_cv_gcc_default_abi_is_sysv_abi=yes])])
if test "$gcry_cv_gcc_default_abi_is_sysv_abi" = "yes" ; then
AC_DEFINE(HAVE_GCC_DEFAULT_ABI_IS_SYSV_ABI,1,
[Defined if default calling convention is 'sysv_abi'])
fi
fi
# Restore flags.
CFLAGS=$_gcc_cflags_save;
#
# Check whether GCC inline assembler supports SSSE3 instructions
# This is required for the AES-NI instructions.
#
AC_CACHE_CHECK([whether GCC inline assembler supports SSSE3 instructions],
[gcry_cv_gcc_inline_asm_ssse3],
[if test "$mpi_cpu_arch" != "x86" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_inline_asm_ssse3="n/a"
else
gcry_cv_gcc_inline_asm_ssse3=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[static unsigned char be_mask[16] __attribute__ ((aligned (16))) =
{ 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1, 0 };
void a(void) {
__asm__("pshufb %[mask], %%xmm2\n\t"::[mask]"m"(*be_mask):);
}]], [ a(); ] )],
[gcry_cv_gcc_inline_asm_ssse3=yes])
fi])
if test "$gcry_cv_gcc_inline_asm_ssse3" = "yes" ; then
AC_DEFINE(HAVE_GCC_INLINE_ASM_SSSE3,1,
[Defined if inline assembler supports SSSE3 instructions])
fi
#
# Check whether GCC inline assembler supports PCLMUL instructions.
#
AC_CACHE_CHECK([whether GCC inline assembler supports PCLMUL instructions],
[gcry_cv_gcc_inline_asm_pclmul],
[if test "$mpi_cpu_arch" != "x86" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_inline_asm_pclmul="n/a"
else
gcry_cv_gcc_inline_asm_pclmul=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[void a(void) {
__asm__("pclmulqdq \$0, %%xmm1, %%xmm3\n\t":::"cc");
}]], [ a(); ] )],
[gcry_cv_gcc_inline_asm_pclmul=yes])
fi])
if test "$gcry_cv_gcc_inline_asm_pclmul" = "yes" ; then
AC_DEFINE(HAVE_GCC_INLINE_ASM_PCLMUL,1,
[Defined if inline assembler supports PCLMUL instructions])
fi
#
# Check whether GCC inline assembler supports SHA Extensions instructions.
#
AC_CACHE_CHECK([whether GCC inline assembler supports SHA Extensions instructions],
[gcry_cv_gcc_inline_asm_shaext],
[if test "$mpi_cpu_arch" != "x86" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_inline_asm_shaext="n/a"
else
gcry_cv_gcc_inline_asm_shaext=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[void a(void) {
__asm__("sha1rnds4 \$0, %%xmm1, %%xmm3\n\t":::"cc");
__asm__("sha1nexte %%xmm1, %%xmm3\n\t":::"cc");
__asm__("sha1msg1 %%xmm1, %%xmm3\n\t":::"cc");
__asm__("sha1msg2 %%xmm1, %%xmm3\n\t":::"cc");
__asm__("sha256rnds2 %%xmm0, %%xmm1, %%xmm3\n\t":::"cc");
__asm__("sha256msg1 %%xmm1, %%xmm3\n\t":::"cc");
__asm__("sha256msg2 %%xmm1, %%xmm3\n\t":::"cc");
}]], [ a(); ] )],
[gcry_cv_gcc_inline_asm_shaext=yes])
fi])
if test "$gcry_cv_gcc_inline_asm_shaext" = "yes" ; then
AC_DEFINE(HAVE_GCC_INLINE_ASM_SHAEXT,1,
[Defined if inline assembler supports SHA Extensions instructions])
fi
#
# Check whether GCC inline assembler supports SSE4.1 instructions.
#
AC_CACHE_CHECK([whether GCC inline assembler supports SSE4.1 instructions],
[gcry_cv_gcc_inline_asm_sse41],
[if test "$mpi_cpu_arch" != "x86" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_inline_asm_sse41="n/a"
else
gcry_cv_gcc_inline_asm_sse41=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[void a(void) {
int i;
__asm__("pextrd \$2, %%xmm0, %[out]\n\t" : [out] "=m" (i));
}]], [ a(); ] )],
[gcry_cv_gcc_inline_asm_sse41=yes])
fi])
if test "$gcry_cv_gcc_inline_asm_sse41" = "yes" ; then
AC_DEFINE(HAVE_GCC_INLINE_ASM_SSE41,1,
[Defined if inline assembler supports SSE4.1 instructions])
fi
#
# Check whether GCC inline assembler supports AVX instructions
#
AC_CACHE_CHECK([whether GCC inline assembler supports AVX instructions],
[gcry_cv_gcc_inline_asm_avx],
[if test "$mpi_cpu_arch" != "x86" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_inline_asm_avx="n/a"
else
gcry_cv_gcc_inline_asm_avx=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[void a(void) {
__asm__("xgetbv; vaesdeclast (%[mem]),%%xmm0,%%xmm7\n\t"::[mem]"r"(0):);
}]], [ a(); ] )],
[gcry_cv_gcc_inline_asm_avx=yes])
fi])
if test "$gcry_cv_gcc_inline_asm_avx" = "yes" ; then
AC_DEFINE(HAVE_GCC_INLINE_ASM_AVX,1,
[Defined if inline assembler supports AVX instructions])
fi
#
# Check whether GCC inline assembler supports AVX2 instructions
#
AC_CACHE_CHECK([whether GCC inline assembler supports AVX2 instructions],
[gcry_cv_gcc_inline_asm_avx2],
[if test "$mpi_cpu_arch" != "x86" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_inline_asm_avx2="n/a"
else
gcry_cv_gcc_inline_asm_avx2=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[void a(void) {
__asm__("xgetbv; vpbroadcastb %%xmm7,%%ymm1\n\t":::"cc");
}]], [ a(); ] )],
[gcry_cv_gcc_inline_asm_avx2=yes])
fi])
if test "$gcry_cv_gcc_inline_asm_avx2" = "yes" ; then
AC_DEFINE(HAVE_GCC_INLINE_ASM_AVX2,1,
[Defined if inline assembler supports AVX2 instructions])
fi
#
# Check whether GCC inline assembler supports VAES and VPCLMUL instructions
#
AC_CACHE_CHECK([whether GCC inline assembler supports VAES and VPCLMUL instructions],
[gcry_cv_gcc_inline_asm_vaes_vpclmul],
[if test "$mpi_cpu_arch" != "x86" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_inline_asm_vaes_vpclmul="n/a"
else
gcry_cv_gcc_inline_asm_vaes_vpclmul=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[void a(void) {
__asm__("vaesenclast %%ymm7,%%ymm7,%%ymm1\n\t":::"cc");/*256-bit*/
__asm__("vaesenclast %%zmm7,%%zmm7,%%zmm1\n\t":::"cc");/*512-bit*/
__asm__("vpclmulqdq \$0,%%ymm7,%%ymm7,%%ymm1\n\t":::"cc");/*256-bit*/
__asm__("vpclmulqdq \$0,%%zmm7,%%zmm7,%%zmm1\n\t":::"cc");/*512-bit*/
}]], [ a(); ] )],
[gcry_cv_gcc_inline_asm_vaes_vpclmul=yes])
fi])
if test "$gcry_cv_gcc_inline_asm_vaes_vpclmul" = "yes" ; then
AC_DEFINE(HAVE_GCC_INLINE_ASM_VAES_VPCLMUL,1,
[Defined if inline assembler supports VAES and VPCLMUL instructions])
fi
#
# Check whether GCC inline assembler supports BMI2 instructions
#
AC_CACHE_CHECK([whether GCC inline assembler supports BMI2 instructions],
[gcry_cv_gcc_inline_asm_bmi2],
[if test "$mpi_cpu_arch" != "x86" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_inline_asm_bmi2="n/a"
else
gcry_cv_gcc_inline_asm_bmi2=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[unsigned int a(unsigned int x, unsigned int y) {
unsigned int tmp1, tmp2;
asm ("rorxl %2, %1, %0"
: "=r" (tmp1)
: "rm0" (x), "J" (32 - ((23) & 31)));
asm ("andnl %2, %1, %0"
: "=r" (tmp2)
: "r0" (x), "rm" (y));
return tmp1 + tmp2;
}]], [ a(1, 2); ] )],
[gcry_cv_gcc_inline_asm_bmi2=yes])
fi])
if test "$gcry_cv_gcc_inline_asm_bmi2" = "yes" ; then
AC_DEFINE(HAVE_GCC_INLINE_ASM_BMI2,1,
[Defined if inline assembler supports BMI2 instructions])
fi
#
# Check whether GCC assembler needs "-Wa,--divide" to correctly handle
# constant division
#
if test $amd64_as_feature_detection = yes; then
AC_CACHE_CHECK([whether GCC assembler handles division correctly],
[gcry_cv_gcc_as_const_division_ok],
[gcry_cv_gcc_as_const_division_ok=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[__asm__(".text\n\tfn:\n\t xorl \$(123456789/12345678), %ebp;\n\t");]],
[fn();])],
[gcry_cv_gcc_as_const_division_ok=yes])])
if test "$gcry_cv_gcc_as_const_division_ok" = "no" ; then
#
# Add '-Wa,--divide' to CPPFLAGS and try check again.
#
_gcc_cppflags_save="$CPPFLAGS"
CPPFLAGS="$CPPFLAGS -Wa,--divide"
AC_CACHE_CHECK([whether GCC assembler handles division correctly with "-Wa,--divide"],
[gcry_cv_gcc_as_const_division_with_wadivide_ok],
[gcry_cv_gcc_as_const_division_with_wadivide_ok=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[__asm__(".text\n\tfn:\n\t xorl \$(123456789/12345678), %ebp;\n\t");]],
[fn();])],
[gcry_cv_gcc_as_const_division_with_wadivide_ok=yes])])
if test "$gcry_cv_gcc_as_const_division_with_wadivide_ok" = "no" ; then
# '-Wa,--divide' did not work, restore old flags.
CPPFLAGS="$_gcc_cppflags_save"
fi
fi
fi
#
# Check whether GCC assembler supports features needed for our amd64
# implementations
#
if test $amd64_as_feature_detection = yes; then
AC_CACHE_CHECK([whether GCC assembler is compatible for amd64 assembly implementations],
[gcry_cv_gcc_amd64_platform_as_ok],
[if test "$mpi_cpu_arch" != "x86" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_amd64_platform_as_ok="n/a"
else
gcry_cv_gcc_amd64_platform_as_ok=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[__asm__(
/* Test if '.type' and '.size' are supported. */
/* These work only on ELF targets. */
".text\n\t"
"asmfunc:\n\t"
".size asmfunc,.-asmfunc;\n\t"
".type asmfunc,@function;\n\t"
/* Test if assembler allows use of '/' for constant division
* (Solaris/x86 issue). If previous constant division check
* and "-Wa,--divide" workaround failed, this causes assembly
* to be disable on this machine. */
"xorl \$(123456789/12345678), %ebp;\n\t"
);]], [ asmfunc(); ])],
[gcry_cv_gcc_amd64_platform_as_ok=yes])
fi])
if test "$gcry_cv_gcc_amd64_platform_as_ok" = "yes" ; then
AC_DEFINE(HAVE_COMPATIBLE_GCC_AMD64_PLATFORM_AS,1,
[Defined if underlying assembler is compatible with amd64 assembly implementations])
fi
if test "$gcry_cv_gcc_amd64_platform_as_ok" = "no" &&
test "$gcry_cv_gcc_attribute_sysv_abi" = "yes" &&
test "$gcry_cv_gcc_default_abi_is_ms_abi" = "yes"; then
AC_CACHE_CHECK([whether GCC assembler is compatible for WIN64 assembly implementations],
[gcry_cv_gcc_win64_platform_as_ok],
[gcry_cv_gcc_win64_platform_as_ok=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[__asm__(
".text\n\t"
".globl asmfunc\n\t"
"asmfunc:\n\t"
"xorq \$(1234), %rbp;\n\t"
);]], [ asmfunc(); ])],
[gcry_cv_gcc_win64_platform_as_ok=yes])])
if test "$gcry_cv_gcc_win64_platform_as_ok" = "yes" ; then
AC_DEFINE(HAVE_COMPATIBLE_GCC_WIN64_PLATFORM_AS,1,
[Defined if underlying assembler is compatible with WIN64 assembly implementations])
fi
fi
fi
#
# Check whether GCC assembler supports features needed for assembly
# implementations that use Intel syntax
#
AC_CACHE_CHECK([whether GCC assembler is compatible for Intel syntax assembly implementations],
[gcry_cv_gcc_platform_as_ok_for_intel_syntax],
[if test "$mpi_cpu_arch" != "x86" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_platform_as_ok_for_intel_syntax="n/a"
else
gcry_cv_gcc_platform_as_ok_for_intel_syntax=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[__asm__(
".intel_syntax noprefix\n\t"
".text\n\t"
"actest:\n\t"
"pxor xmm1, xmm7;\n\t"
"vperm2i128 ymm2, ymm3, ymm0, 1;\n\t"
"add eax, ebp;\n\t"
"rorx eax, ebp, 1;\n\t"
"sub eax, [esp + 4];\n\t"
"add dword ptr [esp + eax], 0b10101;\n\t"
".att_syntax prefix\n\t"
);]], [ actest(); ])],
[gcry_cv_gcc_platform_as_ok_for_intel_syntax=yes])
fi])
if test "$gcry_cv_gcc_platform_as_ok_for_intel_syntax" = "yes" ; then
AC_DEFINE(HAVE_INTEL_SYNTAX_PLATFORM_AS,1,
[Defined if underlying assembler is compatible with Intel syntax assembly implementations])
fi
#
# Check whether compiler is configured for ARMv6 or newer architecture
#
AC_CACHE_CHECK([whether compiler is configured for ARMv6 or newer architecture],
[gcry_cv_cc_arm_arch_is_v6],
[if test "$mpi_cpu_arch" != "arm" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_cc_arm_arch_is_v6="n/a"
else
gcry_cv_cc_arm_arch_is_v6=no
AC_COMPILE_IFELSE([AC_LANG_SOURCE(
[[
#if defined(__arm__) && \
((defined(__ARM_ARCH) && __ARM_ARCH >= 6) \
|| defined(__ARM_ARCH_6__) || defined(__ARM_ARCH_6J__) \
|| defined(__ARM_ARCH_6Z__) || defined(__ARM_ARCH_6ZK__) \
|| defined(__ARM_ARCH_6K__) || defined(__ARM_ARCH_6T2__) \
|| defined(__ARM_ARCH_7__) || defined(__ARM_ARCH_7A__) \
|| defined(__ARM_ARCH_7R__) || defined(__ARM_ARCH_7M__) \
|| defined(__ARM_ARCH_7EM__))
/* empty */
#else
/* fail compile if not ARMv6. */
not_armv6 not_armv6 = (not_armv6)not_armv6;
#endif
]])],
[gcry_cv_cc_arm_arch_is_v6=yes])
fi])
if test "$gcry_cv_cc_arm_arch_is_v6" = "yes" ; then
AC_DEFINE(HAVE_ARM_ARCH_V6,1,
[Defined if ARM architecture is v6 or newer])
fi
#
# Check whether GCC inline assembler supports NEON instructions
#
AC_CACHE_CHECK([whether GCC inline assembler supports NEON instructions],
[gcry_cv_gcc_inline_asm_neon],
[if test "$mpi_cpu_arch" != "arm" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_inline_asm_neon="n/a"
else
gcry_cv_gcc_inline_asm_neon=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[__asm__(
".syntax unified\n\t"
".arm\n\t"
".fpu neon\n\t"
".text\n\t"
"testfn:\n\t"
"vld1.64 {%q0-%q1}, [%r0]!;\n\t"
"vrev64.8 %q0, %q3;\n\t"
"vadd.u64 %q0, %q1;\n\t"
"vadd.s64 %d3, %d2, %d3;\n\t"
);
]], [ testfn(); ])],
[gcry_cv_gcc_inline_asm_neon=yes])
fi])
if test "$gcry_cv_gcc_inline_asm_neon" = "yes" ; then
AC_DEFINE(HAVE_GCC_INLINE_ASM_NEON,1,
[Defined if inline assembler supports NEON instructions])
fi
#
# Check whether GCC inline assembler supports AArch32 Crypto Extension instructions
#
AC_CACHE_CHECK([whether GCC inline assembler supports AArch32 Crypto Extension instructions],
[gcry_cv_gcc_inline_asm_aarch32_crypto],
[if test "$mpi_cpu_arch" != "arm" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_inline_asm_aarch32_crypto="n/a"
else
gcry_cv_gcc_inline_asm_aarch32_crypto=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[__asm__(
".syntax unified\n\t"
".arch armv8-a\n\t"
".arm\n\t"
".fpu crypto-neon-fp-armv8\n\t"
".text\n\t"
"testfn:\n\t"
"sha1h.32 q0, q0;\n\t"
"sha1c.32 q0, q0, q0;\n\t"
"sha1p.32 q0, q0, q0;\n\t"
"sha1su0.32 q0, q0, q0;\n\t"
"sha1su1.32 q0, q0;\n\t"
"sha256h.32 q0, q0, q0;\n\t"
"sha256h2.32 q0, q0, q0;\n\t"
"sha1p.32 q0, q0, q0;\n\t"
"sha256su0.32 q0, q0;\n\t"
"sha256su1.32 q0, q0, q15;\n\t"
"aese.8 q0, q0;\n\t"
"aesd.8 q0, q0;\n\t"
"aesmc.8 q0, q0;\n\t"
"aesimc.8 q0, q0;\n\t"
"vmull.p64 q0, d0, d0;\n\t"
);
]], [ testfn(); ])],
[gcry_cv_gcc_inline_asm_aarch32_crypto=yes])
fi])
if test "$gcry_cv_gcc_inline_asm_aarch32_crypto" = "yes" ; then
AC_DEFINE(HAVE_GCC_INLINE_ASM_AARCH32_CRYPTO,1,
[Defined if inline assembler supports AArch32 Crypto Extension instructions])
fi
#
# Check whether GCC inline assembler supports AArch64 NEON instructions
#
AC_CACHE_CHECK([whether GCC inline assembler supports AArch64 NEON instructions],
[gcry_cv_gcc_inline_asm_aarch64_neon],
[if test "$mpi_cpu_arch" != "aarch64" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_inline_asm_aarch64_neon="n/a"
else
gcry_cv_gcc_inline_asm_aarch64_neon=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[__asm__(
".cpu generic+simd\n\t"
".text\n\t"
"testfn:\n\t"
"mov w0, \#42;\n\t"
"dup v0.8b, w0;\n\t"
"ld4 {v0.8b,v1.8b,v2.8b,v3.8b},[x0],\#32;\n\t"
);
]], [ testfn(); ])],
[gcry_cv_gcc_inline_asm_aarch64_neon=yes])
fi])
if test "$gcry_cv_gcc_inline_asm_aarch64_neon" = "yes" ; then
AC_DEFINE(HAVE_GCC_INLINE_ASM_AARCH64_NEON,1,
[Defined if inline assembler supports AArch64 NEON instructions])
fi
#
# Check whether GCC inline assembler supports AArch64 Crypto Extension instructions
#
AC_CACHE_CHECK([whether GCC inline assembler supports AArch64 Crypto Extension instructions],
[gcry_cv_gcc_inline_asm_aarch64_crypto],
[if test "$mpi_cpu_arch" != "aarch64" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_inline_asm_aarch64_crypto="n/a"
else
gcry_cv_gcc_inline_asm_aarch64_crypto=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[__asm__(
".cpu generic+simd+crypto\n\t"
".text\n\t"
"testfn:\n\t"
"mov w0, \#42;\n\t"
"dup v0.8b, w0;\n\t"
"ld4 {v0.8b,v1.8b,v2.8b,v3.8b},[x0],\#32;\n\t"
"sha1h s0, s0;\n\t"
"sha1c q0, s0, v0.4s;\n\t"
"sha1p q0, s0, v0.4s;\n\t"
"sha1su0 v0.4s, v0.4s, v0.4s;\n\t"
"sha1su1 v0.4s, v0.4s;\n\t"
"sha256h q0, q0, v0.4s;\n\t"
"sha256h2 q0, q0, v0.4s;\n\t"
"sha1p q0, s0, v0.4s;\n\t"
"sha256su0 v0.4s, v0.4s;\n\t"
"sha256su1 v0.4s, v0.4s, v31.4s;\n\t"
"aese v0.16b, v0.16b;\n\t"
"aesd v0.16b, v0.16b;\n\t"
"aesmc v0.16b, v0.16b;\n\t"
"aesimc v0.16b, v0.16b;\n\t"
"pmull v0.1q, v0.1d, v31.1d;\n\t"
"pmull2 v0.1q, v0.2d, v31.2d;\n\t"
);
]], [ testfn(); ])],
[gcry_cv_gcc_inline_asm_aarch64_crypto=yes])
fi])
if test "$gcry_cv_gcc_inline_asm_aarch64_crypto" = "yes" ; then
AC_DEFINE(HAVE_GCC_INLINE_ASM_AARCH64_CRYPTO,1,
[Defined if inline assembler supports AArch64 Crypto Extension instructions])
fi
#
# Check whether PowerPC AltiVec/VSX intrinsics
#
AC_CACHE_CHECK([whether compiler supports PowerPC AltiVec/VSX intrinsics],
[gcry_cv_cc_ppc_altivec],
[if test "$mpi_cpu_arch" != "ppc" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_cc_ppc_altivec="n/a"
else
gcry_cv_cc_ppc_altivec=no
AC_COMPILE_IFELSE([AC_LANG_SOURCE(
[[#include
typedef vector unsigned char block;
typedef vector unsigned int vecu32;
block fn(block in)
{
block t = vec_perm (in, in, vec_vsx_ld (0, (unsigned char*)0));
vecu32 y = vec_vsx_ld (0, (unsigned int*)0);
return vec_cipher_be (t, in) ^ (block)y;
}
]])],
[gcry_cv_cc_ppc_altivec=yes])
fi])
if test "$gcry_cv_cc_ppc_altivec" = "yes" ; then
AC_DEFINE(HAVE_COMPATIBLE_CC_PPC_ALTIVEC,1,
[Defined if underlying compiler supports PowerPC AltiVec/VSX/crypto intrinsics])
fi
_gcc_cflags_save=$CFLAGS
CFLAGS="$CFLAGS -maltivec -mvsx -mcrypto"
if test "$gcry_cv_cc_ppc_altivec" = "no" &&
test "$mpi_cpu_arch" = "ppc" &&
test "$try_asm_modules" == "yes" ; then
AC_CACHE_CHECK([whether compiler supports PowerPC AltiVec/VSX/crypto intrinsics with extra GCC flags],
[gcry_cv_cc_ppc_altivec_cflags],
[gcry_cv_cc_ppc_altivec_cflags=no
AC_COMPILE_IFELSE([AC_LANG_SOURCE(
[[#include
typedef vector unsigned char block;
typedef vector unsigned int vecu32;
block fn(block in)
{
block t = vec_perm (in, in, vec_vsx_ld (0, (unsigned char*)0));
vecu32 y = vec_vsx_ld (0, (unsigned int*)0);
return vec_cipher_be (t, in) ^ (block)y;
}]])],
[gcry_cv_cc_ppc_altivec_cflags=yes])])
if test "$gcry_cv_cc_ppc_altivec_cflags" = "yes" ; then
AC_DEFINE(HAVE_COMPATIBLE_CC_PPC_ALTIVEC,1,
[Defined if underlying compiler supports PowerPC AltiVec/VSX/crypto intrinsics])
AC_DEFINE(HAVE_COMPATIBLE_CC_PPC_ALTIVEC_WITH_CFLAGS,1,
[Defined if underlying compiler supports PowerPC AltiVec/VSX/crypto intrinsics with extra GCC flags])
fi
fi
AM_CONDITIONAL(ENABLE_PPC_VCRYPTO_EXTRA_CFLAGS,
test "$gcry_cv_cc_ppc_altivec_cflags" = "yes")
# Restore flags.
CFLAGS=$_gcc_cflags_save;
#
# Check whether GCC inline assembler supports PowerPC AltiVec/VSX/crypto instructions
#
AC_CACHE_CHECK([whether GCC inline assembler supports PowerPC AltiVec/VSX/crypto instructions],
[gcry_cv_gcc_inline_asm_ppc_altivec],
[if test "$mpi_cpu_arch" != "ppc" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_inline_asm_ppc_altivec="n/a"
else
gcry_cv_gcc_inline_asm_ppc_altivec=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[__asm__(".globl testfn;\n"
".text\n\t"
"testfn:\n"
"stvx %v31,%r12,%r0;\n"
"lvx %v20,%r12,%r0;\n"
"vcipher %v0, %v1, %v22;\n"
"lxvw4x %vs32, %r0, %r1;\n"
"vadduwm %v0, %v1, %v22;\n"
"vshasigmaw %v0, %v1, 0, 15;\n"
"vshasigmad %v0, %v1, 0, 15;\n"
"vpmsumd %v11, %v11, %v11;\n"
);
]], [ testfn(); ] )],
[gcry_cv_gcc_inline_asm_ppc_altivec=yes])
fi])
if test "$gcry_cv_gcc_inline_asm_ppc_altivec" = "yes" ; then
AC_DEFINE(HAVE_GCC_INLINE_ASM_PPC_ALTIVEC,1,
[Defined if inline assembler supports PowerPC AltiVec/VSX/crypto instructions])
fi
#
# Check whether GCC inline assembler supports PowerISA 3.00 instructions
#
AC_CACHE_CHECK([whether GCC inline assembler supports PowerISA 3.00 instructions],
[gcry_cv_gcc_inline_asm_ppc_arch_3_00],
[if test "$mpi_cpu_arch" != "ppc" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_inline_asm_ppc_arch_3_00="n/a"
else
gcry_cv_gcc_inline_asm_ppc_arch_3_00=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[__asm__(".text\n\t"
".globl testfn;\n"
"testfn:\n"
"stxvb16x %r1,%v12,%v30;\n"
);
]], [ testfn(); ])],
[gcry_cv_gcc_inline_asm_ppc_arch_3_00=yes])
fi])
if test "$gcry_cv_gcc_inline_asm_ppc_arch_3_00" = "yes" ; then
AC_DEFINE(HAVE_GCC_INLINE_ASM_PPC_ARCH_3_00,1,
[Defined if inline assembler supports PowerISA 3.00 instructions])
fi
#
# Check whether GCC inline assembler supports zSeries instructions
#
AC_CACHE_CHECK([whether GCC inline assembler supports zSeries instructions],
[gcry_cv_gcc_inline_asm_s390x],
[if test "$mpi_cpu_arch" != "s390x" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_inline_asm_s390x="n/a"
else
gcry_cv_gcc_inline_asm_s390x=no
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[typedef unsigned int u128_t __attribute__ ((mode (TI)));
unsigned int testfunc(unsigned int x, void *y, unsigned int z)
{
unsigned long fac[8];
register unsigned long reg0 asm("0") = 0;
register unsigned long reg1 asm("1") = x;
u128_t r1 = ((u128_t)(unsigned long)y << 64) | (unsigned long)z;
u128_t r2 = 0;
u128_t r3 = 0;
asm volatile (".insn rre,0xb92e << 16, %[r1], %[r2]\n\t"
: [r1] "+a" (r1), [r2] "+a" (r2)
: "r" (reg0), "r" (reg1)
: "cc", "memory");
asm volatile (".insn rrf,0xb929 << 16, %[r1], %[r2], %[r3], 0\n\t"
: [r1] "+a" (r1), [r2] "+a" (r2), [r3] "+a" (r3)
: "r" (reg0), "r" (reg1)
: "cc", "memory");
reg0 = 8 - 1;
asm ("stfle %1\n\t"
: "+d" (reg0), "=Q" (fac[0])
:
: "cc", "memory");
asm volatile ("mvc 0(16, %0), 0(%1)\n\t"
:
: "a" (y), "a" (fac)
: "memory");
asm volatile ("xc 0(16, %0), 0(%0)\n\t"
:
: "a" (fac)
: "memory");
asm volatile ("risbgn %%r11, %%r11, 0, 129, 0\n\t"
:
:
: "memory", "r11");
asm volatile ("algrk %%r14, %%r14, %%r14\n\t"
:
:
: "memory", "r14");
return (unsigned int)r1 ^ reg0;
}
]] , [ testfunc(0, 0, 0); ])],
[gcry_cv_gcc_inline_asm_s390x=yes])
fi])
if test "$gcry_cv_gcc_inline_asm_s390x" = "yes" ; then
AC_DEFINE(HAVE_GCC_INLINE_ASM_S390X,1,
[Defined if inline assembler supports zSeries instructions])
fi
#
# Check whether GCC inline assembler supports zSeries vector instructions
#
AC_CACHE_CHECK([whether GCC inline assembler supports zSeries vector instructions],
[gcry_cv_gcc_inline_asm_s390x_vx],
[if test "$mpi_cpu_arch" != "s390x" ||
test "$try_asm_modules" != "yes" ; then
gcry_cv_gcc_inline_asm_s390x_vx="n/a"
else
gcry_cv_gcc_inline_asm_s390x_vx=no
if test "$gcry_cv_gcc_inline_asm_s390x" = "yes" ; then
AC_LINK_IFELSE([AC_LANG_PROGRAM(
[[void testfunc(void)
{
asm volatile (".machine \"z13+vx\"\n\t"
"vx %%v0, %%v1, %%v31\n\t"
"verllf %%v11, %%v11, (16)(0)\n\t"
:
:
: "memory");
}
]], [ testfunc(); ])],
[gcry_cv_gcc_inline_asm_s390x_vx=yes])
fi
fi])
if test "$gcry_cv_gcc_inline_asm_s390x_vx" = "yes" ; then
AC_DEFINE(HAVE_GCC_INLINE_ASM_S390X_VX,1,
[Defined if inline assembler supports zSeries vector instructions])
fi
#######################################
#### Checks for library functions. ####
#######################################
AC_FUNC_VPRINTF
# We have replacements for these in src/missing-string.c
AC_CHECK_FUNCS(stpcpy strcasecmp)
# We have replacements for these in src/g10lib.h
AC_CHECK_FUNCS(strtoul memmove stricmp atexit raise)
# Other checks
AC_CHECK_FUNCS(strerror rand mmap getpagesize sysconf waitpid wait4)
AC_CHECK_FUNCS(gettimeofday getrusage gethrtime clock_gettime syslog)
AC_CHECK_FUNCS(syscall fcntl ftruncate flockfile getauxval elf_aux_info)
AC_CHECK_FUNCS(explicit_bzero explicit_memset getentropy)
GNUPG_CHECK_MLOCK
#
# Replacement functions.
#
AC_REPLACE_FUNCS([getpid clock])
#
# Check whether it is necessary to link against libdl.
#
DL_LIBS=""
if test "$use_hmac_binary_check" != no ; then
_gcry_save_libs="$LIBS"
LIBS=""
AC_SEARCH_LIBS(dlopen, c dl,,,)
DL_LIBS=$LIBS
LIBS="$_gcry_save_libs"
fi
AC_SUBST(DL_LIBS)
#
# Check whether we can use Linux capabilities as requested.
#
if test "$use_capabilities" = "yes" ; then
use_capabilities=no
AC_CHECK_HEADERS(sys/capability.h)
if test "$ac_cv_header_sys_capability_h" = "yes" ; then
AC_CHECK_LIB(cap, cap_init, ac_need_libcap=1)
if test "$ac_cv_lib_cap_cap_init" = "yes"; then
AC_DEFINE(USE_CAPABILITIES,1,
[define if capabilities should be used])
LIBS="$LIBS -lcap"
use_capabilities=yes
fi
fi
if test "$use_capabilities" = "no" ; then
AC_MSG_WARN([[
***
*** The use of capabilities on this system is not possible.
*** You need a recent Linux kernel and some patches:
*** fcaps-2.2.9-990610.patch (kernel patch for 2.2.9)
*** fcap-module-990613.tar.gz (kernel module)
*** libcap-1.92.tar.gz (user mode library and utilities)
*** And you have to configure the kernel with CONFIG_VFS_CAP_PLUGIN
*** set (filesystems menu). Be warned: This code is *really* ALPHA.
***]])
fi
fi
# Check whether a random device is available.
if test "$try_dev_random" = yes ; then
AC_CACHE_CHECK(for random device, ac_cv_have_dev_random,
[if test -r "$NAME_OF_DEV_RANDOM" && test -r "$NAME_OF_DEV_URANDOM" ; then
ac_cv_have_dev_random=yes; else ac_cv_have_dev_random=no; fi])
if test "$ac_cv_have_dev_random" = yes; then
AC_DEFINE(HAVE_DEV_RANDOM,1,
[defined if the system supports a random device] )
fi
else
AC_MSG_CHECKING(for random device)
ac_cv_have_dev_random=no
AC_MSG_RESULT(has been disabled)
fi
# Figure out the random modules for this configuration.
if test "$random" = "default"; then
# Select default value.
if test "$ac_cv_func_getentropy" = yes; then
random_modules="getentropy"
elif test "$ac_cv_have_dev_random" = yes; then
# Try Linuxish random device.
random_modules="linux"
else
case "${host}" in
*-*-mingw32ce*)
# WindowsCE random device.
random_modules="w32ce"
;;
*-*-mingw32*|*-*-cygwin*)
# Windows random device.
random_modules="w32"
;;
*)
# Build everything, allow to select at runtime.
random_modules="$auto_random_modules"
;;
esac
fi
else
if test "$random" = "auto"; then
# Build everything, allow to select at runtime.
random_modules="$auto_random_modules"
else
random_modules="$random"
fi
fi
#
# Other defines
#
if test mym4_isgit = "yes"; then
AC_DEFINE(IS_DEVELOPMENT_VERSION,1,
[Defined if this is not a regular release])
fi
AM_CONDITIONAL(CROSS_COMPILING, test x$cross_compiling = xyes)
# This is handy for debugging so the compiler doesn't rearrange
# things and eliminate variables.
AC_ARG_ENABLE(optimization,
AS_HELP_STRING([--disable-optimization],
[disable compiler optimization]),
[if test $enableval = no ; then
CFLAGS=`echo $CFLAGS | sed 's/-O[[0-9]]//'`
fi])
AC_MSG_NOTICE([checking for cc features])
# CFLAGS mangling when using gcc.
if test "$GCC" = yes; then
AC_MSG_CHECKING([if gcc supports -fno-delete-null-pointer-checks])
_gcc_cflags_save=$CFLAGS
CFLAGS="-fno-delete-null-pointer-checks"
AC_COMPILE_IFELSE([AC_LANG_PROGRAM([],[])],_gcc_wopt=yes,_gcc_wopt=no)
AC_MSG_RESULT($_gcc_wopt)
CFLAGS=$_gcc_cflags_save;
if test x"$_gcc_wopt" = xyes ; then
CFLAGS="$CFLAGS -fno-delete-null-pointer-checks"
fi
CFLAGS="$CFLAGS -Wall"
if test "$USE_MAINTAINER_MODE" = "yes"; then
CFLAGS="$CFLAGS -Wcast-align -Wshadow -Wstrict-prototypes"
CFLAGS="$CFLAGS -Wformat -Wno-format-y2k -Wformat-security"
# If -Wno-missing-field-initializers is supported we can enable a
# a bunch of really useful warnings.
AC_MSG_CHECKING([if gcc supports -Wno-missing-field-initializers])
_gcc_cflags_save=$CFLAGS
CFLAGS="-Wno-missing-field-initializers"
AC_COMPILE_IFELSE([AC_LANG_PROGRAM([],[])],_gcc_wopt=yes,_gcc_wopt=no)
AC_MSG_RESULT($_gcc_wopt)
CFLAGS=$_gcc_cflags_save;
if test x"$_gcc_wopt" = xyes ; then
CFLAGS="$CFLAGS -W -Wextra -Wbad-function-cast"
CFLAGS="$CFLAGS -Wwrite-strings"
CFLAGS="$CFLAGS -Wdeclaration-after-statement"
CFLAGS="$CFLAGS -Wno-missing-field-initializers"
CFLAGS="$CFLAGS -Wno-sign-compare"
fi
AC_MSG_CHECKING([if gcc supports -Wpointer-arith])
_gcc_cflags_save=$CFLAGS
CFLAGS="-Wpointer-arith"
AC_COMPILE_IFELSE([AC_LANG_PROGRAM([],[])],_gcc_wopt=yes,_gcc_wopt=no)
AC_MSG_RESULT($_gcc_wopt)
CFLAGS=$_gcc_cflags_save;
if test x"$_gcc_wopt" = xyes ; then
CFLAGS="$CFLAGS -Wpointer-arith"
fi
fi
fi
# Check whether as(1) supports a noeexecstack feature. This test
# includes an override option.
CL_AS_NOEXECSTACK
AC_SUBST(LIBGCRYPT_CONFIG_API_VERSION)
AC_SUBST(LIBGCRYPT_CONFIG_LIBS)
AC_SUBST(LIBGCRYPT_CONFIG_CFLAGS)
AC_SUBST(LIBGCRYPT_CONFIG_HOST)
AC_SUBST(LIBGCRYPT_THREAD_MODULES)
AC_CONFIG_COMMANDS([gcrypt-conf],[[
chmod +x src/libgcrypt-config
]],[[
prefix=$prefix
exec_prefix=$exec_prefix
libdir=$libdir
datadir=$datadir
DATADIRNAME=$DATADIRNAME
]])
#####################
#### Conclusion. ####
#####################
# Check that requested feature can actually be used and define
# ENABLE_foo_SUPPORT macros.
if test x"$aesnisupport" = xyes ; then
if test "$gcry_cv_gcc_inline_asm_ssse3" != "yes" ; then
aesnisupport="no (unsupported by compiler)"
fi
fi
if test x"$shaextsupport" = xyes ; then
if test "$gcry_cv_gcc_inline_asm_shaext" != "yes" ; then
shaextsupport="no (unsupported by compiler)"
fi
fi
if test x"$pclmulsupport" = xyes ; then
if test "$gcry_cv_gcc_inline_asm_pclmul" != "yes" ; then
pclmulsupport="no (unsupported by compiler)"
fi
fi
if test x"$sse41support" = xyes ; then
if test "$gcry_cv_gcc_inline_asm_sse41" != "yes" ; then
sse41support="no (unsupported by compiler)"
fi
fi
if test x"$avxsupport" = xyes ; then
if test "$gcry_cv_gcc_inline_asm_avx" != "yes" ; then
avxsupport="no (unsupported by compiler)"
fi
fi
if test x"$avx2support" = xyes ; then
if test "$gcry_cv_gcc_inline_asm_avx2" != "yes" ; then
avx2support="no (unsupported by compiler)"
fi
fi
if test x"$neonsupport" = xyes ; then
if test "$gcry_cv_gcc_inline_asm_neon" != "yes" ; then
if test "$gcry_cv_gcc_inline_asm_aarch64_neon" != "yes" ; then
neonsupport="no (unsupported by compiler)"
fi
fi
fi
if test x"$armcryptosupport" = xyes ; then
if test "$gcry_cv_gcc_inline_asm_aarch32_crypto" != "yes" ; then
if test "$gcry_cv_gcc_inline_asm_aarch64_crypto" != "yes" ; then
neonsupport="no (unsupported by compiler)"
fi
fi
fi
if test x"$aesnisupport" = xyes ; then
AC_DEFINE(ENABLE_AESNI_SUPPORT, 1,
[Enable support for Intel AES-NI instructions.])
fi
if test x"$shaextsupport" = xyes ; then
AC_DEFINE(ENABLE_SHAEXT_SUPPORT, 1,
[Enable support for Intel SHAEXT instructions.])
fi
if test x"$pclmulsupport" = xyes ; then
AC_DEFINE(ENABLE_PCLMUL_SUPPORT, 1,
[Enable support for Intel PCLMUL instructions.])
fi
if test x"$sse41support" = xyes ; then
AC_DEFINE(ENABLE_SSE41_SUPPORT, 1,
[Enable support for Intel SSE4.1 instructions.])
fi
if test x"$avxsupport" = xyes ; then
AC_DEFINE(ENABLE_AVX_SUPPORT,1,
[Enable support for Intel AVX instructions.])
fi
if test x"$avx2support" = xyes ; then
AC_DEFINE(ENABLE_AVX2_SUPPORT,1,
[Enable support for Intel AVX2 instructions.])
fi
if test x"$neonsupport" = xyes ; then
AC_DEFINE(ENABLE_NEON_SUPPORT,1,
[Enable support for ARM NEON instructions.])
fi
if test x"$armcryptosupport" = xyes ; then
AC_DEFINE(ENABLE_ARM_CRYPTO_SUPPORT,1,
[Enable support for ARMv8 Crypto Extension instructions.])
fi
if test x"$ppccryptosupport" = xyes ; then
AC_DEFINE(ENABLE_PPC_CRYPTO_SUPPORT,1,
[Enable support for POWER 8 (PowerISA 2.07) crypto extension.])
fi
if test x"$jentsupport" = xyes ; then
AC_DEFINE(ENABLE_JENT_SUPPORT, 1,
[Enable support for the jitter entropy collector.])
fi
if test x"$padlocksupport" = xyes ; then
AC_DEFINE(ENABLE_PADLOCK_SUPPORT, 1,
[Enable support for the PadLock engine.])
fi
if test x"$drngsupport" = xyes ; then
AC_DEFINE(ENABLE_DRNG_SUPPORT, 1,
[Enable support for Intel DRNG (RDRAND instruction).])
fi
if test x"$force_soft_hwfeatures" = xyes ; then
AC_DEFINE(ENABLE_FORCE_SOFT_HWFEATURES, 1,
[Enable forcing 'soft' HW feature bits on (for testing).])
fi
# Define conditional sources and config.h symbols depending on the
# selected ciphers, pubkey-ciphers, digests, kdfs, and random modules.
LIST_MEMBER(arcfour, $enabled_ciphers)
if test "$found" = "1"; then
GCRYPT_CIPHERS="$GCRYPT_CIPHERS arcfour.lo"
AC_DEFINE(USE_ARCFOUR, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS arcfour-amd64.lo"
;;
esac
fi
LIST_MEMBER(blowfish, $enabled_ciphers)
if test "$found" = "1" ; then
GCRYPT_CIPHERS="$GCRYPT_CIPHERS blowfish.lo"
AC_DEFINE(USE_BLOWFISH, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS blowfish-amd64.lo"
;;
arm*-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS blowfish-arm.lo"
;;
esac
fi
LIST_MEMBER(cast5, $enabled_ciphers)
if test "$found" = "1" ; then
GCRYPT_CIPHERS="$GCRYPT_CIPHERS cast5.lo"
AC_DEFINE(USE_CAST5, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS cast5-amd64.lo"
;;
arm*-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS cast5-arm.lo"
;;
esac
fi
LIST_MEMBER(des, $enabled_ciphers)
if test "$found" = "1" ; then
GCRYPT_CIPHERS="$GCRYPT_CIPHERS des.lo"
AC_DEFINE(USE_DES, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS des-amd64.lo"
;;
esac
fi
LIST_MEMBER(aes, $enabled_ciphers)
if test "$found" = "1" ; then
GCRYPT_CIPHERS="$GCRYPT_CIPHERS rijndael.lo"
AC_DEFINE(USE_AES, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-amd64.lo"
# Build with the SSSE3 implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-ssse3-amd64.lo"
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-ssse3-amd64-asm.lo"
# Build with the VAES/AVX2 implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-vaes.lo"
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-vaes-avx2-amd64.lo"
;;
arm*-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-arm.lo"
# Build with the ARMv8/AArch32 CE implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-armv8-ce.lo"
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-armv8-aarch32-ce.lo"
;;
aarch64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-aarch64.lo"
# Build with the ARMv8/AArch64 CE implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-armv8-ce.lo"
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-armv8-aarch64-ce.lo"
;;
powerpc64le-*-*)
# Build with the crypto extension implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-ppc.lo"
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-ppc9le.lo"
;;
powerpc64-*-*)
# Big-Endian.
# Build with the crypto extension implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-ppc.lo"
;;
powerpc-*-*)
# Big-Endian.
# Build with the crypto extension implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-ppc.lo"
;;
s390x-*-*)
# Big-Endian.
# Build with the crypto extension implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-s390x.lo"
;;
esac
case "$mpi_cpu_arch" in
x86)
# Build with the AES-NI implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-aesni.lo"
# Build with the Padlock implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS rijndael-padlock.lo"
;;
esac
fi
LIST_MEMBER(twofish, $enabled_ciphers)
if test "$found" = "1" ; then
GCRYPT_CIPHERS="$GCRYPT_CIPHERS twofish.lo"
AC_DEFINE(USE_TWOFISH, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS twofish-amd64.lo"
if test x"$avx2support" = xyes ; then
# Build with the AVX2 implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS twofish-avx2-amd64.lo"
fi
;;
arm*-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS twofish-arm.lo"
;;
aarch64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS twofish-aarch64.lo"
;;
esac
fi
LIST_MEMBER(serpent, $enabled_ciphers)
if test "$found" = "1" ; then
GCRYPT_CIPHERS="$GCRYPT_CIPHERS serpent.lo"
AC_DEFINE(USE_SERPENT, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the SSE2 implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS serpent-sse2-amd64.lo"
;;
esac
if test x"$avx2support" = xyes ; then
# Build with the AVX2 implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS serpent-avx2-amd64.lo"
fi
if test x"$neonsupport" = xyes ; then
# Build with the NEON implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS serpent-armv7-neon.lo"
fi
fi
LIST_MEMBER(rfc2268, $enabled_ciphers)
if test "$found" = "1" ; then
GCRYPT_CIPHERS="$GCRYPT_CIPHERS rfc2268.lo"
AC_DEFINE(USE_RFC2268, 1, [Defined if this module should be included])
fi
LIST_MEMBER(seed, $enabled_ciphers)
if test "$found" = "1" ; then
GCRYPT_CIPHERS="$GCRYPT_CIPHERS seed.lo"
AC_DEFINE(USE_SEED, 1, [Defined if this module should be included])
fi
LIST_MEMBER(camellia, $enabled_ciphers)
if test "$found" = "1" ; then
GCRYPT_CIPHERS="$GCRYPT_CIPHERS camellia.lo camellia-glue.lo"
AC_DEFINE(USE_CAMELLIA, 1, [Defined if this module should be included])
case "${host}" in
arm*-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS camellia-arm.lo"
;;
aarch64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS camellia-aarch64.lo"
;;
esac
if test x"$avxsupport" = xyes ; then
if test x"$aesnisupport" = xyes ; then
# Build with the AES-NI/AVX implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS camellia-aesni-avx-amd64.lo"
fi
fi
if test x"$avx2support" = xyes ; then
if test x"$aesnisupport" = xyes ; then
# Build with the AES-NI/AVX2 implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS camellia-aesni-avx2-amd64.lo"
# Build with the VAES/AVX2 implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS camellia-vaes-avx2-amd64.lo"
fi
fi
fi
LIST_MEMBER(idea, $enabled_ciphers)
if test "$found" = "1" ; then
GCRYPT_CIPHERS="$GCRYPT_CIPHERS idea.lo"
AC_DEFINE(USE_IDEA, 1, [Defined if this module should be included])
fi
LIST_MEMBER(salsa20, $enabled_ciphers)
if test "$found" = "1" ; then
GCRYPT_CIPHERS="$GCRYPT_CIPHERS salsa20.lo"
AC_DEFINE(USE_SALSA20, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS salsa20-amd64.lo"
;;
esac
if test x"$neonsupport" = xyes ; then
# Build with the NEON implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS salsa20-armv7-neon.lo"
fi
fi
LIST_MEMBER(gost28147, $enabled_ciphers)
if test "$found" = "1" ; then
GCRYPT_CIPHERS="$GCRYPT_CIPHERS gost28147.lo"
AC_DEFINE(USE_GOST28147, 1, [Defined if this module should be included])
fi
LIST_MEMBER(chacha20, $enabled_ciphers)
if test "$found" = "1" ; then
GCRYPT_CIPHERS="$GCRYPT_CIPHERS chacha20.lo"
AC_DEFINE(USE_CHACHA20, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS chacha20-amd64-ssse3.lo"
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS chacha20-amd64-avx2.lo"
;;
aarch64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS chacha20-aarch64.lo"
;;
powerpc64le-*-*)
# Build with the ppc8 vector implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS chacha20-ppc.lo"
;;
powerpc64-*-*)
# Build with the ppc8 vector implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS chacha20-ppc.lo"
;;
powerpc-*-*)
# Build with the ppc8 vector implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS chacha20-ppc.lo"
;;
s390x-*-*)
# Build with the s390x/zSeries vector implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS chacha20-s390x.lo"
;;
esac
if test x"$neonsupport" = xyes ; then
# Build with the NEON implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS chacha20-armv7-neon.lo"
fi
fi
LIST_MEMBER(sm4, $enabled_ciphers)
if test "$found" = "1" ; then
GCRYPT_CIPHERS="$GCRYPT_CIPHERS sm4.lo"
AC_DEFINE(USE_SM4, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS sm4-aesni-avx-amd64.lo"
GCRYPT_ASM_CIPHERS="$GCRYPT_ASM_CIPHERS sm4-aesni-avx2-amd64.lo"
;;
esac
fi
LIST_MEMBER(dsa, $enabled_pubkey_ciphers)
if test "$found" = "1" ; then
GCRYPT_PUBKEY_CIPHERS="$GCRYPT_PUBKEY_CIPHERS dsa.lo"
AC_DEFINE(USE_DSA, 1, [Defined if this module should be included])
fi
LIST_MEMBER(rsa, $enabled_pubkey_ciphers)
if test "$found" = "1" ; then
GCRYPT_PUBKEY_CIPHERS="$GCRYPT_PUBKEY_CIPHERS rsa.lo"
AC_DEFINE(USE_RSA, 1, [Defined if this module should be included])
fi
LIST_MEMBER(elgamal, $enabled_pubkey_ciphers)
if test "$found" = "1" ; then
GCRYPT_PUBKEY_CIPHERS="$GCRYPT_PUBKEY_CIPHERS elgamal.lo"
AC_DEFINE(USE_ELGAMAL, 1, [Defined if this module should be included])
fi
LIST_MEMBER(ecc, $enabled_pubkey_ciphers)
if test "$found" = "1" ; then
GCRYPT_PUBKEY_CIPHERS="$GCRYPT_PUBKEY_CIPHERS \
ecc.lo ecc-curves.lo ecc-misc.lo \
ecc-ecdh.lo ecc-ecdsa.lo ecc-eddsa.lo ecc-gost.lo \
ecc-sm2.lo"
AC_DEFINE(USE_ECC, 1, [Defined if this module should be included])
fi
LIST_MEMBER(crc, $enabled_digests)
if test "$found" = "1" ; then
GCRYPT_DIGESTS="$GCRYPT_DIGESTS crc.lo"
AC_DEFINE(USE_CRC, 1, [Defined if this module should be included])
case "${host}" in
i?86-*-* | x86_64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS crc-intel-pclmul.lo"
;;
aarch64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS crc-armv8-ce.lo"
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS crc-armv8-aarch64-ce.lo"
;;
powerpc64le-*-*)
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS crc-ppc.lo"
;;
powerpc64-*-*)
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS crc-ppc.lo"
;;
powerpc-*-*)
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS crc-ppc.lo"
;;
esac
fi
LIST_MEMBER(gostr3411-94, $enabled_digests)
if test "$found" = "1" ; then
# GOST R 34.11-94 internally uses GOST 28147-89
LIST_MEMBER(gost28147, $enabled_ciphers)
if test "$found" = "1" ; then
GCRYPT_DIGESTS="$GCRYPT_DIGESTS gostr3411-94.lo"
AC_DEFINE(USE_GOST_R_3411_94, 1, [Defined if this module should be included])
fi
fi
LIST_MEMBER(stribog, $enabled_digests)
if test "$found" = "1" ; then
GCRYPT_DIGESTS="$GCRYPT_DIGESTS stribog.lo"
AC_DEFINE(USE_GOST_R_3411_12, 1, [Defined if this module should be included])
fi
LIST_MEMBER(md2, $enabled_digests)
if test "$found" = "1" ; then
GCRYPT_DIGESTS="$GCRYPT_DIGESTS md2.lo"
AC_DEFINE(USE_MD2, 1, [Defined if this module should be included])
fi
LIST_MEMBER(md4, $enabled_digests)
if test "$found" = "1" ; then
GCRYPT_DIGESTS="$GCRYPT_DIGESTS md4.lo"
AC_DEFINE(USE_MD4, 1, [Defined if this module should be included])
fi
LIST_MEMBER(md5, $enabled_digests)
if test "$found" = "1" ; then
GCRYPT_DIGESTS="$GCRYPT_DIGESTS md5.lo"
AC_DEFINE(USE_MD5, 1, [Defined if this module should be included])
fi
LIST_MEMBER(rmd160, $enabled_digests)
if test "$found" = "1" ; then
GCRYPT_DIGESTS="$GCRYPT_DIGESTS rmd160.lo"
AC_DEFINE(USE_RMD160, 1, [Defined if this module should be included])
fi
LIST_MEMBER(sha256, $enabled_digests)
if test "$found" = "1" ; then
GCRYPT_DIGESTS="$GCRYPT_DIGESTS sha256.lo"
AC_DEFINE(USE_SHA256, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha256-ssse3-amd64.lo"
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha256-avx-amd64.lo"
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha256-avx2-bmi2-amd64.lo"
;;
arm*-*-*)
# Build with the assembly implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha256-armv8-aarch32-ce.lo"
;;
aarch64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha256-armv8-aarch64-ce.lo"
;;
powerpc64le-*-*)
# Build with the crypto extension implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha256-ppc.lo"
;;
powerpc64-*-*)
# Big-Endian.
# Build with the crypto extension implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha256-ppc.lo"
;;
powerpc-*-*)
# Big-Endian.
# Build with the crypto extension implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha256-ppc.lo"
esac
case "$mpi_cpu_arch" in
x86)
# Build with the SHAEXT implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha256-intel-shaext.lo"
;;
esac
fi
LIST_MEMBER(sha512, $enabled_digests)
if test "$found" = "1" ; then
GCRYPT_DIGESTS="$GCRYPT_DIGESTS sha512.lo"
AC_DEFINE(USE_SHA512, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha512-ssse3-amd64.lo"
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha512-avx-amd64.lo"
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha512-avx2-bmi2-amd64.lo"
;;
i?86-*-*)
# Build with the assembly implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha512-ssse3-i386.lo"
;;
arm*-*-*)
# Build with the assembly implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha512-arm.lo"
;;
powerpc64le-*-*)
# Build with the crypto extension implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha512-ppc.lo"
;;
powerpc64-*-*)
# Big-Endian.
# Build with the crypto extension implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha512-ppc.lo"
;;
powerpc-*-*)
# Big-Endian.
# Build with the crypto extension implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha512-ppc.lo"
esac
if test x"$neonsupport" = xyes ; then
# Build with the NEON implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha512-armv7-neon.lo"
fi
fi
LIST_MEMBER(sha3, $enabled_digests)
if test "$found" = "1" ; then
GCRYPT_DIGESTS="$GCRYPT_DIGESTS keccak.lo"
AC_DEFINE(USE_SHA3, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the assembly implementation
:
;;
esac
if test x"$neonsupport" = xyes ; then
# Build with the NEON implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS keccak-armv7-neon.lo"
fi
fi
LIST_MEMBER(tiger, $enabled_digests)
if test "$found" = "1" ; then
GCRYPT_DIGESTS="$GCRYPT_DIGESTS tiger.lo"
AC_DEFINE(USE_TIGER, 1, [Defined if this module should be included])
fi
LIST_MEMBER(whirlpool, $enabled_digests)
if test "$found" = "1" ; then
GCRYPT_DIGESTS="$GCRYPT_DIGESTS whirlpool.lo"
AC_DEFINE(USE_WHIRLPOOL, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS whirlpool-sse2-amd64.lo"
;;
esac
fi
LIST_MEMBER(blake2, $enabled_digests)
if test "$found" = "1" ; then
GCRYPT_DIGESTS="$GCRYPT_DIGESTS blake2.lo"
AC_DEFINE(USE_BLAKE2, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS blake2b-amd64-avx2.lo"
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS blake2s-amd64-avx.lo"
;;
esac
fi
LIST_MEMBER(sm3, $enabled_digests)
if test "$found" = "1" ; then
GCRYPT_DIGESTS="$GCRYPT_DIGESTS sm3.lo"
AC_DEFINE(USE_SM3, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sm3-avx-bmi2-amd64.lo"
;;
esac
fi
# SHA-1 needs to be included always for example because it is used by
# random-csprng.c.
GCRYPT_DIGESTS="$GCRYPT_DIGESTS sha1.lo"
AC_DEFINE(USE_SHA1, 1, [Defined if this module should be included])
case "${host}" in
x86_64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha1-ssse3-amd64.lo"
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha1-avx-amd64.lo"
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha1-avx-bmi2-amd64.lo"
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha1-avx2-bmi2-amd64.lo"
;;
arm*-*-*)
# Build with the assembly implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha1-armv7-neon.lo"
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha1-armv8-aarch32-ce.lo"
;;
aarch64-*-*)
# Build with the assembly implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha1-armv8-aarch64-ce.lo"
;;
esac
case "$mpi_cpu_arch" in
x86)
# Build with the SHAEXT implementation
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS sha1-intel-shaext.lo"
;;
esac
# Arch specific GCM implementations
case "${host}" in
i?86-*-* | x86_64-*-*)
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS cipher-gcm-intel-pclmul.lo"
;;
arm*-*-*)
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS cipher-gcm-armv7-neon.lo"
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS cipher-gcm-armv8-aarch32-ce.lo"
;;
aarch64-*-*)
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS cipher-gcm-armv8-aarch64-ce.lo"
;;
powerpc64le-*-* | powerpc64-*-* | powerpc-*-*)
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS cipher-gcm-ppc.lo"
;;
esac
# Arch specific MAC implementations
case "${host}" in
s390x-*-*)
GCRYPT_ASM_DIGESTS="$GCRYPT_ASM_DIGESTS poly1305-s390x.lo"
;;
esac
LIST_MEMBER(scrypt, $enabled_kdfs)
if test "$found" = "1" ; then
GCRYPT_KDFS="$GCRYPT_KDFS scrypt.lo"
AC_DEFINE(USE_SCRYPT, 1, [Defined if this module should be included])
fi
LIST_MEMBER(getentropy, $random_modules)
if test "$found" = "1" ; then
GCRYPT_RANDOM="$GCRYPT_RANDOM rndgetentropy.lo"
AC_DEFINE(USE_RNDGETENTROPY, 1, [Defined if the getentropy RNG should be used.])
fi
LIST_MEMBER(linux, $random_modules)
if test "$found" = "1" ; then
GCRYPT_RANDOM="$GCRYPT_RANDOM rndlinux.lo"
AC_DEFINE(USE_RNDLINUX, 1, [Defined if the /dev/random RNG should be used.])
fi
LIST_MEMBER(unix, $random_modules)
if test "$found" = "1" ; then
GCRYPT_RANDOM="$GCRYPT_RANDOM rndunix.lo"
AC_DEFINE(USE_RNDUNIX, 1, [Defined if the default Unix RNG should be used.])
fi
LIST_MEMBER(egd, $random_modules)
if test "$found" = "1" ; then
GCRYPT_RANDOM="$GCRYPT_RANDOM rndegd.lo"
AC_DEFINE(USE_RNDEGD, 1, [Defined if the EGD based RNG should be used.])
fi
LIST_MEMBER(w32, $random_modules)
if test "$found" = "1" ; then
GCRYPT_RANDOM="$GCRYPT_RANDOM rndw32.lo"
AC_DEFINE(USE_RNDW32, 1,
[Defined if the Windows specific RNG should be used.])
fi
LIST_MEMBER(w32ce, $random_modules)
if test "$found" = "1" ; then
GCRYPT_RANDOM="$GCRYPT_RANDOM rndw32ce.lo"
AC_DEFINE(USE_RNDW32CE, 1,
[Defined if the WindowsCE specific RNG should be used.])
fi
if test "$try_asm_modules" = yes ; then
# Build with assembly implementations
GCRYPT_CIPHERS="$GCRYPT_CIPHERS $GCRYPT_ASM_CIPHERS"
GCRYPT_DIGESTS="$GCRYPT_DIGESTS $GCRYPT_ASM_DIGESTS"
fi
AC_SUBST([GCRYPT_CIPHERS])
AC_SUBST([GCRYPT_PUBKEY_CIPHERS])
AC_SUBST([GCRYPT_DIGESTS])
AC_SUBST([GCRYPT_KDFS])
AC_SUBST([GCRYPT_RANDOM])
AC_SUBST(LIBGCRYPT_CIPHERS, $enabled_ciphers)
AC_SUBST(LIBGCRYPT_PUBKEY_CIPHERS, $enabled_pubkey_ciphers)
AC_SUBST(LIBGCRYPT_DIGESTS, $enabled_digests)
# For printing the configuration we need a colon separated list of
# algorithm names.
tmp=`echo "$enabled_ciphers" | tr ' ' : `
AC_DEFINE_UNQUOTED(LIBGCRYPT_CIPHERS, "$tmp",
[List of available cipher algorithms])
tmp=`echo "$enabled_pubkey_ciphers" | tr ' ' : `
AC_DEFINE_UNQUOTED(LIBGCRYPT_PUBKEY_CIPHERS, "$tmp",
[List of available public key cipher algorithms])
tmp=`echo "$enabled_digests" | tr ' ' : `
AC_DEFINE_UNQUOTED(LIBGCRYPT_DIGESTS, "$tmp",
[List of available digest algorithms])
tmp=`echo "$enabled_kdfs" | tr ' ' : `
AC_DEFINE_UNQUOTED(LIBGCRYPT_KDFS, "$tmp",
[List of available KDF algorithms])
#
# Define conditional sources depending on the used hardware platform.
# Note that all possible modules must also be listed in
# src/Makefile.am (EXTRA_libgcrypt_la_SOURCES).
#
GCRYPT_HWF_MODULES=
case "$mpi_cpu_arch" in
x86)
AC_DEFINE(HAVE_CPU_ARCH_X86, 1, [Defined for the x86 platforms])
GCRYPT_HWF_MODULES="libgcrypt_la-hwf-x86.lo"
;;
alpha)
AC_DEFINE(HAVE_CPU_ARCH_ALPHA, 1, [Defined for Alpha platforms])
;;
sparc)
AC_DEFINE(HAVE_CPU_ARCH_SPARC, 1, [Defined for SPARC platforms])
;;
mips)
AC_DEFINE(HAVE_CPU_ARCH_MIPS, 1, [Defined for MIPS platforms])
;;
m68k)
AC_DEFINE(HAVE_CPU_ARCH_M68K, 1, [Defined for M68k platforms])
;;
ppc)
AC_DEFINE(HAVE_CPU_ARCH_PPC, 1, [Defined for PPC platforms])
GCRYPT_HWF_MODULES="libgcrypt_la-hwf-ppc.lo"
;;
arm)
AC_DEFINE(HAVE_CPU_ARCH_ARM, 1, [Defined for ARM platforms])
GCRYPT_HWF_MODULES="libgcrypt_la-hwf-arm.lo"
;;
aarch64)
AC_DEFINE(HAVE_CPU_ARCH_ARM, 1, [Defined for ARM AArch64 platforms])
GCRYPT_HWF_MODULES="libgcrypt_la-hwf-arm.lo"
;;
s390x)
AC_DEFINE(HAVE_CPU_ARCH_S390X, 1, [Defined for s390x/zSeries platforms])
GCRYPT_HWF_MODULES="libgcrypt_la-hwf-s390x.lo"
;;
esac
AC_SUBST([GCRYPT_HWF_MODULES])
#
# Option to disable building of doc file
#
build_doc=yes
AC_ARG_ENABLE([doc], AS_HELP_STRING([--disable-doc],
[do not build the documentation]),
build_doc=$enableval, build_doc=yes)
AM_CONDITIONAL([BUILD_DOC], [test "x$build_doc" != xno])
#
# Provide information about the build.
#
BUILD_REVISION="mym4_revision"
AC_SUBST(BUILD_REVISION)
AC_DEFINE_UNQUOTED(BUILD_REVISION, "$BUILD_REVISION",
[GIT commit id revision used to build this package])
changequote(,)dnl
BUILD_VERSION=`echo "$PACKAGE_VERSION" | sed 's/\([0-9.]*\).*/\1./'`
changequote([,])dnl
BUILD_VERSION="${BUILD_VERSION}mym4_revision_dec"
BUILD_FILEVERSION=`echo "${BUILD_VERSION}" | tr . ,`
AC_SUBST(BUILD_VERSION)
AC_SUBST(BUILD_FILEVERSION)
AC_ARG_ENABLE([build-timestamp],
AS_HELP_STRING([--enable-build-timestamp],
[set an explicit build timestamp for reproducibility.
(default is the current time in ISO-8601 format)]),
[if test "$enableval" = "yes"; then
BUILD_TIMESTAMP=`date -u +%Y-%m-%dT%H:%M+0000 2>/dev/null || date`
else
BUILD_TIMESTAMP="$enableval"
fi],
[BUILD_TIMESTAMP=""])
AC_SUBST(BUILD_TIMESTAMP)
AC_DEFINE_UNQUOTED(BUILD_TIMESTAMP, "$BUILD_TIMESTAMP",
[The time this package was configured for a build])
# And create the files.
AC_CONFIG_FILES([
Makefile
m4/Makefile
compat/Makefile
mpi/Makefile
cipher/Makefile
random/Makefile
doc/Makefile
src/Makefile
src/gcrypt.h
src/libgcrypt-config
src/libgcrypt.pc
src/versioninfo.rc
tests/Makefile
])
AC_CONFIG_FILES([tests/hashtest-256g], [chmod +x tests/hashtest-256g])
AC_CONFIG_FILES([tests/basic-disable-all-hwf], [chmod +x tests/basic-disable-all-hwf])
AC_OUTPUT
detection_module="${GCRYPT_HWF_MODULES%.lo}"
test -n "$detection_module" || detection_module="none"
# Give some feedback
GCRY_MSG_SHOW([],[])
GCRY_MSG_SHOW([Libgcrypt],[v${VERSION} has been configured as follows:])
GCRY_MSG_SHOW([],[])
GCRY_MSG_SHOW([Platform: ],[$PRINTABLE_OS_NAME ($host)])
GCRY_MSG_SHOW([Hardware detection module:],[$detection_module])
GCRY_MSG_WRAP([Enabled cipher algorithms:],[$enabled_ciphers])
GCRY_MSG_WRAP([Enabled digest algorithms:],[$enabled_digests])
GCRY_MSG_WRAP([Enabled kdf algorithms: ],[$enabled_kdfs])
GCRY_MSG_WRAP([Enabled pubkey algorithms:],[$enabled_pubkey_ciphers])
GCRY_MSG_SHOW([Random number generator: ],[$random])
GCRY_MSG_SHOW([Try using jitter entropy: ],[$jentsupport])
GCRY_MSG_SHOW([Using linux capabilities: ],[$use_capabilities])
GCRY_MSG_SHOW([FIPS module version: ],[$fips_module_version])
GCRY_MSG_SHOW([Try using Padlock crypto: ],[$padlocksupport])
GCRY_MSG_SHOW([Try using AES-NI crypto: ],[$aesnisupport])
GCRY_MSG_SHOW([Try using Intel SHAEXT: ],[$shaextsupport])
GCRY_MSG_SHOW([Try using Intel PCLMUL: ],[$pclmulsupport])
GCRY_MSG_SHOW([Try using Intel SSE4.1: ],[$sse41support])
GCRY_MSG_SHOW([Try using DRNG (RDRAND): ],[$drngsupport])
GCRY_MSG_SHOW([Try using Intel AVX: ],[$avxsupport])
GCRY_MSG_SHOW([Try using Intel AVX2: ],[$avx2support])
GCRY_MSG_SHOW([Try using ARM NEON: ],[$neonsupport])
GCRY_MSG_SHOW([Try using ARMv8 crypto: ],[$armcryptosupport])
GCRY_MSG_SHOW([Try using PPC crypto: ],[$ppccryptosupport])
GCRY_MSG_SHOW([],[])
if test "x${gpg_config_script_warn}" != x; then
cat <.
*/
/*
This random number generator is modelled after the one described in
Peter Gutmann's 1998 Usenix Security Symposium paper: "Software
Generation of Practically Strong Random Numbers". See also chapter
6 in his book "Cryptographic Security Architecture", New York,
2004, ISBN 0-387-95387-6.
Note that the acronym CSPRNG stands for "Continuously Seeded
PseudoRandom Number Generator" as used in Peter's implementation of
the paper and not only for "Cryptographically Secure PseudoRandom
Number Generator".
*/
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#ifdef HAVE_GETHRTIME
#include
#endif
#ifdef HAVE_GETTIMEOFDAY
#include
#endif
#ifdef HAVE_GETRUSAGE
#include
#endif
#ifdef __MINGW32__
#include
#endif
#ifdef HAVE_W32_SYSTEM
#include
#endif
#include "g10lib.h"
#include "random.h"
#include "rand-internal.h"
#include "cipher.h" /* _gcry_sha1_hash_buffer */
#include "../cipher/sha1.h" /* _gcry_sha1_mixblock */
#ifndef RAND_MAX /* For SunOS. */
#define RAND_MAX 32767
#endif
/* Check whether we can lock the seed file read write. */
#if defined(HAVE_FCNTL) && defined(HAVE_FTRUNCATE) && !defined(HAVE_W32_SYSTEM)
#define LOCK_SEED_FILE 1
#else
#define LOCK_SEED_FILE 0
#endif
/* Define the constant we use for transforming the pool at read-out. */
#if SIZEOF_UNSIGNED_LONG == 8
#define ADD_VALUE 0xa5a5a5a5a5a5a5a5
#elif SIZEOF_UNSIGNED_LONG == 4
#define ADD_VALUE 0xa5a5a5a5
#else
#error weird size for an unsigned long
#endif
/* Contstants pertaining to the hash pool. */
#define BLOCKLEN 64 /* Hash this amount of bytes... */
#define DIGESTLEN 20 /* ... into a digest of this length (sha-1). */
/* POOLBLOCKS is the number of digests which make up the pool. */
#define POOLBLOCKS 30
/* POOLSIZE must be a multiple of the digest length to make the AND
operations faster, the size should also be a multiple of unsigned
long. */
#define POOLSIZE (POOLBLOCKS*DIGESTLEN)
#if (POOLSIZE % SIZEOF_UNSIGNED_LONG)
#error Please make sure that poolsize is a multiple of unsigned long
#endif
#define POOLWORDS (POOLSIZE / SIZEOF_UNSIGNED_LONG)
/* RNDPOOL is the pool we use to collect the entropy and to stir it
up. Its allocated size is POOLSIZE+BLOCKLEN. Note that this is
also an indication on whether the module has been fully
initialized. */
static unsigned char *rndpool;
/* KEYPOOL is used as a scratch copy to read out random from RNDPOOL.
Its allocated size is also POOLSIZE+BLOCKLEN. */
static unsigned char *keypool;
/* This is the offset into RNDPOOL where the next random bytes are to
be mixed in. */
static size_t pool_writepos;
/* When reading data out of KEYPOOL, we start the read at different
positions. This variable keeps track on where to read next. */
static size_t pool_readpos;
/* This flag is set to true as soon as the pool has been completely
filled the first time. This may happen either by reading a seed
file or by adding enough entropy. */
static int pool_filled;
/* This counter is used to track whether the initial seeding has been
done with enough bytes from a reliable entropy source. */
static size_t pool_filled_counter;
/* If random of level GCRY_VERY_STRONG_RANDOM has been requested we
have stricter requirements on what kind of entropy is in the pool.
In particular POOL_FILLED is not sufficient. Thus we add some
extra seeding and set this flag to true if the extra seeding has
been done. */
static int did_initial_extra_seeding;
/* This variable is used to estimated the amount of fresh entropy
available in RNDPOOL. */
static int pool_balance;
/* After a mixing operation this variable will be set to true and
cleared if new entropy has been added or a remix is required for
other reasons. */
static int just_mixed;
/* The name of the seed file or NULL if no seed file has been defined.
The seed file needs to be registered at initialization time. We
keep a malloced copy here. */
static char *seed_file_name;
/* If a seed file has been registered and maybe updated on exit this
flag set. */
static int allow_seed_file_update;
/* Option flag set at initialiation time to force allocation of the
pool in secure memory. */
static int secure_alloc;
/* This function pointer is set to the actual entropy gathering
function during initialization. After initialization it is
guaranteed to point to function. (On systems without a random
gatherer module a dummy function is used).*/
static int (*slow_gather_fnc)(void (*)(const void*, size_t,
enum random_origins),
enum random_origins, size_t, int);
/* This function is set to the actual fast entropy gathering function
during initialization. If it is NULL, no such function is
available. */
static void (*fast_gather_fnc)(void (*)(const void*, size_t,
enum random_origins),
enum random_origins);
/* Option flag useful for debugging and the test suite. If set
requests for very strong random are degraded to strong random. Not
used by regular applications. */
static int quick_test;
/* This is the lock we use to protect all pool operations. */
GPGRT_LOCK_DEFINE (pool_lock);
/* This is a helper for assert calls. These calls are used to assert
that functions are called in a locked state. It is not meant to be
thread-safe but as a method to get aware of missing locks in the
test suite. */
static int pool_is_locked;
/* We keep some counters in this structure for the sake of the
_gcry_random_dump_stats () function. */
static struct
{
unsigned long mixrnd;
unsigned long mixkey;
unsigned long slowpolls;
unsigned long fastpolls;
unsigned long getbytes1;
unsigned long ngetbytes1;
unsigned long getbytes2;
unsigned long ngetbytes2;
unsigned long addbytes;
unsigned long naddbytes;
} rndstats;
/* --- Prototypes --- */
static void read_pool (byte *buffer, size_t length, int level );
static void add_randomness (const void *buffer, size_t length,
enum random_origins origin);
static void random_poll (void);
static void do_fast_random_poll (void);
static int (*getfnc_gather_random (void))(void (*)(const void*, size_t,
enum random_origins),
enum random_origins, size_t, int);
static void (*getfnc_fast_random_poll (void))(void (*)(const void*, size_t,
enum random_origins),
enum random_origins);
static void read_random_source (enum random_origins origin,
size_t length, int level);
�
/* --- Functions --- */
/* Basic initialization which is required to initialize mutexes and
such. It does not run a full initialization so that the filling of
the random pool can be delayed until it is actually needed. We
assume that this function is used before any concurrent access
happens. */
static void
initialize_basics(void)
{
static int initialized;
if (!initialized)
{
initialized = 1;
-#ifdef USE_RANDOM_DAEMON
- _gcry_daemon_initialize_basics ();
-#endif /*USE_RANDOM_DAEMON*/
-
/* Make sure that we are still using the values we have
traditionally used for the random levels. */
gcry_assert (GCRY_WEAK_RANDOM == 0
&& GCRY_STRONG_RANDOM == 1
&& GCRY_VERY_STRONG_RANDOM == 2);
}
}
/* Take the pool lock. */
static void
lock_pool (void)
{
int err;
err = gpgrt_lock_lock (&pool_lock);
if (err)
log_fatal ("failed to acquire the pool lock: %s\n", gpg_strerror (err));
pool_is_locked = 1;
}
/* Release the pool lock. */
static void
unlock_pool (void)
{
int err;
pool_is_locked = 0;
err = gpgrt_lock_unlock (&pool_lock);
if (err)
log_fatal ("failed to release the pool lock: %s\n", gpg_strerror (err));
}
/* Full initialization of this module. */
static void
initialize(void)
{
/* Although the basic initialization should have happened already,
we call it here to make sure that all prerequisites are met. */
initialize_basics ();
/* Now we can look the pool and complete the initialization if
necessary. */
lock_pool ();
if (!rndpool)
{
/* The data buffer is allocated somewhat larger, so that we can
use this extra space (which is allocated in secure memory) as
a temporary hash buffer */
rndpool = (secure_alloc
? xcalloc_secure (1, POOLSIZE + BLOCKLEN)
: xcalloc (1, POOLSIZE + BLOCKLEN));
keypool = (secure_alloc
? xcalloc_secure (1, POOLSIZE + BLOCKLEN)
: xcalloc (1, POOLSIZE + BLOCKLEN));
/* Setup the slow entropy gathering function. The code requires
that this function exists. */
slow_gather_fnc = getfnc_gather_random ();
/* Setup the fast entropy gathering function. */
fast_gather_fnc = getfnc_fast_random_poll ();
}
unlock_pool ();
}
/* Initialize this random subsystem. If FULL is false, this function
merely calls the initialize and does not do anything more. Doing
this is not really required but when running in a threaded
environment we might get a race condition otherwise. */
void
_gcry_rngcsprng_initialize (int full)
{
if (!full)
initialize_basics ();
else
initialize ();
}
/* Try to close the FDs of the random gather module. This is
currently only implemented for rndlinux. */
void
_gcry_rngcsprng_close_fds (void)
{
lock_pool ();
#if USE_RNDGETENTROPY
_gcry_rndgetentropy_gather_random (NULL, 0, 0, 0);
#endif
#if USE_RNDLINUX
_gcry_rndlinux_gather_random (NULL, 0, 0, 0);
#endif
pool_writepos = 0;
pool_readpos = 0;
pool_filled = 0;
pool_filled_counter = 0;
did_initial_extra_seeding = 0;
pool_balance = 0;
just_mixed = 0;
xfree (rndpool);
xfree (keypool);
rndpool = NULL;
keypool = NULL;
unlock_pool ();
}
void
_gcry_rngcsprng_dump_stats (void)
{
/* In theory we would need to lock the stats here. However this
function is usually called during cleanup and then we _might_ run
into problems. */
log_info ("random usage: poolsize=%d mixed=%lu polls=%lu/%lu added=%lu/%lu\n"
" outmix=%lu getlvl1=%lu/%lu getlvl2=%lu/%lu%s\n",
POOLSIZE, rndstats.mixrnd, rndstats.slowpolls, rndstats.fastpolls,
rndstats.naddbytes, rndstats.addbytes,
rndstats.mixkey, rndstats.ngetbytes1, rndstats.getbytes1,
rndstats.ngetbytes2, rndstats.getbytes2,
_gcry_rndhw_failed_p()? " (hwrng failed)":"");
}
/* This function should be called during initialization and before
initialization of this module to place the random pools into secure
memory. */
void
_gcry_rngcsprng_secure_alloc (void)
{
secure_alloc = 1;
}
/* This may be called before full initialization to degrade the
quality of the RNG for the sake of a faster running test suite. */
void
_gcry_rngcsprng_enable_quick_gen (void)
{
quick_test = 1;
}
/* This function returns true if no real RNG is available or the
quality of the RNG has been degraded for test purposes. */
int
_gcry_rngcsprng_is_faked (void)
{
/* We need to initialize due to the runtime determination of
available entropy gather modules. */
initialize();
return quick_test;
}
/* Add BUFLEN bytes from BUF to the internal random pool. QUALITY
should be in the range of 0..100 to indicate the goodness of the
entropy added, or -1 for goodness not known. */
gcry_error_t
_gcry_rngcsprng_add_bytes (const void *buf, size_t buflen, int quality)
{
size_t nbytes;
const char *bufptr;
if (quality == -1)
quality = 35;
else if (quality > 100)
quality = 100;
else if (quality < 0)
quality = 0;
if (!buf)
return gpg_error (GPG_ERR_INV_ARG);
if (!buflen || quality < 10)
return 0; /* Take a shortcut. */
/* Because we don't increment the entropy estimation with FASTPOLL,
we don't need to take lock that estimation while adding from an
external source. This limited entropy estimation also means that
we can't take QUALITY into account. */
initialize_basics ();
bufptr = buf;
while (buflen)
{
nbytes = buflen > POOLSIZE? POOLSIZE : buflen;
lock_pool ();
if (rndpool)
add_randomness (bufptr, nbytes, RANDOM_ORIGIN_EXTERNAL);
unlock_pool ();
bufptr += nbytes;
buflen -= nbytes;
}
return 0;
}
/* Public function to fill the buffer with LENGTH bytes of
cryptographically strong random bytes. Level GCRY_WEAK_RANDOM is
not very strong, GCRY_STRONG_RANDOM is strong enough for most
usage, GCRY_VERY_STRONG_RANDOM is good for key generation stuff but
may be very slow. */
void
_gcry_rngcsprng_randomize (void *buffer, size_t length,
enum gcry_random_level level)
{
unsigned char *p;
/* Make sure we are initialized. */
initialize ();
/* Handle our hack used for regression tests of Libgcrypt. */
if ( quick_test && level > GCRY_STRONG_RANDOM )
level = GCRY_STRONG_RANDOM;
/* Make sure the level is okay. */
level &= 3;
/* Acquire the pool lock. */
lock_pool ();
/* Update the statistics. */
if (level >= GCRY_VERY_STRONG_RANDOM)
{
rndstats.getbytes2 += length;
rndstats.ngetbytes2++;
}
else
{
rndstats.getbytes1 += length;
rndstats.ngetbytes1++;
}
/* Read the random into the provided buffer. */
for (p = buffer; length > 0;)
{
size_t n;
n = length > POOLSIZE? POOLSIZE : length;
read_pool (p, n, level);
length -= n;
p += n;
}
/* Release the pool lock. */
unlock_pool ();
}
/*
* Mix the 600 byte pool. Note that the 64 byte scratch area directly
* follows the pool. The numbers in the diagram give the number of
* bytes.
* <................600...............> <.64.>
* pool |------------------------------------| |------|
* <20><.24.> <20>
* | | +-----+
* +-----|-------------------------------|-+
* +-------------------------------|-|-+
* v v v
* |------|
*
* +---------------------------------------+
* v
* <20>
* pool' |------------------------------------|
* <20><20><.24.>
* +---|-----|---------------------------+
* +-----|---------------------------|-+
* +---------------------------|-|-+
* v v v
* |------|
*
* |
* +-----------------------------------+
* v
* <20>
* pool'' |------------------------------------|
* <20><20><20><.24.>
* +---|-----|-----------------------+
* +-----|-----------------------|-+
* +-----------------------|-|-+
* v v v
*
* and so on until we did this for all 30 blocks.
*
* To better protect against implementation errors in this code, we
* xor a digest of the entire pool into the pool before mixing.
*
* Note: this function must only be called with a locked pool.
*/
static void
mix_pool(unsigned char *pool)
{
static unsigned char failsafe_digest[DIGESTLEN];
static int failsafe_digest_valid;
unsigned char *hashbuf = pool + POOLSIZE;
unsigned char *p, *pend;
int i, n;
SHA1_CONTEXT md;
unsigned int nburn;
#if DIGESTLEN != 20
#error must have a digest length of 20 for SHA-1
#endif
gcry_assert (pool_is_locked);
_gcry_sha1_mixblock_init (&md);
/* pool_0 -> pool'. */
pend = pool + POOLSIZE;
memcpy (hashbuf, pend - DIGESTLEN, DIGESTLEN);
memcpy (hashbuf+DIGESTLEN, pool, BLOCKLEN-DIGESTLEN);
nburn = _gcry_sha1_mixblock (&md, hashbuf);
memcpy (pool, hashbuf, DIGESTLEN);
if (failsafe_digest_valid && pool == rndpool)
{
for (i=0; i < DIGESTLEN; i++)
pool[i] ^= failsafe_digest[i];
}
/* Loop for the remaining iterations. */
p = pool;
for (n=1; n < POOLBLOCKS; n++)
{
if (p + BLOCKLEN < pend)
memcpy (hashbuf, p, BLOCKLEN);
else
{
unsigned char *pp = p;
for (i=0; i < BLOCKLEN; i++ )
{
if ( pp >= pend )
pp = pool;
hashbuf[i] = *pp++;
}
}
_gcry_sha1_mixblock (&md, hashbuf);
p += DIGESTLEN;
memcpy (p, hashbuf, DIGESTLEN);
}
/* Our hash implementation does only leave small parts (64 bytes)
of the pool on the stack, so it is okay not to require secure
memory here. Before we use this pool, it will be copied to the
help buffer anyway. */
if ( pool == rndpool)
{
_gcry_sha1_hash_buffer (failsafe_digest, pool, POOLSIZE);
failsafe_digest_valid = 1;
}
_gcry_burn_stack (nburn);
}
void
_gcry_rngcsprng_set_seed_file (const char *name)
{
if (seed_file_name)
BUG ();
seed_file_name = xstrdup (name);
}
/* Helper for my_open.
* Return a malloced wide char string from an UTF-8 encoded input
* string STRING. Caller must free this value. Returns NULL and sets
* ERRNO on failure. Calling this function with STRING set to NULL is
* not defined. */
#ifdef HAVE_W32_SYSTEM
static wchar_t *
utf8_to_wchar (const char *string)
{
int n;
size_t nbytes;
wchar_t *result;
n = MultiByteToWideChar (CP_UTF8, 0, string, -1, NULL, 0);
if (n < 0)
{
gpg_err_set_errno (EINVAL);
return NULL;
}
nbytes = (size_t)(n+1) * sizeof(*result);
if (nbytes / sizeof(*result) != (n+1))
{
gpg_err_set_errno (ENOMEM);
return NULL;
}
result = xtrymalloc (nbytes);
if (!result)
return NULL;
n = MultiByteToWideChar (CP_UTF8, 0, string, -1, result, n);
if (n < 0)
{
xfree (result);
gpg_err_set_errno (EINVAL);
result = NULL;
}
return result;
}
#endif /*HAVE_W32_SYSTEM*/
/* Helper for my_open. */
#ifdef HAVE_W32_SYSTEM
static int
any8bitchar (const char *string)
{
if (string)
for ( ; *string; string++)
if ((*string & 0x80))
return 1;
return 0;
}
#endif /*HAVE_W32_SYSTEM*/
/* A wrapper around open to handle Unicode file names under Windows. */
static int
my_open (const char *name, int flags, unsigned int mode)
{
#ifdef HAVE_W32_SYSTEM
if (any8bitchar (name))
{
wchar_t *wname;
int ret;
wname = utf8_to_wchar (name);
if (!wname)
return -1;
ret = _wopen (wname, flags, mode);
xfree (wname);
return ret;
}
else
return open (name, flags, mode);
#else
return open (name, flags, mode);
#endif
}
/* Lock an open file identified by file descriptor FD and wait a
reasonable time to succeed. With FOR_WRITE set to true a write
lock will be taken. FNAME is used only for diagnostics. Returns 0
on success or -1 on error. */
static int
lock_seed_file (int fd, const char *fname, int for_write)
{
#ifdef __GCC__
#warning Check whether we can lock on Windows.
#endif
#if LOCK_SEED_FILE
struct flock lck;
struct timeval tv;
int backoff=0;
/* We take a lock on the entire file. */
memset (&lck, 0, sizeof lck);
lck.l_type = for_write? F_WRLCK : F_RDLCK;
lck.l_whence = SEEK_SET;
while (fcntl (fd, F_SETLK, &lck) == -1)
{
if (errno != EAGAIN && errno != EACCES)
{
log_info (_("can't lock `%s': %s\n"), fname, strerror (errno));
return -1;
}
if (backoff > 2) /* Show the first message after ~2.25 seconds. */
log_info( _("waiting for lock on `%s'...\n"), fname);
tv.tv_sec = backoff;
tv.tv_usec = 250000;
select (0, NULL, NULL, NULL, &tv);
if (backoff < 10)
backoff++ ;
}
#else
(void)fd;
(void)fname;
(void)for_write;
#endif /*!LOCK_SEED_FILE*/
return 0;
}
/* Read in a seed from the random_seed file and return true if this
was successful.
Note: Multiple instances of applications sharing the same random
seed file can be started in parallel, in which case they will read
out the same pool and then race for updating it (the last update
overwrites earlier updates). They will differentiate only by the
weak entropy that is added in read_seed_file based on the PID and
clock, and up to 32 bytes from a non-blocking entropy source. The
consequence is that the output of these different instances is
correlated to some extent. In the perfect scenario, the attacker
can control (or at least guess) the PID and clock of the
application, and drain the system's entropy pool to reduce the "up
to 32 bytes" above to 0. Then the dependencies of the initial
states of the pools are completely known. */
static int
read_seed_file (void)
{
int fd;
struct stat sb;
unsigned char buffer[POOLSIZE];
int n;
gcry_assert (pool_is_locked);
if (!seed_file_name)
return 0;
#ifdef HAVE_DOSISH_SYSTEM
fd = my_open (seed_file_name, O_RDONLY | O_BINARY, 0);
#else
fd = my_open (seed_file_name, O_RDONLY, 0);
#endif
if( fd == -1 && errno == ENOENT)
{
allow_seed_file_update = 1;
return 0;
}
if (fd == -1 )
{
log_info(_("can't open `%s': %s\n"), seed_file_name, strerror(errno) );
return 0;
}
if (lock_seed_file (fd, seed_file_name, 0))
{
close (fd);
return 0;
}
if (fstat( fd, &sb ) )
{
log_info(_("can't stat `%s': %s\n"), seed_file_name, strerror(errno) );
close(fd);
return 0;
}
if (!S_ISREG(sb.st_mode) )
{
log_info(_("`%s' is not a regular file - ignored\n"), seed_file_name );
close(fd);
return 0;
}
if (!sb.st_size )
{
log_info(_("note: random_seed file is empty\n") );
close(fd);
allow_seed_file_update = 1;
return 0;
}
if (sb.st_size != POOLSIZE )
{
log_info(_("warning: invalid size of random_seed file - not used\n") );
close(fd);
return 0;
}
do
{
n = read( fd, buffer, POOLSIZE );
}
while (n == -1 && errno == EINTR );
if (n != POOLSIZE)
{
log_fatal(_("can't read `%s': %s\n"), seed_file_name,strerror(errno) );
close(fd);/*NOTREACHED*/
return 0;
}
close(fd);
add_randomness( buffer, POOLSIZE, RANDOM_ORIGIN_INIT );
/* add some minor entropy to the pool now (this will also force a mixing) */
{
pid_t x = getpid();
add_randomness( &x, sizeof(x), RANDOM_ORIGIN_INIT );
}
{
time_t x = time(NULL);
add_randomness( &x, sizeof(x), RANDOM_ORIGIN_INIT );
}
{
clock_t x = clock();
add_randomness( &x, sizeof(x), RANDOM_ORIGIN_INIT );
}
/* And read a few bytes from our entropy source. If we have the
* Jitter RNG we can fast get a lot of entropy. Thus we read 1024
* bits from that source.
*
* Without the Jitter RNG we keep the old method of reading only a
* few bytes usually from /dev/urandom which won't block. */
if (_gcry_rndjent_get_version (NULL))
read_random_source (RANDOM_ORIGIN_INIT, 128, GCRY_STRONG_RANDOM);
else
read_random_source (RANDOM_ORIGIN_INIT, 32, GCRY_STRONG_RANDOM);
allow_seed_file_update = 1;
return 1;
}
void
_gcry_rngcsprng_update_seed_file (void)
{
unsigned long *sp, *dp;
int fd, i;
/* We do only a basic initialization so that we can lock the pool.
This is required to cope with the case that this function is
called by some cleanup code at a point where the RNG has never
been initialized. */
initialize_basics ();
lock_pool ();
if ( !seed_file_name || !rndpool || !pool_filled )
{
unlock_pool ();
return;
}
if ( !allow_seed_file_update )
{
unlock_pool ();
log_info(_("note: random_seed file not updated\n"));
return;
}
/* At this point we know that there is something in the pool and
thus we can conclude that the pool has been fully initialized. */
/* Copy the entropy pool to a scratch pool and mix both of them. */
for (i=0,dp=(unsigned long*)(void*)keypool, sp=(unsigned long*)(void*)rndpool;
i < POOLWORDS; i++, dp++, sp++ )
{
*dp = *sp + ADD_VALUE;
}
mix_pool(rndpool); rndstats.mixrnd++;
mix_pool(keypool); rndstats.mixkey++;
#if defined(HAVE_DOSISH_SYSTEM) || defined(__CYGWIN__)
fd = my_open (seed_file_name, O_WRONLY|O_CREAT|O_TRUNC|O_BINARY,
S_IRUSR|S_IWUSR );
#else
# if LOCK_SEED_FILE
fd = my_open (seed_file_name, O_WRONLY|O_CREAT, S_IRUSR|S_IWUSR );
# else
fd = my_open (seed_file_name, O_WRONLY|O_CREAT|O_TRUNC, S_IRUSR|S_IWUSR );
# endif
#endif
if (fd == -1 )
log_info (_("can't create `%s': %s\n"), seed_file_name, strerror(errno) );
else if (lock_seed_file (fd, seed_file_name, 1))
{
close (fd);
}
#if LOCK_SEED_FILE
else if (ftruncate (fd, 0))
{
log_info(_("can't write `%s': %s\n"), seed_file_name, strerror(errno));
close (fd);
}
#endif /*LOCK_SEED_FILE*/
else
{
do
{
i = write (fd, keypool, POOLSIZE );
}
while (i == -1 && errno == EINTR);
if (i != POOLSIZE)
log_info (_("can't write `%s': %s\n"),seed_file_name, strerror(errno));
if (close(fd))
log_info (_("can't close `%s': %s\n"),seed_file_name, strerror(errno));
}
unlock_pool ();
}
/* Read random out of the pool. This function is the core of the
public random functions. Note that Level GCRY_WEAK_RANDOM is not
anymore handled special and in fact is an alias in the API for
level GCRY_STRONG_RANDOM. Must be called with the pool already
locked. */
static void
read_pool (byte *buffer, size_t length, int level)
{
int i;
unsigned long *sp, *dp;
/* The volatile is there to make sure the compiler does not optimize
the code away in case the getpid function is badly attributed.
Note that we keep a pid in a static variable as well as in a
stack based one; the latter is to detect ill behaving thread
libraries, ignoring the pool mutexes. */
static volatile pid_t my_pid = (pid_t)(-1);
volatile pid_t my_pid2;
gcry_assert (pool_is_locked);
retry:
/* Get our own pid, so that we can detect a fork. */
my_pid2 = getpid ();
if (my_pid == (pid_t)(-1))
my_pid = my_pid2;
if ( my_pid != my_pid2 )
{
/* We detected a plain fork; i.e. we are now the child. Update
the static pid and add some randomness. */
pid_t x;
my_pid = my_pid2;
x = my_pid;
add_randomness (&x, sizeof(x), RANDOM_ORIGIN_INIT);
just_mixed = 0; /* Make sure it will get mixed. */
}
gcry_assert (pool_is_locked);
/* Our code does not allow to extract more than POOLSIZE. Better
check it here. */
if (length > POOLSIZE)
{
log_bug("too many random bits requested\n");
}
if (!pool_filled)
{
if (read_seed_file() )
pool_filled = 1;
}
/* For level 2 quality (key generation) we always make sure that the
pool has been seeded enough initially. */
if (level == GCRY_VERY_STRONG_RANDOM && !did_initial_extra_seeding)
{
size_t needed;
pool_balance = 0;
needed = length - pool_balance;
if (needed < 16) /* At least 128 bits. */
needed = 16;
else if( needed > POOLSIZE )
BUG ();
read_random_source (RANDOM_ORIGIN_EXTRAPOLL, needed,
GCRY_VERY_STRONG_RANDOM);
pool_balance += needed;
did_initial_extra_seeding = 1;
}
/* For level 2 make sure that there is enough random in the pool. */
if (level == GCRY_VERY_STRONG_RANDOM && pool_balance < length)
{
size_t needed;
if (pool_balance < 0)
pool_balance = 0;
needed = length - pool_balance;
if (needed > POOLSIZE)
BUG ();
read_random_source (RANDOM_ORIGIN_EXTRAPOLL, needed,
GCRY_VERY_STRONG_RANDOM);
pool_balance += needed;
}
/* Make sure the pool is filled. */
while (!pool_filled)
random_poll();
/* Always do a fast random poll (we have to use the unlocked version). */
do_fast_random_poll();
/* Mix the pid in so that we for sure won't deliver the same random
after a fork. */
{
pid_t apid = my_pid;
add_randomness (&apid, sizeof (apid), RANDOM_ORIGIN_INIT);
}
/* Mix the pool (if add_randomness() didn't it). */
if (!just_mixed)
{
mix_pool(rndpool);
rndstats.mixrnd++;
}
/* Create a new pool. */
for(i=0,dp=(unsigned long*)(void*)keypool, sp=(unsigned long*)(void*)rndpool;
i < POOLWORDS; i++, dp++, sp++ )
*dp = *sp + ADD_VALUE;
/* Mix both pools. */
mix_pool(rndpool); rndstats.mixrnd++;
mix_pool(keypool); rndstats.mixkey++;
/* Read the requested data. We use a read pointer to read from a
different position each time. */
while (length--)
{
*buffer++ = keypool[pool_readpos++];
if (pool_readpos >= POOLSIZE)
pool_readpos = 0;
pool_balance--;
}
if (pool_balance < 0)
pool_balance = 0;
/* Clear the keypool. */
memset (keypool, 0, POOLSIZE);
/* We need to detect whether a fork has happened. A fork might have
an identical pool and thus the child and the parent could emit
the very same random number. This test here is to detect forks
in a multi-threaded process. It does not work with all thread
implementations in particular not with pthreads. However it is
good enough for GNU Pth. */
if ( getpid () != my_pid2 )
{
pid_t x = getpid();
add_randomness (&x, sizeof(x), RANDOM_ORIGIN_INIT);
just_mixed = 0; /* Make sure it will get mixed. */
my_pid = x; /* Also update the static pid. */
goto retry;
}
}
/* Add LENGTH bytes of randomness from buffer to the pool. ORIGIN is
used to specify the randomness origin. This is one of the
RANDOM_ORIGIN_* values. */
static void
add_randomness (const void *buffer, size_t length, enum random_origins origin)
{
const unsigned char *p = buffer;
size_t count = 0;
gcry_assert (pool_is_locked);
rndstats.addbytes += length;
rndstats.naddbytes++;
while (length-- )
{
rndpool[pool_writepos++] ^= *p++;
count++;
if (pool_writepos >= POOLSIZE )
{
/* It is possible that we are invoked before the pool is
filled using an unreliable origin of entropy, for example
the fast random poll. To avoid flagging the pool as
filled in this case, we track the initial filling state
separately. See also the remarks about the seed file. */
if (origin >= RANDOM_ORIGIN_SLOWPOLL && !pool_filled)
{
pool_filled_counter += count;
count = 0;
if (pool_filled_counter >= POOLSIZE)
pool_filled = 1;
}
pool_writepos = 0;
mix_pool(rndpool); rndstats.mixrnd++;
just_mixed = !length;
}
}
}
static void
random_poll()
{
rndstats.slowpolls++;
read_random_source (RANDOM_ORIGIN_SLOWPOLL, POOLSIZE/5, GCRY_STRONG_RANDOM);
}
/* Runtime determination of the slow entropy gathering module. */
static int (*
getfnc_gather_random (void))(void (*)(const void*, size_t,
enum random_origins),
enum random_origins, size_t, int)
{
int (*fnc)(void (*)(const void*, size_t, enum random_origins),
enum random_origins, size_t, int);
#if USE_RNDGETENTROPY
fnc = _gcry_rndgetentropy_gather_random;
return fnc;
#endif
#if USE_RNDLINUX
if ( !access (NAME_OF_DEV_RANDOM, R_OK)
&& !access (NAME_OF_DEV_URANDOM, R_OK))
{
fnc = _gcry_rndlinux_gather_random;
return fnc;
}
#endif
#if USE_RNDEGD
if ( _gcry_rndegd_connect_socket (1) != -1 )
{
fnc = _gcry_rndegd_gather_random;
return fnc;
}
#endif
#if USE_RNDUNIX
fnc = _gcry_rndunix_gather_random;
return fnc;
#endif
#if USE_RNDW32
fnc = _gcry_rndw32_gather_random;
return fnc;
#endif
#if USE_RNDW32CE
fnc = _gcry_rndw32ce_gather_random;
return fnc;
#endif
log_fatal (_("no entropy gathering module detected\n"));
return NULL; /*NOTREACHED*/
}
/* Runtime determination of the fast entropy gathering function.
(Currently a compile time method is used.) */
static void (*
getfnc_fast_random_poll (void))( void (*)(const void*, size_t,
enum random_origins),
enum random_origins)
{
#if USE_RNDW32
return _gcry_rndw32_gather_random_fast;
#endif
#if USE_RNDW32CE
return _gcry_rndw32ce_gather_random_fast;
#endif
return NULL;
}
static void
do_fast_random_poll (void)
{
gcry_assert (pool_is_locked);
rndstats.fastpolls++;
if (fast_gather_fnc)
fast_gather_fnc (add_randomness, RANDOM_ORIGIN_FASTPOLL);
/* Continue with the generic functions. */
#if HAVE_GETHRTIME
{
hrtime_t tv;
tv = gethrtime();
add_randomness( &tv, sizeof(tv), RANDOM_ORIGIN_FASTPOLL );
}
#elif HAVE_GETTIMEOFDAY
{
struct timeval tv;
if( gettimeofday( &tv, NULL ) )
BUG();
add_randomness( &tv.tv_sec, sizeof(tv.tv_sec), RANDOM_ORIGIN_FASTPOLL );
add_randomness( &tv.tv_usec, sizeof(tv.tv_usec), RANDOM_ORIGIN_FASTPOLL );
}
#elif HAVE_CLOCK_GETTIME
{ struct timespec tv;
if( clock_gettime( CLOCK_REALTIME, &tv ) == -1 )
BUG();
add_randomness( &tv.tv_sec, sizeof(tv.tv_sec), RANDOM_ORIGIN_FASTPOLL );
add_randomness( &tv.tv_nsec, sizeof(tv.tv_nsec), RANDOM_ORIGIN_FASTPOLL );
}
#else /* use times */
# ifndef HAVE_DOSISH_SYSTEM
{ struct tms buf;
times( &buf );
add_randomness( &buf, sizeof buf, RANDOM_ORIGIN_FASTPOLL );
}
# endif
#endif
#ifdef HAVE_GETRUSAGE
# ifdef RUSAGE_SELF
{
struct rusage buf;
/* QNX/Neutrino does return ENOSYS - so we just ignore it and add
whatever is in buf. In a chroot environment it might not work
at all (i.e. because /proc/ is not accessible), so we better
ignore all error codes and hope for the best. */
getrusage (RUSAGE_SELF, &buf );
add_randomness( &buf, sizeof buf, RANDOM_ORIGIN_FASTPOLL );
memset( &buf, 0, sizeof buf );
}
# else /*!RUSAGE_SELF*/
# ifdef __GCC__
# warning There is no RUSAGE_SELF on this system
# endif
# endif /*!RUSAGE_SELF*/
#endif /*HAVE_GETRUSAGE*/
/* Time and clock are available on all systems - so we better do it
just in case one of the above functions didn't work. */
{
time_t x = time(NULL);
add_randomness( &x, sizeof(x), RANDOM_ORIGIN_FASTPOLL );
}
{
clock_t x = clock();
add_randomness( &x, sizeof(x), RANDOM_ORIGIN_FASTPOLL );
}
/* If the system features a fast hardware RNG, read some bytes from
there. */
_gcry_rndhw_poll_fast (add_randomness, RANDOM_ORIGIN_FASTPOLL);
}
/* The fast random pool function as called at some places in
libgcrypt. This is merely a wrapper to make sure that this module
is initialized and to lock the pool. Note, that this function is a
NOP unless a random function has been used or _gcry_initialize (1)
has been used. We use this hack so that the internal use of this
function in cipher_open and md_open won't start filling up the
random pool, even if no random will be required by the process. */
void
_gcry_rngcsprng_fast_poll (void)
{
initialize_basics ();
lock_pool ();
if (rndpool)
{
/* Yes, we are fully initialized. */
do_fast_random_poll ();
}
unlock_pool ();
}
static void
read_random_source (enum random_origins origin, size_t length, int level)
{
if ( !slow_gather_fnc )
log_fatal ("Slow entropy gathering module not yet initialized\n");
if (slow_gather_fnc (add_randomness, origin, length, level) < 0)
log_fatal ("No way to gather entropy for the RNG\n");
}
diff --git a/random/random.h b/random/random.h
index caac4b64..eedf1d0f 100644
--- a/random/random.h
+++ b/random/random.h
@@ -1,77 +1,69 @@
/* random.h - random functions
* Copyright (C) 1998, 2002, 2006 Free Software Foundation, Inc.
*
* This file is part of Libgcrypt.
*
* Libgcrypt is free software; you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as
* published by the Free Software Foundation; either version 2.1 of
* the License, or (at your option) any later version.
*
* Libgcrypt is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA
*/
#ifndef G10_RANDOM_H
#define G10_RANDOM_H
#include "types.h"
#include "../src/gcrypt-testapi.h" /* struct gcry_drbg_test_vector */
/*-- random.c --*/
void _gcry_register_random_progress (void (*cb)(void *,const char*,int,int,int),
void *cb_data );
void _gcry_set_preferred_rng_type (int type);
void _gcry_random_initialize (int full);
void _gcry_random_close_fds (void);
int _gcry_get_rng_type (int ignore_fips_mode);
void _gcry_random_dump_stats(void);
void _gcry_secure_random_alloc(void);
void _gcry_enable_quick_random_gen (void);
int _gcry_random_is_faked(void);
void _gcry_set_random_seed_file (const char *name);
void _gcry_update_random_seed_file (void);
void _gcry_fast_random_poll( void );
gcry_err_code_t _gcry_random_init_external_test (void **r_context,
unsigned int flags,
const void *key,
size_t keylen,
const void *seed,
size_t seedlen,
const void *dt,
size_t dtlen);
gcry_err_code_t _gcry_random_run_external_test (void *context,
char *buffer, size_t buflen);
void _gcry_random_deinit_external_test (void *context);
/*-- random-drbg.c --*/
gpg_err_code_t _gcry_rngdrbg_reinit (const char *flagstr,
gcry_buffer_t *pers, int npers);
gpg_err_code_t _gcry_rngdrbg_cavs_test (struct gcry_drbg_test_vector *t,
unsigned char *buf);
gpg_err_code_t _gcry_rngdrbg_healthcheck_one (struct gcry_drbg_test_vector *t);
/*-- rndegd.c --*/
gpg_error_t _gcry_rndegd_set_socket_name (const char *name);
/*-- rndjent.c --*/
unsigned int _gcry_rndjent_get_version (int *r_active);
-/*-- random-daemon.c (only used from random.c) --*/
-#ifdef USE_RANDOM_DAEMON
-void _gcry_daemon_initialize_basics (void);
-int _gcry_daemon_randomize (const char *socketname,
- void *buffer, size_t length,
- enum gcry_random_level level);
-#endif /*USE_RANDOM_DAEMON*/
-
#endif /*G10_RANDOM_H*/