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008071917d
Move the s390 CRC32 assembly code into the lib directory and wire it up to the library interface. This allows it to be used without going through the crypto API. It remains usable via the crypto API too via the shash algorithms that use the library interface. Thus all the arch-specific "shash" code becomes unnecessary and is removed. Note: to see the diff from arch/s390/crypto/crc32-vx.c to arch/s390/lib/crc32-glue.c, view this commit with 'git show -M10'. Reviewed-by: Ard Biesheuvel <ardb@kernel.org> Link: https://lore.kernel.org/r/20241202010844.144356-10-ebiggers@kernel.org Signed-off-by: Eric Biggers <ebiggers@google.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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