// SPDX-License-Identifier: GPL-2.0 /* * Hash acceleration support for Rockchip Crypto v2 * * Copyright (c) 2020, Rockchip Electronics Co., Ltd. * * Author: Lin Jinhan * * Some ideas are from marvell/cesa.c and s5p-sss.c driver. */ #include #include #include "rk_crypto_core.h" #include "rk_crypto_v2.h" #include "rk_crypto_v2_reg.h" #include "rk_crypto_ahash_utils.h" #include "rk_crypto_utils.h" #define RK_HASH_CTX_MAGIC 0x1A1A1A1A #define RK_POLL_PERIOD_US 100 #define RK_POLL_TIMEOUT_US 50000 static const u32 hash_algo2bc[] = { [HASH_ALGO_MD5] = CRYPTO_MD5, [HASH_ALGO_SHA1] = CRYPTO_SHA1, [HASH_ALGO_SHA224] = CRYPTO_SHA224, [HASH_ALGO_SHA256] = CRYPTO_SHA256, [HASH_ALGO_SHA384] = CRYPTO_SHA384, [HASH_ALGO_SHA512] = CRYPTO_SHA512, [HASH_ALGO_SM3] = CRYPTO_SM3, }; static void rk_hash_reset(struct rk_crypto_dev *rk_dev) { int ret; u32 tmp = 0, tmp_mask = 0; unsigned int pool_timeout_us = 1000; CRYPTO_WRITE(rk_dev, CRYPTO_DMA_INT_EN, 0x00); tmp = CRYPTO_SW_CC_RESET; tmp_mask = tmp << CRYPTO_WRITE_MASK_SHIFT; CRYPTO_WRITE(rk_dev, CRYPTO_RST_CTL, tmp | tmp_mask); /* This is usually done in 20 clock cycles */ ret = read_poll_timeout_atomic(CRYPTO_READ, tmp, !tmp, 0, pool_timeout_us, false, rk_dev, CRYPTO_RST_CTL); if (ret) dev_err(rk_dev->dev, "cipher reset pool timeout %ums.", pool_timeout_us); CRYPTO_WRITE(rk_dev, CRYPTO_HASH_CTL, 0xffff0000); /* clear dma int status */ tmp = CRYPTO_READ(rk_dev, CRYPTO_DMA_INT_ST); CRYPTO_WRITE(rk_dev, CRYPTO_DMA_INT_ST, tmp); } static int rk_crypto_irq_handle(int irq, void *dev_id) { struct rk_crypto_dev *rk_dev = platform_get_drvdata(dev_id); u32 interrupt_status; struct rk_hw_crypto_v2_info *hw_info = (struct rk_hw_crypto_v2_info *)rk_dev->hw_info; struct rk_alg_ctx *alg_ctx = rk_ahash_alg_ctx(rk_dev); /* disable crypto irq */ CRYPTO_WRITE(rk_dev, CRYPTO_DMA_INT_EN, 0); interrupt_status = CRYPTO_READ(rk_dev, CRYPTO_DMA_INT_ST); CRYPTO_WRITE(rk_dev, CRYPTO_DMA_INT_ST, interrupt_status); interrupt_status &= CRYPTO_LOCKSTEP_MASK; if (interrupt_status != CRYPTO_SRC_ITEM_DONE_INT_ST) { dev_err(rk_dev->dev, "DMA desc = %p\n", hw_info->hw_desc.lli_head); dev_err(rk_dev->dev, "DMA addr_in = %08x\n", (u32)alg_ctx->addr_in); dev_err(rk_dev->dev, "DMA addr_out = %08x\n", (u32)alg_ctx->addr_out); dev_err(rk_dev->dev, "DMA count = %08x\n", alg_ctx->count); dev_err(rk_dev->dev, "DMA desc_dma = %08x\n", (u32)hw_info->hw_desc.lli_head_dma); dev_err(rk_dev->dev, "DMA Error status = %08x\n", interrupt_status); dev_err(rk_dev->dev, "DMA CRYPTO_DMA_LLI_ADDR status = %08x\n", CRYPTO_READ(rk_dev, CRYPTO_DMA_LLI_ADDR)); dev_err(rk_dev->dev, "DMA CRYPTO_DMA_ST status = %08x\n", CRYPTO_READ(rk_dev, CRYPTO_DMA_ST)); dev_err(rk_dev->dev, "DMA CRYPTO_DMA_STATE status = %08x\n", CRYPTO_READ(rk_dev, CRYPTO_DMA_STATE)); dev_err(rk_dev->dev, "DMA CRYPTO_DMA_LLI_RADDR status = %08x\n", CRYPTO_READ(rk_dev, CRYPTO_DMA_LLI_RADDR)); dev_err(rk_dev->dev, "DMA CRYPTO_DMA_SRC_RADDR status = %08x\n", CRYPTO_READ(rk_dev, CRYPTO_DMA_SRC_RADDR)); dev_err(rk_dev->dev, "DMA CRYPTO_DMA_DST_RADDR status = %08x\n", CRYPTO_READ(rk_dev, CRYPTO_DMA_DST_RADDR)); rk_dev->err = -EFAULT; } return 0; } static void rk_ahash_crypto_complete(struct crypto_async_request *base, int err) { struct ahash_request *req = ahash_request_cast(base); struct crypto_ahash *tfm = crypto_ahash_reqtfm(req); struct rk_ahash_ctx *ctx = crypto_ahash_ctx(tfm); struct rk_alg_ctx *alg_ctx = rk_ahash_alg_ctx(ctx->rk_dev); struct rk_hw_crypto_v2_info *hw_info = ctx->rk_dev->hw_info; struct crypto_lli_desc *lli_desc = hw_info->hw_desc.lli_head; if (err) { rk_hash_reset(ctx->rk_dev); pr_err("aligned = %u, align_size = %u\n", alg_ctx->aligned, alg_ctx->align_size); pr_err("total = %u, left = %u, count = %u\n", alg_ctx->total, alg_ctx->left_bytes, alg_ctx->count); pr_err("lli->src = %08x\n", lli_desc->src_addr); pr_err("lli->src_len = %08x\n", lli_desc->src_len); pr_err("lli->dst = %08x\n", lli_desc->dst_addr); pr_err("lli->dst_len = %08x\n", lli_desc->dst_len); pr_err("lli->dma_ctl = %08x\n", lli_desc->dma_ctrl); pr_err("lli->usr_def = %08x\n", lli_desc->user_define); pr_err("lli->next = %08x\n\n\n", lli_desc->next_addr); } if (base->complete) base->complete(base, err); } static inline void clear_hash_out_reg(struct rk_crypto_dev *rk_dev) { rk_crypto_clear_regs(rk_dev, CRYPTO_HASH_DOUT_0, 16); } static int write_key_reg(struct rk_crypto_dev *rk_dev, const u8 *key, u32 key_len) { rk_crypto_write_regs(rk_dev, CRYPTO_CH0_KEY_0, key, key_len); return 0; } static int rk_hw_hash_init(struct rk_crypto_dev *rk_dev, u32 algo, u32 type) { u32 reg_ctrl = 0; if (algo >= ARRAY_SIZE(hash_algo2bc)) goto exit; rk_hash_reset(rk_dev); clear_hash_out_reg(rk_dev); reg_ctrl = hash_algo2bc[algo] | CRYPTO_HW_PAD_ENABLE; if (IS_TYPE_HMAC(type)) { CRYPTO_TRACE("this is hmac"); reg_ctrl |= CRYPTO_HMAC_ENABLE; } CRYPTO_WRITE(rk_dev, CRYPTO_HASH_CTL, reg_ctrl | CRYPTO_WRITE_MASK_ALL); CRYPTO_WRITE(rk_dev, CRYPTO_FIFO_CTL, 0x00030003); return 0; exit: CRYPTO_WRITE(rk_dev, CRYPTO_HASH_CTL, 0 | CRYPTO_WRITE_MASK_ALL); return -EINVAL; } static void clean_hash_setting(struct rk_crypto_dev *rk_dev) { CRYPTO_WRITE(rk_dev, CRYPTO_DMA_INT_EN, 0); CRYPTO_WRITE(rk_dev, CRYPTO_HASH_CTL, 0 | CRYPTO_WRITE_MASK_ALL); } static int rk_ahash_import(struct ahash_request *req, const void *in) { struct rk_ahash_ctx state; /* 'in' may not be aligned so memcpy to local variable */ memcpy(&state, in, sizeof(state)); ///TODO: deal with import return 0; } static int rk_ahash_export(struct ahash_request *req, void *out) { struct rk_ahash_ctx state; /* Don't let anything leak to 'out' */ memset(&state, 0, sizeof(state)); ///TODO: deal with import memcpy(out, &state, sizeof(state)); return 0; } static int rk_ahash_dma_start(struct rk_crypto_dev *rk_dev, uint32_t flag) { struct rk_hw_crypto_v2_info *hw_info = (struct rk_hw_crypto_v2_info *)rk_dev->hw_info; struct rk_alg_ctx *alg_ctx = rk_ahash_alg_ctx(rk_dev); struct rk_ahash_ctx *ctx = rk_ahash_ctx_cast(rk_dev); struct crypto_lli_desc *lli_head, *lli_tail; u32 dma_ctl = CRYPTO_DMA_RESTART; bool is_final = flag & RK_FLAG_FINAL; int ret; CRYPTO_TRACE("ctx->calc_cnt = %u, count %u Byte, is_final = %d", ctx->calc_cnt, alg_ctx->count, is_final); if (alg_ctx->count % rk_hash_reserve_block && !is_final) { dev_err(rk_dev->dev, "count = %u is not aligned with [%u]\n", alg_ctx->count, rk_hash_reserve_block); return -EINVAL; } if (alg_ctx->count == 0) { /* do nothing */ CRYPTO_TRACE("empty calc"); return 0; } if (alg_ctx->aligned) ret = rk_crypto_hw_desc_init(&hw_info->hw_desc, alg_ctx->sg_src, NULL, alg_ctx->count); else ret = rk_crypto_hw_desc_init(&hw_info->hw_desc, &alg_ctx->sg_tmp, NULL, alg_ctx->count); if (ret) return ret; lli_head = hw_info->hw_desc.lli_head; lli_tail = hw_info->hw_desc.lli_tail; lli_tail->dma_ctrl = is_final ? LLI_DMA_CTRL_LAST : LLI_DMA_CTRL_PAUSE; lli_tail->dma_ctrl |= LLI_DMA_CTRL_SRC_DONE; lli_tail->next_addr = hw_info->hw_desc.lli_head_dma; if (ctx->calc_cnt == 0) { dma_ctl = CRYPTO_DMA_START; lli_head->user_define |= LLI_USER_CIPHER_START; lli_head->user_define |= LLI_USER_STRING_START; CRYPTO_WRITE(rk_dev, CRYPTO_DMA_LLI_ADDR, hw_info->hw_desc.lli_head_dma); CRYPTO_WRITE(rk_dev, CRYPTO_HASH_CTL, (CRYPTO_HASH_ENABLE << CRYPTO_WRITE_MASK_SHIFT) | CRYPTO_HASH_ENABLE); } if (is_final && alg_ctx->left_bytes == 0) lli_tail->user_define |= LLI_USER_STRING_LAST; CRYPTO_TRACE("dma_ctrl = %08x, user_define = %08x, len = %u", lli_head->dma_ctrl, lli_head->user_define, alg_ctx->count); rk_crypto_dump_hw_desc(&hw_info->hw_desc); dma_wmb(); /* enable crypto irq */ CRYPTO_WRITE(rk_dev, CRYPTO_DMA_INT_EN, 0x7f); CRYPTO_WRITE(rk_dev, CRYPTO_DMA_CTL, dma_ctl | dma_ctl << CRYPTO_WRITE_MASK_SHIFT); return 0; } static int rk_ahash_get_result(struct rk_crypto_dev *rk_dev, uint8_t *data, uint32_t data_len) { int ret = 0; u32 reg_ctrl = 0; ret = read_poll_timeout_atomic(CRYPTO_READ, reg_ctrl, reg_ctrl & CRYPTO_HASH_IS_VALID, RK_POLL_PERIOD_US, RK_POLL_TIMEOUT_US, false, rk_dev, CRYPTO_HASH_VALID); if (ret) goto exit; rk_crypto_read_regs(rk_dev, CRYPTO_HASH_DOUT_0, data, data_len); CRYPTO_WRITE(rk_dev, CRYPTO_HASH_VALID, CRYPTO_HASH_IS_VALID); exit: clean_hash_setting(rk_dev); return ret; } static int rk_cra_hash_init(struct crypto_tfm *tfm) { struct rk_crypto_algt *algt = rk_ahash_get_algt(__crypto_ahash_cast(tfm)); const char *alg_name = crypto_tfm_alg_name(tfm); struct rk_ahash_ctx *ctx = crypto_tfm_ctx(tfm); struct rk_crypto_dev *rk_dev = algt->rk_dev; struct rk_alg_ctx *alg_ctx = &ctx->algs_ctx; CRYPTO_TRACE(); rk_hash_reserve_block = RK_HASH_RESERVE_BLOCK; memset(ctx, 0x00, sizeof(*ctx)); if (!rk_dev->request_crypto) return -EFAULT; alg_ctx->align_size = 64; alg_ctx->ops.start = rk_ahash_start; alg_ctx->ops.update = rk_ahash_crypto_rx; alg_ctx->ops.complete = rk_ahash_crypto_complete; alg_ctx->ops.irq_handle = rk_crypto_irq_handle; alg_ctx->ops.hw_write_key = write_key_reg; alg_ctx->ops.hw_init = rk_hw_hash_init; alg_ctx->ops.hw_dma_start = rk_ahash_dma_start; alg_ctx->ops.hw_get_result = rk_ahash_get_result; ctx->rk_dev = rk_dev; ctx->hash_tmp = (u8 *)get_zeroed_page(GFP_KERNEL | GFP_DMA32); if (!ctx->hash_tmp) { dev_err(rk_dev->dev, "Can't get zeroed page for hash tmp.\n"); return -ENOMEM; } rk_dev->request_crypto(rk_dev, alg_name); crypto_ahash_set_reqsize(__crypto_ahash_cast(tfm), sizeof(struct rk_ahash_rctx)); algt->alg.hash.halg.statesize = sizeof(struct rk_ahash_ctx); return 0; } static void rk_cra_hash_exit(struct crypto_tfm *tfm) { struct rk_ahash_ctx *ctx = crypto_tfm_ctx(tfm); CRYPTO_TRACE(); if (ctx->hash_tmp) free_page((unsigned long)ctx->hash_tmp); ctx->rk_dev->release_crypto(ctx->rk_dev, crypto_tfm_alg_name(tfm)); } struct rk_crypto_algt rk_v2_ahash_md5 = RK_HASH_ALGO_INIT(MD5, md5); struct rk_crypto_algt rk_v2_ahash_sha1 = RK_HASH_ALGO_INIT(SHA1, sha1); struct rk_crypto_algt rk_v2_ahash_sha224 = RK_HASH_ALGO_INIT(SHA224, sha224); struct rk_crypto_algt rk_v2_ahash_sha256 = RK_HASH_ALGO_INIT(SHA256, sha256); struct rk_crypto_algt rk_v2_ahash_sha384 = RK_HASH_ALGO_INIT(SHA384, sha384); struct rk_crypto_algt rk_v2_ahash_sha512 = RK_HASH_ALGO_INIT(SHA512, sha512); struct rk_crypto_algt rk_v2_ahash_sm3 = RK_HASH_ALGO_INIT(SM3, sm3); struct rk_crypto_algt rk_v2_hmac_md5 = RK_HMAC_ALGO_INIT(MD5, md5); struct rk_crypto_algt rk_v2_hmac_sha1 = RK_HMAC_ALGO_INIT(SHA1, sha1); struct rk_crypto_algt rk_v2_hmac_sha256 = RK_HMAC_ALGO_INIT(SHA256, sha256); struct rk_crypto_algt rk_v2_hmac_sha512 = RK_HMAC_ALGO_INIT(SHA512, sha512); struct rk_crypto_algt rk_v2_hmac_sm3 = RK_HMAC_ALGO_INIT(SM3, sm3);