From 096441298ecd1c123f1d37c2b34d6b6bb3c42e93 Mon Sep 17 00:00:00 2001 From: Manjunath S Matti Date: Thu, 14 Sep 2023 06:15:57 -0500 Subject: [PATCH 1/5] Preparation for Power optimizations Optimized functions for Power will make use of GNU indirect functions, an extension to support different implementations of the same function, which can be selected during runtime. This will be used to provide optimized functions for different processor versions. Since this is a GNU extension, we placed the definition of the Z_IFUNC macro under `contrib/gcc`. This can be reused by other archs as well. Author: Matheus Castanho Author: Rogerio Alves Signed-off-by: Manjunath Matti --- CMakeLists.txt | 71 ++++++++++++++++++++++++++++++++++++++++++ configure | 66 +++++++++++++++++++++++++++++++++++++++ contrib/README.contrib | 8 +++++ contrib/gcc/zifunc.h | 60 +++++++++++++++++++++++++++++++++++ contrib/power/power.h | 4 +++ 5 files changed, 209 insertions(+) create mode 100644 contrib/gcc/zifunc.h create mode 100644 contrib/power/power.h Index: zlib-1.3.1/CMakeLists.txt =================================================================== --- zlib-1.3.1.orig/CMakeLists.txt +++ zlib-1.3.1/CMakeLists.txt @@ -7,6 +7,8 @@ set(VERSION "1.3.1") option(ZLIB_BUILD_EXAMPLES "Enable Zlib Examples" ON) +option(POWER "Enable building power implementation") + set(INSTALL_BIN_DIR "${CMAKE_INSTALL_PREFIX}/bin" CACHE PATH "Installation directory for executables") set(INSTALL_LIB_DIR "${CMAKE_INSTALL_PREFIX}/lib" CACHE PATH "Installation directory for libraries") set(INSTALL_INC_DIR "${CMAKE_INSTALL_PREFIX}/include" CACHE PATH "Installation directory for headers") @@ -128,6 +130,76 @@ if(NOT MINGW) ) endif() +if(CMAKE_COMPILER_IS_GNUCC) + + # test to see if we can use a GNU indirect function to detect and load optimized code at runtime + CHECK_C_SOURCE_COMPILES(" + static int test_ifunc_native(void) + { + return 1; + } + static int (*(check_ifunc_native(void)))(void) + { + return test_ifunc_native; + } + int test_ifunc(void) __attribute__ ((ifunc (\"check_ifunc_native\"))); + int main(void) + { + return 0; + } + " HAS_C_ATTR_IFUNC) + + if(HAS_C_ATTR_IFUNC) + add_definitions(-DHAVE_IFUNC) + set(ZLIB_PRIVATE_HDRS ${ZLIB_PRIVATE_HDRS} contrib/gcc/zifunc.h) + endif() + + if(POWER) + # Test to see if we can use the optimizations for Power + CHECK_C_SOURCE_COMPILES(" + #ifndef _ARCH_PPC + #error \"Target is not Power\" + #endif + #ifndef __BUILTIN_CPU_SUPPORTS__ + #error \"Target doesn't support __builtin_cpu_supports()\" + #endif + int main() { return 0; } + " HAS_POWER_SUPPORT) + + if(HAS_POWER_SUPPORT AND HAS_C_ATTR_IFUNC) + add_definitions(-DZ_POWER_OPT) + + set(CMAKE_REQUIRED_FLAGS -mcpu=power8) + CHECK_C_SOURCE_COMPILES("int main(void){return 0;}" POWER8) + + if(POWER8) + add_definitions(-DZ_POWER8) + set(ZLIB_POWER8 + contrib/power/crc32_z_power8.c) + + set_source_files_properties( + ${ZLIB_POWER8} + PROPERTIES COMPILE_FLAGS -mcpu=power8) + endif() + + set(CMAKE_REQUIRED_FLAGS -mcpu=power9) + CHECK_C_SOURCE_COMPILES("int main(void){return 0;}" POWER9) + + if(POWER9) + add_definitions(-DZ_POWER9) + set(ZLIB_POWER9 ) + + set_source_files_properties( + ${ZLIB_POWER9} + PROPERTIES COMPILE_FLAGS -mcpu=power9) + endif() + + set(ZLIB_PRIVATE_HDRS ${ZLIB_PRIVATE_HDRS} contrib/power/power.h) + set(ZLIB_SRCS ${ZLIB_SRCS} ${ZLIB_POWER8} ${ZLIB_POWER9}) + endif() + endif() +endif() + # parse the full version number from zlib.h and include in ZLIB_FULL_VERSION file(READ ${CMAKE_CURRENT_SOURCE_DIR}/zlib.h _zlib_h_contents) string(REGEX REPLACE ".*#define[ \t]+ZLIB_VERSION[ \t]+\"([-0-9A-Za-z.]+)\".*" @@ -202,6 +274,10 @@ if(ZLIB_BUILD_EXAMPLES) target_link_libraries(example zlib) add_test(example example) + add_executable(crc32_test test/crc32_test.c) + target_link_libraries(crc32_test zlib) + add_test(crc32_test crc32_test) + add_executable(minigzip test/minigzip.c) target_link_libraries(minigzip zlib) Index: zlib-1.3.1/configure =================================================================== --- zlib-1.3.1.orig/configure +++ zlib-1.3.1/configure @@ -118,6 +118,7 @@ case "$1" in echo ' configure [--const] [--zprefix] [--prefix=PREFIX] [--eprefix=EXPREFIX]' | tee -a configure.log echo ' [--static] [--64] [--libdir=LIBDIR] [--sharedlibdir=LIBDIR]' | tee -a configure.log echo ' [--includedir=INCLUDEDIR] [--archs="-arch i386 -arch x86_64"]' | tee -a configure.log + echo ' [--dfltcc] [--dfltcc-level-mask=MASK]' | tee -a configure.log exit 0 ;; -p*=* | --prefix=*) prefix=`echo $1 | sed 's/.*=//'`; shift ;; -e*=* | --eprefix=*) exec_prefix=`echo $1 | sed 's/.*=//'`; shift ;; @@ -144,6 +145,16 @@ case "$1" in --sanitize) address=1; shift ;; --address) address=1; shift ;; --memory) memory=1; shift ;; + --dfltcc) + CFLAGS="$CFLAGS -DDFLTCC" + OBJC="$OBJC dfltcc.o" + PIC_OBJC="$PIC_OBJC dfltcc.lo" + shift + ;; + --dfltcc-level-mask=*) + CFLAGS="$CFLAGS -DDFLTCC_LEVEL_MASK=`echo $1 | sed 's/.*=//'`" + shift + ;; *) echo "unknown option: $1" | tee -a configure.log echo "$0 --help for help" | tee -a configure.log @@ -835,6 +846,114 @@ EOF fi fi +# Check whether sys/sdt.h is available +cat > $test.c << EOF +#include +int main() { return 0; } +EOF +if try $CC -c $CFLAGS $test.c; then + echo "Checking for sys/sdt.h ... Yes." | tee -a configure.log + CFLAGS="$CFLAGS -DHAVE_SYS_SDT_H" + SFLAGS="$SFLAGS -DHAVE_SYS_SDT_H" +else + echo "Checking for sys/sdt.h ... No." | tee -a configure.log +fi + +# test to see if we can use a gnu indirection function to detect and load optimized code at runtime +echo >> configure.log +cat > $test.c <> configure.log +cat > $test.c < $test.c + + if tryboth $CC -c $CFLAGS -mcpu=power8 $test.c; then + POWER8="-DZ_POWER8" + PIC_OBJC="${PIC_OBJC} crc32_z_power8.lo" + OBJC="${OBJC} crc32_z_power8.o" + echo "Checking for -mcpu=power8 support... Yes." | tee -a configure.log + else + echo "Checking for -mcpu=power8 support... No." | tee -a configure.log + fi + + if tryboth $CC -c $CFLAGS -mcpu=power9 $test.c; then + POWER9="-DZ_POWER9" + PIC_OBJC="${PIC_OBJC}" + OBJC="${OBJC}" + echo "Checking for -mcpu=power9 support... Yes." | tee -a configure.log + else + echo "Checking for -mcpu=power9 support... No." | tee -a configure.log + fi + + SFLAGS="${SFLAGS} ${POWER8} ${POWER9} -DZ_POWER_OPT" + CFLAGS="${CFLAGS} ${POWER8} ${POWER9} -DZ_POWER_OPT" + echo "Checking for Power optimizations support... Yes." | tee -a configure.log +else + echo "Checking for Power optimizations support... No." | tee -a configure.log +fi + +# check if we are compiling for s390 and binutils support vector extensions +VGFMAFLAG=-march=z13 +cat > $test.c <> configure.log echo ALL = $ALL >> configure.log @@ -866,6 +985,7 @@ echo mandir = $mandir >> configure.log echo prefix = $prefix >> configure.log echo sharedlibdir = $sharedlibdir >> configure.log echo uname = $uname >> configure.log +echo VGFMAFLAG = $VGFMAFLAG >> configure.log # update Makefile with the configure results sed < ${SRCDIR}Makefile.in " @@ -875,6 +995,7 @@ sed < ${SRCDIR}Makefile.in " /^LDFLAGS *=/s#=.*#=$LDFLAGS# /^LDSHARED *=/s#=.*#=$LDSHARED# /^CPP *=/s#=.*#=$CPP# +/^VGFMAFLAG *=/s#=.*#=$VGFMAFLAG# /^STATICLIB *=/s#=.*#=$STATICLIB# /^SHAREDLIB *=/s#=.*#=$SHAREDLIB# /^SHAREDLIBV *=/s#=.*#=$SHAREDLIBV# Index: zlib-1.3.1/contrib/README.contrib =================================================================== --- zlib-1.3.1.orig/contrib/README.contrib +++ zlib-1.3.1/contrib/README.contrib @@ -11,6 +11,10 @@ ada/ by Dmitriy Anisimkov Decompressor for output of PKWare Data Compression Library (DCL) +gcc/ by Matheus Castanho + and Rogerio Alves + Optimization helpers using GCC-specific extensions + delphi/ by Cosmin Truta Support for Delphi and C++ Builder @@ -42,10 +46,19 @@ minizip/ by Gilles Vollant et al. Support for Pascal +power/ by Daniel Black + Matheus Castanho + and Rogerio Alves + Optimized functions for Power processors + puff/ by Mark Adler Small, low memory usage inflate. Also serves to provide an unambiguous description of the deflate format. +s390/ by Ilya Leoshkevich + Hardware-accelerated deflate on IBM Z with DEFLATE CONVERSION CALL + instruction. + testzlib/ by Gilles Vollant Example of the use of zlib Index: zlib-1.3.1/contrib/gcc/zifunc.h =================================================================== --- /dev/null +++ zlib-1.3.1/contrib/gcc/zifunc.h @@ -0,0 +1,79 @@ +/* Copyright (C) 2019 Matheus Castanho , IBM + * 2019 Rogerio Alves , IBM + * For conditions of distribution and use, see copyright notice in zlib.h + */ + +#ifndef Z_IFUNC_H_ +#define Z_IFUNC_H_ + +/* Helpers for arch optimizations */ + +#if defined(__clang__) +#if __has_feature(coverage_sanitizer) +#define Z_IFUNC_NO_SANCOV __attribute__((no_sanitize("coverage"))) +#else /* __has_feature(coverage_sanitizer) */ +#define Z_IFUNC_NO_SANCOV +#endif /* __has_feature(coverage_sanitizer) */ +#else /* __clang__ */ +#define Z_IFUNC_NO_SANCOV +#endif /* __clang__ */ + +#ifdef __s390__ +#define Z_IFUNC_PARAMS unsigned long hwcap +#define Z_IFUNC_ATTRS Z_IFUNC_NO_SANCOV +#else /* __s390__ */ +#define Z_IFUNC_PARAMS void +#define Z_IFUNC_ATTRS +#endif /* __s390__ */ + +#define Z_IFUNC(fname) \ + typeof(fname) fname __attribute__ ((ifunc (#fname "_resolver"))); \ + Z_IFUNC_ATTRS \ + local typeof(fname) *fname##_resolver(Z_IFUNC_PARAMS) +/* This is a helper macro to declare a resolver for an indirect function + * (ifunc). Let's say you have function + * + * int foo (int a); + * + * for which you want to provide different implementations, for example: + * + * int foo_clever (int a) { + * ... clever things ... + * } + * + * int foo_smart (int a) { + * ... smart things ... + * } + * + * You will have to declare foo() as an indirect function and also provide a + * resolver for it, to choose between foo_clever() and foo_smart() based on + * some criteria you define (e.g. processor features). + * + * Since most likely foo() has a default implementation somewhere in zlib, you + * may have to rename it so the 'foo' symbol can be used by the ifunc without + * conflicts. + * + * #define foo foo_default + * int foo (int a) { + * ... + * } + * #undef foo + * + * Now you just have to provide a resolver function to choose which function + * should be used (decided at runtime on the first call to foo()): + * + * Z_IFUNC(foo) { + * if (... some condition ...) + * return foo_clever; + * + * if (... other condition ...) + * return foo_smart; + * + * return foo_default; + * } + * + * All calls to foo() throughout the code can remain untouched, all the magic + * will be done by the linker using the resolver function. + */ + +#endif /* Z_IFUNC_H_ */ Index: zlib-1.3.1/contrib/power/power.h =================================================================== --- /dev/null +++ zlib-1.3.1/contrib/power/power.h @@ -0,0 +1,8 @@ +/* Copyright (C) 2019 Matheus Castanho , IBM + * 2019 Rogerio Alves , IBM + * For conditions of distribution and use, see copyright notice in zlib.h + */ + +#include "../../zconf.h" + +unsigned long _crc32_z_power8(unsigned long, const Bytef *, z_size_t); Index: zlib-1.3.1/Makefile.in =================================================================== --- zlib-1.3.1.orig/Makefile.in +++ zlib-1.3.1/Makefile.in @@ -25,6 +25,7 @@ LDFLAGS= TEST_LIBS=-L. libz.a LDSHARED=$(CC) CPP=$(CC) -E +VGFMAFLAG= STATICLIB=libz.a SHAREDLIB=libz.so @@ -71,11 +72,11 @@ PIC_OBJS = $(PIC_OBJC) $(PIC_OBJA) all: static shared -static: example$(EXE) minigzip$(EXE) +static: crc32_test$(EXE) example$(EXE) minigzip$(EXE) -shared: examplesh$(EXE) minigzipsh$(EXE) +shared: crc32_testsh$(EXE) examplesh$(EXE) minigzipsh$(EXE) -all64: example64$(EXE) minigzip64$(EXE) +all64: crc32_test64$(EXE) example64$(EXE) minigzip64$(EXE) check: test @@ -83,7 +84,7 @@ test: all teststatic testshared teststatic: static @TMPST=tmpst_$$; \ - if echo hello world | ${QEMU_RUN} ./minigzip | ${QEMU_RUN} ./minigzip -d && ${QEMU_RUN} ./example $$TMPST ; then \ + if echo hello world | ${QEMU_RUN} ./minigzip | ${QEMU_RUN} ./minigzip -d && ${QEMU_RUN} ./example $$TMPST && ${QEMU_RUN} ./crc32_test; then \ echo ' *** zlib test OK ***'; \ else \ echo ' *** zlib test FAILED ***'; false; \ @@ -96,7 +97,7 @@ testshared: shared DYLD_LIBRARY_PATH=`pwd`:$(DYLD_LIBRARY_PATH) ; export DYLD_LIBRARY_PATH; \ SHLIB_PATH=`pwd`:$(SHLIB_PATH) ; export SHLIB_PATH; \ TMPSH=tmpsh_$$; \ - if echo hello world | ${QEMU_RUN} ./minigzipsh | ${QEMU_RUN} ./minigzipsh -d && ${QEMU_RUN} ./examplesh $$TMPSH; then \ + if echo hello world | ${QEMU_RUN} ./minigzipsh | ${QEMU_RUN} ./minigzipsh -d && ${QEMU_RUN} ./examplesh $$TMPSH && ${QEMU_RUN} ./crc32_testsh; then \ echo ' *** zlib shared test OK ***'; \ else \ echo ' *** zlib shared test FAILED ***'; false; \ @@ -105,7 +106,7 @@ testshared: shared test64: all64 @TMP64=tmp64_$$; \ - if echo hello world | ${QEMU_RUN} ./minigzip64 | ${QEMU_RUN} ./minigzip64 -d && ${QEMU_RUN} ./example64 $$TMP64; then \ + if echo hello world | ${QEMU_RUN} ./minigzip64 | ${QEMU_RUN} ./minigzip64 -d && ${QEMU_RUN} ./example64 $$TMP64 && ${QEMU_RUN} ./crc32_test64; then \ echo ' *** zlib 64-bit test OK ***'; \ else \ echo ' *** zlib 64-bit test FAILED ***'; false; \ @@ -139,12 +140,26 @@ match.lo: match.S mv _match.o match.lo rm -f _match.s +dfltcc.o: $(SRCDIR)contrib/s390/dfltcc.c $(SRCDIR)zlib.h zconf.h + $(CC) $(CFLAGS) $(ZINC) -c -o $@ $(SRCDIR)contrib/s390/dfltcc.c + +dfltcc.lo: $(SRCDIR)contrib/s390/dfltcc.c $(SRCDIR)zlib.h zconf.h + -@mkdir objs 2>/dev/null || test -d objs + $(CC) $(SFLAGS) $(ZINC) -DPIC -c -o objs/dfltcc.o $(SRCDIR)contrib/s390/dfltcc.c + -@mv objs/dfltcc.o $@ + +crc32_test.o: $(SRCDIR)test/crc32_test.c $(SRCDIR)zlib.h zconf.h + $(CC) $(CFLAGS) $(ZINCOUT) -c -o $@ $(SRCDIR)test/crc32_test.c + example.o: $(SRCDIR)test/example.c $(SRCDIR)zlib.h zconf.h $(CC) $(CFLAGS) $(ZINCOUT) -c -o $@ $(SRCDIR)test/example.c minigzip.o: $(SRCDIR)test/minigzip.c $(SRCDIR)zlib.h zconf.h $(CC) $(CFLAGS) $(ZINCOUT) -c -o $@ $(SRCDIR)test/minigzip.c +crc32_test64.o: $(SRCDIR)test/crc32_test.c $(SRCDIR)zlib.h zconf.h + $(CC) $(CFLAGS) $(ZINCOUT) -D_FILE_OFFSET_BITS=64 -c -o $@ $(SRCDIR)test/crc32_test.c + example64.o: $(SRCDIR)test/example.c $(SRCDIR)zlib.h zconf.h $(CC) $(CFLAGS) $(ZINCOUT) -D_FILE_OFFSET_BITS=64 -c -o $@ $(SRCDIR)test/example.c @@ -158,6 +173,12 @@ adler32.o: $(SRCDIR)adler32.c crc32.o: $(SRCDIR)crc32.c $(CC) $(CFLAGS) $(ZINC) -c -o $@ $(SRCDIR)crc32.c +crc32_z_power8.o: $(SRCDIR)contrib/power/crc32_z_power8.c + $(CC) $(CFLAGS) -mcpu=power8 $(ZINC) -c -o $@ $(SRCDIR)contrib/power/crc32_z_power8.c + +crc32-vx.o: $(SRCDIR)contrib/s390/crc32-vx.c + $(CC) $(CFLAGS) $(VGFMAFLAG) $(ZINC) -c -o $@ $(SRCDIR)contrib/s390/crc32-vx.c + deflate.o: $(SRCDIR)deflate.c $(CC) $(CFLAGS) $(ZINC) -c -o $@ $(SRCDIR)deflate.c @@ -208,6 +229,16 @@ crc32.lo: $(SRCDIR)crc32.c $(CC) $(SFLAGS) $(ZINC) -DPIC -c -o objs/crc32.o $(SRCDIR)crc32.c -@mv objs/crc32.o $@ +crc32-vx.lo: $(SRCDIR)contrib/s390/crc32-vx.c + -@mkdir objs 2>/dev/null || test -d objs + $(CC) $(SFLAGS) $(VGFMAFLAG) $(ZINC) -DPIC -c -o objs/crc32-vx.o $(SRCDIR)contrib/s390/crc32-vx.c + -@mv objs/crc32-vx.o $@ + +crc32_z_power8.lo: $(SRCDIR)contrib/power/crc32_z_power8.c + -@mkdir objs 2>/dev/null || test -d objs + $(CC) $(SFLAGS) -mcpu=power8 $(ZINC) -DPIC -c -o objs/crc32_z_power8.o $(SRCDIR)contrib/power/crc32_z_power8.c + -@mv objs/crc32_z_power8.o $@ + deflate.lo: $(SRCDIR)deflate.c -@mkdir objs 2>/dev/null || test -d objs $(CC) $(SFLAGS) $(ZINC) -DPIC -c -o objs/deflate.o $(SRCDIR)deflate.c @@ -281,18 +312,27 @@ placebo $(SHAREDLIBV): $(PIC_OBJS) libz. ln -s $@ $(SHAREDLIBM) -@rmdir objs +crc32_test$(EXE): crc32_test.o $(STATICLIB) + $(CC) $(CFLAGS) $(LDFLAGS) -o $@ crc32_test.o $(TEST_LIBS) + example$(EXE): example.o $(STATICLIB) $(CC) $(CFLAGS) $(LDFLAGS) -o $@ example.o $(TEST_LIBS) minigzip$(EXE): minigzip.o $(STATICLIB) $(CC) $(CFLAGS) $(LDFLAGS) -o $@ minigzip.o $(TEST_LIBS) +crc32_testsh$(EXE): crc32_test.o $(SHAREDLIBV) + $(CC) $(CFLAGS) -o $@ crc32_test.o -L. $(SHAREDLIBV) + examplesh$(EXE): example.o $(SHAREDLIBV) $(CC) $(CFLAGS) -o $@ example.o $(LDFLAGS) -L. $(SHAREDLIBV) minigzipsh$(EXE): minigzip.o $(SHAREDLIBV) $(CC) $(CFLAGS) -o $@ minigzip.o $(LDFLAGS) -L. $(SHAREDLIBV) +crc32_test64$(EXE): crc32_test64.o $(STATICLIB) + $(CC) $(CFLAGS) $(LDFLAGS) -o $@ crc32_test64.o $(TEST_LIBS) + example64$(EXE): example64.o $(STATICLIB) $(CC) $(CFLAGS) $(LDFLAGS) -o $@ example64.o $(TEST_LIBS) @@ -368,8 +408,8 @@ minizip-clean: mostlyclean: clean clean: minizip-clean rm -f *.o *.lo *~ \ - example$(EXE) minigzip$(EXE) examplesh$(EXE) minigzipsh$(EXE) \ - example64$(EXE) minigzip64$(EXE) \ + crc32_test$(EXE) example$(EXE) minigzip$(EXE) crc32_testsh$(EXE) examplesh$(EXE) minigzipsh$(EXE) \ + crc32_test64$(EXE) example64$(EXE) minigzip64$(EXE) \ infcover \ libz.* foo.gz so_locations \ _match.s maketree contrib/infback9/*.o @@ -391,7 +431,7 @@ tags: adler32.o zutil.o: $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h gzclose.o gzlib.o gzread.o gzwrite.o: $(SRCDIR)zlib.h zconf.h $(SRCDIR)gzguts.h -compress.o example.o minigzip.o uncompr.o: $(SRCDIR)zlib.h zconf.h +compress.o crc32_test.o example.o minigzip.o uncompr.o: $(SRCDIR)zlib.h zconf.h crc32.o: $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h $(SRCDIR)crc32.h deflate.o: $(SRCDIR)deflate.h $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h infback.o inflate.o: $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h $(SRCDIR)inftrees.h $(SRCDIR)inflate.h $(SRCDIR)inffast.h $(SRCDIR)inffixed.h @@ -401,7 +441,7 @@ trees.o: $(SRCDIR)deflate.h $(SRCDIR)zut adler32.lo zutil.lo: $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h gzclose.lo gzlib.lo gzread.lo gzwrite.lo: $(SRCDIR)zlib.h zconf.h $(SRCDIR)gzguts.h -compress.lo example.lo minigzip.lo uncompr.lo: $(SRCDIR)zlib.h zconf.h +compress.lo crc32_test.lo example.lo minigzip.lo uncompr.lo: $(SRCDIR)zlib.h zconf.h crc32.lo: $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h $(SRCDIR)crc32.h deflate.lo: $(SRCDIR)deflate.h $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h infback.lo inflate.lo: $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h $(SRCDIR)inftrees.h $(SRCDIR)inflate.h $(SRCDIR)inffast.h $(SRCDIR)inffixed.h Index: zlib-1.3.1/contrib/power/clang_workaround.h =================================================================== --- /dev/null +++ zlib-1.3.1/contrib/power/clang_workaround.h @@ -0,0 +1,87 @@ +#ifndef CLANG_WORKAROUNDS_H +#define CLANG_WORKAROUNDS_H + +/* + * These stubs fix clang incompatibilities with GCC builtins. + */ + +#ifndef __builtin_crypto_vpmsumw +#define __builtin_crypto_vpmsumw __builtin_crypto_vpmsumb +#endif +#ifndef __builtin_crypto_vpmsumd +#define __builtin_crypto_vpmsumd __builtin_crypto_vpmsumb +#endif + +static inline +__vector unsigned long long __attribute__((overloadable)) +vec_ld(int __a, const __vector unsigned long long* __b) +{ + return (__vector unsigned long long)__builtin_altivec_lvx(__a, __b); +} + +/* + * GCC __builtin_pack_vector_int128 returns a vector __int128_t but Clang + * does not recognize this type. On GCC this builtin is translated to a + * xxpermdi instruction that only moves the registers __a, __b instead generates + * a load. + * + * Clang has vec_xxpermdi intrinsics. It was implemented in 4.0.0. + */ +static inline +__vector unsigned long long __builtin_pack_vector (unsigned long __a, + unsigned long __b) +{ + #if defined(__BIG_ENDIAN__) + __vector unsigned long long __v = {__a, __b}; + #else + __vector unsigned long long __v = {__b, __a}; + #endif + return __v; +} + +/* + * Clang 7 changed the behavior of vec_xxpermdi in order to provide the same + * behavior of GCC. That means code adapted to Clang >= 7 does not work on + * Clang <= 6. So, fallback to __builtin_unpack_vector() on Clang <= 6. + */ +#if !defined vec_xxpermdi || __clang_major__ <= 6 + +static inline +unsigned long __builtin_unpack_vector (__vector unsigned long long __v, + int __o) +{ + return __v[__o]; +} + +#if defined(__BIG_ENDIAN__) +#define __builtin_unpack_vector_0(a) __builtin_unpack_vector ((a), 0) +#define __builtin_unpack_vector_1(a) __builtin_unpack_vector ((a), 1) +#else +#define __builtin_unpack_vector_0(a) __builtin_unpack_vector ((a), 1) +#define __builtin_unpack_vector_1(a) __builtin_unpack_vector ((a), 0) +#endif + +#else + +static inline +unsigned long __builtin_unpack_vector_0 (__vector unsigned long long __v) +{ + #if defined(__BIG_ENDIAN__) + return vec_xxpermdi(__v, __v, 0x0)[0]; + #else + return vec_xxpermdi(__v, __v, 0x3)[0]; + #endif +} + +static inline +unsigned long __builtin_unpack_vector_1 (__vector unsigned long long __v) +{ + #if defined(__BIG_ENDIAN__) + return vec_xxpermdi(__v, __v, 0x3)[0]; + #else + return vec_xxpermdi(__v, __v, 0x0)[0]; + #endif +} +#endif /* vec_xxpermdi */ + +#endif Index: zlib-1.3.1/contrib/power/crc32_constants.h =================================================================== --- /dev/null +++ zlib-1.3.1/contrib/power/crc32_constants.h @@ -0,0 +1,1206 @@ +/* +* +* THIS FILE IS GENERATED WITH +./crc32_constants -c -r -x 0x04C11DB7 + +* This is from https://github.com/antonblanchard/crc32-vpmsum/ +* DO NOT MODIFY IT MANUALLY! +* +*/ + +#define CRC 0x4c11db7 +#define CRC_XOR +#define REFLECT +#define MAX_SIZE 32768 + +#ifndef __ASSEMBLER__ +#ifdef CRC_TABLE +static const unsigned int crc_table[] = { + 0x00000000, 0x77073096, 0xee0e612c, 0x990951ba, + 0x076dc419, 0x706af48f, 0xe963a535, 0x9e6495a3, + 0x0edb8832, 0x79dcb8a4, 0xe0d5e91e, 0x97d2d988, + 0x09b64c2b, 0x7eb17cbd, 0xe7b82d07, 0x90bf1d91, + 0x1db71064, 0x6ab020f2, 0xf3b97148, 0x84be41de, + 0x1adad47d, 0x6ddde4eb, 0xf4d4b551, 0x83d385c7, + 0x136c9856, 0x646ba8c0, 0xfd62f97a, 0x8a65c9ec, + 0x14015c4f, 0x63066cd9, 0xfa0f3d63, 0x8d080df5, + 0x3b6e20c8, 0x4c69105e, 0xd56041e4, 0xa2677172, + 0x3c03e4d1, 0x4b04d447, 0xd20d85fd, 0xa50ab56b, + 0x35b5a8fa, 0x42b2986c, 0xdbbbc9d6, 0xacbcf940, + 0x32d86ce3, 0x45df5c75, 0xdcd60dcf, 0xabd13d59, + 0x26d930ac, 0x51de003a, 0xc8d75180, 0xbfd06116, + 0x21b4f4b5, 0x56b3c423, 0xcfba9599, 0xb8bda50f, + 0x2802b89e, 0x5f058808, 0xc60cd9b2, 0xb10be924, + 0x2f6f7c87, 0x58684c11, 0xc1611dab, 0xb6662d3d, + 0x76dc4190, 0x01db7106, 0x98d220bc, 0xefd5102a, + 0x71b18589, 0x06b6b51f, 0x9fbfe4a5, 0xe8b8d433, + 0x7807c9a2, 0x0f00f934, 0x9609a88e, 0xe10e9818, + 0x7f6a0dbb, 0x086d3d2d, 0x91646c97, 0xe6635c01, + 0x6b6b51f4, 0x1c6c6162, 0x856530d8, 0xf262004e, + 0x6c0695ed, 0x1b01a57b, 0x8208f4c1, 0xf50fc457, + 0x65b0d9c6, 0x12b7e950, 0x8bbeb8ea, 0xfcb9887c, + 0x62dd1ddf, 0x15da2d49, 0x8cd37cf3, 0xfbd44c65, + 0x4db26158, 0x3ab551ce, 0xa3bc0074, 0xd4bb30e2, + 0x4adfa541, 0x3dd895d7, 0xa4d1c46d, 0xd3d6f4fb, + 0x4369e96a, 0x346ed9fc, 0xad678846, 0xda60b8d0, + 0x44042d73, 0x33031de5, 0xaa0a4c5f, 0xdd0d7cc9, + 0x5005713c, 0x270241aa, 0xbe0b1010, 0xc90c2086, + 0x5768b525, 0x206f85b3, 0xb966d409, 0xce61e49f, + 0x5edef90e, 0x29d9c998, 0xb0d09822, 0xc7d7a8b4, + 0x59b33d17, 0x2eb40d81, 0xb7bd5c3b, 0xc0ba6cad, + 0xedb88320, 0x9abfb3b6, 0x03b6e20c, 0x74b1d29a, + 0xead54739, 0x9dd277af, 0x04db2615, 0x73dc1683, + 0xe3630b12, 0x94643b84, 0x0d6d6a3e, 0x7a6a5aa8, + 0xe40ecf0b, 0x9309ff9d, 0x0a00ae27, 0x7d079eb1, + 0xf00f9344, 0x8708a3d2, 0x1e01f268, 0x6906c2fe, + 0xf762575d, 0x806567cb, 0x196c3671, 0x6e6b06e7, + 0xfed41b76, 0x89d32be0, 0x10da7a5a, 0x67dd4acc, + 0xf9b9df6f, 0x8ebeeff9, 0x17b7be43, 0x60b08ed5, + 0xd6d6a3e8, 0xa1d1937e, 0x38d8c2c4, 0x4fdff252, + 0xd1bb67f1, 0xa6bc5767, 0x3fb506dd, 0x48b2364b, + 0xd80d2bda, 0xaf0a1b4c, 0x36034af6, 0x41047a60, + 0xdf60efc3, 0xa867df55, 0x316e8eef, 0x4669be79, + 0xcb61b38c, 0xbc66831a, 0x256fd2a0, 0x5268e236, + 0xcc0c7795, 0xbb0b4703, 0x220216b9, 0x5505262f, + 0xc5ba3bbe, 0xb2bd0b28, 0x2bb45a92, 0x5cb36a04, + 0xc2d7ffa7, 0xb5d0cf31, 0x2cd99e8b, 0x5bdeae1d, + 0x9b64c2b0, 0xec63f226, 0x756aa39c, 0x026d930a, + 0x9c0906a9, 0xeb0e363f, 0x72076785, 0x05005713, + 0x95bf4a82, 0xe2b87a14, 0x7bb12bae, 0x0cb61b38, + 0x92d28e9b, 0xe5d5be0d, 0x7cdcefb7, 0x0bdbdf21, + 0x86d3d2d4, 0xf1d4e242, 0x68ddb3f8, 0x1fda836e, + 0x81be16cd, 0xf6b9265b, 0x6fb077e1, 0x18b74777, + 0x88085ae6, 0xff0f6a70, 0x66063bca, 0x11010b5c, + 0x8f659eff, 0xf862ae69, 0x616bffd3, 0x166ccf45, + 0xa00ae278, 0xd70dd2ee, 0x4e048354, 0x3903b3c2, + 0xa7672661, 0xd06016f7, 0x4969474d, 0x3e6e77db, + 0xaed16a4a, 0xd9d65adc, 0x40df0b66, 0x37d83bf0, + 0xa9bcae53, 0xdebb9ec5, 0x47b2cf7f, 0x30b5ffe9, + 0xbdbdf21c, 0xcabac28a, 0x53b39330, 0x24b4a3a6, + 0xbad03605, 0xcdd70693, 0x54de5729, 0x23d967bf, + 0xb3667a2e, 0xc4614ab8, 0x5d681b02, 0x2a6f2b94, + 0xb40bbe37, 0xc30c8ea1, 0x5a05df1b, 0x2d02ef8d,}; + +#endif /* CRC_TABLE */ +#ifdef POWER8_INTRINSICS + +/* Constants */ + +/* Reduce 262144 kbits to 1024 bits */ +static const __vector unsigned long long vcrc_const[255] + __attribute__((aligned (16))) = { +#ifdef __LITTLE_ENDIAN__ + /* x^261120 mod p(x)` << 1, x^261184 mod p(x)` << 1 */ + { 0x0000000099ea94a8, 0x00000001651797d2 }, + /* x^260096 mod p(x)` << 1, x^260160 mod p(x)` << 1 */ + { 0x00000000945a8420, 0x0000000021e0d56c }, + /* x^259072 mod p(x)` << 1, x^259136 mod p(x)` << 1 */ + { 0x0000000030762706, 0x000000000f95ecaa }, + /* x^258048 mod p(x)` << 1, x^258112 mod p(x)` << 1 */ + { 0x00000001a52fc582, 0x00000001ebd224ac }, + /* x^257024 mod p(x)` << 1, x^257088 mod p(x)` << 1 */ + { 0x00000001a4a7167a, 0x000000000ccb97ca }, + /* x^256000 mod p(x)` << 1, x^256064 mod p(x)` << 1 */ + { 0x000000000c18249a, 0x00000001006ec8a8 }, + /* x^254976 mod p(x)` << 1, x^255040 mod p(x)` << 1 */ + { 0x00000000a924ae7c, 0x000000014f58f196 }, + /* x^253952 mod p(x)` << 1, x^254016 mod p(x)` << 1 */ + { 0x00000001e12ccc12, 0x00000001a7192ca6 }, + /* x^252928 mod p(x)` << 1, x^252992 mod p(x)` << 1 */ + { 0x00000000a0b9d4ac, 0x000000019a64bab2 }, + /* x^251904 mod p(x)` << 1, x^251968 mod p(x)` << 1 */ + { 0x0000000095e8ddfe, 0x0000000014f4ed2e }, + /* x^250880 mod p(x)` << 1, x^250944 mod p(x)` << 1 */ + { 0x00000000233fddc4, 0x000000011092b6a2 }, + /* x^249856 mod p(x)` << 1, x^249920 mod p(x)` << 1 */ + { 0x00000001b4529b62, 0x00000000c8a1629c }, + /* x^248832 mod p(x)` << 1, x^248896 mod p(x)` << 1 */ + { 0x00000001a7fa0e64, 0x000000017bf32e8e }, + /* x^247808 mod p(x)` << 1, x^247872 mod p(x)` << 1 */ + { 0x00000001b5334592, 0x00000001f8cc6582 }, + /* x^246784 mod p(x)` << 1, x^246848 mod p(x)` << 1 */ + { 0x000000011f8ee1b4, 0x000000008631ddf0 }, + /* x^245760 mod p(x)` << 1, x^245824 mod p(x)` << 1 */ + { 0x000000006252e632, 0x000000007e5a76d0 }, + /* x^244736 mod p(x)` << 1, x^244800 mod p(x)` << 1 */ + { 0x00000000ab973e84, 0x000000002b09b31c }, + /* x^243712 mod p(x)` << 1, x^243776 mod p(x)` << 1 */ + { 0x000000007734f5ec, 0x00000001b2df1f84 }, + /* x^242688 mod p(x)` << 1, x^242752 mod p(x)` << 1 */ + { 0x000000007c547798, 0x00000001d6f56afc }, + /* x^241664 mod p(x)` << 1, x^241728 mod p(x)` << 1 */ + { 0x000000007ec40210, 0x00000001b9b5e70c }, + /* x^240640 mod p(x)` << 1, x^240704 mod p(x)` << 1 */ + { 0x00000001ab1695a8, 0x0000000034b626d2 }, + /* x^239616 mod p(x)` << 1, x^239680 mod p(x)` << 1 */ + { 0x0000000090494bba, 0x000000014c53479a }, + /* x^238592 mod p(x)` << 1, x^238656 mod p(x)` << 1 */ + { 0x00000001123fb816, 0x00000001a6d179a4 }, + /* x^237568 mod p(x)` << 1, x^237632 mod p(x)` << 1 */ + { 0x00000001e188c74c, 0x000000015abd16b4 }, + /* x^236544 mod p(x)` << 1, x^236608 mod p(x)` << 1 */ + { 0x00000001c2d3451c, 0x00000000018f9852 }, + /* x^235520 mod p(x)` << 1, x^235584 mod p(x)` << 1 */ + { 0x00000000f55cf1ca, 0x000000001fb3084a }, + /* x^234496 mod p(x)` << 1, x^234560 mod p(x)` << 1 */ + { 0x00000001a0531540, 0x00000000c53dfb04 }, + /* x^233472 mod p(x)` << 1, x^233536 mod p(x)` << 1 */ + { 0x0000000132cd7ebc, 0x00000000e10c9ad6 }, + /* x^232448 mod p(x)` << 1, x^232512 mod p(x)` << 1 */ + { 0x0000000073ab7f36, 0x0000000025aa994a }, + /* x^231424 mod p(x)` << 1, x^231488 mod p(x)` << 1 */ + { 0x0000000041aed1c2, 0x00000000fa3a74c4 }, + /* x^230400 mod p(x)` << 1, x^230464 mod p(x)` << 1 */ + { 0x0000000136c53800, 0x0000000033eb3f40 }, + /* x^229376 mod p(x)` << 1, x^229440 mod p(x)` << 1 */ + { 0x0000000126835a30, 0x000000017193f296 }, + /* x^228352 mod p(x)` << 1, x^228416 mod p(x)` << 1 */ + { 0x000000006241b502, 0x0000000043f6c86a }, + /* x^227328 mod p(x)` << 1, x^227392 mod p(x)` << 1 */ + { 0x00000000d5196ad4, 0x000000016b513ec6 }, + /* x^226304 mod p(x)` << 1, x^226368 mod p(x)` << 1 */ + { 0x000000009cfa769a, 0x00000000c8f25b4e }, + /* x^225280 mod p(x)` << 1, x^225344 mod p(x)` << 1 */ + { 0x00000000920e5df4, 0x00000001a45048ec }, + /* x^224256 mod p(x)` << 1, x^224320 mod p(x)` << 1 */ + { 0x0000000169dc310e, 0x000000000c441004 }, + /* x^223232 mod p(x)` << 1, x^223296 mod p(x)` << 1 */ + { 0x0000000009fc331c, 0x000000000e17cad6 }, + /* x^222208 mod p(x)` << 1, x^222272 mod p(x)` << 1 */ + { 0x000000010d94a81e, 0x00000001253ae964 }, + /* x^221184 mod p(x)` << 1, x^221248 mod p(x)` << 1 */ + { 0x0000000027a20ab2, 0x00000001d7c88ebc }, + /* x^220160 mod p(x)` << 1, x^220224 mod p(x)` << 1 */ + { 0x0000000114f87504, 0x00000001e7ca913a }, + /* x^219136 mod p(x)` << 1, x^219200 mod p(x)` << 1 */ + { 0x000000004b076d96, 0x0000000033ed078a }, + /* x^218112 mod p(x)` << 1, x^218176 mod p(x)` << 1 */ + { 0x00000000da4d1e74, 0x00000000e1839c78 }, + /* x^217088 mod p(x)` << 1, x^217152 mod p(x)` << 1 */ + { 0x000000001b81f672, 0x00000001322b267e }, + /* x^216064 mod p(x)` << 1, x^216128 mod p(x)` << 1 */ + { 0x000000009367c988, 0x00000000638231b6 }, + /* x^215040 mod p(x)` << 1, x^215104 mod p(x)` << 1 */ + { 0x00000001717214ca, 0x00000001ee7f16f4 }, + /* x^214016 mod p(x)` << 1, x^214080 mod p(x)` << 1 */ + { 0x000000009f47d820, 0x0000000117d9924a }, + /* x^212992 mod p(x)` << 1, x^213056 mod p(x)` << 1 */ + { 0x000000010d9a47d2, 0x00000000e1a9e0c4 }, + /* x^211968 mod p(x)` << 1, x^212032 mod p(x)` << 1 */ + { 0x00000000a696c58c, 0x00000001403731dc }, + /* x^210944 mod p(x)` << 1, x^211008 mod p(x)` << 1 */ + { 0x000000002aa28ec6, 0x00000001a5ea9682 }, + /* x^209920 mod p(x)` << 1, x^209984 mod p(x)` << 1 */ + { 0x00000001fe18fd9a, 0x0000000101c5c578 }, + /* x^208896 mod p(x)` << 1, x^208960 mod p(x)` << 1 */ + { 0x000000019d4fc1ae, 0x00000000dddf6494 }, + /* x^207872 mod p(x)` << 1, x^207936 mod p(x)` << 1 */ + { 0x00000001ba0e3dea, 0x00000000f1c3db28 }, + /* x^206848 mod p(x)` << 1, x^206912 mod p(x)` << 1 */ + { 0x0000000074b59a5e, 0x000000013112fb9c }, + /* x^205824 mod p(x)` << 1, x^205888 mod p(x)` << 1 */ + { 0x00000000f2b5ea98, 0x00000000b680b906 }, + /* x^204800 mod p(x)` << 1, x^204864 mod p(x)` << 1 */ + { 0x0000000187132676, 0x000000001a282932 }, + /* x^203776 mod p(x)` << 1, x^203840 mod p(x)` << 1 */ + { 0x000000010a8c6ad4, 0x0000000089406e7e }, + /* x^202752 mod p(x)` << 1, x^202816 mod p(x)` << 1 */ + { 0x00000001e21dfe70, 0x00000001def6be8c }, + /* x^201728 mod p(x)` << 1, x^201792 mod p(x)` << 1 */ + { 0x00000001da0050e4, 0x0000000075258728 }, + /* x^200704 mod p(x)` << 1, x^200768 mod p(x)` << 1 */ + { 0x00000000772172ae, 0x000000019536090a }, + /* x^199680 mod p(x)` << 1, x^199744 mod p(x)` << 1 */ + { 0x00000000e47724aa, 0x00000000f2455bfc }, + /* x^198656 mod p(x)` << 1, x^198720 mod p(x)` << 1 */ + { 0x000000003cd63ac4, 0x000000018c40baf4 }, + /* x^197632 mod p(x)` << 1, x^197696 mod p(x)` << 1 */ + { 0x00000001bf47d352, 0x000000004cd390d4 }, + /* x^196608 mod p(x)` << 1, x^196672 mod p(x)` << 1 */ + { 0x000000018dc1d708, 0x00000001e4ece95a }, + /* x^195584 mod p(x)` << 1, x^195648 mod p(x)` << 1 */ + { 0x000000002d4620a4, 0x000000001a3ee918 }, + /* x^194560 mod p(x)` << 1, x^194624 mod p(x)` << 1 */ + { 0x0000000058fd1740, 0x000000007c652fb8 }, + /* x^193536 mod p(x)` << 1, x^193600 mod p(x)` << 1 */ + { 0x00000000dadd9bfc, 0x000000011c67842c }, + /* x^192512 mod p(x)` << 1, x^192576 mod p(x)` << 1 */ + { 0x00000001ea2140be, 0x00000000254f759c }, + /* x^191488 mod p(x)` << 1, x^191552 mod p(x)` << 1 */ + { 0x000000009de128ba, 0x000000007ece94ca }, + /* x^190464 mod p(x)` << 1, x^190528 mod p(x)` << 1 */ + { 0x000000013ac3aa8e, 0x0000000038f258c2 }, + /* x^189440 mod p(x)` << 1, x^189504 mod p(x)` << 1 */ + { 0x0000000099980562, 0x00000001cdf17b00 }, + /* x^188416 mod p(x)` << 1, x^188480 mod p(x)` << 1 */ + { 0x00000001c1579c86, 0x000000011f882c16 }, + /* x^187392 mod p(x)` << 1, x^187456 mod p(x)` << 1 */ + { 0x0000000068dbbf94, 0x0000000100093fc8 }, + /* x^186368 mod p(x)` << 1, x^186432 mod p(x)` << 1 */ + { 0x000000004509fb04, 0x00000001cd684f16 }, + /* x^185344 mod p(x)` << 1, x^185408 mod p(x)` << 1 */ + { 0x00000001202f6398, 0x000000004bc6a70a }, + /* x^184320 mod p(x)` << 1, x^184384 mod p(x)` << 1 */ + { 0x000000013aea243e, 0x000000004fc7e8e4 }, + /* x^183296 mod p(x)` << 1, x^183360 mod p(x)` << 1 */ + { 0x00000001b4052ae6, 0x0000000130103f1c }, + /* x^182272 mod p(x)` << 1, x^182336 mod p(x)` << 1 */ + { 0x00000001cd2a0ae8, 0x0000000111b0024c }, + /* x^181248 mod p(x)` << 1, x^181312 mod p(x)` << 1 */ + { 0x00000001fe4aa8b4, 0x000000010b3079da }, + /* x^180224 mod p(x)` << 1, x^180288 mod p(x)` << 1 */ + { 0x00000001d1559a42, 0x000000010192bcc2 }, + /* x^179200 mod p(x)` << 1, x^179264 mod p(x)` << 1 */ + { 0x00000001f3e05ecc, 0x0000000074838d50 }, + /* x^178176 mod p(x)` << 1, x^178240 mod p(x)` << 1 */ + { 0x0000000104ddd2cc, 0x000000001b20f520 }, + /* x^177152 mod p(x)` << 1, x^177216 mod p(x)` << 1 */ + { 0x000000015393153c, 0x0000000050c3590a }, + /* x^176128 mod p(x)` << 1, x^176192 mod p(x)` << 1 */ + { 0x0000000057e942c6, 0x00000000b41cac8e }, + /* x^175104 mod p(x)` << 1, x^175168 mod p(x)` << 1 */ + { 0x000000012c633850, 0x000000000c72cc78 }, + /* x^174080 mod p(x)` << 1, x^174144 mod p(x)` << 1 */ + { 0x00000000ebcaae4c, 0x0000000030cdb032 }, + /* x^173056 mod p(x)` << 1, x^173120 mod p(x)` << 1 */ + { 0x000000013ee532a6, 0x000000013e09fc32 }, + /* x^172032 mod p(x)` << 1, x^172096 mod p(x)` << 1 */ + { 0x00000001bf0cbc7e, 0x000000001ed624d2 }, + /* x^171008 mod p(x)` << 1, x^171072 mod p(x)` << 1 */ + { 0x00000000d50b7a5a, 0x00000000781aee1a }, + /* x^169984 mod p(x)` << 1, x^170048 mod p(x)` << 1 */ + { 0x0000000002fca6e8, 0x00000001c4d8348c }, + /* x^168960 mod p(x)` << 1, x^169024 mod p(x)` << 1 */ + { 0x000000007af40044, 0x0000000057a40336 }, + /* x^167936 mod p(x)` << 1, x^168000 mod p(x)` << 1 */ + { 0x0000000016178744, 0x0000000085544940 }, + /* x^166912 mod p(x)` << 1, x^166976 mod p(x)` << 1 */ + { 0x000000014c177458, 0x000000019cd21e80 }, + /* x^165888 mod p(x)` << 1, x^165952 mod p(x)` << 1 */ + { 0x000000011b6ddf04, 0x000000013eb95bc0 }, + /* x^164864 mod p(x)` << 1, x^164928 mod p(x)` << 1 */ + { 0x00000001f3e29ccc, 0x00000001dfc9fdfc }, + /* x^163840 mod p(x)` << 1, x^163904 mod p(x)` << 1 */ + { 0x0000000135ae7562, 0x00000000cd028bc2 }, + /* x^162816 mod p(x)` << 1, x^162880 mod p(x)` << 1 */ + { 0x0000000190ef812c, 0x0000000090db8c44 }, + /* x^161792 mod p(x)` << 1, x^161856 mod p(x)` << 1 */ + { 0x0000000067a2c786, 0x000000010010a4ce }, + /* x^160768 mod p(x)` << 1, x^160832 mod p(x)` << 1 */ + { 0x0000000048b9496c, 0x00000001c8f4c72c }, + /* x^159744 mod p(x)` << 1, x^159808 mod p(x)` << 1 */ + { 0x000000015a422de6, 0x000000001c26170c }, + /* x^158720 mod p(x)` << 1, x^158784 mod p(x)` << 1 */ + { 0x00000001ef0e3640, 0x00000000e3fccf68 }, + /* x^157696 mod p(x)` << 1, x^157760 mod p(x)` << 1 */ + { 0x00000001006d2d26, 0x00000000d513ed24 }, + /* x^156672 mod p(x)` << 1, x^156736 mod p(x)` << 1 */ + { 0x00000001170d56d6, 0x00000000141beada }, + /* x^155648 mod p(x)` << 1, x^155712 mod p(x)` << 1 */ + { 0x00000000a5fb613c, 0x000000011071aea0 }, + /* x^154624 mod p(x)` << 1, x^154688 mod p(x)` << 1 */ + { 0x0000000040bbf7fc, 0x000000012e19080a }, + /* x^153600 mod p(x)` << 1, x^153664 mod p(x)` << 1 */ + { 0x000000016ac3a5b2, 0x0000000100ecf826 }, + /* x^152576 mod p(x)` << 1, x^152640 mod p(x)` << 1 */ + { 0x00000000abf16230, 0x0000000069b09412 }, + /* x^151552 mod p(x)` << 1, x^151616 mod p(x)` << 1 */ + { 0x00000001ebe23fac, 0x0000000122297bac }, + /* x^150528 mod p(x)` << 1, x^150592 mod p(x)` << 1 */ + { 0x000000008b6a0894, 0x00000000e9e4b068 }, + /* x^149504 mod p(x)` << 1, x^149568 mod p(x)` << 1 */ + { 0x00000001288ea478, 0x000000004b38651a }, + /* x^148480 mod p(x)` << 1, x^148544 mod p(x)` << 1 */ + { 0x000000016619c442, 0x00000001468360e2 }, + /* x^147456 mod p(x)` << 1, x^147520 mod p(x)` << 1 */ + { 0x0000000086230038, 0x00000000121c2408 }, + /* x^146432 mod p(x)` << 1, x^146496 mod p(x)` << 1 */ + { 0x000000017746a756, 0x00000000da7e7d08 }, + /* x^145408 mod p(x)` << 1, x^145472 mod p(x)` << 1 */ + { 0x0000000191b8f8f8, 0x00000001058d7652 }, + /* x^144384 mod p(x)` << 1, x^144448 mod p(x)` << 1 */ + { 0x000000008e167708, 0x000000014a098a90 }, + /* x^143360 mod p(x)` << 1, x^143424 mod p(x)` << 1 */ + { 0x0000000148b22d54, 0x0000000020dbe72e }, + /* x^142336 mod p(x)` << 1, x^142400 mod p(x)` << 1 */ + { 0x0000000044ba2c3c, 0x000000011e7323e8 }, + /* x^141312 mod p(x)` << 1, x^141376 mod p(x)` << 1 */ + { 0x00000000b54d2b52, 0x00000000d5d4bf94 }, + /* x^140288 mod p(x)` << 1, x^140352 mod p(x)` << 1 */ + { 0x0000000005a4fd8a, 0x0000000199d8746c }, + /* x^139264 mod p(x)` << 1, x^139328 mod p(x)` << 1 */ + { 0x0000000139f9fc46, 0x00000000ce9ca8a0 }, + /* x^138240 mod p(x)` << 1, x^138304 mod p(x)` << 1 */ + { 0x000000015a1fa824, 0x00000000136edece }, + /* x^137216 mod p(x)` << 1, x^137280 mod p(x)` << 1 */ + { 0x000000000a61ae4c, 0x000000019b92a068 }, + /* x^136192 mod p(x)` << 1, x^136256 mod p(x)` << 1 */ + { 0x0000000145e9113e, 0x0000000071d62206 }, + /* x^135168 mod p(x)` << 1, x^135232 mod p(x)` << 1 */ + { 0x000000006a348448, 0x00000000dfc50158 }, + /* x^134144 mod p(x)` << 1, x^134208 mod p(x)` << 1 */ + { 0x000000004d80a08c, 0x00000001517626bc }, + /* x^133120 mod p(x)` << 1, x^133184 mod p(x)` << 1 */ + { 0x000000014b6837a0, 0x0000000148d1e4fa }, + /* x^132096 mod p(x)` << 1, x^132160 mod p(x)` << 1 */ + { 0x000000016896a7fc, 0x0000000094d8266e }, + /* x^131072 mod p(x)` << 1, x^131136 mod p(x)` << 1 */ + { 0x000000014f187140, 0x00000000606c5e34 }, + /* x^130048 mod p(x)` << 1, x^130112 mod p(x)` << 1 */ + { 0x000000019581b9da, 0x000000019766beaa }, + /* x^129024 mod p(x)` << 1, x^129088 mod p(x)` << 1 */ + { 0x00000001091bc984, 0x00000001d80c506c }, + /* x^128000 mod p(x)` << 1, x^128064 mod p(x)` << 1 */ + { 0x000000001067223c, 0x000000001e73837c }, + /* x^126976 mod p(x)` << 1, x^127040 mod p(x)` << 1 */ + { 0x00000001ab16ea02, 0x0000000064d587de }, + /* x^125952 mod p(x)` << 1, x^126016 mod p(x)` << 1 */ + { 0x000000013c4598a8, 0x00000000f4a507b0 }, + /* x^124928 mod p(x)` << 1, x^124992 mod p(x)` << 1 */ + { 0x00000000b3735430, 0x0000000040e342fc }, + /* x^123904 mod p(x)` << 1, x^123968 mod p(x)` << 1 */ + { 0x00000001bb3fc0c0, 0x00000001d5ad9c3a }, + /* x^122880 mod p(x)` << 1, x^122944 mod p(x)` << 1 */ + { 0x00000001570ae19c, 0x0000000094a691a4 }, + /* x^121856 mod p(x)` << 1, x^121920 mod p(x)` << 1 */ + { 0x00000001ea910712, 0x00000001271ecdfa }, + /* x^120832 mod p(x)` << 1, x^120896 mod p(x)` << 1 */ + { 0x0000000167127128, 0x000000009e54475a }, + /* x^119808 mod p(x)` << 1, x^119872 mod p(x)` << 1 */ + { 0x0000000019e790a2, 0x00000000c9c099ee }, + /* x^118784 mod p(x)` << 1, x^118848 mod p(x)` << 1 */ + { 0x000000003788f710, 0x000000009a2f736c }, + /* x^117760 mod p(x)` << 1, x^117824 mod p(x)` << 1 */ + { 0x00000001682a160e, 0x00000000bb9f4996 }, + /* x^116736 mod p(x)` << 1, x^116800 mod p(x)` << 1 */ + { 0x000000007f0ebd2e, 0x00000001db688050 }, + /* x^115712 mod p(x)` << 1, x^115776 mod p(x)` << 1 */ + { 0x000000002b032080, 0x00000000e9b10af4 }, + /* x^114688 mod p(x)` << 1, x^114752 mod p(x)` << 1 */ + { 0x00000000cfd1664a, 0x000000012d4545e4 }, + /* x^113664 mod p(x)` << 1, x^113728 mod p(x)` << 1 */ + { 0x00000000aa1181c2, 0x000000000361139c }, + /* x^112640 mod p(x)` << 1, x^112704 mod p(x)` << 1 */ + { 0x00000000ddd08002, 0x00000001a5a1a3a8 }, + /* x^111616 mod p(x)` << 1, x^111680 mod p(x)` << 1 */ + { 0x00000000e8dd0446, 0x000000006844e0b0 }, + /* x^110592 mod p(x)` << 1, x^110656 mod p(x)` << 1 */ + { 0x00000001bbd94a00, 0x00000000c3762f28 }, + /* x^109568 mod p(x)` << 1, x^109632 mod p(x)` << 1 */ + { 0x00000000ab6cd180, 0x00000001d26287a2 }, + /* x^108544 mod p(x)` << 1, x^108608 mod p(x)` << 1 */ + { 0x0000000031803ce2, 0x00000001f6f0bba8 }, + /* x^107520 mod p(x)` << 1, x^107584 mod p(x)` << 1 */ + { 0x0000000024f40b0c, 0x000000002ffabd62 }, + /* x^106496 mod p(x)` << 1, x^106560 mod p(x)` << 1 */ + { 0x00000001ba1d9834, 0x00000000fb4516b8 }, + /* x^105472 mod p(x)` << 1, x^105536 mod p(x)` << 1 */ + { 0x0000000104de61aa, 0x000000018cfa961c }, + /* x^104448 mod p(x)` << 1, x^104512 mod p(x)` << 1 */ + { 0x0000000113e40d46, 0x000000019e588d52 }, + /* x^103424 mod p(x)` << 1, x^103488 mod p(x)` << 1 */ + { 0x00000001415598a0, 0x00000001180f0bbc }, + /* x^102400 mod p(x)` << 1, x^102464 mod p(x)` << 1 */ + { 0x00000000bf6c8c90, 0x00000000e1d9177a }, + /* x^101376 mod p(x)` << 1, x^101440 mod p(x)` << 1 */ + { 0x00000001788b0504, 0x0000000105abc27c }, + /* x^100352 mod p(x)` << 1, x^100416 mod p(x)` << 1 */ + { 0x0000000038385d02, 0x00000000972e4a58 }, + /* x^99328 mod p(x)` << 1, x^99392 mod p(x)` << 1 */ + { 0x00000001b6c83844, 0x0000000183499a5e }, + /* x^98304 mod p(x)` << 1, x^98368 mod p(x)` << 1 */ + { 0x0000000051061a8a, 0x00000001c96a8cca }, + /* x^97280 mod p(x)` << 1, x^97344 mod p(x)` << 1 */ + { 0x000000017351388a, 0x00000001a1a5b60c }, + /* x^96256 mod p(x)` << 1, x^96320 mod p(x)` << 1 */ + { 0x0000000132928f92, 0x00000000e4b6ac9c }, + /* x^95232 mod p(x)` << 1, x^95296 mod p(x)` << 1 */ + { 0x00000000e6b4f48a, 0x00000001807e7f5a }, + /* x^94208 mod p(x)` << 1, x^94272 mod p(x)` << 1 */ + { 0x0000000039d15e90, 0x000000017a7e3bc8 }, + /* x^93184 mod p(x)` << 1, x^93248 mod p(x)` << 1 */ + { 0x00000000312d6074, 0x00000000d73975da }, + /* x^92160 mod p(x)` << 1, x^92224 mod p(x)` << 1 */ + { 0x000000017bbb2cc4, 0x000000017375d038 }, + /* x^91136 mod p(x)` << 1, x^91200 mod p(x)` << 1 */ + { 0x000000016ded3e18, 0x00000000193680bc }, + /* x^90112 mod p(x)` << 1, x^90176 mod p(x)` << 1 */ + { 0x00000000f1638b16, 0x00000000999b06f6 }, + /* x^89088 mod p(x)` << 1, x^89152 mod p(x)` << 1 */ + { 0x00000001d38b9ecc, 0x00000001f685d2b8 }, + /* x^88064 mod p(x)` << 1, x^88128 mod p(x)` << 1 */ + { 0x000000018b8d09dc, 0x00000001f4ecbed2 }, + /* x^87040 mod p(x)` << 1, x^87104 mod p(x)` << 1 */ + { 0x00000000e7bc27d2, 0x00000000ba16f1a0 }, + /* x^86016 mod p(x)` << 1, x^86080 mod p(x)` << 1 */ + { 0x00000000275e1e96, 0x0000000115aceac4 }, + /* x^84992 mod p(x)` << 1, x^85056 mod p(x)` << 1 */ + { 0x00000000e2e3031e, 0x00000001aeff6292 }, + /* x^83968 mod p(x)` << 1, x^84032 mod p(x)` << 1 */ + { 0x00000001041c84d8, 0x000000009640124c }, + /* x^82944 mod p(x)` << 1, x^83008 mod p(x)` << 1 */ + { 0x00000000706ce672, 0x0000000114f41f02 }, + /* x^81920 mod p(x)` << 1, x^81984 mod p(x)` << 1 */ + { 0x000000015d5070da, 0x000000009c5f3586 }, + /* x^80896 mod p(x)` << 1, x^80960 mod p(x)` << 1 */ + { 0x0000000038f9493a, 0x00000001878275fa }, + /* x^79872 mod p(x)` << 1, x^79936 mod p(x)` << 1 */ + { 0x00000000a3348a76, 0x00000000ddc42ce8 }, + /* x^78848 mod p(x)` << 1, x^78912 mod p(x)` << 1 */ + { 0x00000001ad0aab92, 0x0000000181d2c73a }, + /* x^77824 mod p(x)` << 1, x^77888 mod p(x)` << 1 */ + { 0x000000019e85f712, 0x0000000141c9320a }, + /* x^76800 mod p(x)` << 1, x^76864 mod p(x)` << 1 */ + { 0x000000005a871e76, 0x000000015235719a }, + /* x^75776 mod p(x)` << 1, x^75840 mod p(x)` << 1 */ + { 0x000000017249c662, 0x00000000be27d804 }, + /* x^74752 mod p(x)` << 1, x^74816 mod p(x)` << 1 */ + { 0x000000003a084712, 0x000000006242d45a }, + /* x^73728 mod p(x)` << 1, x^73792 mod p(x)` << 1 */ + { 0x00000000ed438478, 0x000000009a53638e }, + /* x^72704 mod p(x)` << 1, x^72768 mod p(x)` << 1 */ + { 0x00000000abac34cc, 0x00000001001ecfb6 }, + /* x^71680 mod p(x)` << 1, x^71744 mod p(x)` << 1 */ + { 0x000000005f35ef3e, 0x000000016d7c2d64 }, + /* x^70656 mod p(x)` << 1, x^70720 mod p(x)` << 1 */ + { 0x0000000047d6608c, 0x00000001d0ce46c0 }, + /* x^69632 mod p(x)` << 1, x^69696 mod p(x)` << 1 */ + { 0x000000002d01470e, 0x0000000124c907b4 }, + /* x^68608 mod p(x)` << 1, x^68672 mod p(x)` << 1 */ + { 0x0000000158bbc7b0, 0x0000000018a555ca }, + /* x^67584 mod p(x)` << 1, x^67648 mod p(x)` << 1 */ + { 0x00000000c0a23e8e, 0x000000006b0980bc }, + /* x^66560 mod p(x)` << 1, x^66624 mod p(x)` << 1 */ + { 0x00000001ebd85c88, 0x000000008bbba964 }, + /* x^65536 mod p(x)` << 1, x^65600 mod p(x)` << 1 */ + { 0x000000019ee20bb2, 0x00000001070a5a1e }, + /* x^64512 mod p(x)` << 1, x^64576 mod p(x)` << 1 */ + { 0x00000001acabf2d6, 0x000000002204322a }, + /* x^63488 mod p(x)` << 1, x^63552 mod p(x)` << 1 */ + { 0x00000001b7963d56, 0x00000000a27524d0 }, + /* x^62464 mod p(x)` << 1, x^62528 mod p(x)` << 1 */ + { 0x000000017bffa1fe, 0x0000000020b1e4ba }, + /* x^61440 mod p(x)` << 1, x^61504 mod p(x)` << 1 */ + { 0x000000001f15333e, 0x0000000032cc27fc }, + /* x^60416 mod p(x)` << 1, x^60480 mod p(x)` << 1 */ + { 0x000000018593129e, 0x0000000044dd22b8 }, + /* x^59392 mod p(x)` << 1, x^59456 mod p(x)` << 1 */ + { 0x000000019cb32602, 0x00000000dffc9e0a }, + /* x^58368 mod p(x)` << 1, x^58432 mod p(x)` << 1 */ + { 0x0000000142b05cc8, 0x00000001b7a0ed14 }, + /* x^57344 mod p(x)` << 1, x^57408 mod p(x)` << 1 */ + { 0x00000001be49e7a4, 0x00000000c7842488 }, + /* x^56320 mod p(x)` << 1, x^56384 mod p(x)` << 1 */ + { 0x0000000108f69d6c, 0x00000001c02a4fee }, + /* x^55296 mod p(x)` << 1, x^55360 mod p(x)` << 1 */ + { 0x000000006c0971f0, 0x000000003c273778 }, + /* x^54272 mod p(x)` << 1, x^54336 mod p(x)` << 1 */ + { 0x000000005b16467a, 0x00000001d63f8894 }, + /* x^53248 mod p(x)` << 1, x^53312 mod p(x)` << 1 */ + { 0x00000001551a628e, 0x000000006be557d6 }, + /* x^52224 mod p(x)` << 1, x^52288 mod p(x)` << 1 */ + { 0x000000019e42ea92, 0x000000006a7806ea }, + /* x^51200 mod p(x)` << 1, x^51264 mod p(x)` << 1 */ + { 0x000000012fa83ff2, 0x000000016155aa0c }, + /* x^50176 mod p(x)` << 1, x^50240 mod p(x)` << 1 */ + { 0x000000011ca9cde0, 0x00000000908650ac }, + /* x^49152 mod p(x)` << 1, x^49216 mod p(x)` << 1 */ + { 0x00000000c8e5cd74, 0x00000000aa5a8084 }, + /* x^48128 mod p(x)` << 1, x^48192 mod p(x)` << 1 */ + { 0x0000000096c27f0c, 0x0000000191bb500a }, + /* x^47104 mod p(x)` << 1, x^47168 mod p(x)` << 1 */ + { 0x000000002baed926, 0x0000000064e9bed0 }, + /* x^46080 mod p(x)` << 1, x^46144 mod p(x)` << 1 */ + { 0x000000017c8de8d2, 0x000000009444f302 }, + /* x^45056 mod p(x)` << 1, x^45120 mod p(x)` << 1 */ + { 0x00000000d43d6068, 0x000000019db07d3c }, + /* x^44032 mod p(x)` << 1, x^44096 mod p(x)` << 1 */ + { 0x00000000cb2c4b26, 0x00000001359e3e6e }, + /* x^43008 mod p(x)` << 1, x^43072 mod p(x)` << 1 */ + { 0x0000000145b8da26, 0x00000001e4f10dd2 }, + /* x^41984 mod p(x)` << 1, x^42048 mod p(x)` << 1 */ + { 0x000000018fff4b08, 0x0000000124f5735e }, + /* x^40960 mod p(x)` << 1, x^41024 mod p(x)` << 1 */ + { 0x0000000150b58ed0, 0x0000000124760a4c }, + /* x^39936 mod p(x)` << 1, x^40000 mod p(x)` << 1 */ + { 0x00000001549f39bc, 0x000000000f1fc186 }, + /* x^38912 mod p(x)` << 1, x^38976 mod p(x)` << 1 */ + { 0x00000000ef4d2f42, 0x00000000150e4cc4 }, + /* x^37888 mod p(x)` << 1, x^37952 mod p(x)` << 1 */ + { 0x00000001b1468572, 0x000000002a6204e8 }, + /* x^36864 mod p(x)` << 1, x^36928 mod p(x)` << 1 */ + { 0x000000013d7403b2, 0x00000000beb1d432 }, + /* x^35840 mod p(x)` << 1, x^35904 mod p(x)` << 1 */ + { 0x00000001a4681842, 0x0000000135f3f1f0 }, + /* x^34816 mod p(x)` << 1, x^34880 mod p(x)` << 1 */ + { 0x0000000167714492, 0x0000000074fe2232 }, + /* x^33792 mod p(x)` << 1, x^33856 mod p(x)` << 1 */ + { 0x00000001e599099a, 0x000000001ac6e2ba }, + /* x^32768 mod p(x)` << 1, x^32832 mod p(x)` << 1 */ + { 0x00000000fe128194, 0x0000000013fca91e }, + /* x^31744 mod p(x)` << 1, x^31808 mod p(x)` << 1 */ + { 0x0000000077e8b990, 0x0000000183f4931e }, + /* x^30720 mod p(x)` << 1, x^30784 mod p(x)` << 1 */ + { 0x00000001a267f63a, 0x00000000b6d9b4e4 }, + /* x^29696 mod p(x)` << 1, x^29760 mod p(x)` << 1 */ + { 0x00000001945c245a, 0x00000000b5188656 }, + /* x^28672 mod p(x)` << 1, x^28736 mod p(x)` << 1 */ + { 0x0000000149002e76, 0x0000000027a81a84 }, + /* x^27648 mod p(x)` << 1, x^27712 mod p(x)` << 1 */ + { 0x00000001bb8310a4, 0x0000000125699258 }, + /* x^26624 mod p(x)` << 1, x^26688 mod p(x)` << 1 */ + { 0x000000019ec60bcc, 0x00000001b23de796 }, + /* x^25600 mod p(x)` << 1, x^25664 mod p(x)` << 1 */ + { 0x000000012d8590ae, 0x00000000fe4365dc }, + /* x^24576 mod p(x)` << 1, x^24640 mod p(x)` << 1 */ + { 0x0000000065b00684, 0x00000000c68f497a }, + /* x^23552 mod p(x)` << 1, x^23616 mod p(x)` << 1 */ + { 0x000000015e5aeadc, 0x00000000fbf521ee }, + /* x^22528 mod p(x)` << 1, x^22592 mod p(x)` << 1 */ + { 0x00000000b77ff2b0, 0x000000015eac3378 }, + /* x^21504 mod p(x)` << 1, x^21568 mod p(x)` << 1 */ + { 0x0000000188da2ff6, 0x0000000134914b90 }, + /* x^20480 mod p(x)` << 1, x^20544 mod p(x)` << 1 */ + { 0x0000000063da929a, 0x0000000016335cfe }, + /* x^19456 mod p(x)` << 1, x^19520 mod p(x)` << 1 */ + { 0x00000001389caa80, 0x000000010372d10c }, + /* x^18432 mod p(x)` << 1, x^18496 mod p(x)` << 1 */ + { 0x000000013db599d2, 0x000000015097b908 }, + /* x^17408 mod p(x)` << 1, x^17472 mod p(x)` << 1 */ + { 0x0000000122505a86, 0x00000001227a7572 }, + /* x^16384 mod p(x)` << 1, x^16448 mod p(x)` << 1 */ + { 0x000000016bd72746, 0x000000009a8f75c0 }, + /* x^15360 mod p(x)` << 1, x^15424 mod p(x)` << 1 */ + { 0x00000001c3faf1d4, 0x00000000682c77a2 }, + /* x^14336 mod p(x)` << 1, x^14400 mod p(x)` << 1 */ + { 0x00000001111c826c, 0x00000000231f091c }, + /* x^13312 mod p(x)` << 1, x^13376 mod p(x)` << 1 */ + { 0x00000000153e9fb2, 0x000000007d4439f2 }, + /* x^12288 mod p(x)` << 1, x^12352 mod p(x)` << 1 */ + { 0x000000002b1f7b60, 0x000000017e221efc }, + /* x^11264 mod p(x)` << 1, x^11328 mod p(x)` << 1 */ + { 0x00000000b1dba570, 0x0000000167457c38 }, + /* x^10240 mod p(x)` << 1, x^10304 mod p(x)` << 1 */ + { 0x00000001f6397b76, 0x00000000bdf081c4 }, + /* x^9216 mod p(x)` << 1, x^9280 mod p(x)` << 1 */ + { 0x0000000156335214, 0x000000016286d6b0 }, + /* x^8192 mod p(x)` << 1, x^8256 mod p(x)` << 1 */ + { 0x00000001d70e3986, 0x00000000c84f001c }, + /* x^7168 mod p(x)` << 1, x^7232 mod p(x)` << 1 */ + { 0x000000003701a774, 0x0000000064efe7c0 }, + /* x^6144 mod p(x)` << 1, x^6208 mod p(x)` << 1 */ + { 0x00000000ac81ef72, 0x000000000ac2d904 }, + /* x^5120 mod p(x)` << 1, x^5184 mod p(x)` << 1 */ + { 0x0000000133212464, 0x00000000fd226d14 }, + /* x^4096 mod p(x)` << 1, x^4160 mod p(x)` << 1 */ + { 0x00000000e4e45610, 0x000000011cfd42e0 }, + /* x^3072 mod p(x)` << 1, x^3136 mod p(x)` << 1 */ + { 0x000000000c1bd370, 0x000000016e5a5678 }, + /* x^2048 mod p(x)` << 1, x^2112 mod p(x)` << 1 */ + { 0x00000001a7b9e7a6, 0x00000001d888fe22 }, + /* x^1024 mod p(x)` << 1, x^1088 mod p(x)` << 1 */ + { 0x000000007d657a10, 0x00000001af77fcd4 } +#else /* __LITTLE_ENDIAN__ */ + /* x^261120 mod p(x)` << 1, x^261184 mod p(x)` << 1 */ + { 0x00000001651797d2, 0x0000000099ea94a8 }, + /* x^260096 mod p(x)` << 1, x^260160 mod p(x)` << 1 */ + { 0x0000000021e0d56c, 0x00000000945a8420 }, + /* x^259072 mod p(x)` << 1, x^259136 mod p(x)` << 1 */ + { 0x000000000f95ecaa, 0x0000000030762706 }, + /* x^258048 mod p(x)` << 1, x^258112 mod p(x)` << 1 */ + { 0x00000001ebd224ac, 0x00000001a52fc582 }, + /* x^257024 mod p(x)` << 1, x^257088 mod p(x)` << 1 */ + { 0x000000000ccb97ca, 0x00000001a4a7167a }, + /* x^256000 mod p(x)` << 1, x^256064 mod p(x)` << 1 */ + { 0x00000001006ec8a8, 0x000000000c18249a }, + /* x^254976 mod p(x)` << 1, x^255040 mod p(x)` << 1 */ + { 0x000000014f58f196, 0x00000000a924ae7c }, + /* x^253952 mod p(x)` << 1, x^254016 mod p(x)` << 1 */ + { 0x00000001a7192ca6, 0x00000001e12ccc12 }, + /* x^252928 mod p(x)` << 1, x^252992 mod p(x)` << 1 */ + { 0x000000019a64bab2, 0x00000000a0b9d4ac }, + /* x^251904 mod p(x)` << 1, x^251968 mod p(x)` << 1 */ + { 0x0000000014f4ed2e, 0x0000000095e8ddfe }, + /* x^250880 mod p(x)` << 1, x^250944 mod p(x)` << 1 */ + { 0x000000011092b6a2, 0x00000000233fddc4 }, + /* x^249856 mod p(x)` << 1, x^249920 mod p(x)` << 1 */ + { 0x00000000c8a1629c, 0x00000001b4529b62 }, + /* x^248832 mod p(x)` << 1, x^248896 mod p(x)` << 1 */ + { 0x000000017bf32e8e, 0x00000001a7fa0e64 }, + /* x^247808 mod p(x)` << 1, x^247872 mod p(x)` << 1 */ + { 0x00000001f8cc6582, 0x00000001b5334592 }, + /* x^246784 mod p(x)` << 1, x^246848 mod p(x)` << 1 */ + { 0x000000008631ddf0, 0x000000011f8ee1b4 }, + /* x^245760 mod p(x)` << 1, x^245824 mod p(x)` << 1 */ + { 0x000000007e5a76d0, 0x000000006252e632 }, + /* x^244736 mod p(x)` << 1, x^244800 mod p(x)` << 1 */ + { 0x000000002b09b31c, 0x00000000ab973e84 }, + /* x^243712 mod p(x)` << 1, x^243776 mod p(x)` << 1 */ + { 0x00000001b2df1f84, 0x000000007734f5ec }, + /* x^242688 mod p(x)` << 1, x^242752 mod p(x)` << 1 */ + { 0x00000001d6f56afc, 0x000000007c547798 }, + /* x^241664 mod p(x)` << 1, x^241728 mod p(x)` << 1 */ + { 0x00000001b9b5e70c, 0x000000007ec40210 }, + /* x^240640 mod p(x)` << 1, x^240704 mod p(x)` << 1 */ + { 0x0000000034b626d2, 0x00000001ab1695a8 }, + /* x^239616 mod p(x)` << 1, x^239680 mod p(x)` << 1 */ + { 0x000000014c53479a, 0x0000000090494bba }, + /* x^238592 mod p(x)` << 1, x^238656 mod p(x)` << 1 */ + { 0x00000001a6d179a4, 0x00000001123fb816 }, + /* x^237568 mod p(x)` << 1, x^237632 mod p(x)` << 1 */ + { 0x000000015abd16b4, 0x00000001e188c74c }, + /* x^236544 mod p(x)` << 1, x^236608 mod p(x)` << 1 */ + { 0x00000000018f9852, 0x00000001c2d3451c }, + /* x^235520 mod p(x)` << 1, x^235584 mod p(x)` << 1 */ + { 0x000000001fb3084a, 0x00000000f55cf1ca }, + /* x^234496 mod p(x)` << 1, x^234560 mod p(x)` << 1 */ + { 0x00000000c53dfb04, 0x00000001a0531540 }, + /* x^233472 mod p(x)` << 1, x^233536 mod p(x)` << 1 */ + { 0x00000000e10c9ad6, 0x0000000132cd7ebc }, + /* x^232448 mod p(x)` << 1, x^232512 mod p(x)` << 1 */ + { 0x0000000025aa994a, 0x0000000073ab7f36 }, + /* x^231424 mod p(x)` << 1, x^231488 mod p(x)` << 1 */ + { 0x00000000fa3a74c4, 0x0000000041aed1c2 }, + /* x^230400 mod p(x)` << 1, x^230464 mod p(x)` << 1 */ + { 0x0000000033eb3f40, 0x0000000136c53800 }, + /* x^229376 mod p(x)` << 1, x^229440 mod p(x)` << 1 */ + { 0x000000017193f296, 0x0000000126835a30 }, + /* x^228352 mod p(x)` << 1, x^228416 mod p(x)` << 1 */ + { 0x0000000043f6c86a, 0x000000006241b502 }, + /* x^227328 mod p(x)` << 1, x^227392 mod p(x)` << 1 */ + { 0x000000016b513ec6, 0x00000000d5196ad4 }, + /* x^226304 mod p(x)` << 1, x^226368 mod p(x)` << 1 */ + { 0x00000000c8f25b4e, 0x000000009cfa769a }, + /* x^225280 mod p(x)` << 1, x^225344 mod p(x)` << 1 */ + { 0x00000001a45048ec, 0x00000000920e5df4 }, + /* x^224256 mod p(x)` << 1, x^224320 mod p(x)` << 1 */ + { 0x000000000c441004, 0x0000000169dc310e }, + /* x^223232 mod p(x)` << 1, x^223296 mod p(x)` << 1 */ + { 0x000000000e17cad6, 0x0000000009fc331c }, + /* x^222208 mod p(x)` << 1, x^222272 mod p(x)` << 1 */ + { 0x00000001253ae964, 0x000000010d94a81e }, + /* x^221184 mod p(x)` << 1, x^221248 mod p(x)` << 1 */ + { 0x00000001d7c88ebc, 0x0000000027a20ab2 }, + /* x^220160 mod p(x)` << 1, x^220224 mod p(x)` << 1 */ + { 0x00000001e7ca913a, 0x0000000114f87504 }, + /* x^219136 mod p(x)` << 1, x^219200 mod p(x)` << 1 */ + { 0x0000000033ed078a, 0x000000004b076d96 }, + /* x^218112 mod p(x)` << 1, x^218176 mod p(x)` << 1 */ + { 0x00000000e1839c78, 0x00000000da4d1e74 }, + /* x^217088 mod p(x)` << 1, x^217152 mod p(x)` << 1 */ + { 0x00000001322b267e, 0x000000001b81f672 }, + /* x^216064 mod p(x)` << 1, x^216128 mod p(x)` << 1 */ + { 0x00000000638231b6, 0x000000009367c988 }, + /* x^215040 mod p(x)` << 1, x^215104 mod p(x)` << 1 */ + { 0x00000001ee7f16f4, 0x00000001717214ca }, + /* x^214016 mod p(x)` << 1, x^214080 mod p(x)` << 1 */ + { 0x0000000117d9924a, 0x000000009f47d820 }, + /* x^212992 mod p(x)` << 1, x^213056 mod p(x)` << 1 */ + { 0x00000000e1a9e0c4, 0x000000010d9a47d2 }, + /* x^211968 mod p(x)` << 1, x^212032 mod p(x)` << 1 */ + { 0x00000001403731dc, 0x00000000a696c58c }, + /* x^210944 mod p(x)` << 1, x^211008 mod p(x)` << 1 */ + { 0x00000001a5ea9682, 0x000000002aa28ec6 }, + /* x^209920 mod p(x)` << 1, x^209984 mod p(x)` << 1 */ + { 0x0000000101c5c578, 0x00000001fe18fd9a }, + /* x^208896 mod p(x)` << 1, x^208960 mod p(x)` << 1 */ + { 0x00000000dddf6494, 0x000000019d4fc1ae }, + /* x^207872 mod p(x)` << 1, x^207936 mod p(x)` << 1 */ + { 0x00000000f1c3db28, 0x00000001ba0e3dea }, + /* x^206848 mod p(x)` << 1, x^206912 mod p(x)` << 1 */ + { 0x000000013112fb9c, 0x0000000074b59a5e }, + /* x^205824 mod p(x)` << 1, x^205888 mod p(x)` << 1 */ + { 0x00000000b680b906, 0x00000000f2b5ea98 }, + /* x^204800 mod p(x)` << 1, x^204864 mod p(x)` << 1 */ + { 0x000000001a282932, 0x0000000187132676 }, + /* x^203776 mod p(x)` << 1, x^203840 mod p(x)` << 1 */ + { 0x0000000089406e7e, 0x000000010a8c6ad4 }, + /* x^202752 mod p(x)` << 1, x^202816 mod p(x)` << 1 */ + { 0x00000001def6be8c, 0x00000001e21dfe70 }, + /* x^201728 mod p(x)` << 1, x^201792 mod p(x)` << 1 */ + { 0x0000000075258728, 0x00000001da0050e4 }, + /* x^200704 mod p(x)` << 1, x^200768 mod p(x)` << 1 */ + { 0x000000019536090a, 0x00000000772172ae }, + /* x^199680 mod p(x)` << 1, x^199744 mod p(x)` << 1 */ + { 0x00000000f2455bfc, 0x00000000e47724aa }, + /* x^198656 mod p(x)` << 1, x^198720 mod p(x)` << 1 */ + { 0x000000018c40baf4, 0x000000003cd63ac4 }, + /* x^197632 mod p(x)` << 1, x^197696 mod p(x)` << 1 */ + { 0x000000004cd390d4, 0x00000001bf47d352 }, + /* x^196608 mod p(x)` << 1, x^196672 mod p(x)` << 1 */ + { 0x00000001e4ece95a, 0x000000018dc1d708 }, + /* x^195584 mod p(x)` << 1, x^195648 mod p(x)` << 1 */ + { 0x000000001a3ee918, 0x000000002d4620a4 }, + /* x^194560 mod p(x)` << 1, x^194624 mod p(x)` << 1 */ + { 0x000000007c652fb8, 0x0000000058fd1740 }, + /* x^193536 mod p(x)` << 1, x^193600 mod p(x)` << 1 */ + { 0x000000011c67842c, 0x00000000dadd9bfc }, + /* x^192512 mod p(x)` << 1, x^192576 mod p(x)` << 1 */ + { 0x00000000254f759c, 0x00000001ea2140be }, + /* x^191488 mod p(x)` << 1, x^191552 mod p(x)` << 1 */ + { 0x000000007ece94ca, 0x000000009de128ba }, + /* x^190464 mod p(x)` << 1, x^190528 mod p(x)` << 1 */ + { 0x0000000038f258c2, 0x000000013ac3aa8e }, + /* x^189440 mod p(x)` << 1, x^189504 mod p(x)` << 1 */ + { 0x00000001cdf17b00, 0x0000000099980562 }, + /* x^188416 mod p(x)` << 1, x^188480 mod p(x)` << 1 */ + { 0x000000011f882c16, 0x00000001c1579c86 }, + /* x^187392 mod p(x)` << 1, x^187456 mod p(x)` << 1 */ + { 0x0000000100093fc8, 0x0000000068dbbf94 }, + /* x^186368 mod p(x)` << 1, x^186432 mod p(x)` << 1 */ + { 0x00000001cd684f16, 0x000000004509fb04 }, + /* x^185344 mod p(x)` << 1, x^185408 mod p(x)` << 1 */ + { 0x000000004bc6a70a, 0x00000001202f6398 }, + /* x^184320 mod p(x)` << 1, x^184384 mod p(x)` << 1 */ + { 0x000000004fc7e8e4, 0x000000013aea243e }, + /* x^183296 mod p(x)` << 1, x^183360 mod p(x)` << 1 */ + { 0x0000000130103f1c, 0x00000001b4052ae6 }, + /* x^182272 mod p(x)` << 1, x^182336 mod p(x)` << 1 */ + { 0x0000000111b0024c, 0x00000001cd2a0ae8 }, + /* x^181248 mod p(x)` << 1, x^181312 mod p(x)` << 1 */ + { 0x000000010b3079da, 0x00000001fe4aa8b4 }, + /* x^180224 mod p(x)` << 1, x^180288 mod p(x)` << 1 */ + { 0x000000010192bcc2, 0x00000001d1559a42 }, + /* x^179200 mod p(x)` << 1, x^179264 mod p(x)` << 1 */ + { 0x0000000074838d50, 0x00000001f3e05ecc }, + /* x^178176 mod p(x)` << 1, x^178240 mod p(x)` << 1 */ + { 0x000000001b20f520, 0x0000000104ddd2cc }, + /* x^177152 mod p(x)` << 1, x^177216 mod p(x)` << 1 */ + { 0x0000000050c3590a, 0x000000015393153c }, + /* x^176128 mod p(x)` << 1, x^176192 mod p(x)` << 1 */ + { 0x00000000b41cac8e, 0x0000000057e942c6 }, + /* x^175104 mod p(x)` << 1, x^175168 mod p(x)` << 1 */ + { 0x000000000c72cc78, 0x000000012c633850 }, + /* x^174080 mod p(x)` << 1, x^174144 mod p(x)` << 1 */ + { 0x0000000030cdb032, 0x00000000ebcaae4c }, + /* x^173056 mod p(x)` << 1, x^173120 mod p(x)` << 1 */ + { 0x000000013e09fc32, 0x000000013ee532a6 }, + /* x^172032 mod p(x)` << 1, x^172096 mod p(x)` << 1 */ + { 0x000000001ed624d2, 0x00000001bf0cbc7e }, + /* x^171008 mod p(x)` << 1, x^171072 mod p(x)` << 1 */ + { 0x00000000781aee1a, 0x00000000d50b7a5a }, + /* x^169984 mod p(x)` << 1, x^170048 mod p(x)` << 1 */ + { 0x00000001c4d8348c, 0x0000000002fca6e8 }, + /* x^168960 mod p(x)` << 1, x^169024 mod p(x)` << 1 */ + { 0x0000000057a40336, 0x000000007af40044 }, + /* x^167936 mod p(x)` << 1, x^168000 mod p(x)` << 1 */ + { 0x0000000085544940, 0x0000000016178744 }, + /* x^166912 mod p(x)` << 1, x^166976 mod p(x)` << 1 */ + { 0x000000019cd21e80, 0x000000014c177458 }, + /* x^165888 mod p(x)` << 1, x^165952 mod p(x)` << 1 */ + { 0x000000013eb95bc0, 0x000000011b6ddf04 }, + /* x^164864 mod p(x)` << 1, x^164928 mod p(x)` << 1 */ + { 0x00000001dfc9fdfc, 0x00000001f3e29ccc }, + /* x^163840 mod p(x)` << 1, x^163904 mod p(x)` << 1 */ + { 0x00000000cd028bc2, 0x0000000135ae7562 }, + /* x^162816 mod p(x)` << 1, x^162880 mod p(x)` << 1 */ + { 0x0000000090db8c44, 0x0000000190ef812c }, + /* x^161792 mod p(x)` << 1, x^161856 mod p(x)` << 1 */ + { 0x000000010010a4ce, 0x0000000067a2c786 }, + /* x^160768 mod p(x)` << 1, x^160832 mod p(x)` << 1 */ + { 0x00000001c8f4c72c, 0x0000000048b9496c }, + /* x^159744 mod p(x)` << 1, x^159808 mod p(x)` << 1 */ + { 0x000000001c26170c, 0x000000015a422de6 }, + /* x^158720 mod p(x)` << 1, x^158784 mod p(x)` << 1 */ + { 0x00000000e3fccf68, 0x00000001ef0e3640 }, + /* x^157696 mod p(x)` << 1, x^157760 mod p(x)` << 1 */ + { 0x00000000d513ed24, 0x00000001006d2d26 }, + /* x^156672 mod p(x)` << 1, x^156736 mod p(x)` << 1 */ + { 0x00000000141beada, 0x00000001170d56d6 }, + /* x^155648 mod p(x)` << 1, x^155712 mod p(x)` << 1 */ + { 0x000000011071aea0, 0x00000000a5fb613c }, + /* x^154624 mod p(x)` << 1, x^154688 mod p(x)` << 1 */ + { 0x000000012e19080a, 0x0000000040bbf7fc }, + /* x^153600 mod p(x)` << 1, x^153664 mod p(x)` << 1 */ + { 0x0000000100ecf826, 0x000000016ac3a5b2 }, + /* x^152576 mod p(x)` << 1, x^152640 mod p(x)` << 1 */ + { 0x0000000069b09412, 0x00000000abf16230 }, + /* x^151552 mod p(x)` << 1, x^151616 mod p(x)` << 1 */ + { 0x0000000122297bac, 0x00000001ebe23fac }, + /* x^150528 mod p(x)` << 1, x^150592 mod p(x)` << 1 */ + { 0x00000000e9e4b068, 0x000000008b6a0894 }, + /* x^149504 mod p(x)` << 1, x^149568 mod p(x)` << 1 */ + { 0x000000004b38651a, 0x00000001288ea478 }, + /* x^148480 mod p(x)` << 1, x^148544 mod p(x)` << 1 */ + { 0x00000001468360e2, 0x000000016619c442 }, + /* x^147456 mod p(x)` << 1, x^147520 mod p(x)` << 1 */ + { 0x00000000121c2408, 0x0000000086230038 }, + /* x^146432 mod p(x)` << 1, x^146496 mod p(x)` << 1 */ + { 0x00000000da7e7d08, 0x000000017746a756 }, + /* x^145408 mod p(x)` << 1, x^145472 mod p(x)` << 1 */ + { 0x00000001058d7652, 0x0000000191b8f8f8 }, + /* x^144384 mod p(x)` << 1, x^144448 mod p(x)` << 1 */ + { 0x000000014a098a90, 0x000000008e167708 }, + /* x^143360 mod p(x)` << 1, x^143424 mod p(x)` << 1 */ + { 0x0000000020dbe72e, 0x0000000148b22d54 }, + /* x^142336 mod p(x)` << 1, x^142400 mod p(x)` << 1 */ + { 0x000000011e7323e8, 0x0000000044ba2c3c }, + /* x^141312 mod p(x)` << 1, x^141376 mod p(x)` << 1 */ + { 0x00000000d5d4bf94, 0x00000000b54d2b52 }, + /* x^140288 mod p(x)` << 1, x^140352 mod p(x)` << 1 */ + { 0x0000000199d8746c, 0x0000000005a4fd8a }, + /* x^139264 mod p(x)` << 1, x^139328 mod p(x)` << 1 */ + { 0x00000000ce9ca8a0, 0x0000000139f9fc46 }, + /* x^138240 mod p(x)` << 1, x^138304 mod p(x)` << 1 */ + { 0x00000000136edece, 0x000000015a1fa824 }, + /* x^137216 mod p(x)` << 1, x^137280 mod p(x)` << 1 */ + { 0x000000019b92a068, 0x000000000a61ae4c }, + /* x^136192 mod p(x)` << 1, x^136256 mod p(x)` << 1 */ + { 0x0000000071d62206, 0x0000000145e9113e }, + /* x^135168 mod p(x)` << 1, x^135232 mod p(x)` << 1 */ + { 0x00000000dfc50158, 0x000000006a348448 }, + /* x^134144 mod p(x)` << 1, x^134208 mod p(x)` << 1 */ + { 0x00000001517626bc, 0x000000004d80a08c }, + /* x^133120 mod p(x)` << 1, x^133184 mod p(x)` << 1 */ + { 0x0000000148d1e4fa, 0x000000014b6837a0 }, + /* x^132096 mod p(x)` << 1, x^132160 mod p(x)` << 1 */ + { 0x0000000094d8266e, 0x000000016896a7fc }, + /* x^131072 mod p(x)` << 1, x^131136 mod p(x)` << 1 */ + { 0x00000000606c5e34, 0x000000014f187140 }, + /* x^130048 mod p(x)` << 1, x^130112 mod p(x)` << 1 */ + { 0x000000019766beaa, 0x000000019581b9da }, + /* x^129024 mod p(x)` << 1, x^129088 mod p(x)` << 1 */ + { 0x00000001d80c506c, 0x00000001091bc984 }, + /* x^128000 mod p(x)` << 1, x^128064 mod p(x)` << 1 */ + { 0x000000001e73837c, 0x000000001067223c }, + /* x^126976 mod p(x)` << 1, x^127040 mod p(x)` << 1 */ + { 0x0000000064d587de, 0x00000001ab16ea02 }, + /* x^125952 mod p(x)` << 1, x^126016 mod p(x)` << 1 */ + { 0x00000000f4a507b0, 0x000000013c4598a8 }, + /* x^124928 mod p(x)` << 1, x^124992 mod p(x)` << 1 */ + { 0x0000000040e342fc, 0x00000000b3735430 }, + /* x^123904 mod p(x)` << 1, x^123968 mod p(x)` << 1 */ + { 0x00000001d5ad9c3a, 0x00000001bb3fc0c0 }, + /* x^122880 mod p(x)` << 1, x^122944 mod p(x)` << 1 */ + { 0x0000000094a691a4, 0x00000001570ae19c }, + /* x^121856 mod p(x)` << 1, x^121920 mod p(x)` << 1 */ + { 0x00000001271ecdfa, 0x00000001ea910712 }, + /* x^120832 mod p(x)` << 1, x^120896 mod p(x)` << 1 */ + { 0x000000009e54475a, 0x0000000167127128 }, + /* x^119808 mod p(x)` << 1, x^119872 mod p(x)` << 1 */ + { 0x00000000c9c099ee, 0x0000000019e790a2 }, + /* x^118784 mod p(x)` << 1, x^118848 mod p(x)` << 1 */ + { 0x000000009a2f736c, 0x000000003788f710 }, + /* x^117760 mod p(x)` << 1, x^117824 mod p(x)` << 1 */ + { 0x00000000bb9f4996, 0x00000001682a160e }, + /* x^116736 mod p(x)` << 1, x^116800 mod p(x)` << 1 */ + { 0x00000001db688050, 0x000000007f0ebd2e }, + /* x^115712 mod p(x)` << 1, x^115776 mod p(x)` << 1 */ + { 0x00000000e9b10af4, 0x000000002b032080 }, + /* x^114688 mod p(x)` << 1, x^114752 mod p(x)` << 1 */ + { 0x000000012d4545e4, 0x00000000cfd1664a }, + /* x^113664 mod p(x)` << 1, x^113728 mod p(x)` << 1 */ + { 0x000000000361139c, 0x00000000aa1181c2 }, + /* x^112640 mod p(x)` << 1, x^112704 mod p(x)` << 1 */ + { 0x00000001a5a1a3a8, 0x00000000ddd08002 }, + /* x^111616 mod p(x)` << 1, x^111680 mod p(x)` << 1 */ + { 0x000000006844e0b0, 0x00000000e8dd0446 }, + /* x^110592 mod p(x)` << 1, x^110656 mod p(x)` << 1 */ + { 0x00000000c3762f28, 0x00000001bbd94a00 }, + /* x^109568 mod p(x)` << 1, x^109632 mod p(x)` << 1 */ + { 0x00000001d26287a2, 0x00000000ab6cd180 }, + /* x^108544 mod p(x)` << 1, x^108608 mod p(x)` << 1 */ + { 0x00000001f6f0bba8, 0x0000000031803ce2 }, + /* x^107520 mod p(x)` << 1, x^107584 mod p(x)` << 1 */ + { 0x000000002ffabd62, 0x0000000024f40b0c }, + /* x^106496 mod p(x)` << 1, x^106560 mod p(x)` << 1 */ + { 0x00000000fb4516b8, 0x00000001ba1d9834 }, + /* x^105472 mod p(x)` << 1, x^105536 mod p(x)` << 1 */ + { 0x000000018cfa961c, 0x0000000104de61aa }, + /* x^104448 mod p(x)` << 1, x^104512 mod p(x)` << 1 */ + { 0x000000019e588d52, 0x0000000113e40d46 }, + /* x^103424 mod p(x)` << 1, x^103488 mod p(x)` << 1 */ + { 0x00000001180f0bbc, 0x00000001415598a0 }, + /* x^102400 mod p(x)` << 1, x^102464 mod p(x)` << 1 */ + { 0x00000000e1d9177a, 0x00000000bf6c8c90 }, + /* x^101376 mod p(x)` << 1, x^101440 mod p(x)` << 1 */ + { 0x0000000105abc27c, 0x00000001788b0504 }, + /* x^100352 mod p(x)` << 1, x^100416 mod p(x)` << 1 */ + { 0x00000000972e4a58, 0x0000000038385d02 }, + /* x^99328 mod p(x)` << 1, x^99392 mod p(x)` << 1 */ + { 0x0000000183499a5e, 0x00000001b6c83844 }, + /* x^98304 mod p(x)` << 1, x^98368 mod p(x)` << 1 */ + { 0x00000001c96a8cca, 0x0000000051061a8a }, + /* x^97280 mod p(x)` << 1, x^97344 mod p(x)` << 1 */ + { 0x00000001a1a5b60c, 0x000000017351388a }, + /* x^96256 mod p(x)` << 1, x^96320 mod p(x)` << 1 */ + { 0x00000000e4b6ac9c, 0x0000000132928f92 }, + /* x^95232 mod p(x)` << 1, x^95296 mod p(x)` << 1 */ + { 0x00000001807e7f5a, 0x00000000e6b4f48a }, + /* x^94208 mod p(x)` << 1, x^94272 mod p(x)` << 1 */ + { 0x000000017a7e3bc8, 0x0000000039d15e90 }, + /* x^93184 mod p(x)` << 1, x^93248 mod p(x)` << 1 */ + { 0x00000000d73975da, 0x00000000312d6074 }, + /* x^92160 mod p(x)` << 1, x^92224 mod p(x)` << 1 */ + { 0x000000017375d038, 0x000000017bbb2cc4 }, + /* x^91136 mod p(x)` << 1, x^91200 mod p(x)` << 1 */ + { 0x00000000193680bc, 0x000000016ded3e18 }, + /* x^90112 mod p(x)` << 1, x^90176 mod p(x)` << 1 */ + { 0x00000000999b06f6, 0x00000000f1638b16 }, + /* x^89088 mod p(x)` << 1, x^89152 mod p(x)` << 1 */ + { 0x00000001f685d2b8, 0x00000001d38b9ecc }, + /* x^88064 mod p(x)` << 1, x^88128 mod p(x)` << 1 */ + { 0x00000001f4ecbed2, 0x000000018b8d09dc }, + /* x^87040 mod p(x)` << 1, x^87104 mod p(x)` << 1 */ + { 0x00000000ba16f1a0, 0x00000000e7bc27d2 }, + /* x^86016 mod p(x)` << 1, x^86080 mod p(x)` << 1 */ + { 0x0000000115aceac4, 0x00000000275e1e96 }, + /* x^84992 mod p(x)` << 1, x^85056 mod p(x)` << 1 */ + { 0x00000001aeff6292, 0x00000000e2e3031e }, + /* x^83968 mod p(x)` << 1, x^84032 mod p(x)` << 1 */ + { 0x000000009640124c, 0x00000001041c84d8 }, + /* x^82944 mod p(x)` << 1, x^83008 mod p(x)` << 1 */ + { 0x0000000114f41f02, 0x00000000706ce672 }, + /* x^81920 mod p(x)` << 1, x^81984 mod p(x)` << 1 */ + { 0x000000009c5f3586, 0x000000015d5070da }, + /* x^80896 mod p(x)` << 1, x^80960 mod p(x)` << 1 */ + { 0x00000001878275fa, 0x0000000038f9493a }, + /* x^79872 mod p(x)` << 1, x^79936 mod p(x)` << 1 */ + { 0x00000000ddc42ce8, 0x00000000a3348a76 }, + /* x^78848 mod p(x)` << 1, x^78912 mod p(x)` << 1 */ + { 0x0000000181d2c73a, 0x00000001ad0aab92 }, + /* x^77824 mod p(x)` << 1, x^77888 mod p(x)` << 1 */ + { 0x0000000141c9320a, 0x000000019e85f712 }, + /* x^76800 mod p(x)` << 1, x^76864 mod p(x)` << 1 */ + { 0x000000015235719a, 0x000000005a871e76 }, + /* x^75776 mod p(x)` << 1, x^75840 mod p(x)` << 1 */ + { 0x00000000be27d804, 0x000000017249c662 }, + /* x^74752 mod p(x)` << 1, x^74816 mod p(x)` << 1 */ + { 0x000000006242d45a, 0x000000003a084712 }, + /* x^73728 mod p(x)` << 1, x^73792 mod p(x)` << 1 */ + { 0x000000009a53638e, 0x00000000ed438478 }, + /* x^72704 mod p(x)` << 1, x^72768 mod p(x)` << 1 */ + { 0x00000001001ecfb6, 0x00000000abac34cc }, + /* x^71680 mod p(x)` << 1, x^71744 mod p(x)` << 1 */ + { 0x000000016d7c2d64, 0x000000005f35ef3e }, + /* x^70656 mod p(x)` << 1, x^70720 mod p(x)` << 1 */ + { 0x00000001d0ce46c0, 0x0000000047d6608c }, + /* x^69632 mod p(x)` << 1, x^69696 mod p(x)` << 1 */ + { 0x0000000124c907b4, 0x000000002d01470e }, + /* x^68608 mod p(x)` << 1, x^68672 mod p(x)` << 1 */ + { 0x0000000018a555ca, 0x0000000158bbc7b0 }, + /* x^67584 mod p(x)` << 1, x^67648 mod p(x)` << 1 */ + { 0x000000006b0980bc, 0x00000000c0a23e8e }, + /* x^66560 mod p(x)` << 1, x^66624 mod p(x)` << 1 */ + { 0x000000008bbba964, 0x00000001ebd85c88 }, + /* x^65536 mod p(x)` << 1, x^65600 mod p(x)` << 1 */ + { 0x00000001070a5a1e, 0x000000019ee20bb2 }, + /* x^64512 mod p(x)` << 1, x^64576 mod p(x)` << 1 */ + { 0x000000002204322a, 0x00000001acabf2d6 }, + /* x^63488 mod p(x)` << 1, x^63552 mod p(x)` << 1 */ + { 0x00000000a27524d0, 0x00000001b7963d56 }, + /* x^62464 mod p(x)` << 1, x^62528 mod p(x)` << 1 */ + { 0x0000000020b1e4ba, 0x000000017bffa1fe }, + /* x^61440 mod p(x)` << 1, x^61504 mod p(x)` << 1 */ + { 0x0000000032cc27fc, 0x000000001f15333e }, + /* x^60416 mod p(x)` << 1, x^60480 mod p(x)` << 1 */ + { 0x0000000044dd22b8, 0x000000018593129e }, + /* x^59392 mod p(x)` << 1, x^59456 mod p(x)` << 1 */ + { 0x00000000dffc9e0a, 0x000000019cb32602 }, + /* x^58368 mod p(x)` << 1, x^58432 mod p(x)` << 1 */ + { 0x00000001b7a0ed14, 0x0000000142b05cc8 }, + /* x^57344 mod p(x)` << 1, x^57408 mod p(x)` << 1 */ + { 0x00000000c7842488, 0x00000001be49e7a4 }, + /* x^56320 mod p(x)` << 1, x^56384 mod p(x)` << 1 */ + { 0x00000001c02a4fee, 0x0000000108f69d6c }, + /* x^55296 mod p(x)` << 1, x^55360 mod p(x)` << 1 */ + { 0x000000003c273778, 0x000000006c0971f0 }, + /* x^54272 mod p(x)` << 1, x^54336 mod p(x)` << 1 */ + { 0x00000001d63f8894, 0x000000005b16467a }, + /* x^53248 mod p(x)` << 1, x^53312 mod p(x)` << 1 */ + { 0x000000006be557d6, 0x00000001551a628e }, + /* x^52224 mod p(x)` << 1, x^52288 mod p(x)` << 1 */ + { 0x000000006a7806ea, 0x000000019e42ea92 }, + /* x^51200 mod p(x)` << 1, x^51264 mod p(x)` << 1 */ + { 0x000000016155aa0c, 0x000000012fa83ff2 }, + /* x^50176 mod p(x)` << 1, x^50240 mod p(x)` << 1 */ + { 0x00000000908650ac, 0x000000011ca9cde0 }, + /* x^49152 mod p(x)` << 1, x^49216 mod p(x)` << 1 */ + { 0x00000000aa5a8084, 0x00000000c8e5cd74 }, + /* x^48128 mod p(x)` << 1, x^48192 mod p(x)` << 1 */ + { 0x0000000191bb500a, 0x0000000096c27f0c }, + /* x^47104 mod p(x)` << 1, x^47168 mod p(x)` << 1 */ + { 0x0000000064e9bed0, 0x000000002baed926 }, + /* x^46080 mod p(x)` << 1, x^46144 mod p(x)` << 1 */ + { 0x000000009444f302, 0x000000017c8de8d2 }, + /* x^45056 mod p(x)` << 1, x^45120 mod p(x)` << 1 */ + { 0x000000019db07d3c, 0x00000000d43d6068 }, + /* x^44032 mod p(x)` << 1, x^44096 mod p(x)` << 1 */ + { 0x00000001359e3e6e, 0x00000000cb2c4b26 }, + /* x^43008 mod p(x)` << 1, x^43072 mod p(x)` << 1 */ + { 0x00000001e4f10dd2, 0x0000000145b8da26 }, + /* x^41984 mod p(x)` << 1, x^42048 mod p(x)` << 1 */ + { 0x0000000124f5735e, 0x000000018fff4b08 }, + /* x^40960 mod p(x)` << 1, x^41024 mod p(x)` << 1 */ + { 0x0000000124760a4c, 0x0000000150b58ed0 }, + /* x^39936 mod p(x)` << 1, x^40000 mod p(x)` << 1 */ + { 0x000000000f1fc186, 0x00000001549f39bc }, + /* x^38912 mod p(x)` << 1, x^38976 mod p(x)` << 1 */ + { 0x00000000150e4cc4, 0x00000000ef4d2f42 }, + /* x^37888 mod p(x)` << 1, x^37952 mod p(x)` << 1 */ + { 0x000000002a6204e8, 0x00000001b1468572 }, + /* x^36864 mod p(x)` << 1, x^36928 mod p(x)` << 1 */ + { 0x00000000beb1d432, 0x000000013d7403b2 }, + /* x^35840 mod p(x)` << 1, x^35904 mod p(x)` << 1 */ + { 0x0000000135f3f1f0, 0x00000001a4681842 }, + /* x^34816 mod p(x)` << 1, x^34880 mod p(x)` << 1 */ + { 0x0000000074fe2232, 0x0000000167714492 }, + /* x^33792 mod p(x)` << 1, x^33856 mod p(x)` << 1 */ + { 0x000000001ac6e2ba, 0x00000001e599099a }, + /* x^32768 mod p(x)` << 1, x^32832 mod p(x)` << 1 */ + { 0x0000000013fca91e, 0x00000000fe128194 }, + /* x^31744 mod p(x)` << 1, x^31808 mod p(x)` << 1 */ + { 0x0000000183f4931e, 0x0000000077e8b990 }, + /* x^30720 mod p(x)` << 1, x^30784 mod p(x)` << 1 */ + { 0x00000000b6d9b4e4, 0x00000001a267f63a }, + /* x^29696 mod p(x)` << 1, x^29760 mod p(x)` << 1 */ + { 0x00000000b5188656, 0x00000001945c245a }, + /* x^28672 mod p(x)` << 1, x^28736 mod p(x)` << 1 */ + { 0x0000000027a81a84, 0x0000000149002e76 }, + /* x^27648 mod p(x)` << 1, x^27712 mod p(x)` << 1 */ + { 0x0000000125699258, 0x00000001bb8310a4 }, + /* x^26624 mod p(x)` << 1, x^26688 mod p(x)` << 1 */ + { 0x00000001b23de796, 0x000000019ec60bcc }, + /* x^25600 mod p(x)` << 1, x^25664 mod p(x)` << 1 */ + { 0x00000000fe4365dc, 0x000000012d8590ae }, + /* x^24576 mod p(x)` << 1, x^24640 mod p(x)` << 1 */ + { 0x00000000c68f497a, 0x0000000065b00684 }, + /* x^23552 mod p(x)` << 1, x^23616 mod p(x)` << 1 */ + { 0x00000000fbf521ee, 0x000000015e5aeadc }, + /* x^22528 mod p(x)` << 1, x^22592 mod p(x)` << 1 */ + { 0x000000015eac3378, 0x00000000b77ff2b0 }, + /* x^21504 mod p(x)` << 1, x^21568 mod p(x)` << 1 */ + { 0x0000000134914b90, 0x0000000188da2ff6 }, + /* x^20480 mod p(x)` << 1, x^20544 mod p(x)` << 1 */ + { 0x0000000016335cfe, 0x0000000063da929a }, + /* x^19456 mod p(x)` << 1, x^19520 mod p(x)` << 1 */ + { 0x000000010372d10c, 0x00000001389caa80 }, + /* x^18432 mod p(x)` << 1, x^18496 mod p(x)` << 1 */ + { 0x000000015097b908, 0x000000013db599d2 }, + /* x^17408 mod p(x)` << 1, x^17472 mod p(x)` << 1 */ + { 0x00000001227a7572, 0x0000000122505a86 }, + /* x^16384 mod p(x)` << 1, x^16448 mod p(x)` << 1 */ + { 0x000000009a8f75c0, 0x000000016bd72746 }, + /* x^15360 mod p(x)` << 1, x^15424 mod p(x)` << 1 */ + { 0x00000000682c77a2, 0x00000001c3faf1d4 }, + /* x^14336 mod p(x)` << 1, x^14400 mod p(x)` << 1 */ + { 0x00000000231f091c, 0x00000001111c826c }, + /* x^13312 mod p(x)` << 1, x^13376 mod p(x)` << 1 */ + { 0x000000007d4439f2, 0x00000000153e9fb2 }, + /* x^12288 mod p(x)` << 1, x^12352 mod p(x)` << 1 */ + { 0x000000017e221efc, 0x000000002b1f7b60 }, + /* x^11264 mod p(x)` << 1, x^11328 mod p(x)` << 1 */ + { 0x0000000167457c38, 0x00000000b1dba570 }, + /* x^10240 mod p(x)` << 1, x^10304 mod p(x)` << 1 */ + { 0x00000000bdf081c4, 0x00000001f6397b76 }, + /* x^9216 mod p(x)` << 1, x^9280 mod p(x)` << 1 */ + { 0x000000016286d6b0, 0x0000000156335214 }, + /* x^8192 mod p(x)` << 1, x^8256 mod p(x)` << 1 */ + { 0x00000000c84f001c, 0x00000001d70e3986 }, + /* x^7168 mod p(x)` << 1, x^7232 mod p(x)` << 1 */ + { 0x0000000064efe7c0, 0x000000003701a774 }, + /* x^6144 mod p(x)` << 1, x^6208 mod p(x)` << 1 */ + { 0x000000000ac2d904, 0x00000000ac81ef72 }, + /* x^5120 mod p(x)` << 1, x^5184 mod p(x)` << 1 */ + { 0x00000000fd226d14, 0x0000000133212464 }, + /* x^4096 mod p(x)` << 1, x^4160 mod p(x)` << 1 */ + { 0x000000011cfd42e0, 0x00000000e4e45610 }, + /* x^3072 mod p(x)` << 1, x^3136 mod p(x)` << 1 */ + { 0x000000016e5a5678, 0x000000000c1bd370 }, + /* x^2048 mod p(x)` << 1, x^2112 mod p(x)` << 1 */ + { 0x00000001d888fe22, 0x00000001a7b9e7a6 }, + /* x^1024 mod p(x)` << 1, x^1088 mod p(x)` << 1 */ + { 0x00000001af77fcd4, 0x000000007d657a10 } +#endif /* __LITTLE_ENDIAN__ */ + }; + +/* Reduce final 1024-2048 bits to 64 bits, shifting 32 bits to include the trailing 32 bits of zeros */ + +static const __vector unsigned long long vcrc_short_const[16] + __attribute__((aligned (16))) = { +#ifdef __LITTLE_ENDIAN__ + /* x^1952 mod p(x) , x^1984 mod p(x) , x^2016 mod p(x) , x^2048 mod p(x) */ + { 0x99168a18ec447f11, 0xed837b2613e8221e }, + /* x^1824 mod p(x) , x^1856 mod p(x) , x^1888 mod p(x) , x^1920 mod p(x) */ + { 0xe23e954e8fd2cd3c, 0xc8acdd8147b9ce5a }, + /* x^1696 mod p(x) , x^1728 mod p(x) , x^1760 mod p(x) , x^1792 mod p(x) */ + { 0x92f8befe6b1d2b53, 0xd9ad6d87d4277e25 }, + /* x^1568 mod p(x) , x^1600 mod p(x) , x^1632 mod p(x) , x^1664 mod p(x) */ + { 0xf38a3556291ea462, 0xc10ec5e033fbca3b }, + /* x^1440 mod p(x) , x^1472 mod p(x) , x^1504 mod p(x) , x^1536 mod p(x) */ + { 0x974ac56262b6ca4b, 0xc0b55b0e82e02e2f }, + /* x^1312 mod p(x) , x^1344 mod p(x) , x^1376 mod p(x) , x^1408 mod p(x) */ + { 0x855712b3784d2a56, 0x71aa1df0e172334d }, + /* x^1184 mod p(x) , x^1216 mod p(x) , x^1248 mod p(x) , x^1280 mod p(x) */ + { 0xa5abe9f80eaee722, 0xfee3053e3969324d }, + /* x^1056 mod p(x) , x^1088 mod p(x) , x^1120 mod p(x) , x^1152 mod p(x) */ + { 0x1fa0943ddb54814c, 0xf44779b93eb2bd08 }, + /* x^928 mod p(x) , x^960 mod p(x) , x^992 mod p(x) , x^1024 mod p(x) */ + { 0xa53ff440d7bbfe6a, 0xf5449b3f00cc3374 }, + /* x^800 mod p(x) , x^832 mod p(x) , x^864 mod p(x) , x^896 mod p(x) */ + { 0xebe7e3566325605c, 0x6f8346e1d777606e }, + /* x^672 mod p(x) , x^704 mod p(x) , x^736 mod p(x) , x^768 mod p(x) */ + { 0xc65a272ce5b592b8, 0xe3ab4f2ac0b95347 }, + /* x^544 mod p(x) , x^576 mod p(x) , x^608 mod p(x) , x^640 mod p(x) */ + { 0x5705a9ca4721589f, 0xaa2215ea329ecc11 }, + /* x^416 mod p(x) , x^448 mod p(x) , x^480 mod p(x) , x^512 mod p(x) */ + { 0xe3720acb88d14467, 0x1ed8f66ed95efd26 }, + /* x^288 mod p(x) , x^320 mod p(x) , x^352 mod p(x) , x^384 mod p(x) */ + { 0xba1aca0315141c31, 0x78ed02d5a700e96a }, + /* x^160 mod p(x) , x^192 mod p(x) , x^224 mod p(x) , x^256 mod p(x) */ + { 0xad2a31b3ed627dae, 0xba8ccbe832b39da3 }, + /* x^32 mod p(x) , x^64 mod p(x) , x^96 mod p(x) , x^128 mod p(x) */ + { 0x6655004fa06a2517, 0xedb88320b1e6b092 } +#else /* __LITTLE_ENDIAN__ */ + /* x^1952 mod p(x) , x^1984 mod p(x) , x^2016 mod p(x) , x^2048 mod p(x) */ + { 0xed837b2613e8221e, 0x99168a18ec447f11 }, + /* x^1824 mod p(x) , x^1856 mod p(x) , x^1888 mod p(x) , x^1920 mod p(x) */ + { 0xc8acdd8147b9ce5a, 0xe23e954e8fd2cd3c }, + /* x^1696 mod p(x) , x^1728 mod p(x) , x^1760 mod p(x) , x^1792 mod p(x) */ + { 0xd9ad6d87d4277e25, 0x92f8befe6b1d2b53 }, + /* x^1568 mod p(x) , x^1600 mod p(x) , x^1632 mod p(x) , x^1664 mod p(x) */ + { 0xc10ec5e033fbca3b, 0xf38a3556291ea462 }, + /* x^1440 mod p(x) , x^1472 mod p(x) , x^1504 mod p(x) , x^1536 mod p(x) */ + { 0xc0b55b0e82e02e2f, 0x974ac56262b6ca4b }, + /* x^1312 mod p(x) , x^1344 mod p(x) , x^1376 mod p(x) , x^1408 mod p(x) */ + { 0x71aa1df0e172334d, 0x855712b3784d2a56 }, + /* x^1184 mod p(x) , x^1216 mod p(x) , x^1248 mod p(x) , x^1280 mod p(x) */ + { 0xfee3053e3969324d, 0xa5abe9f80eaee722 }, + /* x^1056 mod p(x) , x^1088 mod p(x) , x^1120 mod p(x) , x^1152 mod p(x) */ + { 0xf44779b93eb2bd08, 0x1fa0943ddb54814c }, + /* x^928 mod p(x) , x^960 mod p(x) , x^992 mod p(x) , x^1024 mod p(x) */ + { 0xf5449b3f00cc3374, 0xa53ff440d7bbfe6a }, + /* x^800 mod p(x) , x^832 mod p(x) , x^864 mod p(x) , x^896 mod p(x) */ + { 0x6f8346e1d777606e, 0xebe7e3566325605c }, + /* x^672 mod p(x) , x^704 mod p(x) , x^736 mod p(x) , x^768 mod p(x) */ + { 0xe3ab4f2ac0b95347, 0xc65a272ce5b592b8 }, + /* x^544 mod p(x) , x^576 mod p(x) , x^608 mod p(x) , x^640 mod p(x) */ + { 0xaa2215ea329ecc11, 0x5705a9ca4721589f }, + /* x^416 mod p(x) , x^448 mod p(x) , x^480 mod p(x) , x^512 mod p(x) */ + { 0x1ed8f66ed95efd26, 0xe3720acb88d14467 }, + /* x^288 mod p(x) , x^320 mod p(x) , x^352 mod p(x) , x^384 mod p(x) */ + { 0x78ed02d5a700e96a, 0xba1aca0315141c31 }, + /* x^160 mod p(x) , x^192 mod p(x) , x^224 mod p(x) , x^256 mod p(x) */ + { 0xba8ccbe832b39da3, 0xad2a31b3ed627dae }, + /* x^32 mod p(x) , x^64 mod p(x) , x^96 mod p(x) , x^128 mod p(x) */ + { 0xedb88320b1e6b092, 0x6655004fa06a2517 } +#endif /* __LITTLE_ENDIAN__ */ + }; + +/* Barrett constants */ +/* 33 bit reflected Barrett constant m - (4^32)/n */ + +static const __vector unsigned long long v_Barrett_const[2] + __attribute__((aligned (16))) = { + /* x^64 div p(x) */ +#ifdef __LITTLE_ENDIAN__ + { 0x00000001f7011641, 0x0000000000000000 }, + { 0x00000001db710641, 0x0000000000000000 } +#else /* __LITTLE_ENDIAN__ */ + { 0x0000000000000000, 0x00000001f7011641 }, + { 0x0000000000000000, 0x00000001db710641 } +#endif /* __LITTLE_ENDIAN__ */ + }; +#endif /* POWER8_INTRINSICS */ + +#endif /* __ASSEMBLER__ */ Index: zlib-1.3.1/contrib/power/crc32_z_power8.c =================================================================== --- /dev/null +++ zlib-1.3.1/contrib/power/crc32_z_power8.c @@ -0,0 +1,679 @@ +/* + * Calculate the checksum of data that is 16 byte aligned and a multiple of + * 16 bytes. + * + * The first step is to reduce it to 1024 bits. We do this in 8 parallel + * chunks in order to mask the latency of the vpmsum instructions. If we + * have more than 32 kB of data to checksum we repeat this step multiple + * times, passing in the previous 1024 bits. + * + * The next step is to reduce the 1024 bits to 64 bits. This step adds + * 32 bits of 0s to the end - this matches what a CRC does. We just + * calculate constants that land the data in this 32 bits. + * + * We then use fixed point Barrett reduction to compute a mod n over GF(2) + * for n = CRC using POWER8 instructions. We use x = 32. + * + * http://en.wikipedia.org/wiki/Barrett_reduction + * + * This code uses gcc vector builtins instead using assembly directly. + * + * Copyright (C) 2017 Rogerio Alves , IBM + * + * This program is free software; you can redistribute it and/or + * modify it under the terms of either: + * + * a) the GNU General Public License as published by the Free Software + * Foundation; either version 2 of the License, or (at your option) + * any later version, or + * b) the Apache License, Version 2.0 + */ + +#include +#include "../../zutil.h" +#include "power.h" + +#define POWER8_INTRINSICS +#define CRC_TABLE + +#ifdef CRC32_CONSTANTS_HEADER +#include CRC32_CONSTANTS_HEADER +#else +#include "crc32_constants.h" +#endif + +#define VMX_ALIGN 16 +#define VMX_ALIGN_MASK (VMX_ALIGN-1) + +#ifdef REFLECT +static unsigned int crc32_align(unsigned int crc, const unsigned char *p, + unsigned long len) +{ + while (len--) + crc = crc_table[(crc ^ *p++) & 0xff] ^ (crc >> 8); + return crc; +} +#else +static unsigned int crc32_align(unsigned int crc, const unsigned char *p, + unsigned long len) +{ + while (len--) + crc = crc_table[((crc >> 24) ^ *p++) & 0xff] ^ (crc << 8); + return crc; +} +#endif + +static unsigned int __attribute__ ((aligned (32))) +__crc32_vpmsum(unsigned int crc, const void* p, unsigned long len); + +unsigned long ZLIB_INTERNAL _crc32_z_power8(uLong _crc, const Bytef *_p, + z_size_t _len) +{ + unsigned int prealign; + unsigned int tail; + + /* Map zlib API to crc32_vpmsum API */ + unsigned int crc = (unsigned int) (0xffffffff & _crc); + const unsigned char *p = _p; + unsigned long len = (unsigned long) _len; + + if (p == (const unsigned char *) 0x0) return 0; +#ifdef CRC_XOR + crc ^= 0xffffffff; +#endif + + if (len < VMX_ALIGN + VMX_ALIGN_MASK) { + crc = crc32_align(crc, p, len); + goto out; + } + + if ((unsigned long)p & VMX_ALIGN_MASK) { + prealign = VMX_ALIGN - ((unsigned long)p & VMX_ALIGN_MASK); + crc = crc32_align(crc, p, prealign); + len -= prealign; + p += prealign; + } + + crc = __crc32_vpmsum(crc, p, len & ~VMX_ALIGN_MASK); + + tail = len & VMX_ALIGN_MASK; + if (tail) { + p += len & ~VMX_ALIGN_MASK; + crc = crc32_align(crc, p, tail); + } + +out: +#ifdef CRC_XOR + crc ^= 0xffffffff; +#endif + + /* Convert to zlib API */ + return (unsigned long) crc; +} + +#if defined (__clang__) +#include "clang_workaround.h" +#else +#define __builtin_pack_vector(a, b) __builtin_pack_vector_int128 ((a), (b)) +#define __builtin_unpack_vector_0(a) __builtin_unpack_vector_int128 ((vector __int128_t)(a), 0) +#define __builtin_unpack_vector_1(a) __builtin_unpack_vector_int128 ((vector __int128_t)(a), 1) +#endif + +/* When we have a load-store in a single-dispatch group and address overlap + * such that foward is not allowed (load-hit-store) the group must be flushed. + * A group ending NOP prevents the flush. + */ +#define GROUP_ENDING_NOP asm("ori 2,2,0" ::: "memory") + +#if defined(__BIG_ENDIAN__) && defined (REFLECT) +#define BYTESWAP_DATA +#elif defined(__LITTLE_ENDIAN__) && !defined(REFLECT) +#define BYTESWAP_DATA +#endif + +#ifdef BYTESWAP_DATA +#define VEC_PERM(vr, va, vb, vc) vr = vec_perm(va, vb,\ + (__vector unsigned char) vc) +#if defined(__LITTLE_ENDIAN__) +/* Byte reverse permute constant LE. */ +static const __vector unsigned long long vperm_const + __attribute__ ((aligned(16))) = { 0x08090A0B0C0D0E0FUL, + 0x0001020304050607UL }; +#else +static const __vector unsigned long long vperm_const + __attribute__ ((aligned(16))) = { 0x0F0E0D0C0B0A0908UL, + 0X0706050403020100UL }; +#endif +#else +#define VEC_PERM(vr, va, vb, vc) +#endif + +static unsigned int __attribute__ ((aligned (32))) +__crc32_vpmsum(unsigned int crc, const void* p, unsigned long len) { + + const __vector unsigned long long vzero = {0,0}; + const __vector unsigned long long vones = {0xffffffffffffffffUL, + 0xffffffffffffffffUL}; + +#ifdef REFLECT + const __vector unsigned long long vmask_32bit = + (__vector unsigned long long)vec_sld((__vector unsigned char)vzero, + (__vector unsigned char)vones, 4); +#endif + + const __vector unsigned long long vmask_64bit = + (__vector unsigned long long)vec_sld((__vector unsigned char)vzero, + (__vector unsigned char)vones, 8); + + __vector unsigned long long vcrc; + + __vector unsigned long long vconst1, vconst2; + + /* vdata0-vdata7 will contain our data (p). */ + __vector unsigned long long vdata0, vdata1, vdata2, vdata3, vdata4, + vdata5, vdata6, vdata7; + + /* v0-v7 will contain our checksums */ + __vector unsigned long long v0 = {0,0}; + __vector unsigned long long v1 = {0,0}; + __vector unsigned long long v2 = {0,0}; + __vector unsigned long long v3 = {0,0}; + __vector unsigned long long v4 = {0,0}; + __vector unsigned long long v5 = {0,0}; + __vector unsigned long long v6 = {0,0}; + __vector unsigned long long v7 = {0,0}; + + + /* Vector auxiliary variables. */ + __vector unsigned long long va0, va1, va2, va3, va4, va5, va6, va7; + + unsigned int result = 0; + unsigned int offset; /* Constant table offset. */ + + unsigned long i; /* Counter. */ + unsigned long chunks; + + unsigned long block_size; + int next_block = 0; + + /* Align by 128 bits. The last 128 bit block will be processed at end. */ + unsigned long length = len & 0xFFFFFFFFFFFFFF80UL; + +#ifdef REFLECT + vcrc = (__vector unsigned long long)__builtin_pack_vector(0UL, crc); +#else + vcrc = (__vector unsigned long long)__builtin_pack_vector(crc, 0UL); + + /* Shift into top 32 bits */ + vcrc = (__vector unsigned long long)vec_sld((__vector unsigned char)vcrc, + (__vector unsigned char)vzero, 4); +#endif + + /* Short version. */ + if (len < 256) { + /* Calculate where in the constant table we need to start. */ + offset = 256 - len; + + vconst1 = vec_ld(offset, vcrc_short_const); + vdata0 = vec_ld(0, (__vector unsigned long long*) p); + VEC_PERM(vdata0, vdata0, vconst1, vperm_const); + + /* xor initial value*/ + vdata0 = vec_xor(vdata0, vcrc); + + vdata0 = (__vector unsigned long long) __builtin_crypto_vpmsumw + ((__vector unsigned int)vdata0, (__vector unsigned int)vconst1); + v0 = vec_xor(v0, vdata0); + + for (i = 16; i < len; i += 16) { + vconst1 = vec_ld(offset + i, vcrc_short_const); + vdata0 = vec_ld(i, (__vector unsigned long long*) p); + VEC_PERM(vdata0, vdata0, vconst1, vperm_const); + vdata0 = (__vector unsigned long long) __builtin_crypto_vpmsumw + ((__vector unsigned int)vdata0, (__vector unsigned int)vconst1); + v0 = vec_xor(v0, vdata0); + } + } else { + + /* Load initial values. */ + vdata0 = vec_ld(0, (__vector unsigned long long*) p); + vdata1 = vec_ld(16, (__vector unsigned long long*) p); + + VEC_PERM(vdata0, vdata0, vdata0, vperm_const); + VEC_PERM(vdata1, vdata1, vdata1, vperm_const); + + vdata2 = vec_ld(32, (__vector unsigned long long*) p); + vdata3 = vec_ld(48, (__vector unsigned long long*) p); + + VEC_PERM(vdata2, vdata2, vdata2, vperm_const); + VEC_PERM(vdata3, vdata3, vdata3, vperm_const); + + vdata4 = vec_ld(64, (__vector unsigned long long*) p); + vdata5 = vec_ld(80, (__vector unsigned long long*) p); + + VEC_PERM(vdata4, vdata4, vdata4, vperm_const); + VEC_PERM(vdata5, vdata5, vdata5, vperm_const); + + vdata6 = vec_ld(96, (__vector unsigned long long*) p); + vdata7 = vec_ld(112, (__vector unsigned long long*) p); + + VEC_PERM(vdata6, vdata6, vdata6, vperm_const); + VEC_PERM(vdata7, vdata7, vdata7, vperm_const); + + /* xor in initial value */ + vdata0 = vec_xor(vdata0, vcrc); + + p = (char *)p + 128; + + do { + /* Checksum in blocks of MAX_SIZE. */ + block_size = length; + if (block_size > MAX_SIZE) { + block_size = MAX_SIZE; + } + + length = length - block_size; + + /* + * Work out the offset into the constants table to start at. Each + * constant is 16 bytes, and it is used against 128 bytes of input + * data - 128 / 16 = 8 + */ + offset = (MAX_SIZE/8) - (block_size/8); + /* We reduce our final 128 bytes in a separate step */ + chunks = (block_size/128)-1; + + vconst1 = vec_ld(offset, vcrc_const); + + va0 = __builtin_crypto_vpmsumd ((__vector unsigned long long)vdata0, + (__vector unsigned long long)vconst1); + va1 = __builtin_crypto_vpmsumd ((__vector unsigned long long)vdata1, + (__vector unsigned long long)vconst1); + va2 = __builtin_crypto_vpmsumd ((__vector unsigned long long)vdata2, + (__vector unsigned long long)vconst1); + va3 = __builtin_crypto_vpmsumd ((__vector unsigned long long)vdata3, + (__vector unsigned long long)vconst1); + va4 = __builtin_crypto_vpmsumd ((__vector unsigned long long)vdata4, + (__vector unsigned long long)vconst1); + va5 = __builtin_crypto_vpmsumd ((__vector unsigned long long)vdata5, + (__vector unsigned long long)vconst1); + va6 = __builtin_crypto_vpmsumd ((__vector unsigned long long)vdata6, + (__vector unsigned long long)vconst1); + va7 = __builtin_crypto_vpmsumd ((__vector unsigned long long)vdata7, + (__vector unsigned long long)vconst1); + + if (chunks > 1) { + offset += 16; + vconst2 = vec_ld(offset, vcrc_const); + GROUP_ENDING_NOP; + + vdata0 = vec_ld(0, (__vector unsigned long long*) p); + VEC_PERM(vdata0, vdata0, vdata0, vperm_const); + + vdata1 = vec_ld(16, (__vector unsigned long long*) p); + VEC_PERM(vdata1, vdata1, vdata1, vperm_const); + + vdata2 = vec_ld(32, (__vector unsigned long long*) p); + VEC_PERM(vdata2, vdata2, vdata2, vperm_const); + + vdata3 = vec_ld(48, (__vector unsigned long long*) p); + VEC_PERM(vdata3, vdata3, vdata3, vperm_const); + + vdata4 = vec_ld(64, (__vector unsigned long long*) p); + VEC_PERM(vdata4, vdata4, vdata4, vperm_const); + + vdata5 = vec_ld(80, (__vector unsigned long long*) p); + VEC_PERM(vdata5, vdata5, vdata5, vperm_const); + + vdata6 = vec_ld(96, (__vector unsigned long long*) p); + VEC_PERM(vdata6, vdata6, vdata6, vperm_const); + + vdata7 = vec_ld(112, (__vector unsigned long long*) p); + VEC_PERM(vdata7, vdata7, vdata7, vperm_const); + + p = (char *)p + 128; + + /* + * main loop. We modulo schedule it such that it takes three + * iterations to complete - first iteration load, second + * iteration vpmsum, third iteration xor. + */ + for (i = 0; i < chunks-2; i++) { + vconst1 = vec_ld(offset, vcrc_const); + offset += 16; + GROUP_ENDING_NOP; + + v0 = vec_xor(v0, va0); + va0 = __builtin_crypto_vpmsumd ((__vector unsigned long + long)vdata0, (__vector unsigned long long)vconst2); + vdata0 = vec_ld(0, (__vector unsigned long long*) p); + VEC_PERM(vdata0, vdata0, vdata0, vperm_const); + GROUP_ENDING_NOP; + + v1 = vec_xor(v1, va1); + va1 = __builtin_crypto_vpmsumd ((__vector unsigned long + long)vdata1, (__vector unsigned long long)vconst2); + vdata1 = vec_ld(16, (__vector unsigned long long*) p); + VEC_PERM(vdata1, vdata1, vdata1, vperm_const); + GROUP_ENDING_NOP; + + v2 = vec_xor(v2, va2); + va2 = __builtin_crypto_vpmsumd ((__vector unsigned long + long)vdata2, (__vector unsigned long long)vconst2); + vdata2 = vec_ld(32, (__vector unsigned long long*) p); + VEC_PERM(vdata2, vdata2, vdata2, vperm_const); + GROUP_ENDING_NOP; + + v3 = vec_xor(v3, va3); + va3 = __builtin_crypto_vpmsumd ((__vector unsigned long + long)vdata3, (__vector unsigned long long)vconst2); + vdata3 = vec_ld(48, (__vector unsigned long long*) p); + VEC_PERM(vdata3, vdata3, vdata3, vperm_const); + + vconst2 = vec_ld(offset, vcrc_const); + GROUP_ENDING_NOP; + + v4 = vec_xor(v4, va4); + va4 = __builtin_crypto_vpmsumd ((__vector unsigned long + long)vdata4, (__vector unsigned long long)vconst1); + vdata4 = vec_ld(64, (__vector unsigned long long*) p); + VEC_PERM(vdata4, vdata4, vdata4, vperm_const); + GROUP_ENDING_NOP; + + v5 = vec_xor(v5, va5); + va5 = __builtin_crypto_vpmsumd ((__vector unsigned long + long)vdata5, (__vector unsigned long long)vconst1); + vdata5 = vec_ld(80, (__vector unsigned long long*) p); + VEC_PERM(vdata5, vdata5, vdata5, vperm_const); + GROUP_ENDING_NOP; + + v6 = vec_xor(v6, va6); + va6 = __builtin_crypto_vpmsumd ((__vector unsigned long + long)vdata6, (__vector unsigned long long)vconst1); + vdata6 = vec_ld(96, (__vector unsigned long long*) p); + VEC_PERM(vdata6, vdata6, vdata6, vperm_const); + GROUP_ENDING_NOP; + + v7 = vec_xor(v7, va7); + va7 = __builtin_crypto_vpmsumd ((__vector unsigned long + long)vdata7, (__vector unsigned long long)vconst1); + vdata7 = vec_ld(112, (__vector unsigned long long*) p); + VEC_PERM(vdata7, vdata7, vdata7, vperm_const); + + p = (char *)p + 128; + } + + /* First cool down*/ + vconst1 = vec_ld(offset, vcrc_const); + offset += 16; + + v0 = vec_xor(v0, va0); + va0 = __builtin_crypto_vpmsumd ((__vector unsigned long + long)vdata0, (__vector unsigned long long)vconst1); + GROUP_ENDING_NOP; + + v1 = vec_xor(v1, va1); + va1 = __builtin_crypto_vpmsumd ((__vector unsigned long + long)vdata1, (__vector unsigned long long)vconst1); + GROUP_ENDING_NOP; + + v2 = vec_xor(v2, va2); + va2 = __builtin_crypto_vpmsumd ((__vector unsigned long + long)vdata2, (__vector unsigned long long)vconst1); + GROUP_ENDING_NOP; + + v3 = vec_xor(v3, va3); + va3 = __builtin_crypto_vpmsumd ((__vector unsigned long + long)vdata3, (__vector unsigned long long)vconst1); + GROUP_ENDING_NOP; + + v4 = vec_xor(v4, va4); + va4 = __builtin_crypto_vpmsumd ((__vector unsigned long + long)vdata4, (__vector unsigned long long)vconst1); + GROUP_ENDING_NOP; + + v5 = vec_xor(v5, va5); + va5 = __builtin_crypto_vpmsumd ((__vector unsigned long + long)vdata5, (__vector unsigned long long)vconst1); + GROUP_ENDING_NOP; + + v6 = vec_xor(v6, va6); + va6 = __builtin_crypto_vpmsumd ((__vector unsigned long + long)vdata6, (__vector unsigned long long)vconst1); + GROUP_ENDING_NOP; + + v7 = vec_xor(v7, va7); + va7 = __builtin_crypto_vpmsumd ((__vector unsigned long + long)vdata7, (__vector unsigned long long)vconst1); + }/* else */ + + /* Second cool down. */ + v0 = vec_xor(v0, va0); + v1 = vec_xor(v1, va1); + v2 = vec_xor(v2, va2); + v3 = vec_xor(v3, va3); + v4 = vec_xor(v4, va4); + v5 = vec_xor(v5, va5); + v6 = vec_xor(v6, va6); + v7 = vec_xor(v7, va7); + +#ifdef REFLECT + /* + * vpmsumd produces a 96 bit result in the least significant bits + * of the register. Since we are bit reflected we have to shift it + * left 32 bits so it occupies the least significant bits in the + * bit reflected domain. + */ + v0 = (__vector unsigned long long)vec_sld((__vector unsigned char)v0, + (__vector unsigned char)vzero, 4); + v1 = (__vector unsigned long long)vec_sld((__vector unsigned char)v1, + (__vector unsigned char)vzero, 4); + v2 = (__vector unsigned long long)vec_sld((__vector unsigned char)v2, + (__vector unsigned char)vzero, 4); + v3 = (__vector unsigned long long)vec_sld((__vector unsigned char)v3, + (__vector unsigned char)vzero, 4); + v4 = (__vector unsigned long long)vec_sld((__vector unsigned char)v4, + (__vector unsigned char)vzero, 4); + v5 = (__vector unsigned long long)vec_sld((__vector unsigned char)v5, + (__vector unsigned char)vzero, 4); + v6 = (__vector unsigned long long)vec_sld((__vector unsigned char)v6, + (__vector unsigned char)vzero, 4); + v7 = (__vector unsigned long long)vec_sld((__vector unsigned char)v7, + (__vector unsigned char)vzero, 4); +#endif + + /* xor with the last 1024 bits. */ + va0 = vec_ld(0, (__vector unsigned long long*) p); + VEC_PERM(va0, va0, va0, vperm_const); + + va1 = vec_ld(16, (__vector unsigned long long*) p); + VEC_PERM(va1, va1, va1, vperm_const); + + va2 = vec_ld(32, (__vector unsigned long long*) p); + VEC_PERM(va2, va2, va2, vperm_const); + + va3 = vec_ld(48, (__vector unsigned long long*) p); + VEC_PERM(va3, va3, va3, vperm_const); + + va4 = vec_ld(64, (__vector unsigned long long*) p); + VEC_PERM(va4, va4, va4, vperm_const); + + va5 = vec_ld(80, (__vector unsigned long long*) p); + VEC_PERM(va5, va5, va5, vperm_const); + + va6 = vec_ld(96, (__vector unsigned long long*) p); + VEC_PERM(va6, va6, va6, vperm_const); + + va7 = vec_ld(112, (__vector unsigned long long*) p); + VEC_PERM(va7, va7, va7, vperm_const); + + p = (char *)p + 128; + + vdata0 = vec_xor(v0, va0); + vdata1 = vec_xor(v1, va1); + vdata2 = vec_xor(v2, va2); + vdata3 = vec_xor(v3, va3); + vdata4 = vec_xor(v4, va4); + vdata5 = vec_xor(v5, va5); + vdata6 = vec_xor(v6, va6); + vdata7 = vec_xor(v7, va7); + + /* Check if we have more blocks to process */ + next_block = 0; + if (length != 0) { + next_block = 1; + + /* zero v0-v7 */ + v0 = vec_xor(v0, v0); + v1 = vec_xor(v1, v1); + v2 = vec_xor(v2, v2); + v3 = vec_xor(v3, v3); + v4 = vec_xor(v4, v4); + v5 = vec_xor(v5, v5); + v6 = vec_xor(v6, v6); + v7 = vec_xor(v7, v7); + } + length = length + 128; + + } while (next_block); + + /* Calculate how many bytes we have left. */ + length = (len & 127); + + /* Calculate where in (short) constant table we need to start. */ + offset = 128 - length; + + v0 = vec_ld(offset, vcrc_short_const); + v1 = vec_ld(offset + 16, vcrc_short_const); + v2 = vec_ld(offset + 32, vcrc_short_const); + v3 = vec_ld(offset + 48, vcrc_short_const); + v4 = vec_ld(offset + 64, vcrc_short_const); + v5 = vec_ld(offset + 80, vcrc_short_const); + v6 = vec_ld(offset + 96, vcrc_short_const); + v7 = vec_ld(offset + 112, vcrc_short_const); + + offset += 128; + + v0 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( + (__vector unsigned int)vdata0,(__vector unsigned int)v0); + v1 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( + (__vector unsigned int)vdata1,(__vector unsigned int)v1); + v2 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( + (__vector unsigned int)vdata2,(__vector unsigned int)v2); + v3 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( + (__vector unsigned int)vdata3,(__vector unsigned int)v3); + v4 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( + (__vector unsigned int)vdata4,(__vector unsigned int)v4); + v5 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( + (__vector unsigned int)vdata5,(__vector unsigned int)v5); + v6 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( + (__vector unsigned int)vdata6,(__vector unsigned int)v6); + v7 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( + (__vector unsigned int)vdata7,(__vector unsigned int)v7); + + /* Now reduce the tail (0-112 bytes). */ + for (i = 0; i < length; i+=16) { + vdata0 = vec_ld(i,(__vector unsigned long long*)p); + VEC_PERM(vdata0, vdata0, vdata0, vperm_const); + va0 = vec_ld(offset + i,vcrc_short_const); + va0 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( + (__vector unsigned int)vdata0,(__vector unsigned int)va0); + v0 = vec_xor(v0, va0); + } + + /* xor all parallel chunks together. */ + v0 = vec_xor(v0, v1); + v2 = vec_xor(v2, v3); + v4 = vec_xor(v4, v5); + v6 = vec_xor(v6, v7); + + v0 = vec_xor(v0, v2); + v4 = vec_xor(v4, v6); + + v0 = vec_xor(v0, v4); + } + + /* Barrett Reduction */ + vconst1 = vec_ld(0, v_Barrett_const); + vconst2 = vec_ld(16, v_Barrett_const); + + v1 = (__vector unsigned long long)vec_sld((__vector unsigned char)v0, + (__vector unsigned char)v0, 8); + v0 = vec_xor(v1,v0); + +#ifdef REFLECT + /* shift left one bit */ + __vector unsigned char vsht_splat = vec_splat_u8 (1); + v0 = (__vector unsigned long long)vec_sll ((__vector unsigned char)v0, + vsht_splat); +#endif + + v0 = vec_and(v0, vmask_64bit); + +#ifndef REFLECT + + /* + * Now for the actual algorithm. The idea is to calculate q, + * the multiple of our polynomial that we need to subtract. By + * doing the computation 2x bits higher (ie 64 bits) and shifting the + * result back down 2x bits, we round down to the nearest multiple. + */ + + /* ma */ + v1 = __builtin_crypto_vpmsumd ((__vector unsigned long long)v0, + (__vector unsigned long long)vconst1); + /* q = floor(ma/(2^64)) */ + v1 = (__vector unsigned long long)vec_sld ((__vector unsigned char)vzero, + (__vector unsigned char)v1, 8); + /* qn */ + v1 = __builtin_crypto_vpmsumd ((__vector unsigned long long)v1, + (__vector unsigned long long)vconst2); + /* a - qn, subtraction is xor in GF(2) */ + v0 = vec_xor (v0, v1); + /* + * Get the result into r3. We need to shift it left 8 bytes: + * V0 [ 0 1 2 X ] + * V0 [ 0 X 2 3 ] + */ + result = __builtin_unpack_vector_1 (v0); +#else + + /* + * The reflected version of Barrett reduction. Instead of bit + * reflecting our data (which is expensive to do), we bit reflect our + * constants and our algorithm, which means the intermediate data in + * our vector registers goes from 0-63 instead of 63-0. We can reflect + * the algorithm because we don't carry in mod 2 arithmetic. + */ + + /* bottom 32 bits of a */ + v1 = vec_and(v0, vmask_32bit); + + /* ma */ + v1 = __builtin_crypto_vpmsumd ((__vector unsigned long long)v1, + (__vector unsigned long long)vconst1); + + /* bottom 32bits of ma */ + v1 = vec_and(v1, vmask_32bit); + /* qn */ + v1 = __builtin_crypto_vpmsumd ((__vector unsigned long long)v1, + (__vector unsigned long long)vconst2); + /* a - qn, subtraction is xor in GF(2) */ + v0 = vec_xor (v0, v1); + + /* + * Since we are bit reflected, the result (ie the low 32 bits) is in + * the high 32 bits. We just need to shift it left 4 bytes + * V0 [ 0 1 X 3 ] + * V0 [ 0 X 2 3 ] + */ + + /* shift result into top 64 bits of */ + v0 = (__vector unsigned long long)vec_sld((__vector unsigned char)v0, + (__vector unsigned char)vzero, 4); + + result = __builtin_unpack_vector_0 (v0); +#endif + + return result; +} Index: zlib-1.3.1/contrib/power/crc32_z_resolver.c =================================================================== --- /dev/null +++ zlib-1.3.1/contrib/power/crc32_z_resolver.c @@ -0,0 +1,15 @@ +/* Copyright (C) 2019 Matheus Castanho , IBM + * For conditions of distribution and use, see copyright notice in zlib.h + */ + +#include "../gcc/zifunc.h" +#include "power.h" + +Z_IFUNC(crc32_z) { +#ifdef Z_POWER8 + if (__builtin_cpu_supports("arch_2_07")) + return _crc32_z_power8; +#endif + + return crc32_z_default; +} Index: zlib-1.3.1/crc32.c =================================================================== --- zlib-1.3.1.orig/crc32.c +++ zlib-1.3.1/crc32.c @@ -691,6 +691,13 @@ local z_word_t crc_word_big(z_word_t dat #endif /* ========================================================================= */ +#if defined(Z_POWER_OPT) || defined(HAVE_S390X_VX) +/* Rename function so resolver can use its symbol. The default version will be + * returned by the resolver if the host has no support for an optimized version. + */ +#define crc32_z crc32_z_default +#endif /* defined(Z_POWER_OPT) || defined(HAVE_S390X_VX) */ + unsigned long ZEXPORT crc32_z(unsigned long crc, const unsigned char FAR *buf, z_size_t len) { /* Return initial CRC, if requested. */ @@ -1009,6 +1016,16 @@ unsigned long ZEXPORT crc32_z(unsigned l return crc ^ 0xffffffff; } +#if defined(Z_POWER_OPT) || defined(HAVE_S390X_VX) +#undef crc32_z +#ifdef Z_POWER_OPT +#include "contrib/power/crc32_z_resolver.c" +#endif /* Z_POWER_OPT */ +#ifdef HAVE_S390X_VX +#include "contrib/s390/crc32_z_resolver.c" +#endif /* HAVE_S390X_VX */ +#endif /* defined(Z_POWER_OPT) || defined(HAVE_S390X_VX) */ + #endif /* ========================================================================= */ Index: zlib-1.3.1/test/crc32_test.c =================================================================== --- /dev/null +++ zlib-1.3.1/test/crc32_test.c @@ -0,0 +1,205 @@ +/* crc32_tes.c -- unit test for crc32 in the zlib compression library + * Copyright (C) 1995-2006, 2010, 2011, 2016, 2019 Rogerio Alves + * For conditions of distribution and use, see copyright notice in zlib.h + */ + +#include "zlib.h" +#include + +#ifdef STDC +# include +# include +#endif + +void test_crc32 OF((uLong crc, Byte* buf, z_size_t len, uLong chk, int line)); +int main OF((void)); + +typedef struct { + int line; + uLong crc; + char* buf; + int len; + uLong expect; +} crc32_test; + +void test_crc32(crc, buf, len, chk, line) + uLong crc; + Byte *buf; + z_size_t len; + uLong chk; + int line; +{ + uLong res = crc32(crc, buf, len); + if (res != chk) { + fprintf(stderr, "FAIL [%d]: crc32 returned 0x%08X expected 0x%08X\n", + line, (unsigned int)res, (unsigned int)chk); + exit(1); + } +} + +static const crc32_test tests[] = { + {__LINE__, 0x0, 0x0, 0, 0x0}, + {__LINE__, 0xffffffff, 0x0, 0, 0x0}, + {__LINE__, 0x0, 0x0, 255, 0x0}, /* BZ 174799. */ + {__LINE__, 0x0, 0x0, 256, 0x0}, + {__LINE__, 0x0, 0x0, 257, 0x0}, + {__LINE__, 0x0, 0x0, 32767, 0x0}, + {__LINE__, 0x0, 0x0, 32768, 0x0}, + {__LINE__, 0x0, 0x0, 32769, 0x0}, + {__LINE__, 0x0, "", 0, 0x0}, + {__LINE__, 0xffffffff, "", 0, 0xffffffff}, + {__LINE__, 0x0, "abacus", 6, 0xc3d7115b}, + {__LINE__, 0x0, "backlog", 7, 0x269205}, + {__LINE__, 0x0, "campfire", 8, 0x22a515f8}, + {__LINE__, 0x0, "delta", 5, 0x9643fed9}, + {__LINE__, 0x0, "executable", 10, 0xd68eda01}, + {__LINE__, 0x0, "file", 4, 0x8c9f3610}, + {__LINE__, 0x0, "greatest", 8, 0xc1abd6cd}, + {__LINE__, 0x0, "hello", 5, 0x3610a686}, + {__LINE__, 0x0, "inverter", 8, 0xc9e962c9}, + {__LINE__, 0x0, "jigsaw", 6, 0xce4e3f69}, + {__LINE__, 0x0, "karate", 6, 0x890be0e2}, + {__LINE__, 0x0, "landscape", 9, 0xc4e0330b}, + {__LINE__, 0x0, "machine", 7, 0x1505df84}, + {__LINE__, 0x0, "nanometer", 9, 0xd4e19f39}, + {__LINE__, 0x0, "oblivion", 8, 0xdae9de77}, + {__LINE__, 0x0, "panama", 6, 0x66b8979c}, + {__LINE__, 0x0, "quest", 5, 0x4317f817}, + {__LINE__, 0x0, "resource", 8, 0xbc91f416}, + {__LINE__, 0x0, "secret", 6, 0x5ca2e8e5}, + {__LINE__, 0x0, "test", 4, 0xd87f7e0c}, + {__LINE__, 0x0, "ultimate", 8, 0x3fc79b0b}, + {__LINE__, 0x0, "vector", 6, 0x1b6e485b}, + {__LINE__, 0x0, "walrus", 6, 0xbe769b97}, + {__LINE__, 0x0, "xeno", 4, 0xe7a06444}, + {__LINE__, 0x0, "yelling", 7, 0xfe3944e5}, + {__LINE__, 0x0, "zlib", 4, 0x73887d3a}, + {__LINE__, 0x0, "4BJD7PocN1VqX0jXVpWB", 20, 0xd487a5a1}, + {__LINE__, 0x0, "F1rPWI7XvDs6nAIRx41l", 20, 0x61a0132e}, + {__LINE__, 0x0, "ldhKlsVkPFOveXgkGtC2", 20, 0xdf02f76}, + {__LINE__, 0x0, "5KKnGOOrs8BvJ35iKTOS", 20, 0x579b2b0a}, + {__LINE__, 0x0, "0l1tw7GOcem06Ddu7yn4", 20, 0xf7d16e2d}, + {__LINE__, 0x0, "MCr47CjPIn9R1IvE1Tm5", 20, 0x731788f5}, + {__LINE__, 0x0, "UcixbzPKTIv0SvILHVdO", 20, 0x7112bb11}, + {__LINE__, 0x0, "dGnAyAhRQDsWw0ESou24", 20, 0xf32a0dac}, + {__LINE__, 0x0, "di0nvmY9UYMYDh0r45XT", 20, 0x625437bb}, + {__LINE__, 0x0, "2XKDwHfAhFsV0RhbqtvH", 20, 0x896930f9}, + {__LINE__, 0x0, "ZhrANFIiIvRnqClIVyeD", 20, 0x8579a37}, + {__LINE__, 0x0, "v7Q9ehzioTOVeDIZioT1", 20, 0x632aa8e0}, + {__LINE__, 0x0, "Yod5hEeKcYqyhfXbhxj2", 20, 0xc829af29}, + {__LINE__, 0x0, "GehSWY2ay4uUKhehXYb0", 20, 0x1b08b7e8}, + {__LINE__, 0x0, "kwytJmq6UqpflV8Y8GoE", 20, 0x4e33b192}, + {__LINE__, 0x0, "70684206568419061514", 20, 0x59a179f0}, + {__LINE__, 0x0, "42015093765128581010", 20, 0xcd1013d7}, + {__LINE__, 0x0, "88214814356148806939", 20, 0xab927546}, + {__LINE__, 0x0, "43472694284527343838", 20, 0x11f3b20c}, + {__LINE__, 0x0, "49769333513942933689", 20, 0xd562d4ca}, + {__LINE__, 0x0, "54979784887993251199", 20, 0x233395f7}, + {__LINE__, 0x0, "58360544869206793220", 20, 0x2d167fd5}, + {__LINE__, 0x0, "27347953487840714234", 20, 0x8b5108ba}, + {__LINE__, 0x0, "07650690295365319082", 20, 0xc46b3cd8}, + {__LINE__, 0x0, "42655507906821911703", 20, 0xc10b2662}, + {__LINE__, 0x0, "29977409200786225655", 20, 0xc9a0f9d2}, + {__LINE__, 0x0, "85181542907229116674", 20, 0x9341357b}, + {__LINE__, 0x0, "87963594337989416799", 20, 0xf0424937}, + {__LINE__, 0x0, "21395988329504168551", 20, 0xd7c4c31f}, + {__LINE__, 0x0, "51991013580943379423", 20, 0xf11edcc4}, + {__LINE__, 0x0, "*]+@!);({_$;}[_},?{?;(_?,=-][@", 30, 0x40795df4}, + {__LINE__, 0x0, "_@:_).&(#.[:[{[:)$++-($_;@[)}+", 30, 0xdd61a631}, + {__LINE__, 0x0, "&[!,[$_==}+.]@!;*(+},[;:)$;)-@", 30, 0xca907a99}, + {__LINE__, 0x0, "]{.[.+?+[[=;[?}_#&;[=)__$$:+=_", 30, 0xf652deac}, + {__LINE__, 0x0, "-%.)=/[@].:.(:,()$;=%@-$?]{%+%", 30, 0xaf39a5a9}, + {__LINE__, 0x0, "+]#$(@&.=:,*];/.!]%/{:){:@(;)$", 30, 0x6bebb4cf}, + {__LINE__, 0x0, ")-._.:?[&:.=+}(*$/=!.${;(=$@!}", 30, 0x76430bac}, + {__LINE__, 0x0, ":(_*&%/[[}+,?#$&*+#[([*-/#;%(]", 30, 0x6c80c388}, + {__LINE__, 0x0, "{[#-;:$/{)(+[}#]/{&!%(@)%:@-$:", 30, 0xd54d977d}, + {__LINE__, 0x0, "_{$*,}(&,@.)):=!/%(&(,,-?$}}}!", 30, 0xe3966ad5}, + {__LINE__, 0x0, "e$98KNzqaV)Y:2X?]77].{gKRD4G5{mHZk,Z)SpU%L3FSgv!Wb8MLAFdi{+fp)c,@8m6v)yXg@]HBDFk?.4&}g5_udE*JHCiH=aL", 100, 0xe7c71db9}, + {__LINE__, 0x0, "r*Fd}ef+5RJQ;+W=4jTR9)R*p!B;]Ed7tkrLi;88U7g@3v!5pk2X6D)vt,.@N8c]@yyEcKi[vwUu@.Ppm@C6%Mv*3Nw}Y,58_aH)", 100, 0xeaa52777}, + {__LINE__, 0x0, "h{bcmdC+a;t+Cf{6Y_dFq-{X4Yu&7uNfVDh?q&_u.UWJU],-GiH7ADzb7-V.Q%4=+v!$L9W+T=bP]$_:]Vyg}A.ygD.r;h-D]m%&", 100, 0xcd472048}, + {__LINE__, 0x7a30360d, "abacus", 6, 0xf8655a84}, + {__LINE__, 0x6fd767ee, "backlog", 7, 0x1ed834b1}, + {__LINE__, 0xefeb7589, "campfire", 8, 0x686cfca}, + {__LINE__, 0x61cf7e6b, "delta", 5, 0x1554e4b1}, + {__LINE__, 0xdc712e2, "executable", 10, 0x761b4254}, + {__LINE__, 0xad23c7fd, "file", 4, 0x7abdd09b}, + {__LINE__, 0x85cb2317, "greatest", 8, 0x4ba91c6b}, + {__LINE__, 0x9eed31b0, "inverter", 8, 0xd5e78ba5}, + {__LINE__, 0xb94f34ca, "jigsaw", 6, 0x23649109}, + {__LINE__, 0xab058a2, "karate", 6, 0xc5591f41}, + {__LINE__, 0x5bff2b7a, "landscape", 9, 0xf10eb644}, + {__LINE__, 0x605c9a5f, "machine", 7, 0xbaa0a636}, + {__LINE__, 0x51bdeea5, "nanometer", 9, 0x6af89afb}, + {__LINE__, 0x85c21c79, "oblivion", 8, 0xecae222b}, + {__LINE__, 0x97216f56, "panama", 6, 0x47dffac4}, + {__LINE__, 0x18444af2, "quest", 5, 0x70c2fe36}, + {__LINE__, 0xbe6ce359, "resource", 8, 0x1471d925}, + {__LINE__, 0x843071f1, "secret", 6, 0x50c9a0db}, + {__LINE__, 0xf2480c60, "ultimate", 8, 0xf973daf8}, + {__LINE__, 0x2d2feb3d, "vector", 6, 0x344ac03d}, + {__LINE__, 0x7490310a, "walrus", 6, 0x6d1408ef}, + {__LINE__, 0x97d247d4, "xeno", 4, 0xe62670b5}, + {__LINE__, 0x93cf7599, "yelling", 7, 0x1b36da38}, + {__LINE__, 0x73c84278, "zlib", 4, 0x6432d127}, + {__LINE__, 0x228a87d1, "4BJD7PocN1VqX0jXVpWB", 20, 0x997107d0}, + {__LINE__, 0xa7a048d0, "F1rPWI7XvDs6nAIRx41l", 20, 0xdc567274}, + {__LINE__, 0x1f0ded40, "ldhKlsVkPFOveXgkGtC2", 20, 0xdcc63870}, + {__LINE__, 0xa804a62f, "5KKnGOOrs8BvJ35iKTOS", 20, 0x6926cffd}, + {__LINE__, 0x508fae6a, "0l1tw7GOcem06Ddu7yn4", 20, 0xb52b38bc}, + {__LINE__, 0xe5adaf4f, "MCr47CjPIn9R1IvE1Tm5", 20, 0xf83b8178}, + {__LINE__, 0x67136a40, "UcixbzPKTIv0SvILHVdO", 20, 0xc5213070}, + {__LINE__, 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"27347953487840714234", 20, 0x4ad14a12}, + {__LINE__, 0x49511de0, "07650690295365319082", 20, 0xe37b5c6c}, + {__LINE__, 0x3db13bc1, "42655507906821911703", 20, 0x7cc497f1}, + {__LINE__, 0xbb899bea, "29977409200786225655", 20, 0x99781bb2}, + {__LINE__, 0xf6cd9436, "85181542907229116674", 20, 0x132256a1}, + {__LINE__, 0x9109e6c3, "87963594337989416799", 20, 0xbfdb2c83}, + {__LINE__, 0x75770fc, "21395988329504168551", 20, 0x8d9d1e81}, + {__LINE__, 0x69b1d19b, "51991013580943379423", 20, 0x7b6d4404}, + {__LINE__, 0xc6132975, "*]+@!);({_$;}[_},?{?;(_?,=-][@", 30, 0x8619f010}, + {__LINE__, 0xd58cb00c, "_@:_).&(#.[:[{[:)$++-($_;@[)}+", 30, 0x15746ac3}, + {__LINE__, 0xb63b8caa, "&[!,[$_==}+.]@!;*(+},[;:)$;)-@", 30, 0xaccf812f}, + {__LINE__, 0x8a45a2b8, "]{.[.+?+[[=;[?}_#&;[=)__$$:+=_", 30, 0x78af45de}, + {__LINE__, 0xcbe95b78, "-%.)=/[@].:.(:,()$;=%@-$?]{%+%", 30, 0x25b06b59}, + {__LINE__, 0x4ef8a54b, "+]#$(@&.=:,*];/.!]%/{:){:@(;)$", 30, 0x4ba0d08f}, + {__LINE__, 0x76ad267a, ")-._.:?[&:.=+}(*$/=!.${;(=$@!}", 30, 0xe26b6aac}, + {__LINE__, 0x569e613c, ":(_*&%/[[}+,?#$&*+#[([*-/#;%(]", 30, 0x7e2b0a66}, + {__LINE__, 0x36aa61da, "{[#-;:$/{)(+[}#]/{&!%(@)%:@-$:", 30, 0xb3430dc7}, + {__LINE__, 0xf67222df, "_{$*,}(&,@.)):=!/%(&(,,-?$}}}!", 30, 0x626c17a}, + {__LINE__, 0x74b34fd3, "e$98KNzqaV)Y:2X?]77].{gKRD4G5{mHZk,Z)SpU%L3FSgv!Wb8MLAFdi{+fp)c,@8m6v)yXg@]HBDFk?.4&}g5_udE*JHCiH=aL", 100, 0xccf98060}, + {__LINE__, 0x351fd770, "r*Fd}ef+5RJQ;+W=4jTR9)R*p!B;]Ed7tkrLi;88U7g@3v!5pk2X6D)vt,.@N8c]@yyEcKi[vwUu@.Ppm@C6%Mv*3Nw}Y,58_aH)", 100, 0xd8b95312}, + {__LINE__, 0xc45aef77, "h{bcmdC+a;t+Cf{6Y_dFq-{X4Yu&7uNfVDh?q&_u.UWJU],-GiH7ADzb7-V.Q%4=+v!$L9W+T=bP]$_:]Vyg}A.ygD.r;h-D]m%&", 100, 0xbb1c9912}, + {__LINE__, 0xc45aef77, "h{bcmdC+a;t+Cf{6Y_dFq-{X4Yu&7uNfVDh?q&_u.UWJU],-GiH7ADzb7-V.Q%4=+v!$L9W+T=bP]$_:]Vyg}A.ygD.r;h-D]m%&" + "h{bcmdC+a;t+Cf{6Y_dFq-{X4Yu&7uNfVDh?q&_u.UWJU],-GiH7ADzb7-V.Q%4=+v!$L9W+T=bP]$_:]Vyg}A.ygD.r;h-D]m%&" + "h{bcmdC+a;t+Cf{6Y_dFq-{X4Yu&7uNfVDh?q&_u.UWJU],-GiH7ADzb7-V.Q%4=+v!$L9W+T=bP]$_:]Vyg}A.ygD.r;h-D]m%&" + "h{bcmdC+a;t+Cf{6Y_dFq-{X4Yu&7uNfVDh?q&_u.UWJU],-GiH7ADzb7-V.Q%4=+v!$L9W+T=bP]$_:]Vyg}A.ygD.r;h-D]m%&" + "h{bcmdC+a;t+Cf{6Y_dFq-{X4Yu&7uNfVDh?q&_u.UWJU],-GiH7ADzb7-V.Q%4=+v!$L9W+T=bP]$_:]Vyg}A.ygD.r;h-D]m%&" + "h{bcmdC+a;t+Cf{6Y_dFq-{X4Yu&7uNfVDh?q&_u.UWJU],-GiH7ADzb7-V.Q%4=+v!$L9W+T=bP]$_:]Vyg}A.ygD.r;h-D]m%&", 600, 0x888AFA5B} +}; + +static const int test_size = sizeof(tests) / sizeof(tests[0]); + +int main(void) +{ + int i; + for (i = 0; i < test_size; i++) { + test_crc32(tests[i].crc, (Byte*) tests[i].buf, tests[i].len, + tests[i].expect, tests[i].line); + } + return 0; +} Index: zlib-1.3.1/contrib/s390/crc32-vx.c =================================================================== --- /dev/null +++ zlib-1.3.1/contrib/s390/crc32-vx.c @@ -0,0 +1,195 @@ +/* + * Hardware-accelerated CRC-32 variants for Linux on z Systems + * + * Use the z/Architecture Vector Extension Facility to accelerate the + * computing of bitreflected CRC-32 checksums. + * + * This CRC-32 implementation algorithm is bitreflected and processes + * the least-significant bit first (Little-Endian). + * + * This code was originally written by Hendrik Brueckner + * for use in the Linux kernel and has been + * relicensed under the zlib license. + */ + +#include "../../zutil.h" + +#include +#include + +typedef unsigned char uv16qi __attribute__((vector_size(16))); +typedef unsigned int uv4si __attribute__((vector_size(16))); +typedef unsigned long long uv2di __attribute__((vector_size(16))); + +uint32_t crc32_le_vgfm_16(uint32_t crc, const unsigned char *buf, size_t len) { + /* + * The CRC-32 constant block contains reduction constants to fold and + * process particular chunks of the input data stream in parallel. + * + * For the CRC-32 variants, the constants are precomputed according to + * these definitions: + * + * R1 = [(x4*128+32 mod P'(x) << 32)]' << 1 + * R2 = [(x4*128-32 mod P'(x) << 32)]' << 1 + * R3 = [(x128+32 mod P'(x) << 32)]' << 1 + * R4 = [(x128-32 mod P'(x) << 32)]' << 1 + * R5 = [(x64 mod P'(x) << 32)]' << 1 + * R6 = [(x32 mod P'(x) << 32)]' << 1 + * + * The bitreflected Barret reduction constant, u', is defined as + * the bit reversal of floor(x**64 / P(x)). + * + * where P(x) is the polynomial in the normal domain and the P'(x) is the + * polynomial in the reversed (bitreflected) domain. + * + * CRC-32 (IEEE 802.3 Ethernet, ...) polynomials: + * + * P(x) = 0x04C11DB7 + * P'(x) = 0xEDB88320 + */ + const uv16qi perm_le2be = {15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1, 0}; /* BE->LE mask */ + const uv2di r2r1 = {0x1C6E41596, 0x154442BD4}; /* R2, R1 */ + const uv2di r4r3 = {0x0CCAA009E, 0x1751997D0}; /* R4, R3 */ + const uv2di r5 = {0, 0x163CD6124}; /* R5 */ + const uv2di ru_poly = {0, 0x1F7011641}; /* u' */ + const uv2di crc_poly = {0, 0x1DB710641}; /* P'(x) << 1 */ + + /* + * Load the initial CRC value. + * + * The CRC value is loaded into the rightmost word of the + * vector register and is later XORed with the LSB portion + * of the loaded input data. + */ + uv2di v0 = {0, 0}; + v0 = (uv2di)vec_insert(crc, (uv4si)v0, 3); + + /* Load a 64-byte data chunk and XOR with CRC */ + uv2di v1 = vec_perm(((uv2di *)buf)[0], ((uv2di *)buf)[0], perm_le2be); + uv2di v2 = vec_perm(((uv2di *)buf)[1], ((uv2di *)buf)[1], perm_le2be); + uv2di v3 = vec_perm(((uv2di *)buf)[2], ((uv2di *)buf)[2], perm_le2be); + uv2di v4 = vec_perm(((uv2di *)buf)[3], ((uv2di *)buf)[3], perm_le2be); + + v1 ^= v0; + buf += 64; + len -= 64; + + while (len >= 64) { + /* Load the next 64-byte data chunk */ + uv16qi part1 = vec_perm(((uv16qi *)buf)[0], ((uv16qi *)buf)[0], perm_le2be); + uv16qi part2 = vec_perm(((uv16qi *)buf)[1], ((uv16qi *)buf)[1], perm_le2be); + uv16qi part3 = vec_perm(((uv16qi *)buf)[2], ((uv16qi *)buf)[2], perm_le2be); + uv16qi part4 = vec_perm(((uv16qi *)buf)[3], ((uv16qi *)buf)[3], perm_le2be); + + /* + * Perform a GF(2) multiplication of the doublewords in V1 with + * the R1 and R2 reduction constants in V0. The intermediate result + * is then folded (accumulated) with the next data chunk in PART1 and + * stored in V1. Repeat this step for the register contents + * in V2, V3, and V4 respectively. + */ + v1 = (uv2di)vec_gfmsum_accum_128(r2r1, v1, part1); + v2 = (uv2di)vec_gfmsum_accum_128(r2r1, v2, part2); + v3 = (uv2di)vec_gfmsum_accum_128(r2r1, v3, part3); + v4 = (uv2di)vec_gfmsum_accum_128(r2r1, v4, part4); + + buf += 64; + len -= 64; + } + + /* + * Fold V1 to V4 into a single 128-bit value in V1. Multiply V1 with R3 + * and R4 and accumulating the next 128-bit chunk until a single 128-bit + * value remains. + */ + v1 = (uv2di)vec_gfmsum_accum_128(r4r3, v1, (uv16qi)v2); + v1 = (uv2di)vec_gfmsum_accum_128(r4r3, v1, (uv16qi)v3); + v1 = (uv2di)vec_gfmsum_accum_128(r4r3, v1, (uv16qi)v4); + + while (len >= 16) { + /* Load next data chunk */ + v2 = vec_perm(*(uv2di *)buf, *(uv2di *)buf, perm_le2be); + + /* Fold next data chunk */ + v1 = (uv2di)vec_gfmsum_accum_128(r4r3, v1, (uv16qi)v2); + + buf += 16; + len -= 16; + } + + /* + * Set up a vector register for byte shifts. The shift value must + * be loaded in bits 1-4 in byte element 7 of a vector register. + * Shift by 8 bytes: 0x40 + * Shift by 4 bytes: 0x20 + */ + uv16qi v9 = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0}; + v9 = vec_insert((unsigned char)0x40, v9, 7); + + /* + * Prepare V0 for the next GF(2) multiplication: shift V0 by 8 bytes + * to move R4 into the rightmost doubleword and set the leftmost + * doubleword to 0x1. + */ + v0 = vec_srb(r4r3, (uv2di)v9); + v0[0] = 1; + + /* + * Compute GF(2) product of V1 and V0. The rightmost doubleword + * of V1 is multiplied with R4. The leftmost doubleword of V1 is + * multiplied by 0x1 and is then XORed with rightmost product. + * Implicitly, the intermediate leftmost product becomes padded + */ + v1 = (uv2di)vec_gfmsum_128(v0, v1); + + /* + * Now do the final 32-bit fold by multiplying the rightmost word + * in V1 with R5 and XOR the result with the remaining bits in V1. + * + * To achieve this by a single VGFMAG, right shift V1 by a word + * and store the result in V2 which is then accumulated. Use the + * vector unpack instruction to load the rightmost half of the + * doubleword into the rightmost doubleword element of V1; the other + * half is loaded in the leftmost doubleword. + * The vector register with CONST_R5 contains the R5 constant in the + * rightmost doubleword and the leftmost doubleword is zero to ignore + * the leftmost product of V1. + */ + v9 = vec_insert((unsigned char)0x20, v9, 7); + v2 = vec_srb(v1, (uv2di)v9); + v1 = vec_unpackl((uv4si)v1); /* Split rightmost doubleword */ + v1 = (uv2di)vec_gfmsum_accum_128(r5, v1, (uv16qi)v2); + + /* + * Apply a Barret reduction to compute the final 32-bit CRC value. + * + * The input values to the Barret reduction are the degree-63 polynomial + * in V1 (R(x)), degree-32 generator polynomial, and the reduction + * constant u. The Barret reduction result is the CRC value of R(x) mod + * P(x). + * + * The Barret reduction algorithm is defined as: + * + * 1. T1(x) = floor( R(x) / x^32 ) GF2MUL u + * 2. T2(x) = floor( T1(x) / x^32 ) GF2MUL P(x) + * 3. C(x) = R(x) XOR T2(x) mod x^32 + * + * Note: The leftmost doubleword of vector register containing + * CONST_RU_POLY is zero and, thus, the intermediate GF(2) product + * is zero and does not contribute to the final result. + */ + + /* T1(x) = floor( R(x) / x^32 ) GF2MUL u */ + v2 = vec_unpackl((uv4si)v1); + v2 = (uv2di)vec_gfmsum_128(ru_poly, v2); + + /* + * Compute the GF(2) product of the CRC polynomial with T1(x) in + * V2 and XOR the intermediate result, T2(x), with the value in V1. + * The final result is stored in word element 2 of V2. + */ + v2 = vec_unpackl((uv4si)v2); + v2 = (uv2di)vec_gfmsum_accum_128(crc_poly, v2, (uv16qi)v1); + + return ((uv4si)v2)[2]; +} Index: zlib-1.3.1/contrib/s390/crc32_z_resolver.c =================================================================== --- /dev/null +++ zlib-1.3.1/contrib/s390/crc32_z_resolver.c @@ -0,0 +1,41 @@ +#include +#include "../gcc/zifunc.h" + +#define VX_MIN_LEN 64 +#define VX_ALIGNMENT 16L +#define VX_ALIGN_MASK (VX_ALIGNMENT - 1) + +unsigned int crc32_le_vgfm_16(unsigned int crc, const unsigned char FAR *buf, z_size_t len); + +local unsigned long s390_crc32_vx(unsigned long crc, const unsigned char FAR *buf, z_size_t len) +{ + uintptr_t prealign, aligned, remaining; + + if (buf == Z_NULL) return 0UL; + + if (len < VX_MIN_LEN + VX_ALIGN_MASK) + return crc32_z_default(crc, buf, len); + + if ((uintptr_t)buf & VX_ALIGN_MASK) { + prealign = VX_ALIGNMENT - ((uintptr_t)buf & VX_ALIGN_MASK); + len -= prealign; + crc = crc32_z_default(crc, buf, prealign); + buf += prealign; + } + aligned = len & ~VX_ALIGN_MASK; + remaining = len & VX_ALIGN_MASK; + + crc = crc32_le_vgfm_16(crc ^ 0xffffffff, buf, (size_t)aligned) ^ 0xffffffff; + + if (remaining) + crc = crc32_z_default(crc, buf + aligned, remaining); + + return crc; +} + +Z_IFUNC(crc32_z) +{ + if (hwcap & HWCAP_S390_VX) + return s390_crc32_vx; + return crc32_z_default; +} Index: zlib-1.3.1/compress.c =================================================================== --- zlib-1.3.1.orig/compress.c +++ zlib-1.3.1/compress.c @@ -5,9 +5,15 @@ /* @(#) $Id$ */ -#define ZLIB_INTERNAL +#include "zutil.h" #include "zlib.h" +#ifdef DFLTCC +# include "contrib/s390/dfltcc.h" +#else +#define DEFLATE_BOUND_COMPLEN(source_len) 0 +#endif + /* =========================================================================== Compresses the source buffer into the destination buffer. The level parameter has the same meaning as in deflateInit. sourceLen is the byte @@ -70,6 +76,12 @@ int ZEXPORT compress(Bytef *dest, uLongf this function needs to be updated. */ uLong ZEXPORT compressBound(uLong sourceLen) { + uLong complen = DEFLATE_BOUND_COMPLEN(sourceLen); + + if (complen > 0) + /* Architecture-specific code provided an upper bound. */ + return complen + ZLIB_WRAPLEN; + return sourceLen + (sourceLen >> 12) + (sourceLen >> 14) + (sourceLen >> 25) + 13; } Index: zlib-1.3.1/contrib/s390/README.txt =================================================================== --- /dev/null +++ zlib-1.3.1/contrib/s390/README.txt @@ -0,0 +1,17 @@ +IBM Z mainframes starting from version z15 provide DFLTCC instruction, +which implements deflate algorithm in hardware with estimated +compression and decompression performance orders of magnitude faster +than the current zlib and ratio comparable with that of level 1. + +This directory adds DFLTCC support. In order to enable it, the following +build commands should be used: + + $ ./configure --dfltcc + $ make + +When built like this, zlib would compress in hardware on level 1, and in +software on all other levels. Decompression will always happen in +hardware. In order to enable DFLTCC compression for levels 1-6 (i.e. to +make it used by default) one could either configure with +--dfltcc-level-mask=0x7e or set the environment variable +DFLTCC_LEVEL_MASK to 0x7e at run time. Index: zlib-1.3.1/contrib/s390/dfltcc.c =================================================================== --- /dev/null +++ zlib-1.3.1/contrib/s390/dfltcc.c @@ -0,0 +1,1004 @@ +/* dfltcc.c - SystemZ DEFLATE CONVERSION CALL support. */ + +/* + Use the following commands to build zlib with DFLTCC support: + + $ ./configure --dfltcc + $ make +*/ + +#define _GNU_SOURCE +#include +#include +#include +#include +#include +#include +#include +#include "../../zutil.h" +#include "../../deflate.h" +#include "../../inftrees.h" +#include "../../inflate.h" +#include "dfltcc.h" +#include "dfltcc_deflate.h" +#ifdef HAVE_SYS_SDT_H +#include +#endif + +/* + C wrapper for the DEFLATE CONVERSION CALL instruction. + */ +typedef enum { + DFLTCC_CC_OK = 0, + DFLTCC_CC_OP1_TOO_SHORT = 1, + DFLTCC_CC_OP2_TOO_SHORT = 2, + DFLTCC_CC_OP2_CORRUPT = 2, + DFLTCC_CC_AGAIN = 3, +} dfltcc_cc; + +#define DFLTCC_QAF 0 +#define DFLTCC_GDHT 1 +#define DFLTCC_CMPR 2 +#define DFLTCC_XPND 4 +#define HBT_CIRCULAR (1 << 7) +#define HB_BITS 15 +#define HB_SIZE (1 << HB_BITS) +#define DFLTCC_FACILITY 151 + +local inline dfltcc_cc dfltcc(int fn, void *param, + Bytef **op1, size_t *len1, + z_const Bytef **op2, size_t *len2, + void *hist) +{ + Bytef *t2 = op1 ? *op1 : NULL; + size_t t3 = len1 ? *len1 : 0; + z_const Bytef *t4 = op2 ? *op2 : NULL; + size_t t5 = len2 ? *len2 : 0; + register int r0 __asm__("r0") = fn; + register void *r1 __asm__("r1") = param; + register Bytef *r2 __asm__("r2") = t2; + register size_t r3 __asm__("r3") = t3; + register z_const Bytef *r4 __asm__("r4") = t4; + register size_t r5 __asm__("r5") = t5; + int cc; + + __asm__ volatile( +#ifdef HAVE_SYS_SDT_H + STAP_PROBE_ASM(zlib, dfltcc_entry, + STAP_PROBE_ASM_TEMPLATE(5)) +#endif + ".insn rrf,0xb9390000,%[r2],%[r4],%[hist],0\n" +#ifdef HAVE_SYS_SDT_H + STAP_PROBE_ASM(zlib, dfltcc_exit, + STAP_PROBE_ASM_TEMPLATE(5)) +#endif + "ipm %[cc]\n" + : [r2] "+r" (r2) + , [r3] "+r" (r3) + , [r4] "+r" (r4) + , [r5] "+r" (r5) + , [cc] "=r" (cc) + : [r0] "r" (r0) + , [r1] "r" (r1) + , [hist] "r" (hist) +#ifdef HAVE_SYS_SDT_H + , STAP_PROBE_ASM_OPERANDS(5, r2, r3, r4, r5, hist) +#endif + : "cc", "memory"); + t2 = r2; t3 = r3; t4 = r4; t5 = r5; + + if (op1) + *op1 = t2; + if (len1) + *len1 = t3; + if (op2) + *op2 = t4; + if (len2) + *len2 = t5; + return (cc >> 28) & 3; +} + +/* + Parameter Block for Query Available Functions. + */ +#define static_assert(c, msg) \ + __attribute__((unused)) \ + static char static_assert_failed_ ## msg[c ? 1 : -1] + +struct dfltcc_qaf_param { + char fns[16]; + char reserved1[8]; + char fmts[2]; + char reserved2[6]; +}; + +static_assert(sizeof(struct dfltcc_qaf_param) == 32, + sizeof_struct_dfltcc_qaf_param_is_32); + +local inline int is_bit_set(const char *bits, int n) +{ + return bits[n / 8] & (1 << (7 - (n % 8))); +} + +local inline void clear_bit(char *bits, int n) +{ + bits[n / 8] &= ~(1 << (7 - (n % 8))); +} + +#define DFLTCC_FMT0 0 + +/* + Parameter Block for Generate Dynamic-Huffman Table, Compress and Expand. + */ +#define CVT_CRC32 0 +#define CVT_ADLER32 1 +#define HTT_FIXED 0 +#define HTT_DYNAMIC 1 + +struct dfltcc_param_v0 { + uint16_t pbvn; /* Parameter-Block-Version Number */ + uint8_t mvn; /* Model-Version Number */ + uint8_t ribm; /* Reserved for IBM use */ + unsigned reserved32 : 31; + unsigned cf : 1; /* Continuation Flag */ + uint8_t reserved64[8]; + unsigned nt : 1; /* New Task */ + unsigned reserved129 : 1; + unsigned cvt : 1; /* Check Value Type */ + unsigned reserved131 : 1; + unsigned htt : 1; /* Huffman-Table Type */ + unsigned bcf : 1; /* Block-Continuation Flag */ + unsigned bcc : 1; /* Block Closing Control */ + unsigned bhf : 1; /* Block Header Final */ + unsigned reserved136 : 1; + unsigned reserved137 : 1; + unsigned dhtgc : 1; /* DHT Generation Control */ + unsigned reserved139 : 5; + unsigned reserved144 : 5; + unsigned sbb : 3; /* Sub-Byte Boundary */ + uint8_t oesc; /* Operation-Ending-Supplemental Code */ + unsigned reserved160 : 12; + unsigned ifs : 4; /* Incomplete-Function Status */ + uint16_t ifl; /* Incomplete-Function Length */ + uint8_t reserved192[8]; + uint8_t reserved256[8]; + uint8_t reserved320[4]; + uint16_t hl; /* History Length */ + unsigned reserved368 : 1; + uint16_t ho : 15; /* History Offset */ + uint32_t cv; /* Check Value */ + unsigned eobs : 15; /* End-of-block Symbol */ + unsigned reserved431: 1; + uint8_t eobl : 4; /* End-of-block Length */ + unsigned reserved436 : 12; + unsigned reserved448 : 4; + uint16_t cdhtl : 12; /* Compressed-Dynamic-Huffman Table + Length */ + uint8_t reserved464[6]; + uint8_t cdht[288]; + uint8_t reserved[32]; + uint8_t csb[1152]; +}; + +static_assert(sizeof(struct dfltcc_param_v0) == 1536, + sizeof_struct_dfltcc_param_v0_is_1536); + +local z_const char *oesc_msg(char *buf, int oesc) +{ + if (oesc == 0x00) + return NULL; /* Successful completion */ + else { + sprintf(buf, "Operation-Ending-Supplemental Code is 0x%.2X", oesc); + return buf; + } +} + +/* + Extension of inflate_state and deflate_state. Must be doubleword-aligned. +*/ +struct dfltcc_state { + struct dfltcc_param_v0 param; /* Parameter block. */ + struct dfltcc_qaf_param af; /* Available functions. */ + uLong level_mask; /* Levels on which to use DFLTCC */ + uLong block_size; /* New block each X bytes */ + uLong block_threshold; /* New block after total_in > X */ + uLong dht_threshold; /* New block only if avail_in >= X */ + char msg[64]; /* Buffer for strm->msg */ +}; + +#define ALIGN_UP(p, size) \ + (__typeof__(p))(((uintptr_t)(p) + ((size) - 1)) & ~((size) - 1)) + +#define GET_DFLTCC_STATE(state) ((struct dfltcc_state *)( \ + (char *)(state) + ALIGN_UP(sizeof(*state), 8))) + +/* + Compress. + */ +local inline int dfltcc_can_deflate_with_params(z_streamp strm, + int level, + uInt window_bits, + int strategy) +{ + deflate_state *state = (deflate_state *)strm->state; + struct dfltcc_state *dfltcc_state = GET_DFLTCC_STATE(state); + + /* Unsupported compression settings */ + if ((dfltcc_state->level_mask & (1 << level)) == 0) + return 0; + if (window_bits != HB_BITS) + return 0; + if (strategy != Z_FIXED && strategy != Z_DEFAULT_STRATEGY) + return 0; + + /* Unsupported hardware */ + if (!is_bit_set(dfltcc_state->af.fns, DFLTCC_GDHT) || + !is_bit_set(dfltcc_state->af.fns, DFLTCC_CMPR) || + !is_bit_set(dfltcc_state->af.fmts, DFLTCC_FMT0)) + return 0; + + return 1; +} + +int ZLIB_INTERNAL dfltcc_can_deflate(z_streamp strm) +{ + deflate_state *state = (deflate_state *)strm->state; + + return dfltcc_can_deflate_with_params(strm, + state->level, + state->w_bits, + state->strategy); +} + +local void dfltcc_gdht(z_streamp strm) +{ + deflate_state *state = (deflate_state *)strm->state; + struct dfltcc_param_v0 *param = &GET_DFLTCC_STATE(state)->param; + size_t avail_in = avail_in = strm->avail_in; + + dfltcc(DFLTCC_GDHT, + param, NULL, NULL, + &strm->next_in, &avail_in, NULL); +} + +local dfltcc_cc dfltcc_cmpr(z_streamp strm) +{ + deflate_state *state = (deflate_state *)strm->state; + struct dfltcc_param_v0 *param = &GET_DFLTCC_STATE(state)->param; + size_t avail_in = strm->avail_in; + size_t avail_out = strm->avail_out; + dfltcc_cc cc; + + cc = dfltcc(DFLTCC_CMPR | HBT_CIRCULAR, + param, &strm->next_out, &avail_out, + &strm->next_in, &avail_in, state->window); + strm->total_in += (strm->avail_in - avail_in); + strm->total_out += (strm->avail_out - avail_out); + strm->avail_in = avail_in; + strm->avail_out = avail_out; + return cc; +} + +local void send_eobs(z_streamp strm, + z_const struct dfltcc_param_v0 *param) +{ + deflate_state *state = (deflate_state *)strm->state; + + _tr_send_bits( + state, + bi_reverse(param->eobs >> (15 - param->eobl), param->eobl), + param->eobl); + flush_pending(strm); + if (state->pending != 0) { + /* The remaining data is located in pending_out[0:pending]. If someone + * calls put_byte() - this might happen in deflate() - the byte will be + * placed into pending_buf[pending], which is incorrect. Move the + * remaining data to the beginning of pending_buf so that put_byte() is + * usable again. + */ + memmove(state->pending_buf, state->pending_out, state->pending); + state->pending_out = state->pending_buf; + } +#ifdef ZLIB_DEBUG + state->compressed_len += param->eobl; +#endif +} + +int ZLIB_INTERNAL dfltcc_deflate(z_streamp strm, int flush, + block_state *result) +{ + deflate_state *state = (deflate_state *)strm->state; + struct dfltcc_state *dfltcc_state = GET_DFLTCC_STATE(state); + struct dfltcc_param_v0 *param = &dfltcc_state->param; + uInt masked_avail_in; + dfltcc_cc cc; + int need_empty_block; + int soft_bcc; + int no_flush; + + if (!dfltcc_can_deflate(strm)) { + /* Clear history. */ + if (flush == Z_FULL_FLUSH) + param->hl = 0; + return 0; + } + +again: + masked_avail_in = 0; + soft_bcc = 0; + no_flush = flush == Z_NO_FLUSH; + + /* No input data. Return, except when Continuation Flag is set, which means + * that DFLTCC has buffered some output in the parameter block and needs to + * be called again in order to flush it. + */ + if (strm->avail_in == 0 && !param->cf) { + /* A block is still open, and the hardware does not support closing + * blocks without adding data. Thus, close it manually. + */ + if (!no_flush && param->bcf) { + send_eobs(strm, param); + param->bcf = 0; + } + /* Let one of deflate_* functions write a trailing empty block. */ + if (flush == Z_FINISH) + return 0; + /* Clear history. */ + if (flush == Z_FULL_FLUSH) + param->hl = 0; + /* Trigger block post-processing if necessary. */ + *result = no_flush ? need_more : block_done; + return 1; + } + + /* There is an open non-BFINAL block, we are not going to close it just + * yet, we have compressed more than DFLTCC_BLOCK_SIZE bytes and we see + * more than DFLTCC_DHT_MIN_SAMPLE_SIZE bytes. Open a new block with a new + * DHT in order to adapt to a possibly changed input data distribution. + */ + if (param->bcf && no_flush && + strm->total_in > dfltcc_state->block_threshold && + strm->avail_in >= dfltcc_state->dht_threshold) { + if (param->cf) { + /* We need to flush the DFLTCC buffer before writing the + * End-of-block Symbol. Mask the input data and proceed as usual. + */ + masked_avail_in += strm->avail_in; + strm->avail_in = 0; + no_flush = 0; + } else { + /* DFLTCC buffer is empty, so we can manually write the + * End-of-block Symbol right away. + */ + send_eobs(strm, param); + param->bcf = 0; + dfltcc_state->block_threshold = + strm->total_in + dfltcc_state->block_size; + } + } + + /* No space for compressed data. If we proceed, dfltcc_cmpr() will return + * DFLTCC_CC_OP1_TOO_SHORT without buffering header bits, but we will still + * set BCF=1, which is wrong. Avoid complications and return early. + */ + if (strm->avail_out == 0) { + *result = need_more; + return 1; + } + + /* The caller gave us too much data. Pass only one block worth of + * uncompressed data to DFLTCC and mask the rest, so that on the next + * iteration we start a new block. + */ + if (no_flush && strm->avail_in > dfltcc_state->block_size) { + masked_avail_in += (strm->avail_in - dfltcc_state->block_size); + strm->avail_in = dfltcc_state->block_size; + } + + /* When we have an open non-BFINAL deflate block and caller indicates that + * the stream is ending, we need to close an open deflate block and open a + * BFINAL one. + */ + need_empty_block = flush == Z_FINISH && param->bcf && !param->bhf; + + /* Translate stream to parameter block */ + param->cvt = state->wrap == 2 ? CVT_CRC32 : CVT_ADLER32; + if (!no_flush) + /* We need to close a block. Always do this in software - when there is + * no input data, the hardware will not honor BCC. */ + soft_bcc = 1; + if (flush == Z_FINISH && !param->bcf) + /* We are about to open a BFINAL block, set Block Header Final bit + * until the stream ends. + */ + param->bhf = 1; + /* DFLTCC-CMPR will write to next_out, so make sure that buffers with + * higher precedence are empty. + */ + Assert(state->pending == 0, "There must be no pending bytes"); + Assert(state->bi_valid < 8, "There must be less than 8 pending bits"); + param->sbb = (unsigned int)state->bi_valid; + if (param->sbb > 0) + *strm->next_out = (Bytef)state->bi_buf; + /* Honor history and check value */ + param->nt = 0; + if (state->wrap == 1) + param->cv = strm->adler; + else if (state->wrap == 2) + param->cv = ZSWAP32(strm->adler); + + /* When opening a block, choose a Huffman-Table Type */ + if (!param->bcf) { + if (state->strategy == Z_FIXED || + (strm->total_in == 0 && dfltcc_state->block_threshold > 0)) + param->htt = HTT_FIXED; + else { + param->htt = HTT_DYNAMIC; + dfltcc_gdht(strm); + } + } + + /* Deflate */ + do { + cc = dfltcc_cmpr(strm); + if (strm->avail_in < 4096 && masked_avail_in > 0) + /* We are about to call DFLTCC with a small input buffer, which is + * inefficient. Since there is masked data, there will be at least + * one more DFLTCC call, so skip the current one and make the next + * one handle more data. + */ + break; + } while (cc == DFLTCC_CC_AGAIN); + + /* Translate parameter block to stream */ + strm->msg = oesc_msg(dfltcc_state->msg, param->oesc); + state->bi_valid = param->sbb; + if (state->bi_valid == 0) + state->bi_buf = 0; /* Avoid accessing next_out */ + else + state->bi_buf = *strm->next_out & ((1 << state->bi_valid) - 1); + if (state->wrap == 1) + strm->adler = param->cv; + else if (state->wrap == 2) + strm->adler = ZSWAP32(param->cv); + + /* Unmask the input data */ + strm->avail_in += masked_avail_in; + masked_avail_in = 0; + + /* If we encounter an error, it means there is a bug in DFLTCC call */ + Assert(cc != DFLTCC_CC_OP2_CORRUPT || param->oesc == 0, "BUG"); + + /* Update Block-Continuation Flag. It will be used to check whether to call + * GDHT the next time. + */ + if (cc == DFLTCC_CC_OK) { + if (soft_bcc) { + send_eobs(strm, param); + param->bcf = 0; + dfltcc_state->block_threshold = + strm->total_in + dfltcc_state->block_size; + } else + param->bcf = 1; + if (flush == Z_FINISH) { + if (need_empty_block) + /* Make the current deflate() call also close the stream */ + return 0; + else { + bi_windup(state); + *result = finish_done; + } + } else { + if (flush == Z_FULL_FLUSH) + param->hl = 0; /* Clear history */ + *result = flush == Z_NO_FLUSH ? need_more : block_done; + } + } else { + param->bcf = 1; + *result = need_more; + } + if (strm->avail_in != 0 && strm->avail_out != 0) + goto again; /* deflate() must use all input or all output */ + return 1; +} + +/* + Expand. + */ +int ZLIB_INTERNAL dfltcc_can_inflate(z_streamp strm) +{ + struct inflate_state *state = (struct inflate_state *)strm->state; + struct dfltcc_state *dfltcc_state = GET_DFLTCC_STATE(state); + + /* Unsupported hardware */ + return is_bit_set(dfltcc_state->af.fns, DFLTCC_XPND) && + is_bit_set(dfltcc_state->af.fmts, DFLTCC_FMT0); +} + +local dfltcc_cc dfltcc_xpnd(z_streamp strm) +{ + struct inflate_state *state = (struct inflate_state *)strm->state; + struct dfltcc_param_v0 *param = &GET_DFLTCC_STATE(state)->param; + size_t avail_in = strm->avail_in; + size_t avail_out = strm->avail_out; + dfltcc_cc cc; + + cc = dfltcc(DFLTCC_XPND | HBT_CIRCULAR, + param, &strm->next_out, &avail_out, + &strm->next_in, &avail_in, state->window); + strm->avail_in = avail_in; + strm->avail_out = avail_out; + return cc; +} + +dfltcc_inflate_action ZLIB_INTERNAL dfltcc_inflate(z_streamp strm, int flush, + int *ret) +{ + struct inflate_state *state = (struct inflate_state *)strm->state; + struct dfltcc_state *dfltcc_state = GET_DFLTCC_STATE(state); + struct dfltcc_param_v0 *param = &dfltcc_state->param; + dfltcc_cc cc; + + if (flush == Z_BLOCK || flush == Z_TREES) { + /* DFLTCC does not support stopping on block boundaries */ + if (dfltcc_inflate_disable(strm)) { + *ret = Z_STREAM_ERROR; + return DFLTCC_INFLATE_BREAK; + } else + return DFLTCC_INFLATE_SOFTWARE; + } + + if (state->last) { + if (state->bits != 0) { + strm->next_in++; + strm->avail_in--; + state->bits = 0; + } + state->mode = CHECK; + return DFLTCC_INFLATE_CONTINUE; + } + + if (strm->avail_in == 0 && !param->cf) + return DFLTCC_INFLATE_BREAK; + + if (inflate_ensure_window(state)) { + state->mode = MEM; + return DFLTCC_INFLATE_CONTINUE; + } + + /* Translate stream to parameter block */ + param->cvt = ((state->wrap & 4) && state->flags) ? CVT_CRC32 : CVT_ADLER32; + param->sbb = state->bits; + if (param->hl) + param->nt = 0; /* Honor history for the first block */ + if (state->wrap & 4) + param->cv = state->flags ? ZSWAP32(state->check) : state->check; + + /* Inflate */ + do { + cc = dfltcc_xpnd(strm); + } while (cc == DFLTCC_CC_AGAIN); + + /* Translate parameter block to stream */ + strm->msg = oesc_msg(dfltcc_state->msg, param->oesc); + state->last = cc == DFLTCC_CC_OK; + state->bits = param->sbb; + if (state->wrap & 4) + strm->adler = state->check = state->flags ? + ZSWAP32(param->cv) : param->cv; + if (cc == DFLTCC_CC_OP2_CORRUPT && param->oesc != 0) { + /* Report an error if stream is corrupted */ + state->mode = BAD; + return DFLTCC_INFLATE_CONTINUE; + } + state->mode = TYPEDO; + /* Break if operands are exhausted, otherwise continue looping */ + return (cc == DFLTCC_CC_OP1_TOO_SHORT || cc == DFLTCC_CC_OP2_TOO_SHORT) ? + DFLTCC_INFLATE_BREAK : DFLTCC_INFLATE_CONTINUE; +} + +int ZLIB_INTERNAL dfltcc_was_inflate_used(z_streamp strm) +{ + struct inflate_state *state = (struct inflate_state *)strm->state; + struct dfltcc_param_v0 *param = &GET_DFLTCC_STATE(state)->param; + + return !param->nt; +} + +/* + Rotates a circular buffer. + The implementation is based on https://cplusplus.com/reference/algorithm/rotate/ + */ +local void rotate(Bytef *start, Bytef *pivot, Bytef *end) +{ + Bytef *p = pivot; + Bytef tmp; + + while (p != start) { + tmp = *start; + *start = *p; + *p = tmp; + + start++; + p++; + + if (p == end) + p = pivot; + else if (start == pivot) + pivot = p; + } +} + +#define MIN(x, y) ({ \ + typeof(x) _x = (x); \ + typeof(y) _y = (y); \ + _x < _y ? _x : _y; \ +}) + +#define MAX(x, y) ({ \ + typeof(x) _x = (x); \ + typeof(y) _y = (y); \ + _x > _y ? _x : _y; \ +}) + +int ZLIB_INTERNAL dfltcc_inflate_disable(z_streamp strm) +{ + struct inflate_state *state = (struct inflate_state *)strm->state; + struct dfltcc_state *dfltcc_state = GET_DFLTCC_STATE(state); + struct dfltcc_param_v0 *param = &dfltcc_state->param; + + if (!dfltcc_can_inflate(strm)) + return 0; + if (dfltcc_was_inflate_used(strm)) + /* DFLTCC has already decompressed some data. Since there is not + * enough information to resume decompression in software, the call + * must fail. + */ + return 1; + /* DFLTCC was not used yet - decompress in software */ + memset(&dfltcc_state->af, 0, sizeof(dfltcc_state->af)); + /* Convert the window from the hardware to the software format */ + rotate(state->window, state->window + param->ho, state->window + HB_SIZE); + state->whave = state->wnext = MIN(param->hl, state->wsize); + return 0; +} + +local int env_dfltcc_disabled; +local int env_source_date_epoch; +local unsigned long env_level_mask; +local unsigned long env_block_size; +local unsigned long env_block_threshold; +local unsigned long env_dht_threshold; +local unsigned long env_ribm; +local uint64_t cpu_facilities[(DFLTCC_FACILITY / 64) + 1]; +local struct dfltcc_qaf_param cpu_af __attribute__((aligned(8))); + +local inline int is_dfltcc_enabled(void) +{ + if (env_dfltcc_disabled) + /* User has explicitly disabled DFLTCC. */ + return 0; + + return is_bit_set((const char *)cpu_facilities, DFLTCC_FACILITY); +} + +local unsigned long xstrtoul(const char *s, unsigned long _default) +{ + char *endptr; + unsigned long result; + + if (!(s && *s)) + return _default; + errno = 0; + result = strtoul(s, &endptr, 0); + return (errno || *endptr) ? _default : result; +} + +__attribute__((constructor)) local void init_globals(void) +{ + const char *env; + register char r0 __asm__("r0"); + + env = secure_getenv("DFLTCC"); + env_dfltcc_disabled = env && !strcmp(env, "0"); + + env = secure_getenv("SOURCE_DATE_EPOCH"); + env_source_date_epoch = !!env; + +#ifndef DFLTCC_LEVEL_MASK +#define DFLTCC_LEVEL_MASK 0x2 +#endif + env_level_mask = xstrtoul(secure_getenv("DFLTCC_LEVEL_MASK"), + DFLTCC_LEVEL_MASK); + +#ifndef DFLTCC_BLOCK_SIZE +#define DFLTCC_BLOCK_SIZE 1048576 +#endif + env_block_size = xstrtoul(secure_getenv("DFLTCC_BLOCK_SIZE"), + DFLTCC_BLOCK_SIZE); + +#ifndef DFLTCC_FIRST_FHT_BLOCK_SIZE +#define DFLTCC_FIRST_FHT_BLOCK_SIZE 4096 +#endif + env_block_threshold = xstrtoul(secure_getenv("DFLTCC_FIRST_FHT_BLOCK_SIZE"), + DFLTCC_FIRST_FHT_BLOCK_SIZE); + +#ifndef DFLTCC_DHT_MIN_SAMPLE_SIZE +#define DFLTCC_DHT_MIN_SAMPLE_SIZE 4096 +#endif + env_dht_threshold = xstrtoul(secure_getenv("DFLTCC_DHT_MIN_SAMPLE_SIZE"), + DFLTCC_DHT_MIN_SAMPLE_SIZE); + +#ifndef DFLTCC_RIBM +#define DFLTCC_RIBM 0 +#endif + env_ribm = xstrtoul(secure_getenv("DFLTCC_RIBM"), DFLTCC_RIBM); + + memset(cpu_facilities, 0, sizeof(cpu_facilities)); + r0 = sizeof(cpu_facilities) / sizeof(cpu_facilities[0]) - 1; + /* STFLE is supported since z9-109 and only in z/Architecture mode. When + * compiling with -m31, gcc defaults to ESA mode, however, since the kernel + * is 64-bit, it's always z/Architecture mode at runtime. + */ + __asm__ volatile( +#ifndef __clang__ + ".machinemode push\n" + ".machinemode zarch\n" +#endif + "stfle %[facilities]\n" +#ifndef __clang__ + ".machinemode pop\n" +#endif + : [facilities] "=Q" (cpu_facilities) + , [r0] "+r" (r0) + : + : "cc"); + + /* Initialize available functions */ + if (is_dfltcc_enabled()) + dfltcc(DFLTCC_QAF, &cpu_af, NULL, NULL, NULL, NULL, NULL); + else + memset(&cpu_af, 0, sizeof(cpu_af)); +} + +/* + Memory management. + + DFLTCC requires parameter blocks and window to be aligned. zlib allows + users to specify their own allocation functions, so using e.g. + `posix_memalign' is not an option. Thus, we overallocate and take the + aligned portion of the buffer. +*/ +void ZLIB_INTERNAL dfltcc_reset(z_streamp strm, uInt size) +{ + struct dfltcc_state *dfltcc_state = + (struct dfltcc_state *)((char *)strm->state + ALIGN_UP(size, 8)); + + memcpy(&dfltcc_state->af, &cpu_af, sizeof(dfltcc_state->af)); + + if (env_source_date_epoch) + /* User needs reproducible results, but the output of DFLTCC_CMPR + * depends on buffers' page offsets. + */ + clear_bit(dfltcc_state->af.fns, DFLTCC_CMPR); + + /* Initialize parameter block */ + memset(&dfltcc_state->param, 0, sizeof(dfltcc_state->param)); + dfltcc_state->param.nt = 1; + + /* Initialize tuning parameters */ + dfltcc_state->level_mask = env_level_mask; + dfltcc_state->block_size = env_block_size; + dfltcc_state->block_threshold = env_block_threshold; + dfltcc_state->dht_threshold = env_dht_threshold; + dfltcc_state->param.ribm = env_ribm; +} + +voidpf ZLIB_INTERNAL dfltcc_alloc_state(z_streamp strm, uInt items, uInt size) +{ + return ZALLOC(strm, + ALIGN_UP(items * size, 8) + sizeof(struct dfltcc_state), + sizeof(unsigned char)); +} + +void ZLIB_INTERNAL dfltcc_copy_state(voidpf dst, const voidpf src, uInt size) +{ + zmemcpy(dst, src, ALIGN_UP(size, 8) + sizeof(struct dfltcc_state)); +} + +static const int PAGE_ALIGN = 0x1000; + +voidpf ZLIB_INTERNAL dfltcc_alloc_window(z_streamp strm, uInt items, uInt size) +{ + voidpf p, w; + + /* To simplify freeing, we store the pointer to the allocated buffer right + * before the window. Note that DFLTCC always uses HB_SIZE bytes. + */ + p = ZALLOC(strm, sizeof(voidpf) + MAX(items * size, HB_SIZE) + PAGE_ALIGN, + sizeof(unsigned char)); + if (p == NULL) + return NULL; + w = ALIGN_UP((char *)p + sizeof(voidpf), PAGE_ALIGN); + *(voidpf *)((char *)w - sizeof(voidpf)) = p; + return w; +} + +void ZLIB_INTERNAL dfltcc_copy_window(void *dest, const void *src, size_t n) +{ + memcpy(dest, src, MAX(n, HB_SIZE)); +} + +void ZLIB_INTERNAL dfltcc_free_window(z_streamp strm, voidpf w) +{ + if (w) + ZFREE(strm, *(voidpf *)((unsigned char *)w - sizeof(voidpf))); +} + +/* + Switching between hardware and software compression. + + DFLTCC does not support all zlib settings, e.g. generation of non-compressed + blocks or alternative window sizes. When such settings are applied on the + fly with deflateParams, we need to convert between hardware and software + window formats. +*/ +int ZLIB_INTERNAL dfltcc_deflate_params(z_streamp strm, int level, + int strategy, int *flush) +{ + deflate_state *state = (deflate_state *)strm->state; + struct dfltcc_state *dfltcc_state = GET_DFLTCC_STATE(state); + struct dfltcc_param_v0 *param = &dfltcc_state->param; + int could_deflate = dfltcc_can_deflate(strm); + int can_deflate = dfltcc_can_deflate_with_params(strm, + level, + state->w_bits, + strategy); + + if (can_deflate == could_deflate) + /* We continue to work in the same mode - no changes needed */ + return Z_OK; + + if (strm->total_in == 0 && param->nt == 1 && param->hl == 0) + /* DFLTCC was not used yet - no changes needed */ + return Z_OK; + + /* For now, do not convert between window formats - simply get rid of the + * old data instead. + */ + *flush = Z_FULL_FLUSH; + return Z_OK; +} + +int ZLIB_INTERNAL dfltcc_deflate_done(z_streamp strm, int flush) +{ + deflate_state *state = (deflate_state *)strm->state; + struct dfltcc_state *dfltcc_state = GET_DFLTCC_STATE(state); + struct dfltcc_param_v0 *param = &dfltcc_state->param; + + /* When deflate(Z_FULL_FLUSH) is called with small avail_out, it might + * close the block without resetting the compression state. Detect this + * situation and return that deflation is not done. + */ + if (flush == Z_FULL_FLUSH && strm->avail_out == 0) + return 0; + + /* Return that deflation is not done if DFLTCC is used and either it + * buffered some data (Continuation Flag is set), or has not written EOBS + * yet (Block-Continuation Flag is set). + */ + return !dfltcc_can_deflate(strm) || (!param->cf && !param->bcf); +} + +/* + Preloading history. +*/ +local void append_history(struct dfltcc_param_v0 *param, + Bytef *history, + const Bytef *buf, + uInt count) +{ + size_t offset; + size_t n; + + /* Do not use more than 32K */ + if (count > HB_SIZE) { + buf += count - HB_SIZE; + count = HB_SIZE; + } + offset = (param->ho + param->hl) % HB_SIZE; + if (offset + count <= HB_SIZE) + /* Circular history buffer does not wrap - copy one chunk */ + zmemcpy(history + offset, buf, count); + else { + /* Circular history buffer wraps - copy two chunks */ + n = HB_SIZE - offset; + zmemcpy(history + offset, buf, n); + zmemcpy(history, buf + n, count - n); + } + n = param->hl + count; + if (n <= HB_SIZE) + /* All history fits into buffer - no need to discard anything */ + param->hl = n; + else { + /* History does not fit into buffer - discard extra bytes */ + param->ho = (param->ho + (n - HB_SIZE)) % HB_SIZE; + param->hl = HB_SIZE; + } +} + +local void get_history(struct dfltcc_param_v0 *param, + const Bytef *history, + Bytef *buf) +{ + if (param->ho + param->hl <= HB_SIZE) + /* Circular history buffer does not wrap - copy one chunk */ + memcpy(buf, history + param->ho, param->hl); + else { + /* Circular history buffer wraps - copy two chunks */ + memcpy(buf, history + param->ho, HB_SIZE - param->ho); + memcpy(buf + HB_SIZE - param->ho, history, param->ho + param->hl - HB_SIZE); + } +} + +int ZLIB_INTERNAL dfltcc_deflate_set_dictionary(z_streamp strm, + const Bytef *dictionary, + uInt dict_length) +{ + deflate_state *state = (deflate_state *)strm->state; + struct dfltcc_state *dfltcc_state = GET_DFLTCC_STATE(state); + struct dfltcc_param_v0 *param = &dfltcc_state->param; + + append_history(param, state->window, dictionary, dict_length); + state->strstart = 1; /* Add FDICT to zlib header */ + state->block_start = state->strstart; /* Make deflate_stored happy */ + return Z_OK; +} + +int ZLIB_INTERNAL dfltcc_deflate_get_dictionary(z_streamp strm, + Bytef *dictionary, + uInt *dict_length) +{ + deflate_state *state = (deflate_state *)strm->state; + struct dfltcc_state *dfltcc_state = GET_DFLTCC_STATE(state); + struct dfltcc_param_v0 *param = &dfltcc_state->param; + + if (dictionary) + get_history(param, state->window, dictionary); + if (dict_length) + *dict_length = param->hl; + return Z_OK; +} + +int ZLIB_INTERNAL dfltcc_inflate_set_dictionary(z_streamp strm, + const Bytef *dictionary, + uInt dict_length) +{ + struct inflate_state *state = (struct inflate_state *)strm->state; + struct dfltcc_state *dfltcc_state = GET_DFLTCC_STATE(state); + struct dfltcc_param_v0 *param = &dfltcc_state->param; + + if (inflate_ensure_window(state)) { + state->mode = MEM; + return Z_MEM_ERROR; + } + + append_history(param, state->window, dictionary, dict_length); + state->havedict = 1; + return Z_OK; +} + +int ZLIB_INTERNAL dfltcc_inflate_get_dictionary(z_streamp strm, + Bytef *dictionary, + uInt *dict_length) +{ + struct inflate_state *state = (struct inflate_state *)strm->state; + struct dfltcc_state *dfltcc_state = GET_DFLTCC_STATE(state); + struct dfltcc_param_v0 *param = &dfltcc_state->param; + + if (dictionary && state->window) + get_history(param, state->window, dictionary); + if (dict_length) + *dict_length = param->hl; + return Z_OK; +} Index: zlib-1.3.1/contrib/s390/dfltcc.h =================================================================== --- /dev/null +++ zlib-1.3.1/contrib/s390/dfltcc.h @@ -0,0 +1,97 @@ +#ifndef DFLTCC_H +#define DFLTCC_H + +#include "../../zlib.h" +#include "../../zutil.h" + +voidpf ZLIB_INTERNAL dfltcc_alloc_state(z_streamp strm, uInt items, uInt size); +void ZLIB_INTERNAL dfltcc_copy_state(voidpf dst, const voidpf src, uInt size); +void ZLIB_INTERNAL dfltcc_reset(z_streamp strm, uInt size); +voidpf ZLIB_INTERNAL dfltcc_alloc_window(z_streamp strm, uInt items, + uInt size); +void ZLIB_INTERNAL dfltcc_copy_window(void *dest, const void *src, size_t n); +void ZLIB_INTERNAL dfltcc_free_window(z_streamp strm, voidpf w); +#define DFLTCC_BLOCK_HEADER_BITS 3 +#define DFLTCC_HLITS_COUNT_BITS 5 +#define DFLTCC_HDISTS_COUNT_BITS 5 +#define DFLTCC_HCLENS_COUNT_BITS 4 +#define DFLTCC_MAX_HCLENS 19 +#define DFLTCC_HCLEN_BITS 3 +#define DFLTCC_MAX_HLITS 286 +#define DFLTCC_MAX_HDISTS 30 +#define DFLTCC_MAX_HLIT_HDIST_BITS 7 +#define DFLTCC_MAX_SYMBOL_BITS 16 +#define DFLTCC_MAX_EOBS_BITS 15 +#define DFLTCC_MAX_PADDING_BITS 7 +#define DEFLATE_BOUND_COMPLEN(source_len) \ + ((DFLTCC_BLOCK_HEADER_BITS + \ + DFLTCC_HLITS_COUNT_BITS + \ + DFLTCC_HDISTS_COUNT_BITS + \ + DFLTCC_HCLENS_COUNT_BITS + \ + DFLTCC_MAX_HCLENS * DFLTCC_HCLEN_BITS + \ + (DFLTCC_MAX_HLITS + DFLTCC_MAX_HDISTS) * DFLTCC_MAX_HLIT_HDIST_BITS + \ + (source_len) * DFLTCC_MAX_SYMBOL_BITS + \ + DFLTCC_MAX_EOBS_BITS + \ + DFLTCC_MAX_PADDING_BITS) >> 3) +int ZLIB_INTERNAL dfltcc_can_inflate(z_streamp strm); +typedef enum { + DFLTCC_INFLATE_CONTINUE, + DFLTCC_INFLATE_BREAK, + DFLTCC_INFLATE_SOFTWARE, +} dfltcc_inflate_action; +dfltcc_inflate_action ZLIB_INTERNAL dfltcc_inflate(z_streamp strm, + int flush, int *ret); +int ZLIB_INTERNAL dfltcc_was_inflate_used(z_streamp strm); +int ZLIB_INTERNAL dfltcc_inflate_disable(z_streamp strm); +int ZLIB_INTERNAL dfltcc_inflate_set_dictionary(z_streamp strm, + const Bytef *dictionary, + uInt dict_length); +int ZLIB_INTERNAL dfltcc_inflate_get_dictionary(z_streamp strm, + Bytef *dictionary, + uInt* dict_length); + +#define ZALLOC_STATE dfltcc_alloc_state +#define ZFREE_STATE ZFREE +#define ZCOPY_STATE dfltcc_copy_state +#define ZALLOC_WINDOW dfltcc_alloc_window +#define ZCOPY_WINDOW dfltcc_copy_window +#define ZFREE_WINDOW dfltcc_free_window +#define TRY_FREE_WINDOW dfltcc_free_window +#define INFLATE_RESET_KEEP_HOOK(strm) \ + dfltcc_reset((strm), sizeof(struct inflate_state)) +#define INFLATE_PRIME_HOOK(strm, bits, value) \ + do { if (dfltcc_inflate_disable((strm))) return Z_STREAM_ERROR; } while (0) +#define INFLATE_TYPEDO_HOOK(strm, flush) \ + if (dfltcc_can_inflate((strm))) { \ + dfltcc_inflate_action action; \ +\ + RESTORE(); \ + action = dfltcc_inflate((strm), (flush), &ret); \ + LOAD(); \ + if (action == DFLTCC_INFLATE_CONTINUE) \ + break; \ + else if (action == DFLTCC_INFLATE_BREAK) \ + goto inf_leave; \ + } +#define INFLATE_NEED_CHECKSUM(strm) (!dfltcc_can_inflate((strm))) +#define INFLATE_NEED_UPDATEWINDOW(strm) (!dfltcc_can_inflate((strm))) +#define INFLATE_MARK_HOOK(strm) \ + do { \ + if (dfltcc_was_inflate_used((strm))) return -(1L << 16); \ + } while (0) +#define INFLATE_SYNC_POINT_HOOK(strm) \ + do { \ + if (dfltcc_was_inflate_used((strm))) return Z_STREAM_ERROR; \ + } while (0) +#define INFLATE_SET_DICTIONARY_HOOK(strm, dict, dict_len) \ + do { \ + if (dfltcc_can_inflate(strm)) \ + return dfltcc_inflate_set_dictionary(strm, dict, dict_len); \ + } while (0) +#define INFLATE_GET_DICTIONARY_HOOK(strm, dict, dict_len) \ + do { \ + if (dfltcc_can_inflate(strm)) \ + return dfltcc_inflate_get_dictionary(strm, dict, dict_len); \ + } while (0) + +#endif Index: zlib-1.3.1/contrib/s390/dfltcc_deflate.h =================================================================== --- /dev/null +++ zlib-1.3.1/contrib/s390/dfltcc_deflate.h @@ -0,0 +1,53 @@ +#ifndef DFLTCC_DEFLATE_H +#define DFLTCC_DEFLATE_H + +#include "dfltcc.h" + +int ZLIB_INTERNAL dfltcc_can_deflate(z_streamp strm); +int ZLIB_INTERNAL dfltcc_deflate(z_streamp strm, + int flush, + block_state *result); +int ZLIB_INTERNAL dfltcc_deflate_params(z_streamp strm, int level, + int strategy, int *flush); +int ZLIB_INTERNAL dfltcc_deflate_done(z_streamp strm, int flush); +int ZLIB_INTERNAL dfltcc_deflate_set_dictionary(z_streamp strm, + const Bytef *dictionary, + uInt dict_length); +int ZLIB_INTERNAL dfltcc_deflate_get_dictionary(z_streamp strm, + Bytef *dictionary, + uInt* dict_length); + +#define DEFLATE_SET_DICTIONARY_HOOK(strm, dict, dict_len) \ + do { \ + if (dfltcc_can_deflate((strm))) \ + return dfltcc_deflate_set_dictionary((strm), (dict), (dict_len)); \ + } while (0) +#define DEFLATE_GET_DICTIONARY_HOOK(strm, dict, dict_len) \ + do { \ + if (dfltcc_can_deflate((strm))) \ + return dfltcc_deflate_get_dictionary((strm), (dict), (dict_len)); \ + } while (0) +#define DEFLATE_RESET_KEEP_HOOK(strm) \ + dfltcc_reset((strm), sizeof(deflate_state)) +#define DEFLATE_PARAMS_HOOK(strm, level, strategy, hook_flush) \ + do { \ + int err; \ +\ + err = dfltcc_deflate_params((strm), \ + (level), \ + (strategy), \ + (hook_flush)); \ + if (err == Z_STREAM_ERROR) \ + return err; \ + } while (0) +#define DEFLATE_DONE dfltcc_deflate_done +#define DEFLATE_BOUND_ADJUST_COMPLEN(strm, complen, source_len) \ + do { \ + if (deflateStateCheck((strm)) || dfltcc_can_deflate((strm))) \ + (complen) = DEFLATE_BOUND_COMPLEN(source_len); \ + } while (0) +#define DEFLATE_NEED_CONSERVATIVE_BOUND(strm) (dfltcc_can_deflate((strm))) +#define DEFLATE_HOOK dfltcc_deflate +#define DEFLATE_NEED_CHECKSUM(strm) (!dfltcc_can_deflate((strm))) + +#endif Index: zlib-1.3.1/deflate.c =================================================================== --- zlib-1.3.1.orig/deflate.c +++ zlib-1.3.1/deflate.c @@ -60,12 +60,24 @@ const char deflate_copyright[] = copyright string in the executable of your product. */ -typedef enum { - need_more, /* block not completed, need more input or more output */ - block_done, /* block flush performed */ - finish_started, /* finish started, need only more output at next deflate */ - finish_done /* finish done, accept no more input or output */ -} block_state; +#ifdef DFLTCC +#include "contrib/s390/dfltcc_deflate.h" +#else +#define ZALLOC_STATE ZALLOC +#define ZFREE_STATE ZFREE +#define ZCOPY_STATE zmemcpy +#define ZALLOC_WINDOW ZALLOC +#define TRY_FREE_WINDOW TRY_FREE +#define DEFLATE_SET_DICTIONARY_HOOK(strm, dict, dict_len) do {} while (0) +#define DEFLATE_GET_DICTIONARY_HOOK(strm, dict, dict_len) do {} while (0) +#define DEFLATE_RESET_KEEP_HOOK(strm) do {} while (0) +#define DEFLATE_PARAMS_HOOK(strm, level, strategy, hook_flush) do {} while (0) +#define DEFLATE_DONE(strm, flush) 1 +#define DEFLATE_BOUND_ADJUST_COMPLEN(strm, complen, sourceLen) do {} while (0) +#define DEFLATE_NEED_CONSERVATIVE_BOUND(strm) 0 +#define DEFLATE_HOOK(strm, flush, bstate) 0 +#define DEFLATE_NEED_CHECKSUM(strm) 1 +#endif typedef block_state (*compress_func)(deflate_state *s, int flush); /* Compression function. Returns the block state after the call. */ @@ -224,7 +236,8 @@ local unsigned read_buf(z_streamp strm, strm->avail_in -= len; zmemcpy(buf, strm->next_in, len); - if (strm->state->wrap == 1) { + if (!DEFLATE_NEED_CHECKSUM(strm)) {} + else if (strm->state->wrap == 1) { strm->adler = adler32(strm->adler, buf, len); } #ifdef GZIP @@ -427,7 +440,7 @@ int ZEXPORT deflateInit2_(z_streamp strm return Z_STREAM_ERROR; } if (windowBits == 8) windowBits = 9; /* until 256-byte window bug fixed */ - s = (deflate_state *) ZALLOC(strm, 1, sizeof(deflate_state)); + s = (deflate_state *) ZALLOC_STATE(strm, 1, sizeof(deflate_state)); if (s == Z_NULL) return Z_MEM_ERROR; strm->state = (struct internal_state FAR *)s; s->strm = strm; @@ -444,7 +457,7 @@ int ZEXPORT deflateInit2_(z_streamp strm s->hash_mask = s->hash_size - 1; s->hash_shift = ((s->hash_bits + MIN_MATCH-1) / MIN_MATCH); - s->window = (Bytef *) ZALLOC(strm, s->w_size, 2*sizeof(Byte)); + s->window = (Bytef *) ZALLOC_WINDOW(strm, s->w_size, 2*sizeof(Byte)); s->prev = (Posf *) ZALLOC(strm, s->w_size, sizeof(Pos)); s->head = (Posf *) ZALLOC(strm, s->hash_size, sizeof(Pos)); @@ -563,6 +576,7 @@ int ZEXPORT deflateSetDictionary(z_strea /* when using zlib wrappers, compute Adler-32 for provided dictionary */ if (wrap == 1) strm->adler = adler32(strm->adler, dictionary, dictLength); + DEFLATE_SET_DICTIONARY_HOOK(strm, dictionary, dictLength); s->wrap = 0; /* avoid computing Adler-32 in read_buf */ /* if dictionary would fill window, just replace the history */ @@ -618,6 +632,7 @@ int ZEXPORT deflateGetDictionary(z_strea if (deflateStateCheck(strm)) return Z_STREAM_ERROR; + DEFLATE_GET_DICTIONARY_HOOK(strm, dictionary, dictLength); s = strm->state; len = s->strstart + s->lookahead; if (len > s->w_size) @@ -662,6 +677,8 @@ int ZEXPORT deflateResetKeep(z_streamp s _tr_init(s); + DEFLATE_RESET_KEEP_HOOK(strm); + return Z_OK; } @@ -750,6 +767,7 @@ int ZEXPORT deflatePrime(z_streamp strm, int ZEXPORT deflateParams(z_streamp strm, int level, int strategy) { deflate_state *s; compress_func func; + int hook_flush = Z_NO_FLUSH; if (deflateStateCheck(strm)) return Z_STREAM_ERROR; s = strm->state; @@ -762,15 +780,18 @@ int ZEXPORT deflateParams(z_streamp strm if (level < 0 || level > 9 || strategy < 0 || strategy > Z_FIXED) { return Z_STREAM_ERROR; } + DEFLATE_PARAMS_HOOK(strm, level, strategy, &hook_flush); func = configuration_table[s->level].func; - if ((strategy != s->strategy || func != configuration_table[level].func) && - s->last_flush != -2) { + if (((strategy != s->strategy || func != configuration_table[level].func) && + s->last_flush != -2) || hook_flush != Z_NO_FLUSH) { /* Flush the last buffer: */ - int err = deflate(strm, Z_BLOCK); + int flush = RANK(hook_flush) > RANK(Z_BLOCK) ? hook_flush : Z_BLOCK; + int err = deflate(strm, flush); if (err == Z_STREAM_ERROR) return err; - if (strm->avail_in || (s->strstart - s->block_start) + s->lookahead) + if (strm->avail_in || (s->strstart - s->block_start) + s->lookahead || + !DEFLATE_DONE(strm, flush)) return Z_BUF_ERROR; } if (s->level != level) { @@ -838,11 +859,13 @@ uLong ZEXPORT deflateBound(z_streamp str ~13% overhead plus a small constant */ fixedlen = sourceLen + (sourceLen >> 3) + (sourceLen >> 8) + (sourceLen >> 9) + 4; + DEFLATE_BOUND_ADJUST_COMPLEN(strm, fixedlen, sourceLen); /* upper bound for stored blocks with length 127 (memLevel == 1) -- ~4% overhead plus a small constant */ storelen = sourceLen + (sourceLen >> 5) + (sourceLen >> 7) + (sourceLen >> 11) + 7; + DEFLATE_BOUND_ADJUST_COMPLEN(strm, storelen, sourceLen); /* if can't get parameters, return larger bound plus a zlib wrapper */ if (deflateStateCheck(strm)) @@ -884,7 +907,8 @@ uLong ZEXPORT deflateBound(z_streamp str } /* if not default parameters, return one of the conservative bounds */ - if (s->w_bits != 15 || s->hash_bits != 8 + 7) + if (DEFLATE_NEED_CONSERVATIVE_BOUND(strm) || + s->w_bits != 15 || s->hash_bits != 8 + 7) return (s->w_bits <= s->hash_bits && s->level ? fixedlen : storelen) + wraplen; @@ -910,7 +934,7 @@ local void putShortMSB(deflate_state *s, * applications may wish to modify it to avoid allocating a large * strm->next_out buffer and copying into it. (See also read_buf()). */ -local void flush_pending(z_streamp strm) { +void ZLIB_INTERNAL flush_pending(z_streamp strm) { unsigned len; deflate_state *s = strm->state; @@ -1177,7 +1201,8 @@ int ZEXPORT deflate(z_streamp strm, int (flush != Z_NO_FLUSH && s->status != FINISH_STATE)) { block_state bstate; - bstate = s->level == 0 ? deflate_stored(s, flush) : + bstate = DEFLATE_HOOK(strm, flush, &bstate) ? bstate : + s->level == 0 ? deflate_stored(s, flush) : s->strategy == Z_HUFFMAN_ONLY ? deflate_huff(s, flush) : s->strategy == Z_RLE ? deflate_rle(s, flush) : (*(configuration_table[s->level].func))(s, flush); @@ -1224,7 +1249,6 @@ int ZEXPORT deflate(z_streamp strm, int } if (flush != Z_FINISH) return Z_OK; - if (s->wrap <= 0) return Z_STREAM_END; /* Write the trailer */ #ifdef GZIP @@ -1240,7 +1264,7 @@ int ZEXPORT deflate(z_streamp strm, int } else #endif - { + if (s->wrap == 1) { putShortMSB(s, (uInt)(strm->adler >> 16)); putShortMSB(s, (uInt)(strm->adler & 0xffff)); } @@ -1249,7 +1273,11 @@ int ZEXPORT deflate(z_streamp strm, int * to flush the rest. */ if (s->wrap > 0) s->wrap = -s->wrap; /* write the trailer only once! */ - return s->pending != 0 ? Z_OK : Z_STREAM_END; + if (s->pending == 0) { + Assert(s->bi_valid == 0, "bi_buf not flushed"); + return Z_STREAM_END; + } + return Z_OK; } /* ========================================================================= */ @@ -1264,9 +1292,9 @@ int ZEXPORT deflateEnd(z_streamp strm) { TRY_FREE(strm, strm->state->pending_buf); TRY_FREE(strm, strm->state->head); TRY_FREE(strm, strm->state->prev); - TRY_FREE(strm, strm->state->window); + TRY_FREE_WINDOW(strm, strm->state->window); - ZFREE(strm, strm->state); + ZFREE_STATE(strm, strm->state); strm->state = Z_NULL; return status == BUSY_STATE ? Z_DATA_ERROR : Z_OK; @@ -1295,13 +1323,13 @@ int ZEXPORT deflateCopy(z_streamp dest, zmemcpy((voidpf)dest, (voidpf)source, sizeof(z_stream)); - ds = (deflate_state *) ZALLOC(dest, 1, sizeof(deflate_state)); + ds = (deflate_state *) ZALLOC_STATE(dest, 1, sizeof(deflate_state)); if (ds == Z_NULL) return Z_MEM_ERROR; dest->state = (struct internal_state FAR *) ds; - zmemcpy((voidpf)ds, (voidpf)ss, sizeof(deflate_state)); + ZCOPY_STATE((voidpf)ds, (voidpf)ss, sizeof(deflate_state)); ds->strm = dest; - ds->window = (Bytef *) ZALLOC(dest, ds->w_size, 2*sizeof(Byte)); + ds->window = (Bytef *) ZALLOC_WINDOW(dest, ds->w_size, 2*sizeof(Byte)); ds->prev = (Posf *) ZALLOC(dest, ds->w_size, sizeof(Pos)); ds->head = (Posf *) ZALLOC(dest, ds->hash_size, sizeof(Pos)); ds->pending_buf = (uchf *) ZALLOC(dest, ds->lit_bufsize, LIT_BUFS); Index: zlib-1.3.1/deflate.h =================================================================== --- zlib-1.3.1.orig/deflate.h +++ zlib-1.3.1/deflate.h @@ -310,6 +310,7 @@ void ZLIB_INTERNAL _tr_flush_bits(deflat void ZLIB_INTERNAL _tr_align(deflate_state *s); void ZLIB_INTERNAL _tr_stored_block(deflate_state *s, charf *buf, ulg stored_len, int last); +void ZLIB_INTERNAL _tr_send_bits(deflate_state *s, int value, int length); #define d_code(dist) \ ((dist) < 256 ? _dist_code[dist] : _dist_code[256+((dist)>>7)]) @@ -374,4 +375,15 @@ void ZLIB_INTERNAL _tr_stored_block(defl flush = _tr_tally(s, distance, length) #endif +typedef enum { + need_more, /* block not completed, need more input or more output */ + block_done, /* block flush performed */ + finish_started, /* finish started, need only more output at next deflate */ + finish_done /* finish done, accept no more input or output */ +} block_state; + +unsigned ZLIB_INTERNAL bi_reverse(unsigned code, int len); +void ZLIB_INTERNAL bi_windup(deflate_state *s); +void ZLIB_INTERNAL flush_pending(z_streamp strm); + #endif /* DEFLATE_H */ Index: zlib-1.3.1/gzguts.h =================================================================== --- zlib-1.3.1.orig/gzguts.h +++ zlib-1.3.1/gzguts.h @@ -152,7 +152,11 @@ /* default i/o buffer size -- double this for output when reading (this and twice this must be able to fit in an unsigned type) */ +#ifdef DFLTCC +#define GZBUFSIZE 131072 +#else #define GZBUFSIZE 8192 +#endif /* gzip modes, also provide a little integrity check on the passed structure */ #define GZ_NONE 0 Index: zlib-1.3.1/inflate.c =================================================================== --- zlib-1.3.1.orig/inflate.c +++ zlib-1.3.1/inflate.c @@ -85,6 +85,27 @@ #include "inflate.h" #include "inffast.h" +/* architecture-specific bits */ +#ifdef DFLTCC +#include "contrib/s390/dfltcc.h" +#else +#define ZALLOC_STATE ZALLOC +#define ZFREE_STATE ZFREE +#define ZCOPY_STATE zmemcpy +#define ZALLOC_WINDOW ZALLOC +#define ZCOPY_WINDOW zmemcpy +#define ZFREE_WINDOW ZFREE +#define INFLATE_RESET_KEEP_HOOK(strm) do {} while (0) +#define INFLATE_PRIME_HOOK(strm, bits, value) do {} while (0) +#define INFLATE_TYPEDO_HOOK(strm, flush) do {} while (0) +#define INFLATE_NEED_CHECKSUM(strm) 1 +#define INFLATE_NEED_UPDATEWINDOW(strm) 1 +#define INFLATE_MARK_HOOK(strm) do {} while (0) +#define INFLATE_SYNC_POINT_HOOK(strm) do {} while (0) +#define INFLATE_SET_DICTIONARY_HOOK(strm, dict, dict_len) do {} while (0) +#define INFLATE_GET_DICTIONARY_HOOK(strm, dict, dict_len) do {} while (0) +#endif + #ifdef MAKEFIXED # ifndef BUILDFIXED # define BUILDFIXED @@ -123,6 +144,7 @@ int ZEXPORT inflateResetKeep(z_streamp s state->lencode = state->distcode = state->next = state->codes; state->sane = 1; state->back = -1; + INFLATE_RESET_KEEP_HOOK(strm); Tracev((stderr, "inflate: reset\n")); return Z_OK; } @@ -165,7 +187,7 @@ int ZEXPORT inflateReset2(z_streamp strm if (windowBits && (windowBits < 8 || windowBits > 15)) return Z_STREAM_ERROR; if (state->window != Z_NULL && state->wbits != (unsigned)windowBits) { - ZFREE(strm, state->window); + ZFREE_WINDOW(strm, state->window); state->window = Z_NULL; } @@ -197,7 +219,7 @@ int ZEXPORT inflateInit2_(z_streamp strm strm->zfree = zcfree; #endif state = (struct inflate_state FAR *) - ZALLOC(strm, 1, sizeof(struct inflate_state)); + ZALLOC_STATE(strm, 1, sizeof(struct inflate_state)); if (state == Z_NULL) return Z_MEM_ERROR; Tracev((stderr, "inflate: allocated\n")); strm->state = (struct internal_state FAR *)state; @@ -206,7 +228,7 @@ int ZEXPORT inflateInit2_(z_streamp strm state->mode = HEAD; /* to pass state test in inflateReset2() */ ret = inflateReset2(strm, windowBits); if (ret != Z_OK) { - ZFREE(strm, state); + ZFREE_STATE(strm, state); strm->state = Z_NULL; } return ret; @@ -223,6 +245,7 @@ int ZEXPORT inflatePrime(z_streamp strm, if (inflateStateCheck(strm)) return Z_STREAM_ERROR; if (bits == 0) return Z_OK; + INFLATE_PRIME_HOOK(strm, bits, value); state = (struct inflate_state FAR *)strm->state; if (bits < 0) { state->hold = 0; @@ -348,6 +371,27 @@ void makefixed(void) } #endif /* MAKEFIXED */ +int ZLIB_INTERNAL inflate_ensure_window(state) + struct inflate_state *state; +{ + /* if it hasn't been done already, allocate space for the window */ + if (state->window == Z_NULL) { + state->window = (unsigned char FAR *) + ZALLOC_WINDOW(state->strm, 1U << state->wbits, + sizeof(unsigned char)); + if (state->window == Z_NULL) return 1; + } + + /* if window not in use yet, initialize */ + if (state->wsize == 0) { + state->wsize = 1U << state->wbits; + state->wnext = 0; + state->whave = 0; + } + + return 0; +} + /* Update the window with the last wsize (normally 32K) bytes written before returning. If window does not exist yet, create it. This is only called @@ -368,20 +412,7 @@ local int updatewindow(z_streamp strm, c state = (struct inflate_state FAR *)strm->state; - /* if it hasn't been done already, allocate space for the window */ - if (state->window == Z_NULL) { - state->window = (unsigned char FAR *) - ZALLOC(strm, 1U << state->wbits, - sizeof(unsigned char)); - if (state->window == Z_NULL) return 1; - } - - /* if window not in use yet, initialize */ - if (state->wsize == 0) { - state->wsize = 1U << state->wbits; - state->wnext = 0; - state->whave = 0; - } + if (inflate_ensure_window(state)) return 1; /* copy state->wsize or less output bytes into the circular window */ if (copy >= state->wsize) { @@ -822,6 +853,7 @@ int ZEXPORT inflate(z_streamp strm, int if (flush == Z_BLOCK || flush == Z_TREES) goto inf_leave; /* fallthrough */ case TYPEDO: + INFLATE_TYPEDO_HOOK(strm, flush); if (state->last) { BYTEBITS(); state->mode = CHECK; @@ -1183,7 +1215,7 @@ int ZEXPORT inflate(z_streamp strm, int out -= left; strm->total_out += out; state->total += out; - if ((state->wrap & 4) && out) + if (INFLATE_NEED_CHECKSUM(strm) && (state->wrap & 4) && out) strm->adler = state->check = UPDATE_CHECK(state->check, put - out, out); out = left; @@ -1238,8 +1270,9 @@ int ZEXPORT inflate(z_streamp strm, int */ inf_leave: RESTORE(); - if (state->wsize || (out != strm->avail_out && state->mode < BAD && - (state->mode < CHECK || flush != Z_FINISH))) + if (INFLATE_NEED_UPDATEWINDOW(strm) && + (state->wsize || (out != strm->avail_out && state->mode < BAD && + (state->mode < CHECK || flush != Z_FINISH)))) if (updatewindow(strm, strm->next_out, out - strm->avail_out)) { state->mode = MEM; return Z_MEM_ERROR; @@ -1249,7 +1282,7 @@ int ZEXPORT inflate(z_streamp strm, int strm->total_in += in; strm->total_out += out; state->total += out; - if ((state->wrap & 4) && out) + if (INFLATE_NEED_CHECKSUM(strm) && (state->wrap & 4) && out) strm->adler = state->check = UPDATE_CHECK(state->check, strm->next_out - out, out); strm->data_type = (int)state->bits + (state->last ? 64 : 0) + @@ -1265,8 +1298,8 @@ int ZEXPORT inflateEnd(z_streamp strm) { if (inflateStateCheck(strm)) return Z_STREAM_ERROR; state = (struct inflate_state FAR *)strm->state; - if (state->window != Z_NULL) ZFREE(strm, state->window); - ZFREE(strm, strm->state); + if (state->window != Z_NULL) ZFREE_WINDOW(strm, state->window); + ZFREE_STATE(strm, strm->state); strm->state = Z_NULL; Tracev((stderr, "inflate: end\n")); return Z_OK; @@ -1280,6 +1313,8 @@ int ZEXPORT inflateGetDictionary(z_strea if (inflateStateCheck(strm)) return Z_STREAM_ERROR; state = (struct inflate_state FAR *)strm->state; + INFLATE_GET_DICTIONARY_HOOK(strm, dictionary, dictLength); + /* copy dictionary */ if (state->whave && dictionary != Z_NULL) { zmemcpy(dictionary, state->window + state->wnext, @@ -1312,6 +1347,8 @@ int ZEXPORT inflateSetDictionary(z_strea return Z_DATA_ERROR; } + INFLATE_SET_DICTIONARY_HOOK(strm, dictionary, dictLength); + /* copy dictionary to window using updatewindow(), which will amend the existing dictionary if appropriate */ ret = updatewindow(strm, dictionary + dictLength, dictLength); @@ -1429,6 +1466,7 @@ int ZEXPORT inflateSyncPoint(z_streamp s struct inflate_state FAR *state; if (inflateStateCheck(strm)) return Z_STREAM_ERROR; + INFLATE_SYNC_POINT_HOOK(strm); state = (struct inflate_state FAR *)strm->state; return state->mode == STORED && state->bits == 0; } @@ -1437,7 +1475,6 @@ int ZEXPORT inflateCopy(z_streamp dest, struct inflate_state FAR *state; struct inflate_state FAR *copy; unsigned char FAR *window; - unsigned wsize; /* check input */ if (inflateStateCheck(source) || dest == Z_NULL) @@ -1446,21 +1483,22 @@ int ZEXPORT inflateCopy(z_streamp dest, /* allocate space */ copy = (struct inflate_state FAR *) - ZALLOC(source, 1, sizeof(struct inflate_state)); + ZALLOC_STATE(source, 1, sizeof(struct inflate_state)); if (copy == Z_NULL) return Z_MEM_ERROR; window = Z_NULL; if (state->window != Z_NULL) { window = (unsigned char FAR *) - ZALLOC(source, 1U << state->wbits, sizeof(unsigned char)); + ZALLOC_WINDOW(source, 1U << state->wbits, + sizeof(unsigned char)); if (window == Z_NULL) { - ZFREE(source, copy); + ZFREE_STATE(source, copy); return Z_MEM_ERROR; } } /* copy state */ zmemcpy((voidpf)dest, (voidpf)source, sizeof(z_stream)); - zmemcpy((voidpf)copy, (voidpf)state, sizeof(struct inflate_state)); + ZCOPY_STATE((voidpf)copy, (voidpf)state, sizeof(struct inflate_state)); copy->strm = dest; if (state->lencode >= state->codes && state->lencode <= state->codes + ENOUGH - 1) { @@ -1469,8 +1507,7 @@ int ZEXPORT inflateCopy(z_streamp dest, } copy->next = copy->codes + (state->next - state->codes); if (window != Z_NULL) { - wsize = 1U << state->wbits; - zmemcpy(window, state->window, wsize); + ZCOPY_WINDOW(window, state->window, 1U << state->wbits); } copy->window = window; dest->state = (struct internal_state FAR *)copy; @@ -1509,6 +1546,7 @@ long ZEXPORT inflateMark(z_streamp strm) if (inflateStateCheck(strm)) return -(1L << 16); + INFLATE_MARK_HOOK(strm); state = (struct inflate_state FAR *)strm->state; return (long)(((unsigned long)((long)state->back)) << 16) + (state->mode == COPY ? state->length : Index: zlib-1.3.1/inflate.h =================================================================== --- zlib-1.3.1.orig/inflate.h +++ zlib-1.3.1/inflate.h @@ -124,3 +124,5 @@ struct inflate_state { int back; /* bits back of last unprocessed length/lit */ unsigned was; /* initial length of match */ }; + +int ZLIB_INTERNAL inflate_ensure_window(struct inflate_state *state); Index: zlib-1.3.1/test/infcover.c =================================================================== --- zlib-1.3.1.orig/test/infcover.c +++ zlib-1.3.1/test/infcover.c @@ -462,8 +462,7 @@ local unsigned pull(void *desc, unsigned local int push(void *desc, unsigned char *buf, unsigned len) { - (void)buf; - (void)len; + buf += len; return desc != Z_NULL; /* force error if desc not null */ } Index: zlib-1.3.1/test/minigzip.c =================================================================== --- zlib-1.3.1.orig/test/minigzip.c +++ zlib-1.3.1/test/minigzip.c @@ -132,7 +132,11 @@ static void pwinerror (s) #endif #define SUFFIX_LEN (sizeof(GZ_SUFFIX)-1) +#ifdef DFLTCC +#define BUFLEN 262144 +#else #define BUFLEN 16384 +#endif #define MAX_NAME_LEN 1024 #ifdef MAXSEG_64K Index: zlib-1.3.1/trees.c =================================================================== --- zlib-1.3.1.orig/trees.c +++ zlib-1.3.1/trees.c @@ -151,7 +151,7 @@ local TCONST static_tree_desc static_bl_ * method would use a table) * IN assertion: 1 <= len <= 15 */ -local unsigned bi_reverse(unsigned code, int len) { +unsigned ZLIB_INTERNAL bi_reverse(unsigned code, int len) { register unsigned res = 0; do { res |= code & 1; @@ -178,7 +178,7 @@ local void bi_flush(deflate_state *s) { /* =========================================================================== * Flush the bit buffer and align the output on a byte boundary */ -local void bi_windup(deflate_state *s) { +void ZLIB_INTERNAL bi_windup(deflate_state *s) { if (s->bi_valid > 8) { put_short(s, s->bi_buf); } else if (s->bi_valid > 0) { @@ -285,6 +285,10 @@ local void send_bits(deflate_state *s, i } #endif /* ZLIB_DEBUG */ +void ZLIB_INTERNAL _tr_send_bits(deflate_state *s, int value, int length) +{ + send_bits(s, value, length); +} /* the arguments must not have side effects */ Index: zlib-1.3.1/zutil.h =================================================================== --- zlib-1.3.1.orig/zutil.h +++ zlib-1.3.1/zutil.h @@ -87,6 +87,8 @@ extern z_const char * const z_errmsg[10] #define PRESET_DICT 0x20 /* preset dictionary flag in zlib header */ +#define ZLIB_WRAPLEN 6 /* zlib format overhead */ + /* target dependencies */ #if defined(MSDOS) || (defined(WINDOWS) && !defined(WIN32))