703d143619
If two different types of SHA hashes were active in the hardware concurrently, a race condition meant the SHA unit could be incorrectly reset leading to all-zero results.
315 lines
8.5 KiB
C
315 lines
8.5 KiB
C
/*
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* ESP32 hardware accelerated SHA1/256/512 implementation
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* based on mbedTLS FIPS-197 compliant version.
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*
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* Copyright (C) 2006-2015, ARM Limited, All Rights Reserved
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* Additions Copyright (C) 2016, Espressif Systems (Shanghai) PTE Ltd
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* SPDX-License-Identifier: Apache-2.0
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*
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* Licensed under the Apache License, Version 2.0 (the "License"); you may
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* not use this file except in compliance with the License.
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* You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
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* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*
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*/
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/*
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* The SHA-1 standard was published by NIST in 1993.
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*
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* http://www.itl.nist.gov/fipspubs/fip180-1.htm
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*/
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#include <string.h>
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#include <stdio.h>
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#include <sys/lock.h>
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#include <byteswap.h>
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#include <assert.h>
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#include "hwcrypto/sha.h"
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#include "rom/ets_sys.h"
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#include "soc/dport_reg.h"
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#include "soc/hwcrypto_reg.h"
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inline static uint32_t SHA_LOAD_REG(esp_sha_type sha_type) {
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return SHA_1_LOAD_REG + sha_type * 0x10;
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}
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inline static uint32_t SHA_BUSY_REG(esp_sha_type sha_type) {
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return SHA_1_BUSY_REG + sha_type * 0x10;
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}
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inline static uint32_t SHA_START_REG(esp_sha_type sha_type) {
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return SHA_1_START_REG + sha_type * 0x10;
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}
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inline static uint32_t SHA_CONTINUE_REG(esp_sha_type sha_type) {
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return SHA_1_CONTINUE_REG + sha_type * 0x10;
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}
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/* Single lock for SHA engine memory block
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*/
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static _lock_t memory_block_lock;
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typedef struct {
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_lock_t lock;
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bool in_use;
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} sha_engine_state;
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/* Pointer to state of each concurrent SHA engine.
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Indexes:
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0 = SHA1
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1 = SHA2_256
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2 = SHA2_384 or SHA2_512
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*/
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static sha_engine_state engine_states[3];
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/* Index into the sha_engine_state array */
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inline static size_t sha_engine_index(esp_sha_type type) {
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switch(type) {
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case SHA1:
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return 0;
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case SHA2_256:
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return 1;
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default:
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return 2;
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}
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}
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/* Return digest length (in bytes) for a given SHA type */
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inline static size_t sha_length(esp_sha_type type) {
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switch(type) {
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case SHA1:
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return 20;
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case SHA2_256:
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return 32;
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case SHA2_384:
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return 48;
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case SHA2_512:
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return 64;
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default:
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return 0;
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}
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}
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/* Return block size (in bytes) for a given SHA type */
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inline static size_t block_length(esp_sha_type type) {
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switch(type) {
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case SHA1:
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case SHA2_256:
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return 64;
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case SHA2_384:
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case SHA2_512:
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return 128;
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default:
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return 0;
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}
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}
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void esp_sha_lock_memory_block(void)
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{
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_lock_acquire(&memory_block_lock);
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}
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void esp_sha_unlock_memory_block(void)
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{
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_lock_release(&memory_block_lock);
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}
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/* Lock to hold when changing SHA engine state,
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allows checking of sha_engines_all_idle()
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*/
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static _lock_t state_change_lock;
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inline static bool sha_engines_all_idle() {
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return !engine_states[0].in_use
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&& !engine_states[1].in_use
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&& !engine_states[2].in_use;
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}
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static void esp_sha_lock_engine_inner(sha_engine_state *engine);
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bool esp_sha_try_lock_engine(esp_sha_type sha_type)
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{
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sha_engine_state *engine = &engine_states[sha_engine_index(sha_type)];
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if(_lock_try_acquire(&engine->lock) != 0) {
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/* This SHA engine is already in use */
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return false;
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} else {
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esp_sha_lock_engine_inner(engine);
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return true;
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}
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}
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void esp_sha_lock_engine(esp_sha_type sha_type)
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{
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sha_engine_state *engine = &engine_states[sha_engine_index(sha_type)];
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_lock_acquire(&engine->lock);
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esp_sha_lock_engine_inner(engine);
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}
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static void esp_sha_lock_engine_inner(sha_engine_state *engine)
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{
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_lock_acquire(&state_change_lock);
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if (sha_engines_all_idle()) {
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DPORT_STALL_OTHER_CPU_START();
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{
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/* Enable SHA hardware */
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_DPORT_REG_SET_BIT(DPORT_PERI_CLK_EN_REG, DPORT_PERI_EN_SHA);
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/* also clear reset on secure boot, otherwise SHA is held in reset */
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_DPORT_REG_CLR_BIT(DPORT_PERI_RST_EN_REG,
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DPORT_PERI_EN_SHA
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| DPORT_PERI_EN_SECUREBOOT);
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ets_sha_enable();
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}
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DPORT_STALL_OTHER_CPU_END();
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}
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assert( !engine->in_use && "in_use flag should be cleared" );
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engine->in_use = true;
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_lock_release(&state_change_lock);
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}
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void esp_sha_unlock_engine(esp_sha_type sha_type)
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{
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sha_engine_state *engine = &engine_states[sha_engine_index(sha_type)];
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_lock_acquire(&state_change_lock);
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assert( engine->in_use && "in_use flag should be set" );
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engine->in_use = false;
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if (sha_engines_all_idle()) {
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/* Disable SHA hardware */
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/* Don't assert reset on secure boot, otherwise AES is held in reset */
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DPORT_STALL_OTHER_CPU_START();
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{
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_DPORT_REG_SET_BIT(DPORT_PERI_RST_EN_REG, DPORT_PERI_EN_SHA);
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_DPORT_REG_CLR_BIT(DPORT_PERI_CLK_EN_REG, DPORT_PERI_EN_SHA);
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}
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DPORT_STALL_OTHER_CPU_END();
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}
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_lock_release(&state_change_lock);
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_lock_release(&engine->lock);
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}
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void esp_sha_wait_idle(void)
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{
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DPORT_STALL_OTHER_CPU_START();
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while(1) {
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if(_DPORT_REG_READ(SHA_1_BUSY_REG) == 0
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&& _DPORT_REG_READ(SHA_256_BUSY_REG) == 0
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&& _DPORT_REG_READ(SHA_384_BUSY_REG) == 0
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&& _DPORT_REG_READ(SHA_512_BUSY_REG) == 0) {
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break;
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}
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}
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DPORT_STALL_OTHER_CPU_END();
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}
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void esp_sha_read_digest_state(esp_sha_type sha_type, void *digest_state)
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{
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sha_engine_state *engine = &engine_states[sha_engine_index(sha_type)];
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assert(engine->in_use && "SHA engine should be locked" );
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esp_sha_lock_memory_block();
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DPORT_STALL_OTHER_CPU_START(); // This block reads from DPORT memory (reg_addr_buf)
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{
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esp_sha_wait_idle();
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_DPORT_REG_WRITE(SHA_LOAD_REG(sha_type), 1);
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while(_DPORT_REG_READ(SHA_BUSY_REG(sha_type)) == 1) { }
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uint32_t *digest_state_words = (uint32_t *)digest_state;
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uint32_t *reg_addr_buf = (uint32_t *)(SHA_TEXT_BASE);
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if(sha_type == SHA2_384 || sha_type == SHA2_512) {
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/* for these ciphers using 64-bit states, swap each pair of words */
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for(int i = 0; i < sha_length(sha_type)/4; i += 2) {
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digest_state_words[i+1] = reg_addr_buf[i];
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digest_state_words[i]= reg_addr_buf[i+1];
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}
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} else {
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memcpy(digest_state_words, reg_addr_buf, sha_length(sha_type));
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}
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}
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DPORT_STALL_OTHER_CPU_END();
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esp_sha_unlock_memory_block();
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}
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void esp_sha_block(esp_sha_type sha_type, const void *data_block, bool is_first_block)
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{
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sha_engine_state *engine = &engine_states[sha_engine_index(sha_type)];
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assert(engine->in_use && "SHA engine should be locked" );
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esp_sha_lock_memory_block();
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esp_sha_wait_idle();
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/* Fill the data block */
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uint32_t *reg_addr_buf = (uint32_t *)(SHA_TEXT_BASE);
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uint32_t *data_words = (uint32_t *)data_block;
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for (int i = 0; i < block_length(sha_type) / 4; i++) {
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reg_addr_buf[i] = __bswap_32(data_words[i]);
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}
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asm volatile ("memw");
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if(is_first_block) {
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DPORT_REG_WRITE(SHA_START_REG(sha_type), 1);
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} else {
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DPORT_REG_WRITE(SHA_CONTINUE_REG(sha_type), 1);
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}
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esp_sha_unlock_memory_block();
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/* Note: deliberately not waiting for this operation to complete,
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as a performance tweak - delay waiting until the next time we need the SHA
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unit, instead.
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*/
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}
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void esp_sha(esp_sha_type sha_type, const unsigned char *input, size_t ilen, unsigned char *output)
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{
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size_t block_len = block_length(sha_type);
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esp_sha_lock_engine(sha_type);
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SHA_CTX ctx;
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ets_sha_init(&ctx);
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while(ilen > 0) {
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size_t chunk_len = (ilen > block_len) ? block_len : ilen;
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esp_sha_lock_memory_block();
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esp_sha_wait_idle();
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DPORT_STALL_OTHER_CPU_START();
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{
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// This SHA ROM function reads DPORT regs
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ets_sha_update(&ctx, sha_type, input, chunk_len * 8);
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}
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DPORT_STALL_OTHER_CPU_END();
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esp_sha_unlock_memory_block();
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input += chunk_len;
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ilen -= chunk_len;
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}
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esp_sha_lock_memory_block();
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esp_sha_wait_idle();
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DPORT_STALL_OTHER_CPU_START();
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{
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ets_sha_finish(&ctx, sha_type, output);
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}
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DPORT_STALL_OTHER_CPU_END();
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esp_sha_unlock_memory_block();
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esp_sha_unlock_engine(sha_type);
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}
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