functable.c - third_party/github.com/zlib-ng/zlib-ng - Git at Google

 /* functable.c -- Choose relevant optimized functions at runtime
  * Copyright (C) 2017 Hans Kristian Rosbach
  * For conditions of distribution and use, see copyright notice in zlib.h
  */

 #include "zbuild.h"
 #include "zendian.h"
 #include "crc32_braid_p.h"
 #include "deflate.h"
 #include "deflate_p.h"
 #include "functable.h"
 #include "cpu_features.h"

 static void init_functable(void) {
     struct functable_s ft;
     struct cpu_features cf;

     cpu_check_features(&cf);

     // Generic code
     ft.adler32 = &adler32_c;
     ft.adler32_fold_copy = &adler32_fold_copy_c;
     ft.chunkmemset_safe = &chunkmemset_safe_c;
     ft.chunksize = &chunksize_c;
     ft.crc32 = &PREFIX(crc32_braid);
     ft.crc32_fold = &crc32_fold_c;
     ft.crc32_fold_copy = &crc32_fold_copy_c;
     ft.crc32_fold_final = &crc32_fold_final_c;
     ft.crc32_fold_reset = &crc32_fold_reset_c;
     ft.inflate_fast = &inflate_fast_c;
     ft.insert_string = &insert_string_c;
     ft.quick_insert_string = &quick_insert_string_c;
     ft.slide_hash = &slide_hash_c;
     ft.update_hash = &update_hash_c;

 #if defined(UNALIGNED_OK) && BYTE_ORDER == LITTLE_ENDIAN
 #  if defined(UNALIGNED64_OK) && defined(HAVE_BUILTIN_CTZLL)
     ft.longest_match = &longest_match_unaligned_64;
     ft.longest_match_slow = &longest_match_slow_unaligned_64;
     ft.compare256 = &compare256_unaligned_64;
 #  elif defined(HAVE_BUILTIN_CTZ)
     ft.longest_match = &longest_match_unaligned_32;
     ft.longest_match_slow = &longest_match_slow_unaligned_32;
     ft.compare256 = &compare256_unaligned_32;
 #  else
     ft.longest_match = &longest_match_unaligned_16;
     ft.longest_match_slow = &longest_match_slow_unaligned_16;
     ft.compare256 = &compare256_unaligned_16;
 #  endif
 #else
     ft.longest_match = &longest_match_c;
     ft.longest_match_slow = &longest_match_slow_c;
     ft.compare256 = &compare256_c;
 #endif


     // Select arch-optimized functions

     // X86 - SSE2
 #ifdef X86_SSE2
 #  if !defined(__x86_64__) && !defined(_M_X64) && !defined(X86_NOCHECK_SSE2)
     if (cf.x86.has_sse2)
 #  endif
     {
         ft.chunkmemset_safe = &chunkmemset_safe_sse2;
         ft.chunksize = &chunksize_sse2;
         ft.inflate_fast = &inflate_fast_sse2;
         ft.slide_hash = &slide_hash_sse2;
 #  ifdef HAVE_BUILTIN_CTZ
         ft.compare256 = &compare256_sse2;
         ft.longest_match = &longest_match_sse2;
         ft.longest_match_slow = &longest_match_slow_sse2;
 #  endif
     }
 #endif
     // X86 - SSSE3
 #ifdef X86_SSSE3
     if (cf.x86.has_ssse3) {
         ft.adler32 = &adler32_ssse3;
 #  ifdef X86_SSE2
         ft.chunkmemset_safe = &chunkmemset_safe_ssse3;
         ft.inflate_fast = &inflate_fast_ssse3;
 #  endif
     }
 #endif
     // X86 - SSE4.2
 #ifdef X86_SSE42
     if (cf.x86.has_sse42) {
         ft.adler32_fold_copy = &adler32_fold_copy_sse42;
         ft.insert_string = &insert_string_sse42;
         ft.quick_insert_string = &quick_insert_string_sse42;
         ft.update_hash = &update_hash_sse42;
     }
 #endif
     // X86 - PCLMUL
 #ifdef X86_PCLMULQDQ_CRC
     if (cf.x86.has_pclmulqdq) {
         ft.crc32 = &crc32_pclmulqdq;
         ft.crc32_fold = &crc32_fold_pclmulqdq;
         ft.crc32_fold_copy = &crc32_fold_pclmulqdq_copy;
         ft.crc32_fold_final = &crc32_fold_pclmulqdq_final;
         ft.crc32_fold_reset = &crc32_fold_pclmulqdq_reset;
     }
 #endif
     // X86 - AVX
 #ifdef X86_AVX2
     if (cf.x86.has_avx2) {
         ft.adler32 = &adler32_avx2;
         ft.adler32_fold_copy = &adler32_fold_copy_avx2;
         ft.chunkmemset_safe = &chunkmemset_safe_avx2;
         ft.chunksize = &chunksize_avx2;
         ft.inflate_fast = &inflate_fast_avx2;
         ft.slide_hash = &slide_hash_avx2;
 #  ifdef HAVE_BUILTIN_CTZ
         ft.compare256 = &compare256_avx2;
         ft.longest_match = &longest_match_avx2;
         ft.longest_match_slow = &longest_match_slow_avx2;
 #  endif
     }
 #endif
 #ifdef X86_AVX512
     if (cf.x86.has_avx512) {
         ft.adler32 = &adler32_avx512;
         ft.adler32_fold_copy = &adler32_fold_copy_avx512;
     }
 #endif
 #ifdef X86_AVX512VNNI
     if (cf.x86.has_avx512vnni) {
         ft.adler32 = &adler32_avx512_vnni;
         ft.adler32_fold_copy = &adler32_fold_copy_avx512_vnni;
     }
 #endif
     // X86 - VPCLMULQDQ
 #if defined(X86_PCLMULQDQ_CRC) && defined(X86_VPCLMULQDQ_CRC)
     if (cf.x86.has_pclmulqdq && cf.x86.has_avx512 && cf.x86.has_vpclmulqdq) {
         ft.crc32 = &crc32_vpclmulqdq;
         ft.crc32_fold = &crc32_fold_vpclmulqdq;
         ft.crc32_fold_copy = &crc32_fold_vpclmulqdq_copy;
         ft.crc32_fold_final = &crc32_fold_vpclmulqdq_final;
         ft.crc32_fold_reset = &crc32_fold_vpclmulqdq_reset;
     }
 #endif


     // ARM - NEON
 #ifdef ARM_NEON
 #  ifndef ARM_NOCHECK_NEON
     if (cf.arm.has_neon)
 #  endif
     {
         ft.adler32 = &adler32_neon;
         ft.chunkmemset_safe = &chunkmemset_safe_neon;
         ft.chunksize = &chunksize_neon;
         ft.inflate_fast = &inflate_fast_neon;
         ft.slide_hash = &slide_hash_neon;
 #  ifdef HAVE_BUILTIN_CTZLL
         ft.compare256 = &compare256_neon;
         ft.longest_match = &longest_match_neon;
         ft.longest_match_slow = &longest_match_slow_neon;
 #  endif
     }
 #endif
     // ARM - ACLE
 #ifdef ARM_ACLE
     if (cf.arm.has_crc32) {
         ft.crc32 = &crc32_acle;
         ft.insert_string = &insert_string_acle;
         ft.quick_insert_string = &quick_insert_string_acle;
         ft.update_hash = &update_hash_acle;
     }
 #endif


     // Power - VMX
 #ifdef PPC_VMX
     if (cf.power.has_altivec) {
         ft.adler32 = &adler32_vmx;
         ft.slide_hash = &slide_hash_vmx;
     }
 #endif
     // Power8 - VSX
 #ifdef POWER8_VSX
     if (cf.power.has_arch_2_07) {
         ft.adler32 = &adler32_power8;
         ft.chunkmemset_safe = &chunkmemset_safe_power8;
         ft.chunksize = &chunksize_power8;
         ft.inflate_fast = &inflate_fast_power8;
         ft.slide_hash = &slide_hash_power8;
     }
 #endif
 #ifdef POWER8_VSX_CRC32
     if (cf.power.has_arch_2_07)
         ft.crc32 = &crc32_power8;
 #endif
     // Power9
 #ifdef POWER9
     if (cf.power.has_arch_3_00) {
         ft.compare256 = &compare256_power9;
         ft.longest_match = &longest_match_power9;
         ft.longest_match_slow = &longest_match_slow_power9;
     }
 #endif


     // S390
 #ifdef S390_CRC32_VX
     if (cf.s390.has_vx)
         ft.crc32 = crc32_s390_vx;
 #endif

     // Assign function pointers individually for atomic operation
     functable.adler32 = ft.adler32;
     functable.adler32_fold_copy = ft.adler32_fold_copy;
     functable.chunkmemset_safe = ft.chunkmemset_safe;
     functable.chunksize = ft.chunksize;
     functable.compare256 = ft.compare256;
     functable.crc32 = ft.crc32;
     functable.crc32_fold = ft.crc32_fold;
     functable.crc32_fold_copy = ft.crc32_fold_copy;
     functable.crc32_fold_final = ft.crc32_fold_final;
     functable.crc32_fold_reset = ft.crc32_fold_reset;
     functable.inflate_fast = ft.inflate_fast;
     functable.insert_string = ft.insert_string;
     functable.longest_match = ft.longest_match;
     functable.longest_match_slow = ft.longest_match_slow;
     functable.quick_insert_string = ft.quick_insert_string;
     functable.slide_hash = ft.slide_hash;
     functable.update_hash = ft.update_hash;
 }

 /* stub functions */
 static uint32_t adler32_stub(uint32_t adler, const uint8_t* buf, size_t len) {
     init_functable();
     return functable.adler32(adler, buf, len);
 }

 static uint32_t adler32_fold_copy_stub(uint32_t adler, uint8_t* dst, const uint8_t* src, size_t len) {
     init_functable();
     return functable.adler32_fold_copy(adler, dst, src, len);
 }

 static uint8_t* chunkmemset_safe_stub(uint8_t* out, unsigned dist, unsigned len, unsigned left) {
     init_functable();
     return functable.chunkmemset_safe(out, dist, len, left);
 }

 static uint32_t chunksize_stub(void) {
     init_functable();
     return functable.chunksize();
 }

 static uint32_t compare256_stub(const uint8_t* src0, const uint8_t* src1) {
     init_functable();
     return functable.compare256(src0, src1);
 }

 static uint32_t crc32_stub(uint32_t crc, const uint8_t* buf, size_t len) {
     init_functable();
     return functable.crc32(crc, buf, len);
 }

 static void crc32_fold_stub(crc32_fold* crc, const uint8_t* src, size_t len, uint32_t init_crc) {
     init_functable();
     functable.crc32_fold(crc, src, len, init_crc);
 }

 static void crc32_fold_copy_stub(crc32_fold* crc, uint8_t* dst, const uint8_t* src, size_t len) {
     init_functable();
     functable.crc32_fold_copy(crc, dst, src, len);
 }

 static uint32_t crc32_fold_final_stub(crc32_fold* crc) {
     init_functable();
     return functable.crc32_fold_final(crc);
 }

 static uint32_t crc32_fold_reset_stub(crc32_fold* crc) {
     init_functable();
     return functable.crc32_fold_reset(crc);
 }

 static void inflate_fast_stub(PREFIX3(stream) *strm, uint32_t start) {
     init_functable();
     functable.inflate_fast(strm, start);
 }

 static void insert_string_stub(deflate_state* const s, uint32_t str, uint32_t count) {
     init_functable();
     functable.insert_string(s, str, count);
 }

 static uint32_t longest_match_stub(deflate_state* const s, Pos cur_match) {
     init_functable();
     return functable.longest_match(s, cur_match);
 }

 static uint32_t longest_match_slow_stub(deflate_state* const s, Pos cur_match) {
     init_functable();
     return functable.longest_match_slow(s, cur_match);
 }

 static Pos quick_insert_string_stub(deflate_state* const s, const uint32_t str) {
     init_functable();
     return functable.quick_insert_string(s, str);
 }

 static void slide_hash_stub(deflate_state* s) {
     init_functable();
     functable.slide_hash(s);
 }

 static uint32_t update_hash_stub(deflate_state* const s, uint32_t h, uint32_t val) {
     init_functable();
     return functable.update_hash(s, h, val);
 }

 /* functable init */
 Z_INTERNAL Z_TLS struct functable_s functable = {
     adler32_stub,
     adler32_fold_copy_stub,
     chunkmemset_safe_stub,
     chunksize_stub,
     compare256_stub,
     crc32_stub,
     crc32_fold_stub,
     crc32_fold_copy_stub,
     crc32_fold_final_stub,
     crc32_fold_reset_stub,
     inflate_fast_stub,
     insert_string_stub,
     longest_match_stub,
     longest_match_slow_stub,
     quick_insert_string_stub,
     slide_hash_stub,
     update_hash_stub
 };
	/* functable.c -- Choose relevant optimized functions at runtime
	* Copyright (C) 2017 Hans Kristian Rosbach
	* For conditions of distribution and use, see copyright notice in zlib.h
	*/

	#include "zbuild.h"
	#include "zendian.h"
	#include "crc32_braid_p.h"
	#include "deflate.h"
	#include "deflate_p.h"
	#include "functable.h"
	#include "cpu_features.h"

	static void init_functable(void) {
	struct functable_s ft;
	struct cpu_features cf;

	cpu_check_features(&cf);

	// Generic code
	ft.adler32 = &adler32_c;
	ft.adler32_fold_copy = &adler32_fold_copy_c;
	ft.chunkmemset_safe = &chunkmemset_safe_c;
	ft.chunksize = &chunksize_c;
	ft.crc32 = &PREFIX(crc32_braid);
	ft.crc32_fold = &crc32_fold_c;
	ft.crc32_fold_copy = &crc32_fold_copy_c;
	ft.crc32_fold_final = &crc32_fold_final_c;
	ft.crc32_fold_reset = &crc32_fold_reset_c;
	ft.inflate_fast = &inflate_fast_c;
	ft.insert_string = &insert_string_c;
	ft.quick_insert_string = &quick_insert_string_c;
	ft.slide_hash = &slide_hash_c;
	ft.update_hash = &update_hash_c;

	#if defined(UNALIGNED_OK) && BYTE_ORDER == LITTLE_ENDIAN
	# if defined(UNALIGNED64_OK) && defined(HAVE_BUILTIN_CTZLL)
	ft.longest_match = &longest_match_unaligned_64;
	ft.longest_match_slow = &longest_match_slow_unaligned_64;
	ft.compare256 = &compare256_unaligned_64;
	# elif defined(HAVE_BUILTIN_CTZ)
	ft.longest_match = &longest_match_unaligned_32;
	ft.longest_match_slow = &longest_match_slow_unaligned_32;
	ft.compare256 = &compare256_unaligned_32;
	# else
	ft.longest_match = &longest_match_unaligned_16;
	ft.longest_match_slow = &longest_match_slow_unaligned_16;
	ft.compare256 = &compare256_unaligned_16;
	# endif
	#else
	ft.longest_match = &longest_match_c;
	ft.longest_match_slow = &longest_match_slow_c;
	ft.compare256 = &compare256_c;
	#endif


	// Select arch-optimized functions

	// X86 - SSE2
	#ifdef X86_SSE2
	# if !defined(__x86_64__) && !defined(_M_X64) && !defined(X86_NOCHECK_SSE2)
	if (cf.x86.has_sse2)
	# endif
	{
	ft.chunkmemset_safe = &chunkmemset_safe_sse2;
	ft.chunksize = &chunksize_sse2;
	ft.inflate_fast = &inflate_fast_sse2;
	ft.slide_hash = &slide_hash_sse2;
	# ifdef HAVE_BUILTIN_CTZ
	ft.compare256 = &compare256_sse2;
	ft.longest_match = &longest_match_sse2;
	ft.longest_match_slow = &longest_match_slow_sse2;
	# endif
	}
	#endif
	// X86 - SSSE3
	#ifdef X86_SSSE3
	if (cf.x86.has_ssse3) {
	ft.adler32 = &adler32_ssse3;
	# ifdef X86_SSE2
	ft.chunkmemset_safe = &chunkmemset_safe_ssse3;
	ft.inflate_fast = &inflate_fast_ssse3;
	# endif
	}
	#endif
	// X86 - SSE4.2
	#ifdef X86_SSE42
	if (cf.x86.has_sse42) {
	ft.adler32_fold_copy = &adler32_fold_copy_sse42;
	ft.insert_string = &insert_string_sse42;
	ft.quick_insert_string = &quick_insert_string_sse42;
	ft.update_hash = &update_hash_sse42;
	}
	#endif
	// X86 - PCLMUL
	#ifdef X86_PCLMULQDQ_CRC
	if (cf.x86.has_pclmulqdq) {
	ft.crc32 = &crc32_pclmulqdq;
	ft.crc32_fold = &crc32_fold_pclmulqdq;
	ft.crc32_fold_copy = &crc32_fold_pclmulqdq_copy;
	ft.crc32_fold_final = &crc32_fold_pclmulqdq_final;
	ft.crc32_fold_reset = &crc32_fold_pclmulqdq_reset;
	}
	#endif
	// X86 - AVX
	#ifdef X86_AVX2
	if (cf.x86.has_avx2) {
	ft.adler32 = &adler32_avx2;
	ft.adler32_fold_copy = &adler32_fold_copy_avx2;
	ft.chunkmemset_safe = &chunkmemset_safe_avx2;
	ft.chunksize = &chunksize_avx2;
	ft.inflate_fast = &inflate_fast_avx2;
	ft.slide_hash = &slide_hash_avx2;
	# ifdef HAVE_BUILTIN_CTZ
	ft.compare256 = &compare256_avx2;
	ft.longest_match = &longest_match_avx2;
	ft.longest_match_slow = &longest_match_slow_avx2;
	# endif
	}
	#endif
	#ifdef X86_AVX512
	if (cf.x86.has_avx512) {
	ft.adler32 = &adler32_avx512;
	ft.adler32_fold_copy = &adler32_fold_copy_avx512;
	}
	#endif
	#ifdef X86_AVX512VNNI
	if (cf.x86.has_avx512vnni) {
	ft.adler32 = &adler32_avx512_vnni;
	ft.adler32_fold_copy = &adler32_fold_copy_avx512_vnni;
	}
	#endif
	// X86 - VPCLMULQDQ
	#if defined(X86_PCLMULQDQ_CRC) && defined(X86_VPCLMULQDQ_CRC)
	if (cf.x86.has_pclmulqdq && cf.x86.has_avx512 && cf.x86.has_vpclmulqdq) {
	ft.crc32 = &crc32_vpclmulqdq;
	ft.crc32_fold = &crc32_fold_vpclmulqdq;
	ft.crc32_fold_copy = &crc32_fold_vpclmulqdq_copy;
	ft.crc32_fold_final = &crc32_fold_vpclmulqdq_final;
	ft.crc32_fold_reset = &crc32_fold_vpclmulqdq_reset;
	}
	#endif


	// ARM - NEON
	#ifdef ARM_NEON
	# ifndef ARM_NOCHECK_NEON
	if (cf.arm.has_neon)
	# endif
	{
	ft.adler32 = &adler32_neon;
	ft.chunkmemset_safe = &chunkmemset_safe_neon;
	ft.chunksize = &chunksize_neon;
	ft.inflate_fast = &inflate_fast_neon;
	ft.slide_hash = &slide_hash_neon;
	# ifdef HAVE_BUILTIN_CTZLL
	ft.compare256 = &compare256_neon;
	ft.longest_match = &longest_match_neon;
	ft.longest_match_slow = &longest_match_slow_neon;
	# endif
	}
	#endif
	// ARM - ACLE
	#ifdef ARM_ACLE
	if (cf.arm.has_crc32) {
	ft.crc32 = &crc32_acle;
	ft.insert_string = &insert_string_acle;
	ft.quick_insert_string = &quick_insert_string_acle;
	ft.update_hash = &update_hash_acle;
	}
	#endif


	// Power - VMX
	#ifdef PPC_VMX
	if (cf.power.has_altivec) {
	ft.adler32 = &adler32_vmx;
	ft.slide_hash = &slide_hash_vmx;
	}
	#endif
	// Power8 - VSX
	#ifdef POWER8_VSX
	if (cf.power.has_arch_2_07) {
	ft.adler32 = &adler32_power8;
	ft.chunkmemset_safe = &chunkmemset_safe_power8;
	ft.chunksize = &chunksize_power8;
	ft.inflate_fast = &inflate_fast_power8;
	ft.slide_hash = &slide_hash_power8;
	}
	#endif
	#ifdef POWER8_VSX_CRC32
	if (cf.power.has_arch_2_07)
	ft.crc32 = &crc32_power8;
	#endif
	// Power9
	#ifdef POWER9
	if (cf.power.has_arch_3_00) {
	ft.compare256 = &compare256_power9;
	ft.longest_match = &longest_match_power9;
	ft.longest_match_slow = &longest_match_slow_power9;
	}
	#endif


	// S390
	#ifdef S390_CRC32_VX
	if (cf.s390.has_vx)
	ft.crc32 = crc32_s390_vx;
	#endif

	// Assign function pointers individually for atomic operation
	functable.adler32 = ft.adler32;
	functable.adler32_fold_copy = ft.adler32_fold_copy;
	functable.chunkmemset_safe = ft.chunkmemset_safe;
	functable.chunksize = ft.chunksize;
	functable.compare256 = ft.compare256;
	functable.crc32 = ft.crc32;
	functable.crc32_fold = ft.crc32_fold;
	functable.crc32_fold_copy = ft.crc32_fold_copy;
	functable.crc32_fold_final = ft.crc32_fold_final;
	functable.crc32_fold_reset = ft.crc32_fold_reset;
	functable.inflate_fast = ft.inflate_fast;
	functable.insert_string = ft.insert_string;
	functable.longest_match = ft.longest_match;
	functable.longest_match_slow = ft.longest_match_slow;
	functable.quick_insert_string = ft.quick_insert_string;
	functable.slide_hash = ft.slide_hash;
	functable.update_hash = ft.update_hash;
	}

	/* stub functions */
	static uint32_t adler32_stub(uint32_t adler, const uint8_t* buf, size_t len) {
	init_functable();
	return functable.adler32(adler, buf, len);
	}

	static uint32_t adler32_fold_copy_stub(uint32_t adler, uint8_t* dst, const uint8_t* src, size_t len) {
	init_functable();
	return functable.adler32_fold_copy(adler, dst, src, len);
	}

	static uint8_t* chunkmemset_safe_stub(uint8_t* out, unsigned dist, unsigned len, unsigned left) {
	init_functable();
	return functable.chunkmemset_safe(out, dist, len, left);
	}

	static uint32_t chunksize_stub(void) {
	init_functable();
	return functable.chunksize();
	}

	static uint32_t compare256_stub(const uint8_t* src0, const uint8_t* src1) {
	init_functable();
	return functable.compare256(src0, src1);
	}

	static uint32_t crc32_stub(uint32_t crc, const uint8_t* buf, size_t len) {
	init_functable();
	return functable.crc32(crc, buf, len);
	}

	static void crc32_fold_stub(crc32_fold* crc, const uint8_t* src, size_t len, uint32_t init_crc) {
	init_functable();
	functable.crc32_fold(crc, src, len, init_crc);
	}

	static void crc32_fold_copy_stub(crc32_fold* crc, uint8_t* dst, const uint8_t* src, size_t len) {
	init_functable();
	functable.crc32_fold_copy(crc, dst, src, len);
	}

	static uint32_t crc32_fold_final_stub(crc32_fold* crc) {
	init_functable();
	return functable.crc32_fold_final(crc);
	}

	static uint32_t crc32_fold_reset_stub(crc32_fold* crc) {
	init_functable();
	return functable.crc32_fold_reset(crc);
	}

	static void inflate_fast_stub(PREFIX3(stream) *strm, uint32_t start) {
	init_functable();
	functable.inflate_fast(strm, start);
	}

	static void insert_string_stub(deflate_state* const s, uint32_t str, uint32_t count) {
	init_functable();
	functable.insert_string(s, str, count);
	}

	static uint32_t longest_match_stub(deflate_state* const s, Pos cur_match) {
	init_functable();
	return functable.longest_match(s, cur_match);
	}

	static uint32_t longest_match_slow_stub(deflate_state* const s, Pos cur_match) {
	init_functable();
	return functable.longest_match_slow(s, cur_match);
	}

	static Pos quick_insert_string_stub(deflate_state* const s, const uint32_t str) {
	init_functable();
	return functable.quick_insert_string(s, str);
	}

	static void slide_hash_stub(deflate_state* s) {
	init_functable();
	functable.slide_hash(s);
	}

	static uint32_t update_hash_stub(deflate_state* const s, uint32_t h, uint32_t val) {
	init_functable();
	return functable.update_hash(s, h, val);
	}

	/* functable init */
	Z_INTERNAL Z_TLS struct functable_s functable = {
	adler32_stub,
	adler32_fold_copy_stub,
	chunkmemset_safe_stub,
	chunksize_stub,
	compare256_stub,
	crc32_stub,
	crc32_fold_stub,
	crc32_fold_copy_stub,
	crc32_fold_final_stub,
	crc32_fold_reset_stub,
	inflate_fast_stub,
	insert_string_stub,
	longest_match_stub,
	longest_match_slow_stub,
	quick_insert_string_stub,
	slide_hash_stub,
	update_hash_stub
	};