/* * Copyright (c) 2015-2017, Intel Corporation * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * * Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of Intel Corporation nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ /* * Matches a byte in a charclass using three shuffles */ #include "ue2common.h" #include "truffle.h" #include "util/arch.h" #include "util/bitutils.h" #include "util/simd_utils.h" #if !defined(HAVE_AVX2) static really_inline const u8 *lastMatch(const u8 *buf, u32 z) { if (unlikely(z != 0xffff)) { u32 pos = clz32(~z & 0xffff); assert(pos >= 16 && pos < 32); return buf + (31 - pos); } return NULL; // no match } static really_inline const u8 *firstMatch(const u8 *buf, u32 z) { if (unlikely(z != 0xffff)) { u32 pos = ctz32(~z & 0xffff); assert(pos < 16); return buf + pos; } return NULL; // no match } static really_inline u32 block(m128 shuf_mask_lo_highclear, m128 shuf_mask_lo_highset, m128 v) { m128 highconst = _mm_set1_epi8(0x80); m128 shuf_mask_hi = _mm_set1_epi64x(0x8040201008040201); // and now do the real work m128 shuf1 = pshufb_m128(shuf_mask_lo_highclear, v); m128 t1 = xor128(v, highconst); m128 shuf2 = pshufb_m128(shuf_mask_lo_highset, t1); m128 t2 = andnot128(highconst, rshift64_m128(v, 4)); m128 shuf3 = pshufb_m128(shuf_mask_hi, t2); m128 tmp = and128(or128(shuf1, shuf2), shuf3); m128 tmp2 = eq128(tmp, zeroes128()); u32 z = movemask128(tmp2); return z; } static const u8 *truffleMini(m128 shuf_mask_lo_highclear, m128 shuf_mask_lo_highset, const u8 *buf, const u8 *buf_end) { uintptr_t len = buf_end - buf; assert(len < 16); m128 chars = zeroes128(); memcpy(&chars, buf, len); u32 z = block(shuf_mask_lo_highclear, shuf_mask_lo_highset, chars); // can't be these bytes in z u32 mask = (0xffff >> (16 - len)) ^ 0xffff; const u8 *rv = firstMatch(buf, z | mask); if (rv) { return rv; } else { return buf_end; } } static really_inline const u8 *fwdBlock(m128 shuf_mask_lo_highclear, m128 shuf_mask_lo_highset, m128 v, const u8 *buf) { u32 z = block(shuf_mask_lo_highclear, shuf_mask_lo_highset, v); return firstMatch(buf, z); } static really_inline const u8 *revBlock(m128 shuf_mask_lo_highclear, m128 shuf_mask_lo_highset, m128 v, const u8 *buf) { u32 z = block(shuf_mask_lo_highclear, shuf_mask_lo_highset, v); return lastMatch(buf, z); } const u8 *truffleExec(m128 shuf_mask_lo_highclear, m128 shuf_mask_lo_highset, const u8 *buf, const u8 *buf_end) { DEBUG_PRINTF("len %zu\n", buf_end - buf); assert(buf && buf_end); assert(buf < buf_end); const u8 *rv; if (buf_end - buf < 16) { return truffleMini(shuf_mask_lo_highclear, shuf_mask_lo_highset, buf, buf_end); } size_t min = (size_t)buf % 16; assert(buf_end - buf >= 16); // Preconditioning: most of the time our buffer won't be aligned. m128 chars = loadu128(buf); rv = fwdBlock(shuf_mask_lo_highclear, shuf_mask_lo_highset, chars, buf); if (rv) { return rv; } buf += (16 - min); const u8 *last_block = buf_end - 16; while (buf < last_block) { m128 lchars = load128(buf); rv = fwdBlock(shuf_mask_lo_highclear, shuf_mask_lo_highset, lchars, buf); if (rv) { return rv; } buf += 16; } // Use an unaligned load to mop up the last 16 bytes and get an accurate // picture to buf_end. assert(buf <= buf_end && buf >= buf_end - 16); chars = loadu128(buf_end - 16); rv = fwdBlock(shuf_mask_lo_highclear, shuf_mask_lo_highset, chars, buf_end - 16); if (rv) { return rv; } return buf_end; } static const u8 *truffleRevMini(m128 shuf_mask_lo_highclear, m128 shuf_mask_lo_highset, const u8 *buf, const u8 *buf_end) { uintptr_t len = buf_end - buf; assert(len < 16); m128 chars = zeroes128(); memcpy(&chars, buf, len); u32 mask = (0xffff >> (16 - len)) ^ 0xffff; u32 z = block(shuf_mask_lo_highclear, shuf_mask_lo_highset, chars); const u8 *rv = lastMatch(buf, z | mask); if (rv) { return rv; } return buf - 1; } const u8 *rtruffleExec(m128 shuf_mask_lo_highclear, m128 shuf_mask_lo_highset, const u8 *buf, const u8 *buf_end) { assert(buf && buf_end); assert(buf < buf_end); const u8 *rv; DEBUG_PRINTF("len %zu\n", buf_end - buf); if (buf_end - buf < 16) { return truffleRevMini(shuf_mask_lo_highclear, shuf_mask_lo_highset, buf, buf_end); } assert(buf_end - buf >= 16); // Preconditioning: most of the time our buffer won't be aligned. m128 chars = loadu128(buf_end - 16); rv = revBlock(shuf_mask_lo_highclear, shuf_mask_lo_highset, chars, buf_end - 16); if (rv) { return rv; } buf_end = (const u8 *)((size_t)buf_end & ~((size_t)0xf)); const u8 *last_block = buf + 16; while (buf_end > last_block) { buf_end -= 16; m128 lchars = load128(buf_end); rv = revBlock(shuf_mask_lo_highclear, shuf_mask_lo_highset, lchars, buf_end); if (rv) { return rv; } } // Use an unaligned load to mop up the last 16 bytes and get an accurate // picture to buf_end. chars = loadu128(buf); rv = revBlock(shuf_mask_lo_highclear, shuf_mask_lo_highset, chars, buf); if (rv) { return rv; } return buf - 1; } #elif !defined(HAVE_AVX512) // AVX2 static really_inline const u8 *lastMatch(const u8 *buf, u32 z) { if (unlikely(z != 0xffffffff)) { u32 pos = clz32(~z); assert(pos < 32); return buf + (31 - pos); } return NULL; // no match } static really_inline const u8 *firstMatch(const u8 *buf, u32 z) { if (unlikely(z != 0xffffffff)) { u32 pos = ctz32(~z); assert(pos < 32); return buf + pos; } return NULL; // no match } static really_inline u32 block(m256 shuf_mask_lo_highclear, m256 shuf_mask_lo_highset, m256 v) { m256 highconst = _mm256_set1_epi8(0x80); m256 shuf_mask_hi = _mm256_set1_epi64x(0x8040201008040201); // and now do the real work m256 shuf1 = pshufb_m256(shuf_mask_lo_highclear, v); m256 t1 = xor256(v, highconst); m256 shuf2 = pshufb_m256(shuf_mask_lo_highset, t1); m256 t2 = andnot256(highconst, rshift64_m256(v, 4)); m256 shuf3 = pshufb_m256(shuf_mask_hi, t2); m256 tmp = and256(or256(shuf1, shuf2), shuf3); m256 tmp2 = eq256(tmp, zeroes256()); u32 z = movemask256(tmp2); return z; } static const u8 *truffleMini(m256 shuf_mask_lo_highclear, m256 shuf_mask_lo_highset, const u8 *buf, const u8 *buf_end) { uintptr_t len = buf_end - buf; assert(len < 32); m256 chars = zeroes256(); memcpy(&chars, buf, len); u32 z = block(shuf_mask_lo_highclear, shuf_mask_lo_highset, chars); // can't be these bytes in z u32 mask = (0xffffffff >> (32 - len)) ^ 0xffffffff; const u8 *rv = firstMatch(buf, z | mask); if (rv) { return rv; } else { return buf_end; } } static really_inline const u8 *fwdBlock(m256 shuf_mask_lo_highclear, m256 shuf_mask_lo_highset, m256 v, const u8 *buf) { u32 z = block(shuf_mask_lo_highclear, shuf_mask_lo_highset, v); return firstMatch(buf, z); } static really_inline const u8 *revBlock(m256 shuf_mask_lo_highclear, m256 shuf_mask_lo_highset, m256 v, const u8 *buf) { u32 z = block(shuf_mask_lo_highclear, shuf_mask_lo_highset, v); return lastMatch(buf, z); } const u8 *truffleExec(m128 shuf_mask_lo_highclear, m128 shuf_mask_lo_highset, const u8 *buf, const u8 *buf_end) { DEBUG_PRINTF("len %zu\n", buf_end - buf); const m256 wide_clear = set2x128(shuf_mask_lo_highclear); const m256 wide_set = set2x128(shuf_mask_lo_highset); assert(buf && buf_end); assert(buf < buf_end); const u8 *rv; if (buf_end - buf < 32) { return truffleMini(wide_clear, wide_set, buf, buf_end); } size_t min = (size_t)buf % 32; assert(buf_end - buf >= 32); // Preconditioning: most of the time our buffer won't be aligned. m256 chars = loadu256(buf); rv = fwdBlock(wide_clear, wide_set, chars, buf); if (rv) { return rv; } buf += (32 - min); const u8 *last_block = buf_end - 32; while (buf < last_block) { m256 lchars = load256(buf); rv = fwdBlock(wide_clear, wide_set, lchars, buf); if (rv) { return rv; } buf += 32; } // Use an unaligned load to mop up the last 32 bytes and get an accurate // picture to buf_end. assert(buf <= buf_end && buf >= buf_end - 32); chars = loadu256(buf_end - 32); rv = fwdBlock(wide_clear, wide_set, chars, buf_end - 32); if (rv) { return rv; } return buf_end; } static const u8 *truffleRevMini(m256 shuf_mask_lo_highclear, m256 shuf_mask_lo_highset, const u8 *buf, const u8 *buf_end) { uintptr_t len = buf_end - buf; assert(len < 32); m256 chars = zeroes256(); memcpy(&chars, buf, len); u32 mask = (0xffffffff >> (32 - len)) ^ 0xffffffff; u32 z = block(shuf_mask_lo_highclear, shuf_mask_lo_highset, chars); const u8 *rv = lastMatch(buf, z | mask); if (rv) { return rv; } return buf - 1; } const u8 *rtruffleExec(m128 shuf_mask_lo_highclear, m128 shuf_mask_lo_highset, const u8 *buf, const u8 *buf_end) { const m256 wide_clear = set2x128(shuf_mask_lo_highclear); const m256 wide_set = set2x128(shuf_mask_lo_highset); assert(buf && buf_end); assert(buf < buf_end); const u8 *rv; DEBUG_PRINTF("len %zu\n", buf_end - buf); if (buf_end - buf < 32) { return truffleRevMini(wide_clear, wide_set, buf, buf_end); } assert(buf_end - buf >= 32); // Preconditioning: most of the time our buffer won't be aligned. m256 chars = loadu256(buf_end - 32); rv = revBlock(wide_clear, wide_set, chars, buf_end - 32); if (rv) { return rv; } buf_end = (const u8 *)((size_t)buf_end & ~((size_t)0x1f)); const u8 *last_block = buf + 32; while (buf_end > last_block) { buf_end -= 32; m256 lchars = load256(buf_end); rv = revBlock(wide_clear, wide_set, lchars, buf_end); if (rv) { return rv; } } // Use an unaligned load to mop up the last 32 bytes and get an accurate // picture to buf_end. chars = loadu256(buf); rv = revBlock(wide_clear, wide_set, chars, buf); if (rv) { return rv; } return buf - 1; } #else // AVX512 static really_inline const u8 *lastMatch(const u8 *buf, u64a z) { if (unlikely(z != ~0ULL)) { u64a pos = clz64(~z); assert(pos < 64); return buf + (63 - pos); } return NULL; // no match } static really_inline const u8 *firstMatch(const u8 *buf, u64a z) { if (unlikely(z != ~0ULL)) { u64a pos = ctz64(~z); assert(pos < 64); DEBUG_PRINTF("pos %llu\n", pos); return buf + pos; } return NULL; // no match } static really_inline u64a block(m512 shuf_mask_lo_highclear, m512 shuf_mask_lo_highset, m512 v) { m512 highconst = set64x8(0x80); m512 shuf_mask_hi = set8x64(0x8040201008040201); // and now do the real work m512 shuf1 = pshufb_m512(shuf_mask_lo_highclear, v); m512 t1 = xor512(v, highconst); m512 shuf2 = pshufb_m512(shuf_mask_lo_highset, t1); m512 t2 = andnot512(highconst, rshift64_m512(v, 4)); m512 shuf3 = pshufb_m512(shuf_mask_hi, t2); m512 tmp = and512(or512(shuf1, shuf2), shuf3); u64a z = eq512mask(tmp, zeroes512()); return z; } static really_inline const u8 *truffleMini(m512 shuf_mask_lo_highclear, m512 shuf_mask_lo_highset, const u8 *buf, const u8 *buf_end) { uintptr_t len = buf_end - buf; assert(len <= 64); __mmask64 mask = (~0ULL) >> (64 - len); m512 chars = loadu_maskz_m512(mask, buf); u64a z = block(shuf_mask_lo_highclear, shuf_mask_lo_highset, chars); const u8 *rv = firstMatch(buf, z | ~mask); return rv; } static really_inline const u8 *fwdBlock(m512 shuf_mask_lo_highclear, m512 shuf_mask_lo_highset, m512 v, const u8 *buf) { u64a z = block(shuf_mask_lo_highclear, shuf_mask_lo_highset, v); return firstMatch(buf, z); } static really_inline const u8 *revBlock(m512 shuf_mask_lo_highclear, m512 shuf_mask_lo_highset, m512 v, const u8 *buf) { u64a z = block(shuf_mask_lo_highclear, shuf_mask_lo_highset, v); return lastMatch(buf, z); } const u8 *truffleExec(m128 shuf_mask_lo_highclear, m128 shuf_mask_lo_highset, const u8 *buf, const u8 *buf_end) { DEBUG_PRINTF("len %zu\n", buf_end - buf); const m512 wide_clear = set4x128(shuf_mask_lo_highclear); const m512 wide_set = set4x128(shuf_mask_lo_highset); assert(buf && buf_end); assert(buf < buf_end); const u8 *rv; if (buf_end - buf <= 64) { rv = truffleMini(wide_clear, wide_set, buf, buf_end); return rv ? rv : buf_end; } assert(buf_end - buf >= 64); if ((uintptr_t)buf % 64) { // Preconditioning: most of the time our buffer won't be aligned. rv = truffleMini(wide_clear, wide_set, buf, ROUNDUP_PTR(buf, 64)); if (rv) { return rv; } buf = ROUNDUP_PTR(buf, 64); } const u8 *last_block = buf_end - 64; while (buf < last_block) { m512 lchars = load512(buf); rv = fwdBlock(wide_clear, wide_set, lchars, buf); if (rv) { return rv; } buf += 64; } // Use an unaligned load to mop up the last 64 bytes and get an accurate // picture to buf_end. assert(buf <= buf_end && buf >= buf_end - 64); m512 chars = loadu512(buf_end - 64); rv = fwdBlock(wide_clear, wide_set, chars, buf_end - 64); if (rv) { return rv; } return buf_end; } static really_inline const u8 *truffleRevMini(m512 shuf_mask_lo_highclear, m512 shuf_mask_lo_highset, const u8 *buf, const u8 *buf_end) { uintptr_t len = buf_end - buf; assert(len < 64); __mmask64 mask = (~0ULL) >> (64 - len); m512 chars = loadu_maskz_m512(mask, buf); u64a z = block(shuf_mask_lo_highclear, shuf_mask_lo_highset, chars); DEBUG_PRINTF("mask 0x%016llx z 0x%016llx\n", mask, z); const u8 *rv = lastMatch(buf, z | ~mask); if (rv) { return rv; } return buf - 1; } const u8 *rtruffleExec(m128 shuf_mask_lo_highclear, m128 shuf_mask_lo_highset, const u8 *buf, const u8 *buf_end) { const m512 wide_clear = set4x128(shuf_mask_lo_highclear); const m512 wide_set = set4x128(shuf_mask_lo_highset); assert(buf && buf_end); assert(buf < buf_end); const u8 *rv; DEBUG_PRINTF("len %zu\n", buf_end - buf); if (buf_end - buf < 64) { return truffleRevMini(wide_clear, wide_set, buf, buf_end); } assert(buf_end - buf >= 64); // Preconditioning: most of the time our buffer won't be aligned. m512 chars = loadu512(buf_end - 64); rv = revBlock(wide_clear, wide_set, chars, buf_end - 64); if (rv) { return rv; } buf_end = (const u8 *)ROUNDDOWN_N((uintptr_t)buf_end, 64); const u8 *last_block = buf + 64; while (buf_end > last_block) { buf_end -= 64; m512 lchars = load512(buf_end); rv = revBlock(wide_clear, wide_set, lchars, buf_end); if (rv) { return rv; } } // Use an unaligned load to mop up the last 64 bytes and get an accurate // picture to buf_end. chars = loadu512(buf); rv = revBlock(wide_clear, wide_set, chars, buf); if (rv) { return rv; } return buf - 1; } #endif