/* chunkcopy.h -- fast chunk copy and set operations * Copyright (C) 2017 ARM, Inc. * Copyright 2017 The Chromium Authors. All rights reserved. * Use of this source code is governed by a BSD-style license that can be * found in the Chromium source repository LICENSE file. */ #ifndef CHUNKCOPY_H #define CHUNKCOPY_H #include #include "zutil.h" #define Z_STATIC_ASSERT(name, assert) typedef char name[(assert) ? 1 : -1] #if __STDC_VERSION__ >= 199901L #define Z_RESTRICT restrict #else #define Z_RESTRICT #endif #if defined(__clang__) || defined(__GNUC__) || defined(__llvm__) #define Z_BUILTIN_MEMCPY __builtin_memcpy #else #define Z_BUILTIN_MEMCPY zmemcpy #endif #if defined(INFLATE_CHUNK_SIMD_NEON) #include typedef uint8x16_t z_vec128i_t; #elif defined(INFLATE_CHUNK_SIMD_SSE2) #include typedef __m128i z_vec128i_t; #else #error chunkcopy.h inflate chunk SIMD is not defined for your build target #endif /* * chunk copy type: the z_vec128i_t type size should be exactly 128-bits * and equal to CHUNKCOPY_CHUNK_SIZE. */ #define CHUNKCOPY_CHUNK_SIZE sizeof(z_vec128i_t) Z_STATIC_ASSERT(vector_128_bits_wide, CHUNKCOPY_CHUNK_SIZE == sizeof(int8_t) * 16); /* * Ask the compiler to perform a wide, unaligned load with a machine * instruction appropriate for the z_vec128i_t type. */ static inline z_vec128i_t loadchunk( const unsigned char FAR* s) { z_vec128i_t v; Z_BUILTIN_MEMCPY(&v, s, sizeof(v)); return v; } /* * Ask the compiler to perform a wide, unaligned store with a machine * instruction appropriate for the z_vec128i_t type. */ static inline void storechunk( unsigned char FAR* d, const z_vec128i_t v) { Z_BUILTIN_MEMCPY(d, &v, sizeof(v)); } /* * Perform a memcpy-like operation, assuming that length is non-zero and that * it's OK to overwrite at least CHUNKCOPY_CHUNK_SIZE bytes of output even if * the length is shorter than this. * * It also guarantees that it will properly unroll the data if the distance * between `out` and `from` is at least CHUNKCOPY_CHUNK_SIZE, which we rely on * in chunkcopy_relaxed(). * * Aside from better memory bus utilisation, this means that short copies * (CHUNKCOPY_CHUNK_SIZE bytes or fewer) will fall straight through the loop * without iteration, which will hopefully make the branch prediction more * reliable. */ static inline unsigned char FAR* chunkcopy_core( unsigned char FAR* out, const unsigned char FAR* from, unsigned len) { const int bump = (--len % CHUNKCOPY_CHUNK_SIZE) + 1; storechunk(out, loadchunk(from)); out += bump; from += bump; len /= CHUNKCOPY_CHUNK_SIZE; while (len-- > 0) { storechunk(out, loadchunk(from)); out += CHUNKCOPY_CHUNK_SIZE; from += CHUNKCOPY_CHUNK_SIZE; } return out; } /* * Like chunkcopy_core(), but avoid writing beyond of legal output. * * Accepts an additional pointer to the end of safe output. A generic safe * copy would use (out + len), but it's normally the case that the end of the * output buffer is beyond the end of the current copy, and this can still be * exploited. */ static inline unsigned char FAR* chunkcopy_core_safe( unsigned char FAR* out, const unsigned char FAR* from, unsigned len, unsigned char FAR* limit) { Assert(out + len <= limit, "chunk copy exceeds safety limit"); if ((limit - out) < (ptrdiff_t)CHUNKCOPY_CHUNK_SIZE) { const unsigned char FAR* Z_RESTRICT rfrom = from; if (len & 8) { Z_BUILTIN_MEMCPY(out, rfrom, 8); out += 8; rfrom += 8; } if (len & 4) { Z_BUILTIN_MEMCPY(out, rfrom, 4); out += 4; rfrom += 4; } if (len & 2) { Z_BUILTIN_MEMCPY(out, rfrom, 2); out += 2; rfrom += 2; } if (len & 1) { *out++ = *rfrom++; } return out; } return chunkcopy_core(out, from, len); } /* * Perform short copies until distance can be rewritten as being at least * CHUNKCOPY_CHUNK_SIZE. * * Assumes it's OK to overwrite at least the first 2*CHUNKCOPY_CHUNK_SIZE * bytes of output even if the copy is shorter than this. This assumption * holds within zlib inflate_fast(), which starts every iteration with at * least 258 bytes of output space available (258 being the maximum length * output from a single token; see inffast.c). */ static inline unsigned char FAR* chunkunroll_relaxed( unsigned char FAR* out, unsigned FAR* dist, unsigned FAR* len) { const unsigned char FAR* from = out - *dist; while (*dist < *len && *dist < CHUNKCOPY_CHUNK_SIZE) { storechunk(out, loadchunk(from)); out += *dist; *len -= *dist; *dist += *dist; } return out; } #if defined(INFLATE_CHUNK_SIMD_NEON) /* * v_load64_dup(): load *src as an unaligned 64-bit int and duplicate it in * every 64-bit component of the 128-bit result (64-bit int splat). */ static inline z_vec128i_t v_load64_dup(const void* src) { return vcombine_u8(vld1_u8(src), vld1_u8(src)); } /* * v_load32_dup(): load *src as an unaligned 32-bit int and duplicate it in * every 32-bit component of the 128-bit result (32-bit int splat). */ static inline z_vec128i_t v_load32_dup(const void* src) { int32_t i32; Z_BUILTIN_MEMCPY(&i32, src, sizeof(i32)); return vreinterpretq_u8_s32(vdupq_n_s32(i32)); } /* * v_load16_dup(): load *src as an unaligned 16-bit int and duplicate it in * every 16-bit component of the 128-bit result (16-bit int splat). */ static inline z_vec128i_t v_load16_dup(const void* src) { int16_t i16; Z_BUILTIN_MEMCPY(&i16, src, sizeof(i16)); return vreinterpretq_u8_s16(vdupq_n_s16(i16)); } /* * v_load8_dup(): load the 8-bit int *src and duplicate it in every 8-bit * component of the 128-bit result (8-bit int splat). */ static inline z_vec128i_t v_load8_dup(const void* src) { return vld1q_dup_u8((const uint8_t*)src); } /* * v_store_128(): store the 128-bit vec in a memory destination (that might * not be 16-byte aligned) void* out. */ static inline void v_store_128(void* out, const z_vec128i_t vec) { vst1q_u8(out, vec); } #elif defined(INFLATE_CHUNK_SIMD_SSE2) /* * v_load64_dup(): load *src as an unaligned 64-bit int and duplicate it in * every 64-bit component of the 128-bit result (64-bit int splat). */ static inline z_vec128i_t v_load64_dup(const void* src) { int64_t i64; Z_BUILTIN_MEMCPY(&i64, src, sizeof(i64)); return _mm_set1_epi64x(i64); } /* * v_load32_dup(): load *src as an unaligned 32-bit int and duplicate it in * every 32-bit component of the 128-bit result (32-bit int splat). */ static inline z_vec128i_t v_load32_dup(const void* src) { int32_t i32; Z_BUILTIN_MEMCPY(&i32, src, sizeof(i32)); return _mm_set1_epi32(i32); } /* * v_load16_dup(): load *src as an unaligned 16-bit int and duplicate it in * every 16-bit component of the 128-bit result (16-bit int splat). */ static inline z_vec128i_t v_load16_dup(const void* src) { int16_t i16; Z_BUILTIN_MEMCPY(&i16, src, sizeof(i16)); return _mm_set1_epi16(i16); } /* * v_load8_dup(): load the 8-bit int *src and duplicate it in every 8-bit * component of the 128-bit result (8-bit int splat). */ static inline z_vec128i_t v_load8_dup(const void* src) { return _mm_set1_epi8(*(const char*)src); } /* * v_store_128(): store the 128-bit vec in a memory destination (that might * not be 16-byte aligned) void* out. */ static inline void v_store_128(void* out, const z_vec128i_t vec) { _mm_storeu_si128((__m128i*)out, vec); } #endif /* * Perform an overlapping copy which behaves as a memset() operation, but * supporting periods other than one, and assume that length is non-zero and * that it's OK to overwrite at least CHUNKCOPY_CHUNK_SIZE*3 bytes of output * even if the length is shorter than this. */ static inline unsigned char FAR* chunkset_core( unsigned char FAR* out, unsigned period, unsigned len) { z_vec128i_t v; const int bump = ((len - 1) % sizeof(v)) + 1; switch (period) { case 1: v = v_load8_dup(out - 1); v_store_128(out, v); out += bump; len -= bump; while (len > 0) { v_store_128(out, v); out += sizeof(v); len -= sizeof(v); } return out; case 2: v = v_load16_dup(out - 2); v_store_128(out, v); out += bump; len -= bump; if (len > 0) { v = v_load16_dup(out - 2); do { v_store_128(out, v); out += sizeof(v); len -= sizeof(v); } while (len > 0); } return out; case 4: v = v_load32_dup(out - 4); v_store_128(out, v); out += bump; len -= bump; if (len > 0) { v = v_load32_dup(out - 4); do { v_store_128(out, v); out += sizeof(v); len -= sizeof(v); } while (len > 0); } return out; case 8: v = v_load64_dup(out - 8); v_store_128(out, v); out += bump; len -= bump; if (len > 0) { v = v_load64_dup(out - 8); do { v_store_128(out, v); out += sizeof(v); len -= sizeof(v); } while (len > 0); } return out; } out = chunkunroll_relaxed(out, &period, &len); return chunkcopy_core(out, out - period, len); } /* * Perform a memcpy-like operation, but assume that length is non-zero and that * it's OK to overwrite at least CHUNKCOPY_CHUNK_SIZE bytes of output even if * the length is shorter than this. * * Unlike chunkcopy_core() above, no guarantee is made regarding the behaviour * of overlapping buffers, regardless of the distance between the pointers. * This is reflected in the `restrict`-qualified pointers, allowing the * compiler to re-order loads and stores. */ static inline unsigned char FAR* chunkcopy_relaxed( unsigned char FAR* Z_RESTRICT out, const unsigned char FAR* Z_RESTRICT from, unsigned len) { return chunkcopy_core(out, from, len); } /* * Like chunkcopy_relaxed(), but avoid writing beyond of legal output. * * Unlike chunkcopy_core_safe() above, no guarantee is made regarding the * behaviour of overlapping buffers, regardless of the distance between the * pointers. This is reflected in the `restrict`-qualified pointers, allowing * the compiler to re-order loads and stores. * * Accepts an additional pointer to the end of safe output. A generic safe * copy would use (out + len), but it's normally the case that the end of the * output buffer is beyond the end of the current copy, and this can still be * exploited. */ static inline unsigned char FAR* chunkcopy_safe( unsigned char FAR* out, const unsigned char FAR* Z_RESTRICT from, unsigned len, unsigned char FAR* limit) { Assert(out + len <= limit, "chunk copy exceeds safety limit"); return chunkcopy_core_safe(out, from, len, limit); } /* * Perform chunky copy within the same buffer, where the source and destination * may potentially overlap. * * Assumes that len > 0 on entry, and that it's safe to write at least * CHUNKCOPY_CHUNK_SIZE*3 bytes to the output. */ static inline unsigned char FAR* chunkcopy_lapped_relaxed( unsigned char FAR* out, unsigned dist, unsigned len) { if (dist < len && dist < CHUNKCOPY_CHUNK_SIZE) { return chunkset_core(out, dist, len); } return chunkcopy_core(out, out - dist, len); } /* * Behave like chunkcopy_lapped_relaxed(), but avoid writing beyond of legal * output. * * Accepts an additional pointer to the end of safe output. A generic safe * copy would use (out + len), but it's normally the case that the end of the * output buffer is beyond the end of the current copy, and this can still be * exploited. */ static inline unsigned char FAR* chunkcopy_lapped_safe( unsigned char FAR* out, unsigned dist, unsigned len, unsigned char FAR* limit) { Assert(out + len <= limit, "chunk copy exceeds safety limit"); if ((limit - out) < (ptrdiff_t)(3 * CHUNKCOPY_CHUNK_SIZE)) { /* TODO(cavalcantii): try harder to optimise this */ while (len-- > 0) { *out = *(out - dist); out++; } return out; } return chunkcopy_lapped_relaxed(out, dist, len); } /* * The chunk-copy code above deals with writing the decoded DEFLATE data to * the output with SIMD methods to increase decode speed. Reading the input * to the DEFLATE decoder with a wide, SIMD method can also increase decode * speed. This option is supported on little endian machines, and reads the * input data in 64-bit (8 byte) chunks. */ #ifdef INFLATE_CHUNK_READ_64LE /* * Buffer the input in a uint64_t (8 bytes) in the wide input reading case. */ typedef uint64_t inflate_holder_t; /* * Ask the compiler to perform a wide, unaligned load of a uint64_t using a * machine instruction appropriate for the uint64_t type. */ static inline inflate_holder_t read64le(const unsigned char FAR *in) { inflate_holder_t input; Z_BUILTIN_MEMCPY(&input, in, sizeof(input)); return input; } #else /* * Otherwise, buffer the input bits using zlib's default input buffer type. */ typedef unsigned long inflate_holder_t; #endif /* INFLATE_CHUNK_READ_64LE */ #undef Z_STATIC_ASSERT #undef Z_RESTRICT #undef Z_BUILTIN_MEMCPY #endif /* CHUNKCOPY_H */