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03325e9b64
Convert CRC-32 LE variants to C. Signed-off-by: Heiko Carstens <hca@linux.ibm.com>
241 lines
7.6 KiB
C
241 lines
7.6 KiB
C
/* SPDX-License-Identifier: GPL-2.0 */
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/*
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* Hardware-accelerated CRC-32 variants for Linux on z Systems
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*
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* Use the z/Architecture Vector Extension Facility to accelerate the
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* computing of bitreflected CRC-32 checksums for IEEE 802.3 Ethernet
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* and Castagnoli.
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*
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* This CRC-32 implementation algorithm is bitreflected and processes
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* the least-significant bit first (Little-Endian).
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*
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* Copyright IBM Corp. 2015
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* Author(s): Hendrik Brueckner <brueckner@linux.vnet.ibm.com>
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*/
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#include <linux/types.h>
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#include <asm/fpu.h>
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#include "crc32-vx.h"
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/* Vector register range containing CRC-32 constants */
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#define CONST_PERM_LE2BE 9
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#define CONST_R2R1 10
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#define CONST_R4R3 11
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#define CONST_R5 12
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#define CONST_RU_POLY 13
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#define CONST_CRC_POLY 14
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/*
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* The CRC-32 constant block contains reduction constants to fold and
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* process particular chunks of the input data stream in parallel.
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*
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* For the CRC-32 variants, the constants are precomputed according to
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* these definitions:
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*
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* R1 = [(x4*128+32 mod P'(x) << 32)]' << 1
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* R2 = [(x4*128-32 mod P'(x) << 32)]' << 1
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* R3 = [(x128+32 mod P'(x) << 32)]' << 1
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* R4 = [(x128-32 mod P'(x) << 32)]' << 1
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* R5 = [(x64 mod P'(x) << 32)]' << 1
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* R6 = [(x32 mod P'(x) << 32)]' << 1
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*
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* The bitreflected Barret reduction constant, u', is defined as
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* the bit reversal of floor(x**64 / P(x)).
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*
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* where P(x) is the polynomial in the normal domain and the P'(x) is the
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* polynomial in the reversed (bitreflected) domain.
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*
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* CRC-32 (IEEE 802.3 Ethernet, ...) polynomials:
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*
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* P(x) = 0x04C11DB7
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* P'(x) = 0xEDB88320
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*
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* CRC-32C (Castagnoli) polynomials:
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*
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* P(x) = 0x1EDC6F41
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* P'(x) = 0x82F63B78
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*/
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static unsigned long constants_CRC_32_LE[] = {
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0x0f0e0d0c0b0a0908, 0x0706050403020100, /* BE->LE mask */
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0x1c6e41596, 0x154442bd4, /* R2, R1 */
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0x0ccaa009e, 0x1751997d0, /* R4, R3 */
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0x0, 0x163cd6124, /* R5 */
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0x0, 0x1f7011641, /* u' */
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0x0, 0x1db710641 /* P'(x) << 1 */
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};
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static unsigned long constants_CRC_32C_LE[] = {
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0x0f0e0d0c0b0a0908, 0x0706050403020100, /* BE->LE mask */
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0x09e4addf8, 0x740eef02, /* R2, R1 */
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0x14cd00bd6, 0xf20c0dfe, /* R4, R3 */
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0x0, 0x0dd45aab8, /* R5 */
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0x0, 0x0dea713f1, /* u' */
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0x0, 0x105ec76f0 /* P'(x) << 1 */
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};
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/**
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* crc32_le_vgfm_generic - Compute CRC-32 (LE variant) with vector registers
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* @crc: Initial CRC value, typically ~0.
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* @buf: Input buffer pointer, performance might be improved if the
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* buffer is on a doubleword boundary.
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* @size: Size of the buffer, must be 64 bytes or greater.
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* @constants: CRC-32 constant pool base pointer.
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*
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* Register usage:
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* V0: Initial CRC value and intermediate constants and results.
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* V1..V4: Data for CRC computation.
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* V5..V8: Next data chunks that are fetched from the input buffer.
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* V9: Constant for BE->LE conversion and shift operations
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* V10..V14: CRC-32 constants.
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*/
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static u32 crc32_le_vgfm_generic(u32 crc, unsigned char const *buf, size_t size, unsigned long *constants)
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{
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/* Load CRC-32 constants */
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fpu_vlm(CONST_PERM_LE2BE, CONST_CRC_POLY, constants);
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/*
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* Load the initial CRC value.
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*
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* The CRC value is loaded into the rightmost word of the
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* vector register and is later XORed with the LSB portion
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* of the loaded input data.
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*/
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fpu_vzero(0); /* Clear V0 */
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fpu_vlvgf(0, crc, 3); /* Load CRC into rightmost word */
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/* Load a 64-byte data chunk and XOR with CRC */
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fpu_vlm(1, 4, buf);
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fpu_vperm(1, 1, 1, CONST_PERM_LE2BE);
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fpu_vperm(2, 2, 2, CONST_PERM_LE2BE);
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fpu_vperm(3, 3, 3, CONST_PERM_LE2BE);
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fpu_vperm(4, 4, 4, CONST_PERM_LE2BE);
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fpu_vx(1, 0, 1); /* V1 ^= CRC */
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buf += 64;
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size -= 64;
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while (size >= 64) {
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fpu_vlm(5, 8, buf);
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fpu_vperm(5, 5, 5, CONST_PERM_LE2BE);
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fpu_vperm(6, 6, 6, CONST_PERM_LE2BE);
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fpu_vperm(7, 7, 7, CONST_PERM_LE2BE);
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fpu_vperm(8, 8, 8, CONST_PERM_LE2BE);
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/*
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* Perform a GF(2) multiplication of the doublewords in V1 with
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* the R1 and R2 reduction constants in V0. The intermediate
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* result is then folded (accumulated) with the next data chunk
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* in V5 and stored in V1. Repeat this step for the register
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* contents in V2, V3, and V4 respectively.
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*/
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fpu_vgfmag(1, CONST_R2R1, 1, 5);
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fpu_vgfmag(2, CONST_R2R1, 2, 6);
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fpu_vgfmag(3, CONST_R2R1, 3, 7);
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fpu_vgfmag(4, CONST_R2R1, 4, 8);
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buf += 64;
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size -= 64;
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}
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/*
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* Fold V1 to V4 into a single 128-bit value in V1. Multiply V1 with R3
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* and R4 and accumulating the next 128-bit chunk until a single 128-bit
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* value remains.
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*/
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fpu_vgfmag(1, CONST_R4R3, 1, 2);
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fpu_vgfmag(1, CONST_R4R3, 1, 3);
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fpu_vgfmag(1, CONST_R4R3, 1, 4);
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while (size >= 16) {
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fpu_vl(2, buf);
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fpu_vperm(2, 2, 2, CONST_PERM_LE2BE);
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fpu_vgfmag(1, CONST_R4R3, 1, 2);
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buf += 16;
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size -= 16;
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}
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/*
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* Set up a vector register for byte shifts. The shift value must
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* be loaded in bits 1-4 in byte element 7 of a vector register.
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* Shift by 8 bytes: 0x40
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* Shift by 4 bytes: 0x20
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*/
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fpu_vleib(9, 0x40, 7);
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/*
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* Prepare V0 for the next GF(2) multiplication: shift V0 by 8 bytes
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* to move R4 into the rightmost doubleword and set the leftmost
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* doubleword to 0x1.
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*/
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fpu_vsrlb(0, CONST_R4R3, 9);
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fpu_vleig(0, 1, 0);
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/*
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* Compute GF(2) product of V1 and V0. The rightmost doubleword
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* of V1 is multiplied with R4. The leftmost doubleword of V1 is
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* multiplied by 0x1 and is then XORed with rightmost product.
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* Implicitly, the intermediate leftmost product becomes padded
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*/
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fpu_vgfmg(1, 0, 1);
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/*
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* Now do the final 32-bit fold by multiplying the rightmost word
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* in V1 with R5 and XOR the result with the remaining bits in V1.
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*
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* To achieve this by a single VGFMAG, right shift V1 by a word
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* and store the result in V2 which is then accumulated. Use the
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* vector unpack instruction to load the rightmost half of the
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* doubleword into the rightmost doubleword element of V1; the other
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* half is loaded in the leftmost doubleword.
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* The vector register with CONST_R5 contains the R5 constant in the
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* rightmost doubleword and the leftmost doubleword is zero to ignore
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* the leftmost product of V1.
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*/
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fpu_vleib(9, 0x20, 7); /* Shift by words */
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fpu_vsrlb(2, 1, 9); /* Store remaining bits in V2 */
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fpu_vupllf(1, 1); /* Split rightmost doubleword */
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fpu_vgfmag(1, CONST_R5, 1, 2); /* V1 = (V1 * R5) XOR V2 */
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/*
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* Apply a Barret reduction to compute the final 32-bit CRC value.
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*
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* The input values to the Barret reduction are the degree-63 polynomial
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* in V1 (R(x)), degree-32 generator polynomial, and the reduction
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* constant u. The Barret reduction result is the CRC value of R(x) mod
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* P(x).
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*
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* The Barret reduction algorithm is defined as:
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*
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* 1. T1(x) = floor( R(x) / x^32 ) GF2MUL u
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* 2. T2(x) = floor( T1(x) / x^32 ) GF2MUL P(x)
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* 3. C(x) = R(x) XOR T2(x) mod x^32
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*
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* Note: The leftmost doubleword of vector register containing
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* CONST_RU_POLY is zero and, thus, the intermediate GF(2) product
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* is zero and does not contribute to the final result.
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*/
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/* T1(x) = floor( R(x) / x^32 ) GF2MUL u */
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fpu_vupllf(2, 1);
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fpu_vgfmg(2, CONST_RU_POLY, 2);
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/*
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* Compute the GF(2) product of the CRC polynomial with T1(x) in
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* V2 and XOR the intermediate result, T2(x), with the value in V1.
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* The final result is stored in word element 2 of V2.
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*/
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fpu_vupllf(2, 2);
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fpu_vgfmag(2, CONST_CRC_POLY, 2, 1);
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return fpu_vlgvf(2, 2);
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}
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u32 crc32_le_vgfm_16(u32 crc, unsigned char const *buf, size_t size)
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{
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return crc32_le_vgfm_generic(crc, buf, size, &constants_CRC_32_LE[0]);
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}
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u32 crc32c_le_vgfm_16(u32 crc, unsigned char const *buf, size_t size)
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{
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return crc32_le_vgfm_generic(crc, buf, size, &constants_CRC_32C_LE[0]);
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}
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