######################################################################## # Implement fast CRC-T10DIF computation with SSE and PCLMULQDQ instructions # # Copyright (c) 2013, Intel Corporation # # Authors: # Erdinc Ozturk <erdinc.ozturk@intel.com> # Vinodh Gopal <vinodh.gopal@intel.com> # James Guilford <james.guilford@intel.com> # Tim Chen <tim.c.chen@linux.intel.com> # # This software is available to you under a choice of one of two # licenses. You may choose to be licensed under the terms of the GNU # General Public License (GPL) Version 2, available from the file # COPYING in the main directory of this source tree, or the # OpenIB.org BSD license below: # # 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 the 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 INTEL CORPORATION ""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 INTEL CORPORATION 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. # # Reference paper titled "Fast CRC Computation for Generic # Polynomials Using PCLMULQDQ Instruction" # URL: http://www.intel.com/content/dam/www/public/us/en/documents # /white-papers/fast-crc-computation-generic-polynomials-pclmulqdq-paper.pdf # #include <linux/linkage.h> .text #define init_crc %edi #define buf %rsi #define len %rdx #define FOLD_CONSTS %xmm10 #define BSWAP_MASK %xmm11 # Fold reg1, reg2 into the next 32 data bytes, storing the result back into # reg1, reg2. .macro fold_32_bytes offset, reg1, reg2 movdqu \offset(buf), %xmm9 movdqu \offset+16(buf), %xmm12 pshufb BSWAP_MASK, %xmm9 pshufb BSWAP_MASK, %xmm12 movdqa \reg1, %xmm8 movdqa \reg2, %xmm13 pclmulqdq $0x00, FOLD_CONSTS, \reg1 pclmulqdq $0x11, FOLD_CONSTS, %xmm8 pclmulqdq $0x00, FOLD_CONSTS, \reg2 pclmulqdq $0x11, FOLD_CONSTS, %xmm13 pxor %xmm9 , \reg1 xorps %xmm8 , \reg1 pxor %xmm12, \reg2 xorps %xmm13, \reg2 .endm # Fold src_reg into dst_reg. .macro fold_16_bytes src_reg, dst_reg movdqa \src_reg, %xmm8 pclmulqdq $0x11, FOLD_CONSTS, \src_reg pclmulqdq $0x00, FOLD_CONSTS, %xmm8 pxor %xmm8, \dst_reg xorps \src_reg, \dst_reg .endm # # u16 crc_t10dif_pcl(u16 init_crc, const *u8 buf, size_t len); # # Assumes len >= 16. # SYM_FUNC_START(crc_t10dif_pcl) movdqa .Lbswap_mask(%rip), BSWAP_MASK # For sizes less than 256 bytes, we can't fold 128 bytes at a time. cmp $256, len jl .Lless_than_256_bytes # Load the first 128 data bytes. Byte swapping is necessary to make the # bit order match the polynomial coefficient order. movdqu 16*0(buf), %xmm0 movdqu 16*1(buf), %xmm1 movdqu 16*2(buf), %xmm2 movdqu 16*3(buf), %xmm3 movdqu 16*4(buf), %xmm4 movdqu 16*5(buf), %xmm5 movdqu 16*6(buf), %xmm6 movdqu 16*7(buf), %xmm7 add $128, buf pshufb BSWAP_MASK, %xmm0 pshufb BSWAP_MASK, %xmm1 pshufb BSWAP_MASK, %xmm2 pshufb BSWAP_MASK, %xmm3 pshufb BSWAP_MASK, %xmm4 pshufb BSWAP_MASK, %xmm5 pshufb BSWAP_MASK, %xmm6 pshufb BSWAP_MASK, %xmm7 # XOR the first 16 data *bits* with the initial CRC value. pxor %xmm8, %xmm8 pinsrw $7, init_crc, %xmm8 pxor %xmm8, %xmm0 movdqa .Lfold_across_128_bytes_consts(%rip), FOLD_CONSTS # Subtract 128 for the 128 data bytes just consumed. Subtract another # 128 to simplify the termination condition of the following loop. sub $256, len # While >= 128 data bytes remain (not counting xmm0-7), fold the 128 # bytes xmm0-7 into them, storing the result back into xmm0-7. .Lfold_128_bytes_loop: fold_32_bytes 0, %xmm0, %xmm1 fold_32_bytes 32, %xmm2, %xmm3 fold_32_bytes 64, %xmm4, %xmm5 fold_32_bytes 96, %xmm6, %xmm7 add $128, buf sub $128, len jge .Lfold_128_bytes_loop # Now fold the 112 bytes in xmm0-xmm6 into the 16 bytes in xmm7. # Fold across 64 bytes. movdqa .Lfold_across_64_bytes_consts(%rip), FOLD_CONSTS fold_16_bytes %xmm0, %xmm4 fold_16_bytes %xmm1, %xmm5 fold_16_bytes %xmm2, %xmm6 fold_16_bytes %xmm3, %xmm7 # Fold across 32 bytes. movdqa .Lfold_across_32_bytes_consts(%rip), FOLD_CONSTS fold_16_bytes %xmm4, %xmm6 fold_16_bytes %xmm5, %xmm7 # Fold across 16 bytes. movdqa .Lfold_across_16_bytes_consts(%rip), FOLD_CONSTS fold_16_bytes %xmm6, %xmm7 # Add 128 to get the correct number of data bytes remaining in 0...127 # (not counting xmm7), following the previous extra subtraction by 128. # Then subtract 16 to simplify the termination condition of the # following loop. add $128-16, len # While >= 16 data bytes remain (not counting xmm7), fold the 16 bytes # xmm7 into them, storing the result back into xmm7. jl .Lfold_16_bytes_loop_done .Lfold_16_bytes_loop: movdqa %xmm7, %xmm8 pclmulqdq $0x11, FOLD_CONSTS, %xmm7 pclmulqdq $0x00, FOLD_CONSTS, %xmm8 pxor %xmm8, %xmm7 movdqu (buf), %xmm0 pshufb BSWAP_MASK, %xmm0 pxor %xmm0 , %xmm7 add $16, buf sub $16, len jge .Lfold_16_bytes_loop .Lfold_16_bytes_loop_done: # Add 16 to get the correct number of data bytes remaining in 0...15 # (not counting xmm7), following the previous extra subtraction by 16. add $16, len je .Lreduce_final_16_bytes .Lhandle_partial_segment: # Reduce the last '16 + len' bytes where 1 <= len <= 15 and the first 16 # bytes are in xmm7 and the rest are the remaining data in 'buf'. To do # this without needing a fold constant for each possible 'len', redivide # the bytes into a first chunk of 'len' bytes and a second chunk of 16 # bytes, then fold the first chunk into the second. movdqa %xmm7, %xmm2 # xmm1 = last 16 original data bytes movdqu -16(buf, len), %xmm1 pshufb BSWAP_MASK, %xmm1 # xmm2 = high order part of second chunk: xmm7 left-shifted by 'len' bytes. lea .Lbyteshift_table+16(%rip), %rax sub len, %rax movdqu (%rax), %xmm0 pshufb %xmm0, %xmm2 # xmm7 = first chunk: xmm7 right-shifted by '16-len' bytes. pxor .Lmask1(%rip), %xmm0 pshufb %xmm0, %xmm7 # xmm1 = second chunk: 'len' bytes from xmm1 (low-order bytes), # then '16-len' bytes from xmm2 (high-order bytes). pblendvb %xmm2, %xmm1 #xmm0 is implicit # Fold the first chunk into the second chunk, storing the result in xmm7. movdqa %xmm7, %xmm8 pclmulqdq $0x11, FOLD_CONSTS, %xmm7 pclmulqdq $0x00, FOLD_CONSTS, %xmm8 pxor %xmm8, %xmm7 pxor %xmm1, %xmm7 .Lreduce_final_16_bytes: # Reduce the 128-bit value M(x), stored in xmm7, to the final 16-bit CRC # Load 'x^48 * (x^48 mod G(x))' and 'x^48 * (x^80 mod G(x))'. movdqa .Lfinal_fold_consts(%rip), FOLD_CONSTS # Fold the high 64 bits into the low 64 bits, while also multiplying by # x^64. This produces a 128-bit value congruent to x^64 * M(x) and # whose low 48 bits are 0. movdqa %xmm7, %xmm0 pclmulqdq $0x11, FOLD_CONSTS, %xmm7 # high bits * x^48 * (x^80 mod G(x)) pslldq $8, %xmm0 pxor %xmm0, %xmm7 # + low bits * x^64 # Fold the high 32 bits into the low 96 bits. This produces a 96-bit # value congruent to x^64 * M(x) and whose low 48 bits are 0. movdqa %xmm7, %xmm0 pand .Lmask2(%rip), %xmm0 # zero high 32 bits psrldq $12, %xmm7 # extract high 32 bits pclmulqdq $0x00, FOLD_CONSTS, %xmm7 # high 32 bits * x^48 * (x^48 mod G(x)) pxor %xmm0, %xmm7 # + low bits # Load G(x) and floor(x^48 / G(x)). movdqa .Lbarrett_reduction_consts(%rip), FOLD_CONSTS # Use Barrett reduction to compute the final CRC value. movdqa %xmm7, %xmm0 pclmulqdq $0x11, FOLD_CONSTS, %xmm7 # high 32 bits * floor(x^48 / G(x)) psrlq $32, %xmm7 # /= x^32 pclmulqdq $0x00, FOLD_CONSTS, %xmm7 # *= G(x) psrlq $48, %xmm0 pxor %xmm7, %xmm0 # + low 16 nonzero bits # Final CRC value (x^16 * M(x)) mod G(x) is in low 16 bits of xmm0. pextrw $0, %xmm0, %eax RET .align 16 .Lless_than_256_bytes: # Checksumming a buffer of length 16...255 bytes # Load the first 16 data bytes. movdqu (buf), %xmm7 pshufb BSWAP_MASK, %xmm7 add $16, buf # XOR the first 16 data *bits* with the initial CRC value. pxor %xmm0, %xmm0 pinsrw $7, init_crc, %xmm0 pxor %xmm0, %xmm7 movdqa .Lfold_across_16_bytes_consts(%rip), FOLD_CONSTS cmp $16, len je .Lreduce_final_16_bytes # len == 16 sub $32, len jge .Lfold_16_bytes_loop # 32 <= len <= 255 add $16, len jmp .Lhandle_partial_segment # 17 <= len <= 31 SYM_FUNC_END(crc_t10dif_pcl) .section .rodata, "a", @progbits .align 16 # Fold constants precomputed from the polynomial 0x18bb7 # G(x) = x^16 + x^15 + x^11 + x^9 + x^8 + x^7 + x^5 + x^4 + x^2 + x^1 + x^0 .Lfold_across_128_bytes_consts: .quad 0x0000000000006123 # x^(8*128) mod G(x) .quad 0x0000000000002295 # x^(8*128+64) mod G(x) .Lfold_across_64_bytes_consts: .quad 0x0000000000001069 # x^(4*128) mod G(x) .quad 0x000000000000dd31 # x^(4*128+64) mod G(x) .Lfold_across_32_bytes_consts: .quad 0x000000000000857d # x^(2*128) mod G(x) .quad 0x0000000000007acc # x^(2*128+64) mod G(x) .Lfold_across_16_bytes_consts: .quad 0x000000000000a010 # x^(1*128) mod G(x) .quad 0x0000000000001faa # x^(1*128+64) mod G(x) .Lfinal_fold_consts: .quad 0x1368000000000000 # x^48 * (x^48 mod G(x)) .quad 0x2d56000000000000 # x^48 * (x^80 mod G(x)) .Lbarrett_reduction_consts: .quad 0x0000000000018bb7 # G(x) .quad 0x00000001f65a57f8 # floor(x^48 / G(x)) .section .rodata.cst16.mask1, "aM", @progbits, 16 .align 16 .Lmask1: .octa 0x80808080808080808080808080808080 .section .rodata.cst16.mask2, "aM", @progbits, 16 .align 16 .Lmask2: .octa 0x00000000FFFFFFFFFFFFFFFFFFFFFFFF .section .rodata.cst16.bswap_mask, "aM", @progbits, 16 .align 16 .Lbswap_mask: .octa 0x000102030405060708090A0B0C0D0E0F .section .rodata.cst32.byteshift_table, "aM", @progbits, 32 .align 16 # For 1 <= len <= 15, the 16-byte vector beginning at &byteshift_table[16 - len] # is the index vector to shift left by 'len' bytes, and is also {0x80, ..., # 0x80} XOR the index vector to shift right by '16 - len' bytes. .Lbyteshift_table: .byte 0x0, 0x81, 0x82, 0x83, 0x84, 0x85, 0x86, 0x87 .byte 0x88, 0x89, 0x8a, 0x8b, 0x8c, 0x8d, 0x8e, 0x8f .byte 0x0, 0x1, 0x2, 0x3, 0x4, 0x5, 0x6, 0x7 .byte 0x8, 0x9, 0xa, 0xb, 0xc, 0xd, 0xe , 0x0