/* * AMD Cryptographic Coprocessor (CCP) driver * * Copyright (C) 2013 Advanced Micro Devices, Inc. * * Author: Tom Lendacky <thomas.lendacky@amd.com> * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 as * published by the Free Software Foundation. */ #include <linux/module.h> #include <linux/kernel.h> #include <linux/pci.h> #include <linux/pci_ids.h> #include <linux/kthread.h> #include <linux/sched.h> #include <linux/interrupt.h> #include <linux/spinlock.h> #include <linux/mutex.h> #include <linux/delay.h> #include <linux/ccp.h> #include <linux/scatterlist.h> #include <crypto/scatterwalk.h> #include <crypto/sha.h> #include "ccp-dev.h" enum ccp_memtype { CCP_MEMTYPE_SYSTEM = 0, CCP_MEMTYPE_KSB, CCP_MEMTYPE_LOCAL, CCP_MEMTYPE__LAST, }; struct ccp_dma_info { dma_addr_t address; unsigned int offset; unsigned int length; enum dma_data_direction dir; }; struct ccp_dm_workarea { struct device *dev; struct dma_pool *dma_pool; unsigned int length; u8 *address; struct ccp_dma_info dma; }; struct ccp_sg_workarea { struct scatterlist *sg; unsigned int nents; unsigned int length; struct scatterlist *dma_sg; struct device *dma_dev; unsigned int dma_count; enum dma_data_direction dma_dir; unsigned int sg_used; u64 bytes_left; }; struct ccp_data { struct ccp_sg_workarea sg_wa; struct ccp_dm_workarea dm_wa; }; struct ccp_mem { enum ccp_memtype type; union { struct ccp_dma_info dma; u32 ksb; } u; }; struct ccp_aes_op { enum ccp_aes_type type; enum ccp_aes_mode mode; enum ccp_aes_action action; }; struct ccp_xts_aes_op { enum ccp_aes_action action; enum ccp_xts_aes_unit_size unit_size; }; struct ccp_sha_op { enum ccp_sha_type type; u64 msg_bits; }; struct ccp_rsa_op { u32 mod_size; u32 input_len; }; struct ccp_passthru_op { enum ccp_passthru_bitwise bit_mod; enum ccp_passthru_byteswap byte_swap; }; struct ccp_ecc_op { enum ccp_ecc_function function; }; struct ccp_op { struct ccp_cmd_queue *cmd_q; u32 jobid; u32 ioc; u32 soc; u32 ksb_key; u32 ksb_ctx; u32 init; u32 eom; struct ccp_mem src; struct ccp_mem dst; union { struct ccp_aes_op aes; struct ccp_xts_aes_op xts; struct ccp_sha_op sha; struct ccp_rsa_op rsa; struct ccp_passthru_op passthru; struct ccp_ecc_op ecc; } u; }; /* SHA initial context values */ static const __be32 ccp_sha1_init[CCP_SHA_CTXSIZE / sizeof(__be32)] = { cpu_to_be32(SHA1_H0), cpu_to_be32(SHA1_H1), cpu_to_be32(SHA1_H2), cpu_to_be32(SHA1_H3), cpu_to_be32(SHA1_H4), 0, 0, 0, }; static const __be32 ccp_sha224_init[CCP_SHA_CTXSIZE / sizeof(__be32)] = { cpu_to_be32(SHA224_H0), cpu_to_be32(SHA224_H1), cpu_to_be32(SHA224_H2), cpu_to_be32(SHA224_H3), cpu_to_be32(SHA224_H4), cpu_to_be32(SHA224_H5), cpu_to_be32(SHA224_H6), cpu_to_be32(SHA224_H7), }; static const __be32 ccp_sha256_init[CCP_SHA_CTXSIZE / sizeof(__be32)] = { cpu_to_be32(SHA256_H0), cpu_to_be32(SHA256_H1), cpu_to_be32(SHA256_H2), cpu_to_be32(SHA256_H3), cpu_to_be32(SHA256_H4), cpu_to_be32(SHA256_H5), cpu_to_be32(SHA256_H6), cpu_to_be32(SHA256_H7), }; /* The CCP cannot perform zero-length sha operations so the caller * is required to buffer data for the final operation. However, a * sha operation for a message with a total length of zero is valid * so known values are required to supply the result. */ static const u8 ccp_sha1_zero[CCP_SHA_CTXSIZE] = { 0xda, 0x39, 0xa3, 0xee, 0x5e, 0x6b, 0x4b, 0x0d, 0x32, 0x55, 0xbf, 0xef, 0x95, 0x60, 0x18, 0x90, 0xaf, 0xd8, 0x07, 0x09, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, }; static const u8 ccp_sha224_zero[CCP_SHA_CTXSIZE] = { 0xd1, 0x4a, 0x02, 0x8c, 0x2a, 0x3a, 0x2b, 0xc9, 0x47, 0x61, 0x02, 0xbb, 0x28, 0x82, 0x34, 0xc4, 0x15, 0xa2, 0xb0, 0x1f, 0x82, 0x8e, 0xa6, 0x2a, 0xc5, 0xb3, 0xe4, 0x2f, 0x00, 0x00, 0x00, 0x00, }; static const u8 ccp_sha256_zero[CCP_SHA_CTXSIZE] = { 0xe3, 0xb0, 0xc4, 0x42, 0x98, 0xfc, 0x1c, 0x14, 0x9a, 0xfb, 0xf4, 0xc8, 0x99, 0x6f, 0xb9, 0x24, 0x27, 0xae, 0x41, 0xe4, 0x64, 0x9b, 0x93, 0x4c, 0xa4, 0x95, 0x99, 0x1b, 0x78, 0x52, 0xb8, 0x55, }; static u32 ccp_addr_lo(struct ccp_dma_info *info) { return lower_32_bits(info->address + info->offset); } static u32 ccp_addr_hi(struct ccp_dma_info *info) { return upper_32_bits(info->address + info->offset) & 0x0000ffff; } static int ccp_do_cmd(struct ccp_op *op, u32 *cr, unsigned int cr_count) { struct ccp_cmd_queue *cmd_q = op->cmd_q; struct ccp_device *ccp = cmd_q->ccp; void __iomem *cr_addr; u32 cr0, cmd; unsigned int i; int ret = 0; /* We could read a status register to see how many free slots * are actually available, but reading that register resets it * and you could lose some error information. */ cmd_q->free_slots--; cr0 = (cmd_q->id << REQ0_CMD_Q_SHIFT) | (op->jobid << REQ0_JOBID_SHIFT) | REQ0_WAIT_FOR_WRITE; if (op->soc) cr0 |= REQ0_STOP_ON_COMPLETE | REQ0_INT_ON_COMPLETE; if (op->ioc || !cmd_q->free_slots) cr0 |= REQ0_INT_ON_COMPLETE; /* Start at CMD_REQ1 */ cr_addr = ccp->io_regs + CMD_REQ0 + CMD_REQ_INCR; mutex_lock(&ccp->req_mutex); /* Write CMD_REQ1 through CMD_REQx first */ for (i = 0; i < cr_count; i++, cr_addr += CMD_REQ_INCR) iowrite32(*(cr + i), cr_addr); /* Tell the CCP to start */ wmb(); iowrite32(cr0, ccp->io_regs + CMD_REQ0); mutex_unlock(&ccp->req_mutex); if (cr0 & REQ0_INT_ON_COMPLETE) { /* Wait for the job to complete */ ret = wait_event_interruptible(cmd_q->int_queue, cmd_q->int_rcvd); if (ret || cmd_q->cmd_error) { /* On error delete all related jobs from the queue */ cmd = (cmd_q->id << DEL_Q_ID_SHIFT) | op->jobid; iowrite32(cmd, ccp->io_regs + DEL_CMD_Q_JOB); if (!ret) ret = -EIO; } else if (op->soc) { /* Delete just head job from the queue on SoC */ cmd = DEL_Q_ACTIVE | (cmd_q->id << DEL_Q_ID_SHIFT) | op->jobid; iowrite32(cmd, ccp->io_regs + DEL_CMD_Q_JOB); } cmd_q->free_slots = CMD_Q_DEPTH(cmd_q->q_status); cmd_q->int_rcvd = 0; } return ret; } static int ccp_perform_aes(struct ccp_op *op) { u32 cr[6]; /* Fill out the register contents for REQ1 through REQ6 */ cr[0] = (CCP_ENGINE_AES << REQ1_ENGINE_SHIFT) | (op->u.aes.type << REQ1_AES_TYPE_SHIFT) | (op->u.aes.mode << REQ1_AES_MODE_SHIFT) | (op->u.aes.action << REQ1_AES_ACTION_SHIFT) | (op->ksb_key << REQ1_KEY_KSB_SHIFT); cr[1] = op->src.u.dma.length - 1; cr[2] = ccp_addr_lo(&op->src.u.dma); cr[3] = (op->ksb_ctx << REQ4_KSB_SHIFT) | (CCP_MEMTYPE_SYSTEM << REQ4_MEMTYPE_SHIFT) | ccp_addr_hi(&op->src.u.dma); cr[4] = ccp_addr_lo(&op->dst.u.dma); cr[5] = (CCP_MEMTYPE_SYSTEM << REQ6_MEMTYPE_SHIFT) | ccp_addr_hi(&op->dst.u.dma); if (op->u.aes.mode == CCP_AES_MODE_CFB) cr[0] |= ((0x7f) << REQ1_AES_CFB_SIZE_SHIFT); if (op->eom) cr[0] |= REQ1_EOM; if (op->init) cr[0] |= REQ1_INIT; return ccp_do_cmd(op, cr, ARRAY_SIZE(cr)); } static int ccp_perform_xts_aes(struct ccp_op *op) { u32 cr[6]; /* Fill out the register contents for REQ1 through REQ6 */ cr[0] = (CCP_ENGINE_XTS_AES_128 << REQ1_ENGINE_SHIFT) | (op->u.xts.action << REQ1_AES_ACTION_SHIFT) | (op->u.xts.unit_size << REQ1_XTS_AES_SIZE_SHIFT) | (op->ksb_key << REQ1_KEY_KSB_SHIFT); cr[1] = op->src.u.dma.length - 1; cr[2] = ccp_addr_lo(&op->src.u.dma); cr[3] = (op->ksb_ctx << REQ4_KSB_SHIFT) | (CCP_MEMTYPE_SYSTEM << REQ4_MEMTYPE_SHIFT) | ccp_addr_hi(&op->src.u.dma); cr[4] = ccp_addr_lo(&op->dst.u.dma); cr[5] = (CCP_MEMTYPE_SYSTEM << REQ6_MEMTYPE_SHIFT) | ccp_addr_hi(&op->dst.u.dma); if (op->eom) cr[0] |= REQ1_EOM; if (op->init) cr[0] |= REQ1_INIT; return ccp_do_cmd(op, cr, ARRAY_SIZE(cr)); } static int ccp_perform_sha(struct ccp_op *op) { u32 cr[6]; /* Fill out the register contents for REQ1 through REQ6 */ cr[0] = (CCP_ENGINE_SHA << REQ1_ENGINE_SHIFT) | (op->u.sha.type << REQ1_SHA_TYPE_SHIFT) | REQ1_INIT; cr[1] = op->src.u.dma.length - 1; cr[2] = ccp_addr_lo(&op->src.u.dma); cr[3] = (op->ksb_ctx << REQ4_KSB_SHIFT) | (CCP_MEMTYPE_SYSTEM << REQ4_MEMTYPE_SHIFT) | ccp_addr_hi(&op->src.u.dma); if (op->eom) { cr[0] |= REQ1_EOM; cr[4] = lower_32_bits(op->u.sha.msg_bits); cr[5] = upper_32_bits(op->u.sha.msg_bits); } else { cr[4] = 0; cr[5] = 0; } return ccp_do_cmd(op, cr, ARRAY_SIZE(cr)); } static int ccp_perform_rsa(struct ccp_op *op) { u32 cr[6]; /* Fill out the register contents for REQ1 through REQ6 */ cr[0] = (CCP_ENGINE_RSA << REQ1_ENGINE_SHIFT) | (op->u.rsa.mod_size << REQ1_RSA_MOD_SIZE_SHIFT) | (op->ksb_key << REQ1_KEY_KSB_SHIFT) | REQ1_EOM; cr[1] = op->u.rsa.input_len - 1; cr[2] = ccp_addr_lo(&op->src.u.dma); cr[3] = (op->ksb_ctx << REQ4_KSB_SHIFT) | (CCP_MEMTYPE_SYSTEM << REQ4_MEMTYPE_SHIFT) | ccp_addr_hi(&op->src.u.dma); cr[4] = ccp_addr_lo(&op->dst.u.dma); cr[5] = (CCP_MEMTYPE_SYSTEM << REQ6_MEMTYPE_SHIFT) | ccp_addr_hi(&op->dst.u.dma); return ccp_do_cmd(op, cr, ARRAY_SIZE(cr)); } static int ccp_perform_passthru(struct ccp_op *op) { u32 cr[6]; /* Fill out the register contents for REQ1 through REQ6 */ cr[0] = (CCP_ENGINE_PASSTHRU << REQ1_ENGINE_SHIFT) | (op->u.passthru.bit_mod << REQ1_PT_BW_SHIFT) | (op->u.passthru.byte_swap << REQ1_PT_BS_SHIFT); if (op->src.type == CCP_MEMTYPE_SYSTEM) cr[1] = op->src.u.dma.length - 1; else cr[1] = op->dst.u.dma.length - 1; if (op->src.type == CCP_MEMTYPE_SYSTEM) { cr[2] = ccp_addr_lo(&op->src.u.dma); cr[3] = (CCP_MEMTYPE_SYSTEM << REQ4_MEMTYPE_SHIFT) | ccp_addr_hi(&op->src.u.dma); if (op->u.passthru.bit_mod != CCP_PASSTHRU_BITWISE_NOOP) cr[3] |= (op->ksb_key << REQ4_KSB_SHIFT); } else { cr[2] = op->src.u.ksb * CCP_KSB_BYTES; cr[3] = (CCP_MEMTYPE_KSB << REQ4_MEMTYPE_SHIFT); } if (op->dst.type == CCP_MEMTYPE_SYSTEM) { cr[4] = ccp_addr_lo(&op->dst.u.dma); cr[5] = (CCP_MEMTYPE_SYSTEM << REQ6_MEMTYPE_SHIFT) | ccp_addr_hi(&op->dst.u.dma); } else { cr[4] = op->dst.u.ksb * CCP_KSB_BYTES; cr[5] = (CCP_MEMTYPE_KSB << REQ6_MEMTYPE_SHIFT); } if (op->eom) cr[0] |= REQ1_EOM; return ccp_do_cmd(op, cr, ARRAY_SIZE(cr)); } static int ccp_perform_ecc(struct ccp_op *op) { u32 cr[6]; /* Fill out the register contents for REQ1 through REQ6 */ cr[0] = REQ1_ECC_AFFINE_CONVERT | (CCP_ENGINE_ECC << REQ1_ENGINE_SHIFT) | (op->u.ecc.function << REQ1_ECC_FUNCTION_SHIFT) | REQ1_EOM; cr[1] = op->src.u.dma.length - 1; cr[2] = ccp_addr_lo(&op->src.u.dma); cr[3] = (CCP_MEMTYPE_SYSTEM << REQ4_MEMTYPE_SHIFT) | ccp_addr_hi(&op->src.u.dma); cr[4] = ccp_addr_lo(&op->dst.u.dma); cr[5] = (CCP_MEMTYPE_SYSTEM << REQ6_MEMTYPE_SHIFT) | ccp_addr_hi(&op->dst.u.dma); return ccp_do_cmd(op, cr, ARRAY_SIZE(cr)); } static u32 ccp_alloc_ksb(struct ccp_device *ccp, unsigned int count) { int start; for (;;) { mutex_lock(&ccp->ksb_mutex); start = (u32)bitmap_find_next_zero_area(ccp->ksb, ccp->ksb_count, ccp->ksb_start, count, 0); if (start <= ccp->ksb_count) { bitmap_set(ccp->ksb, start, count); mutex_unlock(&ccp->ksb_mutex); break; } ccp->ksb_avail = 0; mutex_unlock(&ccp->ksb_mutex); /* Wait for KSB entries to become available */ if (wait_event_interruptible(ccp->ksb_queue, ccp->ksb_avail)) return 0; } return KSB_START + start; } static void ccp_free_ksb(struct ccp_device *ccp, unsigned int start, unsigned int count) { if (!start) return; mutex_lock(&ccp->ksb_mutex); bitmap_clear(ccp->ksb, start - KSB_START, count); ccp->ksb_avail = 1; mutex_unlock(&ccp->ksb_mutex); wake_up_interruptible_all(&ccp->ksb_queue); } static u32 ccp_gen_jobid(struct ccp_device *ccp) { return atomic_inc_return(&ccp->current_id) & CCP_JOBID_MASK; } static void ccp_sg_free(struct ccp_sg_workarea *wa) { if (wa->dma_count) dma_unmap_sg(wa->dma_dev, wa->dma_sg, wa->nents, wa->dma_dir); wa->dma_count = 0; } static int ccp_init_sg_workarea(struct ccp_sg_workarea *wa, struct device *dev, struct scatterlist *sg, u64 len, enum dma_data_direction dma_dir) { memset(wa, 0, sizeof(*wa)); wa->sg = sg; if (!sg) return 0; wa->nents = sg_nents(sg); wa->length = sg->length; wa->bytes_left = len; wa->sg_used = 0; if (len == 0) return 0; if (dma_dir == DMA_NONE) return 0; wa->dma_sg = sg; wa->dma_dev = dev; wa->dma_dir = dma_dir; wa->dma_count = dma_map_sg(dev, sg, wa->nents, dma_dir); if (!wa->dma_count) return -ENOMEM; return 0; } static void ccp_update_sg_workarea(struct ccp_sg_workarea *wa, unsigned int len) { unsigned int nbytes = min_t(u64, len, wa->bytes_left); if (!wa->sg) return; wa->sg_used += nbytes; wa->bytes_left -= nbytes; if (wa->sg_used == wa->sg->length) { wa->sg = sg_next(wa->sg); wa->sg_used = 0; } } static void ccp_dm_free(struct ccp_dm_workarea *wa) { if (wa->length <= CCP_DMAPOOL_MAX_SIZE) { if (wa->address) dma_pool_free(wa->dma_pool, wa->address, wa->dma.address); } else { if (wa->dma.address) dma_unmap_single(wa->dev, wa->dma.address, wa->length, wa->dma.dir); kfree(wa->address); } wa->address = NULL; wa->dma.address = 0; } static int ccp_init_dm_workarea(struct ccp_dm_workarea *wa, struct ccp_cmd_queue *cmd_q, unsigned int len, enum dma_data_direction dir) { memset(wa, 0, sizeof(*wa)); if (!len) return 0; wa->dev = cmd_q->ccp->dev; wa->length = len; if (len <= CCP_DMAPOOL_MAX_SIZE) { wa->dma_pool = cmd_q->dma_pool; wa->address = dma_pool_alloc(wa->dma_pool, GFP_KERNEL, &wa->dma.address); if (!wa->address) return -ENOMEM; wa->dma.length = CCP_DMAPOOL_MAX_SIZE; memset(wa->address, 0, CCP_DMAPOOL_MAX_SIZE); } else { wa->address = kzalloc(len, GFP_KERNEL); if (!wa->address) return -ENOMEM; wa->dma.address = dma_map_single(wa->dev, wa->address, len, dir); if (!wa->dma.address) return -ENOMEM; wa->dma.length = len; } wa->dma.dir = dir; return 0; } static void ccp_set_dm_area(struct ccp_dm_workarea *wa, unsigned int wa_offset, struct scatterlist *sg, unsigned int sg_offset, unsigned int len) { WARN_ON(!wa->address); scatterwalk_map_and_copy(wa->address + wa_offset, sg, sg_offset, len, 0); } static void ccp_get_dm_area(struct ccp_dm_workarea *wa, unsigned int wa_offset, struct scatterlist *sg, unsigned int sg_offset, unsigned int len) { WARN_ON(!wa->address); scatterwalk_map_and_copy(wa->address + wa_offset, sg, sg_offset, len, 1); } static void ccp_reverse_set_dm_area(struct ccp_dm_workarea *wa, struct scatterlist *sg, unsigned int len, unsigned int se_len, bool sign_extend) { unsigned int nbytes, sg_offset, dm_offset, ksb_len, i; u8 buffer[CCP_REVERSE_BUF_SIZE]; BUG_ON(se_len > sizeof(buffer)); sg_offset = len; dm_offset = 0; nbytes = len; while (nbytes) { ksb_len = min_t(unsigned int, nbytes, se_len); sg_offset -= ksb_len; scatterwalk_map_and_copy(buffer, sg, sg_offset, ksb_len, 0); for (i = 0; i < ksb_len; i++) wa->address[dm_offset + i] = buffer[ksb_len - i - 1]; dm_offset += ksb_len; nbytes -= ksb_len; if ((ksb_len != se_len) && sign_extend) { /* Must sign-extend to nearest sign-extend length */ if (wa->address[dm_offset - 1] & 0x80) memset(wa->address + dm_offset, 0xff, se_len - ksb_len); } } } static void ccp_reverse_get_dm_area(struct ccp_dm_workarea *wa, struct scatterlist *sg, unsigned int len) { unsigned int nbytes, sg_offset, dm_offset, ksb_len, i; u8 buffer[CCP_REVERSE_BUF_SIZE]; sg_offset = 0; dm_offset = len; nbytes = len; while (nbytes) { ksb_len = min_t(unsigned int, nbytes, sizeof(buffer)); dm_offset -= ksb_len; for (i = 0; i < ksb_len; i++) buffer[ksb_len - i - 1] = wa->address[dm_offset + i]; scatterwalk_map_and_copy(buffer, sg, sg_offset, ksb_len, 1); sg_offset += ksb_len; nbytes -= ksb_len; } } static void ccp_free_data(struct ccp_data *data, struct ccp_cmd_queue *cmd_q) { ccp_dm_free(&data->dm_wa); ccp_sg_free(&data->sg_wa); } static int ccp_init_data(struct ccp_data *data, struct ccp_cmd_queue *cmd_q, struct scatterlist *sg, u64 sg_len, unsigned int dm_len, enum dma_data_direction dir) { int ret; memset(data, 0, sizeof(*data)); ret = ccp_init_sg_workarea(&data->sg_wa, cmd_q->ccp->dev, sg, sg_len, dir); if (ret) goto e_err; ret = ccp_init_dm_workarea(&data->dm_wa, cmd_q, dm_len, dir); if (ret) goto e_err; return 0; e_err: ccp_free_data(data, cmd_q); return ret; } static unsigned int ccp_queue_buf(struct ccp_data *data, unsigned int from) { struct ccp_sg_workarea *sg_wa = &data->sg_wa; struct ccp_dm_workarea *dm_wa = &data->dm_wa; unsigned int buf_count, nbytes; /* Clear the buffer if setting it */ if (!from) memset(dm_wa->address, 0, dm_wa->length); if (!sg_wa->sg) return 0; /* Perform the copy operation * nbytes will always be <= UINT_MAX because dm_wa->length is * an unsigned int */ nbytes = min_t(u64, sg_wa->bytes_left, dm_wa->length); scatterwalk_map_and_copy(dm_wa->address, sg_wa->sg, sg_wa->sg_used, nbytes, from); /* Update the structures and generate the count */ buf_count = 0; while (sg_wa->bytes_left && (buf_count < dm_wa->length)) { nbytes = min(sg_wa->sg->length - sg_wa->sg_used, dm_wa->length - buf_count); nbytes = min_t(u64, sg_wa->bytes_left, nbytes); buf_count += nbytes; ccp_update_sg_workarea(sg_wa, nbytes); } return buf_count; } static unsigned int ccp_fill_queue_buf(struct ccp_data *data) { return ccp_queue_buf(data, 0); } static unsigned int ccp_empty_queue_buf(struct ccp_data *data) { return ccp_queue_buf(data, 1); } static void ccp_prepare_data(struct ccp_data *src, struct ccp_data *dst, struct ccp_op *op, unsigned int block_size, bool blocksize_op) { unsigned int sg_src_len, sg_dst_len, op_len; /* The CCP can only DMA from/to one address each per operation. This * requires that we find the smallest DMA area between the source * and destination. The resulting len values will always be <= UINT_MAX * because the dma length is an unsigned int. */ sg_src_len = sg_dma_len(src->sg_wa.sg) - src->sg_wa.sg_used; sg_src_len = min_t(u64, src->sg_wa.bytes_left, sg_src_len); if (dst) { sg_dst_len = sg_dma_len(dst->sg_wa.sg) - dst->sg_wa.sg_used; sg_dst_len = min_t(u64, src->sg_wa.bytes_left, sg_dst_len); op_len = min(sg_src_len, sg_dst_len); } else { op_len = sg_src_len; } /* The data operation length will be at least block_size in length * or the smaller of available sg room remaining for the source or * the destination */ op_len = max(op_len, block_size); /* Unless we have to buffer data, there's no reason to wait */ op->soc = 0; if (sg_src_len < block_size) { /* Not enough data in the sg element, so it * needs to be buffered into a blocksize chunk */ int cp_len = ccp_fill_queue_buf(src); op->soc = 1; op->src.u.dma.address = src->dm_wa.dma.address; op->src.u.dma.offset = 0; op->src.u.dma.length = (blocksize_op) ? block_size : cp_len; } else { /* Enough data in the sg element, but we need to * adjust for any previously copied data */ op->src.u.dma.address = sg_dma_address(src->sg_wa.sg); op->src.u.dma.offset = src->sg_wa.sg_used; op->src.u.dma.length = op_len & ~(block_size - 1); ccp_update_sg_workarea(&src->sg_wa, op->src.u.dma.length); } if (dst) { if (sg_dst_len < block_size) { /* Not enough room in the sg element or we're on the * last piece of data (when using padding), so the * output needs to be buffered into a blocksize chunk */ op->soc = 1; op->dst.u.dma.address = dst->dm_wa.dma.address; op->dst.u.dma.offset = 0; op->dst.u.dma.length = op->src.u.dma.length; } else { /* Enough room in the sg element, but we need to * adjust for any previously used area */ op->dst.u.dma.address = sg_dma_address(dst->sg_wa.sg); op->dst.u.dma.offset = dst->sg_wa.sg_used; op->dst.u.dma.length = op->src.u.dma.length; } } } static void ccp_process_data(struct ccp_data *src, struct ccp_data *dst, struct ccp_op *op) { op->init = 0; if (dst) { if (op->dst.u.dma.address == dst->dm_wa.dma.address) ccp_empty_queue_buf(dst); else ccp_update_sg_workarea(&dst->sg_wa, op->dst.u.dma.length); } } static int ccp_copy_to_from_ksb(struct ccp_cmd_queue *cmd_q, struct ccp_dm_workarea *wa, u32 jobid, u32 ksb, u32 byte_swap, bool from) { struct ccp_op op; memset(&op, 0, sizeof(op)); op.cmd_q = cmd_q; op.jobid = jobid; op.eom = 1; if (from) { op.soc = 1; op.src.type = CCP_MEMTYPE_KSB; op.src.u.ksb = ksb; op.dst.type = CCP_MEMTYPE_SYSTEM; op.dst.u.dma.address = wa->dma.address; op.dst.u.dma.length = wa->length; } else { op.src.type = CCP_MEMTYPE_SYSTEM; op.src.u.dma.address = wa->dma.address; op.src.u.dma.length = wa->length; op.dst.type = CCP_MEMTYPE_KSB; op.dst.u.ksb = ksb; } op.u.passthru.byte_swap = byte_swap; return ccp_perform_passthru(&op); } static int ccp_copy_to_ksb(struct ccp_cmd_queue *cmd_q, struct ccp_dm_workarea *wa, u32 jobid, u32 ksb, u32 byte_swap) { return ccp_copy_to_from_ksb(cmd_q, wa, jobid, ksb, byte_swap, false); } static int ccp_copy_from_ksb(struct ccp_cmd_queue *cmd_q, struct ccp_dm_workarea *wa, u32 jobid, u32 ksb, u32 byte_swap) { return ccp_copy_to_from_ksb(cmd_q, wa, jobid, ksb, byte_swap, true); } static int ccp_run_aes_cmac_cmd(struct ccp_cmd_queue *cmd_q, struct ccp_cmd *cmd) { struct ccp_aes_engine *aes = &cmd->u.aes; struct ccp_dm_workarea key, ctx; struct ccp_data src; struct ccp_op op; unsigned int dm_offset; int ret; if (!((aes->key_len == AES_KEYSIZE_128) || (aes->key_len == AES_KEYSIZE_192) || (aes->key_len == AES_KEYSIZE_256))) return -EINVAL; if (aes->src_len & (AES_BLOCK_SIZE - 1)) return -EINVAL; if (aes->iv_len != AES_BLOCK_SIZE) return -EINVAL; if (!aes->key || !aes->iv || !aes->src) return -EINVAL; if (aes->cmac_final) { if (aes->cmac_key_len != AES_BLOCK_SIZE) return -EINVAL; if (!aes->cmac_key) return -EINVAL; } BUILD_BUG_ON(CCP_AES_KEY_KSB_COUNT != 1); BUILD_BUG_ON(CCP_AES_CTX_KSB_COUNT != 1); ret = -EIO; memset(&op, 0, sizeof(op)); op.cmd_q = cmd_q; op.jobid = ccp_gen_jobid(cmd_q->ccp); op.ksb_key = cmd_q->ksb_key; op.ksb_ctx = cmd_q->ksb_ctx; op.init = 1; op.u.aes.type = aes->type; op.u.aes.mode = aes->mode; op.u.aes.action = aes->action; /* All supported key sizes fit in a single (32-byte) KSB entry * and must be in little endian format. Use the 256-bit byte * swap passthru option to convert from big endian to little * endian. */ ret = ccp_init_dm_workarea(&key, cmd_q, CCP_AES_KEY_KSB_COUNT * CCP_KSB_BYTES, DMA_TO_DEVICE); if (ret) return ret; dm_offset = CCP_KSB_BYTES - aes->key_len; ccp_set_dm_area(&key, dm_offset, aes->key, 0, aes->key_len); ret = ccp_copy_to_ksb(cmd_q, &key, op.jobid, op.ksb_key, CCP_PASSTHRU_BYTESWAP_256BIT); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_key; } /* The AES context fits in a single (32-byte) KSB entry and * must be in little endian format. Use the 256-bit byte swap * passthru option to convert from big endian to little endian. */ ret = ccp_init_dm_workarea(&ctx, cmd_q, CCP_AES_CTX_KSB_COUNT * CCP_KSB_BYTES, DMA_BIDIRECTIONAL); if (ret) goto e_key; dm_offset = CCP_KSB_BYTES - AES_BLOCK_SIZE; ccp_set_dm_area(&ctx, dm_offset, aes->iv, 0, aes->iv_len); ret = ccp_copy_to_ksb(cmd_q, &ctx, op.jobid, op.ksb_ctx, CCP_PASSTHRU_BYTESWAP_256BIT); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_ctx; } /* Send data to the CCP AES engine */ ret = ccp_init_data(&src, cmd_q, aes->src, aes->src_len, AES_BLOCK_SIZE, DMA_TO_DEVICE); if (ret) goto e_ctx; while (src.sg_wa.bytes_left) { ccp_prepare_data(&src, NULL, &op, AES_BLOCK_SIZE, true); if (aes->cmac_final && !src.sg_wa.bytes_left) { op.eom = 1; /* Push the K1/K2 key to the CCP now */ ret = ccp_copy_from_ksb(cmd_q, &ctx, op.jobid, op.ksb_ctx, CCP_PASSTHRU_BYTESWAP_256BIT); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_src; } ccp_set_dm_area(&ctx, 0, aes->cmac_key, 0, aes->cmac_key_len); ret = ccp_copy_to_ksb(cmd_q, &ctx, op.jobid, op.ksb_ctx, CCP_PASSTHRU_BYTESWAP_256BIT); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_src; } } ret = ccp_perform_aes(&op); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_src; } ccp_process_data(&src, NULL, &op); } /* Retrieve the AES context - convert from LE to BE using * 32-byte (256-bit) byteswapping */ ret = ccp_copy_from_ksb(cmd_q, &ctx, op.jobid, op.ksb_ctx, CCP_PASSTHRU_BYTESWAP_256BIT); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_src; } /* ...but we only need AES_BLOCK_SIZE bytes */ dm_offset = CCP_KSB_BYTES - AES_BLOCK_SIZE; ccp_get_dm_area(&ctx, dm_offset, aes->iv, 0, aes->iv_len); e_src: ccp_free_data(&src, cmd_q); e_ctx: ccp_dm_free(&ctx); e_key: ccp_dm_free(&key); return ret; } static int ccp_run_aes_cmd(struct ccp_cmd_queue *cmd_q, struct ccp_cmd *cmd) { struct ccp_aes_engine *aes = &cmd->u.aes; struct ccp_dm_workarea key, ctx; struct ccp_data src, dst; struct ccp_op op; unsigned int dm_offset; bool in_place = false; int ret; if (aes->mode == CCP_AES_MODE_CMAC) return ccp_run_aes_cmac_cmd(cmd_q, cmd); if (!((aes->key_len == AES_KEYSIZE_128) || (aes->key_len == AES_KEYSIZE_192) || (aes->key_len == AES_KEYSIZE_256))) return -EINVAL; if (((aes->mode == CCP_AES_MODE_ECB) || (aes->mode == CCP_AES_MODE_CBC) || (aes->mode == CCP_AES_MODE_CFB)) && (aes->src_len & (AES_BLOCK_SIZE - 1))) return -EINVAL; if (!aes->key || !aes->src || !aes->dst) return -EINVAL; if (aes->mode != CCP_AES_MODE_ECB) { if (aes->iv_len != AES_BLOCK_SIZE) return -EINVAL; if (!aes->iv) return -EINVAL; } BUILD_BUG_ON(CCP_AES_KEY_KSB_COUNT != 1); BUILD_BUG_ON(CCP_AES_CTX_KSB_COUNT != 1); ret = -EIO; memset(&op, 0, sizeof(op)); op.cmd_q = cmd_q; op.jobid = ccp_gen_jobid(cmd_q->ccp); op.ksb_key = cmd_q->ksb_key; op.ksb_ctx = cmd_q->ksb_ctx; op.init = (aes->mode == CCP_AES_MODE_ECB) ? 0 : 1; op.u.aes.type = aes->type; op.u.aes.mode = aes->mode; op.u.aes.action = aes->action; /* All supported key sizes fit in a single (32-byte) KSB entry * and must be in little endian format. Use the 256-bit byte * swap passthru option to convert from big endian to little * endian. */ ret = ccp_init_dm_workarea(&key, cmd_q, CCP_AES_KEY_KSB_COUNT * CCP_KSB_BYTES, DMA_TO_DEVICE); if (ret) return ret; dm_offset = CCP_KSB_BYTES - aes->key_len; ccp_set_dm_area(&key, dm_offset, aes->key, 0, aes->key_len); ret = ccp_copy_to_ksb(cmd_q, &key, op.jobid, op.ksb_key, CCP_PASSTHRU_BYTESWAP_256BIT); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_key; } /* The AES context fits in a single (32-byte) KSB entry and * must be in little endian format. Use the 256-bit byte swap * passthru option to convert from big endian to little endian. */ ret = ccp_init_dm_workarea(&ctx, cmd_q, CCP_AES_CTX_KSB_COUNT * CCP_KSB_BYTES, DMA_BIDIRECTIONAL); if (ret) goto e_key; if (aes->mode != CCP_AES_MODE_ECB) { /* Load the AES context - conver to LE */ dm_offset = CCP_KSB_BYTES - AES_BLOCK_SIZE; ccp_set_dm_area(&ctx, dm_offset, aes->iv, 0, aes->iv_len); ret = ccp_copy_to_ksb(cmd_q, &ctx, op.jobid, op.ksb_ctx, CCP_PASSTHRU_BYTESWAP_256BIT); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_ctx; } } /* Prepare the input and output data workareas. For in-place * operations we need to set the dma direction to BIDIRECTIONAL * and copy the src workarea to the dst workarea. */ if (sg_virt(aes->src) == sg_virt(aes->dst)) in_place = true; ret = ccp_init_data(&src, cmd_q, aes->src, aes->src_len, AES_BLOCK_SIZE, in_place ? DMA_BIDIRECTIONAL : DMA_TO_DEVICE); if (ret) goto e_ctx; if (in_place) { dst = src; } else { ret = ccp_init_data(&dst, cmd_q, aes->dst, aes->src_len, AES_BLOCK_SIZE, DMA_FROM_DEVICE); if (ret) goto e_src; } /* Send data to the CCP AES engine */ while (src.sg_wa.bytes_left) { ccp_prepare_data(&src, &dst, &op, AES_BLOCK_SIZE, true); if (!src.sg_wa.bytes_left) { op.eom = 1; /* Since we don't retrieve the AES context in ECB * mode we have to wait for the operation to complete * on the last piece of data */ if (aes->mode == CCP_AES_MODE_ECB) op.soc = 1; } ret = ccp_perform_aes(&op); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_dst; } ccp_process_data(&src, &dst, &op); } if (aes->mode != CCP_AES_MODE_ECB) { /* Retrieve the AES context - convert from LE to BE using * 32-byte (256-bit) byteswapping */ ret = ccp_copy_from_ksb(cmd_q, &ctx, op.jobid, op.ksb_ctx, CCP_PASSTHRU_BYTESWAP_256BIT); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_dst; } /* ...but we only need AES_BLOCK_SIZE bytes */ dm_offset = CCP_KSB_BYTES - AES_BLOCK_SIZE; ccp_get_dm_area(&ctx, dm_offset, aes->iv, 0, aes->iv_len); } e_dst: if (!in_place) ccp_free_data(&dst, cmd_q); e_src: ccp_free_data(&src, cmd_q); e_ctx: ccp_dm_free(&ctx); e_key: ccp_dm_free(&key); return ret; } static int ccp_run_xts_aes_cmd(struct ccp_cmd_queue *cmd_q, struct ccp_cmd *cmd) { struct ccp_xts_aes_engine *xts = &cmd->u.xts; struct ccp_dm_workarea key, ctx; struct ccp_data src, dst; struct ccp_op op; unsigned int unit_size, dm_offset; bool in_place = false; int ret; switch (xts->unit_size) { case CCP_XTS_AES_UNIT_SIZE_16: unit_size = 16; break; case CCP_XTS_AES_UNIT_SIZE_512: unit_size = 512; break; case CCP_XTS_AES_UNIT_SIZE_1024: unit_size = 1024; break; case CCP_XTS_AES_UNIT_SIZE_2048: unit_size = 2048; break; case CCP_XTS_AES_UNIT_SIZE_4096: unit_size = 4096; break; default: return -EINVAL; } if (xts->key_len != AES_KEYSIZE_128) return -EINVAL; if (!xts->final && (xts->src_len & (AES_BLOCK_SIZE - 1))) return -EINVAL; if (xts->iv_len != AES_BLOCK_SIZE) return -EINVAL; if (!xts->key || !xts->iv || !xts->src || !xts->dst) return -EINVAL; BUILD_BUG_ON(CCP_XTS_AES_KEY_KSB_COUNT != 1); BUILD_BUG_ON(CCP_XTS_AES_CTX_KSB_COUNT != 1); ret = -EIO; memset(&op, 0, sizeof(op)); op.cmd_q = cmd_q; op.jobid = ccp_gen_jobid(cmd_q->ccp); op.ksb_key = cmd_q->ksb_key; op.ksb_ctx = cmd_q->ksb_ctx; op.init = 1; op.u.xts.action = xts->action; op.u.xts.unit_size = xts->unit_size; /* All supported key sizes fit in a single (32-byte) KSB entry * and must be in little endian format. Use the 256-bit byte * swap passthru option to convert from big endian to little * endian. */ ret = ccp_init_dm_workarea(&key, cmd_q, CCP_XTS_AES_KEY_KSB_COUNT * CCP_KSB_BYTES, DMA_TO_DEVICE); if (ret) return ret; dm_offset = CCP_KSB_BYTES - AES_KEYSIZE_128; ccp_set_dm_area(&key, dm_offset, xts->key, 0, xts->key_len); ccp_set_dm_area(&key, 0, xts->key, dm_offset, xts->key_len); ret = ccp_copy_to_ksb(cmd_q, &key, op.jobid, op.ksb_key, CCP_PASSTHRU_BYTESWAP_256BIT); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_key; } /* The AES context fits in a single (32-byte) KSB entry and * for XTS is already in little endian format so no byte swapping * is needed. */ ret = ccp_init_dm_workarea(&ctx, cmd_q, CCP_XTS_AES_CTX_KSB_COUNT * CCP_KSB_BYTES, DMA_BIDIRECTIONAL); if (ret) goto e_key; ccp_set_dm_area(&ctx, 0, xts->iv, 0, xts->iv_len); ret = ccp_copy_to_ksb(cmd_q, &ctx, op.jobid, op.ksb_ctx, CCP_PASSTHRU_BYTESWAP_NOOP); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_ctx; } /* Prepare the input and output data workareas. For in-place * operations we need to set the dma direction to BIDIRECTIONAL * and copy the src workarea to the dst workarea. */ if (sg_virt(xts->src) == sg_virt(xts->dst)) in_place = true; ret = ccp_init_data(&src, cmd_q, xts->src, xts->src_len, unit_size, in_place ? DMA_BIDIRECTIONAL : DMA_TO_DEVICE); if (ret) goto e_ctx; if (in_place) { dst = src; } else { ret = ccp_init_data(&dst, cmd_q, xts->dst, xts->src_len, unit_size, DMA_FROM_DEVICE); if (ret) goto e_src; } /* Send data to the CCP AES engine */ while (src.sg_wa.bytes_left) { ccp_prepare_data(&src, &dst, &op, unit_size, true); if (!src.sg_wa.bytes_left) op.eom = 1; ret = ccp_perform_xts_aes(&op); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_dst; } ccp_process_data(&src, &dst, &op); } /* Retrieve the AES context - convert from LE to BE using * 32-byte (256-bit) byteswapping */ ret = ccp_copy_from_ksb(cmd_q, &ctx, op.jobid, op.ksb_ctx, CCP_PASSTHRU_BYTESWAP_256BIT); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_dst; } /* ...but we only need AES_BLOCK_SIZE bytes */ dm_offset = CCP_KSB_BYTES - AES_BLOCK_SIZE; ccp_get_dm_area(&ctx, dm_offset, xts->iv, 0, xts->iv_len); e_dst: if (!in_place) ccp_free_data(&dst, cmd_q); e_src: ccp_free_data(&src, cmd_q); e_ctx: ccp_dm_free(&ctx); e_key: ccp_dm_free(&key); return ret; } static int ccp_run_sha_cmd(struct ccp_cmd_queue *cmd_q, struct ccp_cmd *cmd) { struct ccp_sha_engine *sha = &cmd->u.sha; struct ccp_dm_workarea ctx; struct ccp_data src; struct ccp_op op; int ret; if (sha->ctx_len != CCP_SHA_CTXSIZE) return -EINVAL; if (!sha->ctx) return -EINVAL; if (!sha->final && (sha->src_len & (CCP_SHA_BLOCKSIZE - 1))) return -EINVAL; if (!sha->src_len) { const u8 *sha_zero; /* Not final, just return */ if (!sha->final) return 0; /* CCP can't do a zero length sha operation so the caller * must buffer the data. */ if (sha->msg_bits) return -EINVAL; /* A sha operation for a message with a total length of zero, * return known result. */ switch (sha->type) { case CCP_SHA_TYPE_1: sha_zero = ccp_sha1_zero; break; case CCP_SHA_TYPE_224: sha_zero = ccp_sha224_zero; break; case CCP_SHA_TYPE_256: sha_zero = ccp_sha256_zero; break; default: return -EINVAL; } scatterwalk_map_and_copy((void *)sha_zero, sha->ctx, 0, sha->ctx_len, 1); return 0; } if (!sha->src) return -EINVAL; BUILD_BUG_ON(CCP_SHA_KSB_COUNT != 1); memset(&op, 0, sizeof(op)); op.cmd_q = cmd_q; op.jobid = ccp_gen_jobid(cmd_q->ccp); op.ksb_ctx = cmd_q->ksb_ctx; op.u.sha.type = sha->type; op.u.sha.msg_bits = sha->msg_bits; /* The SHA context fits in a single (32-byte) KSB entry and * must be in little endian format. Use the 256-bit byte swap * passthru option to convert from big endian to little endian. */ ret = ccp_init_dm_workarea(&ctx, cmd_q, CCP_SHA_KSB_COUNT * CCP_KSB_BYTES, DMA_BIDIRECTIONAL); if (ret) return ret; if (sha->first) { const __be32 *init; switch (sha->type) { case CCP_SHA_TYPE_1: init = ccp_sha1_init; break; case CCP_SHA_TYPE_224: init = ccp_sha224_init; break; case CCP_SHA_TYPE_256: init = ccp_sha256_init; break; default: ret = -EINVAL; goto e_ctx; } memcpy(ctx.address, init, CCP_SHA_CTXSIZE); } else { ccp_set_dm_area(&ctx, 0, sha->ctx, 0, sha->ctx_len); } ret = ccp_copy_to_ksb(cmd_q, &ctx, op.jobid, op.ksb_ctx, CCP_PASSTHRU_BYTESWAP_256BIT); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_ctx; } /* Send data to the CCP SHA engine */ ret = ccp_init_data(&src, cmd_q, sha->src, sha->src_len, CCP_SHA_BLOCKSIZE, DMA_TO_DEVICE); if (ret) goto e_ctx; while (src.sg_wa.bytes_left) { ccp_prepare_data(&src, NULL, &op, CCP_SHA_BLOCKSIZE, false); if (sha->final && !src.sg_wa.bytes_left) op.eom = 1; ret = ccp_perform_sha(&op); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_data; } ccp_process_data(&src, NULL, &op); } /* Retrieve the SHA context - convert from LE to BE using * 32-byte (256-bit) byteswapping to BE */ ret = ccp_copy_from_ksb(cmd_q, &ctx, op.jobid, op.ksb_ctx, CCP_PASSTHRU_BYTESWAP_256BIT); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_data; } ccp_get_dm_area(&ctx, 0, sha->ctx, 0, sha->ctx_len); if (sha->final && sha->opad) { /* HMAC operation, recursively perform final SHA */ struct ccp_cmd hmac_cmd; struct scatterlist sg; u64 block_size, digest_size; u8 *hmac_buf; switch (sha->type) { case CCP_SHA_TYPE_1: block_size = SHA1_BLOCK_SIZE; digest_size = SHA1_DIGEST_SIZE; break; case CCP_SHA_TYPE_224: block_size = SHA224_BLOCK_SIZE; digest_size = SHA224_DIGEST_SIZE; break; case CCP_SHA_TYPE_256: block_size = SHA256_BLOCK_SIZE; digest_size = SHA256_DIGEST_SIZE; break; default: ret = -EINVAL; goto e_data; } if (sha->opad_len != block_size) { ret = -EINVAL; goto e_data; } hmac_buf = kmalloc(block_size + digest_size, GFP_KERNEL); if (!hmac_buf) { ret = -ENOMEM; goto e_data; } sg_init_one(&sg, hmac_buf, block_size + digest_size); scatterwalk_map_and_copy(hmac_buf, sha->opad, 0, block_size, 0); memcpy(hmac_buf + block_size, ctx.address, digest_size); memset(&hmac_cmd, 0, sizeof(hmac_cmd)); hmac_cmd.engine = CCP_ENGINE_SHA; hmac_cmd.u.sha.type = sha->type; hmac_cmd.u.sha.ctx = sha->ctx; hmac_cmd.u.sha.ctx_len = sha->ctx_len; hmac_cmd.u.sha.src = &sg; hmac_cmd.u.sha.src_len = block_size + digest_size; hmac_cmd.u.sha.opad = NULL; hmac_cmd.u.sha.opad_len = 0; hmac_cmd.u.sha.first = 1; hmac_cmd.u.sha.final = 1; hmac_cmd.u.sha.msg_bits = (block_size + digest_size) << 3; ret = ccp_run_sha_cmd(cmd_q, &hmac_cmd); if (ret) cmd->engine_error = hmac_cmd.engine_error; kfree(hmac_buf); } e_data: ccp_free_data(&src, cmd_q); e_ctx: ccp_dm_free(&ctx); return ret; } static int ccp_run_rsa_cmd(struct ccp_cmd_queue *cmd_q, struct ccp_cmd *cmd) { struct ccp_rsa_engine *rsa = &cmd->u.rsa; struct ccp_dm_workarea exp, src; struct ccp_data dst; struct ccp_op op; unsigned int ksb_count, i_len, o_len; int ret; if (rsa->key_size > CCP_RSA_MAX_WIDTH) return -EINVAL; if (!rsa->exp || !rsa->mod || !rsa->src || !rsa->dst) return -EINVAL; /* The RSA modulus must precede the message being acted upon, so * it must be copied to a DMA area where the message and the * modulus can be concatenated. Therefore the input buffer * length required is twice the output buffer length (which * must be a multiple of 256-bits). */ o_len = ((rsa->key_size + 255) / 256) * 32; i_len = o_len * 2; ksb_count = o_len / CCP_KSB_BYTES; memset(&op, 0, sizeof(op)); op.cmd_q = cmd_q; op.jobid = ccp_gen_jobid(cmd_q->ccp); op.ksb_key = ccp_alloc_ksb(cmd_q->ccp, ksb_count); if (!op.ksb_key) return -EIO; /* The RSA exponent may span multiple (32-byte) KSB entries and must * be in little endian format. Reverse copy each 32-byte chunk * of the exponent (En chunk to E0 chunk, E(n-1) chunk to E1 chunk) * and each byte within that chunk and do not perform any byte swap * operations on the passthru operation. */ ret = ccp_init_dm_workarea(&exp, cmd_q, o_len, DMA_TO_DEVICE); if (ret) goto e_ksb; ccp_reverse_set_dm_area(&exp, rsa->exp, rsa->exp_len, CCP_KSB_BYTES, false); ret = ccp_copy_to_ksb(cmd_q, &exp, op.jobid, op.ksb_key, CCP_PASSTHRU_BYTESWAP_NOOP); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_exp; } /* Concatenate the modulus and the message. Both the modulus and * the operands must be in little endian format. Since the input * is in big endian format it must be converted. */ ret = ccp_init_dm_workarea(&src, cmd_q, i_len, DMA_TO_DEVICE); if (ret) goto e_exp; ccp_reverse_set_dm_area(&src, rsa->mod, rsa->mod_len, CCP_KSB_BYTES, false); src.address += o_len; /* Adjust the address for the copy operation */ ccp_reverse_set_dm_area(&src, rsa->src, rsa->src_len, CCP_KSB_BYTES, false); src.address -= o_len; /* Reset the address to original value */ /* Prepare the output area for the operation */ ret = ccp_init_data(&dst, cmd_q, rsa->dst, rsa->mod_len, o_len, DMA_FROM_DEVICE); if (ret) goto e_src; op.soc = 1; op.src.u.dma.address = src.dma.address; op.src.u.dma.offset = 0; op.src.u.dma.length = i_len; op.dst.u.dma.address = dst.dm_wa.dma.address; op.dst.u.dma.offset = 0; op.dst.u.dma.length = o_len; op.u.rsa.mod_size = rsa->key_size; op.u.rsa.input_len = i_len; ret = ccp_perform_rsa(&op); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_dst; } ccp_reverse_get_dm_area(&dst.dm_wa, rsa->dst, rsa->mod_len); e_dst: ccp_free_data(&dst, cmd_q); e_src: ccp_dm_free(&src); e_exp: ccp_dm_free(&exp); e_ksb: ccp_free_ksb(cmd_q->ccp, op.ksb_key, ksb_count); return ret; } static int ccp_run_passthru_cmd(struct ccp_cmd_queue *cmd_q, struct ccp_cmd *cmd) { struct ccp_passthru_engine *pt = &cmd->u.passthru; struct ccp_dm_workarea mask; struct ccp_data src, dst; struct ccp_op op; bool in_place = false; unsigned int i; int ret; if (!pt->final && (pt->src_len & (CCP_PASSTHRU_BLOCKSIZE - 1))) return -EINVAL; if (!pt->src || !pt->dst) return -EINVAL; if (pt->bit_mod != CCP_PASSTHRU_BITWISE_NOOP) { if (pt->mask_len != CCP_PASSTHRU_MASKSIZE) return -EINVAL; if (!pt->mask) return -EINVAL; } BUILD_BUG_ON(CCP_PASSTHRU_KSB_COUNT != 1); memset(&op, 0, sizeof(op)); op.cmd_q = cmd_q; op.jobid = ccp_gen_jobid(cmd_q->ccp); if (pt->bit_mod != CCP_PASSTHRU_BITWISE_NOOP) { /* Load the mask */ op.ksb_key = cmd_q->ksb_key; ret = ccp_init_dm_workarea(&mask, cmd_q, CCP_PASSTHRU_KSB_COUNT * CCP_KSB_BYTES, DMA_TO_DEVICE); if (ret) return ret; ccp_set_dm_area(&mask, 0, pt->mask, 0, pt->mask_len); ret = ccp_copy_to_ksb(cmd_q, &mask, op.jobid, op.ksb_key, CCP_PASSTHRU_BYTESWAP_NOOP); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_mask; } } /* Prepare the input and output data workareas. For in-place * operations we need to set the dma direction to BIDIRECTIONAL * and copy the src workarea to the dst workarea. */ if (sg_virt(pt->src) == sg_virt(pt->dst)) in_place = true; ret = ccp_init_data(&src, cmd_q, pt->src, pt->src_len, CCP_PASSTHRU_MASKSIZE, in_place ? DMA_BIDIRECTIONAL : DMA_TO_DEVICE); if (ret) goto e_mask; if (in_place) { dst = src; } else { ret = ccp_init_data(&dst, cmd_q, pt->dst, pt->src_len, CCP_PASSTHRU_MASKSIZE, DMA_FROM_DEVICE); if (ret) goto e_src; } /* Send data to the CCP Passthru engine * Because the CCP engine works on a single source and destination * dma address at a time, each entry in the source scatterlist * (after the dma_map_sg call) must be less than or equal to the * (remaining) length in the destination scatterlist entry and the * length must be a multiple of CCP_PASSTHRU_BLOCKSIZE */ dst.sg_wa.sg_used = 0; for (i = 1; i <= src.sg_wa.dma_count; i++) { if (!dst.sg_wa.sg || (dst.sg_wa.sg->length < src.sg_wa.sg->length)) { ret = -EINVAL; goto e_dst; } if (i == src.sg_wa.dma_count) { op.eom = 1; op.soc = 1; } op.src.type = CCP_MEMTYPE_SYSTEM; op.src.u.dma.address = sg_dma_address(src.sg_wa.sg); op.src.u.dma.offset = 0; op.src.u.dma.length = sg_dma_len(src.sg_wa.sg); op.dst.type = CCP_MEMTYPE_SYSTEM; op.dst.u.dma.address = sg_dma_address(dst.sg_wa.sg); op.dst.u.dma.offset = dst.sg_wa.sg_used; op.dst.u.dma.length = op.src.u.dma.length; ret = ccp_perform_passthru(&op); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_dst; } dst.sg_wa.sg_used += src.sg_wa.sg->length; if (dst.sg_wa.sg_used == dst.sg_wa.sg->length) { dst.sg_wa.sg = sg_next(dst.sg_wa.sg); dst.sg_wa.sg_used = 0; } src.sg_wa.sg = sg_next(src.sg_wa.sg); } e_dst: if (!in_place) ccp_free_data(&dst, cmd_q); e_src: ccp_free_data(&src, cmd_q); e_mask: if (pt->bit_mod != CCP_PASSTHRU_BITWISE_NOOP) ccp_dm_free(&mask); return ret; } static int ccp_run_ecc_mm_cmd(struct ccp_cmd_queue *cmd_q, struct ccp_cmd *cmd) { struct ccp_ecc_engine *ecc = &cmd->u.ecc; struct ccp_dm_workarea src, dst; struct ccp_op op; int ret; u8 *save; if (!ecc->u.mm.operand_1 || (ecc->u.mm.operand_1_len > CCP_ECC_MODULUS_BYTES)) return -EINVAL; if (ecc->function != CCP_ECC_FUNCTION_MINV_384BIT) if (!ecc->u.mm.operand_2 || (ecc->u.mm.operand_2_len > CCP_ECC_MODULUS_BYTES)) return -EINVAL; if (!ecc->u.mm.result || (ecc->u.mm.result_len < CCP_ECC_MODULUS_BYTES)) return -EINVAL; memset(&op, 0, sizeof(op)); op.cmd_q = cmd_q; op.jobid = ccp_gen_jobid(cmd_q->ccp); /* Concatenate the modulus and the operands. Both the modulus and * the operands must be in little endian format. Since the input * is in big endian format it must be converted and placed in a * fixed length buffer. */ ret = ccp_init_dm_workarea(&src, cmd_q, CCP_ECC_SRC_BUF_SIZE, DMA_TO_DEVICE); if (ret) return ret; /* Save the workarea address since it is updated in order to perform * the concatenation */ save = src.address; /* Copy the ECC modulus */ ccp_reverse_set_dm_area(&src, ecc->mod, ecc->mod_len, CCP_ECC_OPERAND_SIZE, false); src.address += CCP_ECC_OPERAND_SIZE; /* Copy the first operand */ ccp_reverse_set_dm_area(&src, ecc->u.mm.operand_1, ecc->u.mm.operand_1_len, CCP_ECC_OPERAND_SIZE, false); src.address += CCP_ECC_OPERAND_SIZE; if (ecc->function != CCP_ECC_FUNCTION_MINV_384BIT) { /* Copy the second operand */ ccp_reverse_set_dm_area(&src, ecc->u.mm.operand_2, ecc->u.mm.operand_2_len, CCP_ECC_OPERAND_SIZE, false); src.address += CCP_ECC_OPERAND_SIZE; } /* Restore the workarea address */ src.address = save; /* Prepare the output area for the operation */ ret = ccp_init_dm_workarea(&dst, cmd_q, CCP_ECC_DST_BUF_SIZE, DMA_FROM_DEVICE); if (ret) goto e_src; op.soc = 1; op.src.u.dma.address = src.dma.address; op.src.u.dma.offset = 0; op.src.u.dma.length = src.length; op.dst.u.dma.address = dst.dma.address; op.dst.u.dma.offset = 0; op.dst.u.dma.length = dst.length; op.u.ecc.function = cmd->u.ecc.function; ret = ccp_perform_ecc(&op); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_dst; } ecc->ecc_result = le16_to_cpup( (const __le16 *)(dst.address + CCP_ECC_RESULT_OFFSET)); if (!(ecc->ecc_result & CCP_ECC_RESULT_SUCCESS)) { ret = -EIO; goto e_dst; } /* Save the ECC result */ ccp_reverse_get_dm_area(&dst, ecc->u.mm.result, CCP_ECC_MODULUS_BYTES); e_dst: ccp_dm_free(&dst); e_src: ccp_dm_free(&src); return ret; } static int ccp_run_ecc_pm_cmd(struct ccp_cmd_queue *cmd_q, struct ccp_cmd *cmd) { struct ccp_ecc_engine *ecc = &cmd->u.ecc; struct ccp_dm_workarea src, dst; struct ccp_op op; int ret; u8 *save; if (!ecc->u.pm.point_1.x || (ecc->u.pm.point_1.x_len > CCP_ECC_MODULUS_BYTES) || !ecc->u.pm.point_1.y || (ecc->u.pm.point_1.y_len > CCP_ECC_MODULUS_BYTES)) return -EINVAL; if (ecc->function == CCP_ECC_FUNCTION_PADD_384BIT) { if (!ecc->u.pm.point_2.x || (ecc->u.pm.point_2.x_len > CCP_ECC_MODULUS_BYTES) || !ecc->u.pm.point_2.y || (ecc->u.pm.point_2.y_len > CCP_ECC_MODULUS_BYTES)) return -EINVAL; } else { if (!ecc->u.pm.domain_a || (ecc->u.pm.domain_a_len > CCP_ECC_MODULUS_BYTES)) return -EINVAL; if (ecc->function == CCP_ECC_FUNCTION_PMUL_384BIT) if (!ecc->u.pm.scalar || (ecc->u.pm.scalar_len > CCP_ECC_MODULUS_BYTES)) return -EINVAL; } if (!ecc->u.pm.result.x || (ecc->u.pm.result.x_len < CCP_ECC_MODULUS_BYTES) || !ecc->u.pm.result.y || (ecc->u.pm.result.y_len < CCP_ECC_MODULUS_BYTES)) return -EINVAL; memset(&op, 0, sizeof(op)); op.cmd_q = cmd_q; op.jobid = ccp_gen_jobid(cmd_q->ccp); /* Concatenate the modulus and the operands. Both the modulus and * the operands must be in little endian format. Since the input * is in big endian format it must be converted and placed in a * fixed length buffer. */ ret = ccp_init_dm_workarea(&src, cmd_q, CCP_ECC_SRC_BUF_SIZE, DMA_TO_DEVICE); if (ret) return ret; /* Save the workarea address since it is updated in order to perform * the concatenation */ save = src.address; /* Copy the ECC modulus */ ccp_reverse_set_dm_area(&src, ecc->mod, ecc->mod_len, CCP_ECC_OPERAND_SIZE, false); src.address += CCP_ECC_OPERAND_SIZE; /* Copy the first point X and Y coordinate */ ccp_reverse_set_dm_area(&src, ecc->u.pm.point_1.x, ecc->u.pm.point_1.x_len, CCP_ECC_OPERAND_SIZE, false); src.address += CCP_ECC_OPERAND_SIZE; ccp_reverse_set_dm_area(&src, ecc->u.pm.point_1.y, ecc->u.pm.point_1.y_len, CCP_ECC_OPERAND_SIZE, false); src.address += CCP_ECC_OPERAND_SIZE; /* Set the first point Z coordianate to 1 */ *src.address = 0x01; src.address += CCP_ECC_OPERAND_SIZE; if (ecc->function == CCP_ECC_FUNCTION_PADD_384BIT) { /* Copy the second point X and Y coordinate */ ccp_reverse_set_dm_area(&src, ecc->u.pm.point_2.x, ecc->u.pm.point_2.x_len, CCP_ECC_OPERAND_SIZE, false); src.address += CCP_ECC_OPERAND_SIZE; ccp_reverse_set_dm_area(&src, ecc->u.pm.point_2.y, ecc->u.pm.point_2.y_len, CCP_ECC_OPERAND_SIZE, false); src.address += CCP_ECC_OPERAND_SIZE; /* Set the second point Z coordianate to 1 */ *src.address = 0x01; src.address += CCP_ECC_OPERAND_SIZE; } else { /* Copy the Domain "a" parameter */ ccp_reverse_set_dm_area(&src, ecc->u.pm.domain_a, ecc->u.pm.domain_a_len, CCP_ECC_OPERAND_SIZE, false); src.address += CCP_ECC_OPERAND_SIZE; if (ecc->function == CCP_ECC_FUNCTION_PMUL_384BIT) { /* Copy the scalar value */ ccp_reverse_set_dm_area(&src, ecc->u.pm.scalar, ecc->u.pm.scalar_len, CCP_ECC_OPERAND_SIZE, false); src.address += CCP_ECC_OPERAND_SIZE; } } /* Restore the workarea address */ src.address = save; /* Prepare the output area for the operation */ ret = ccp_init_dm_workarea(&dst, cmd_q, CCP_ECC_DST_BUF_SIZE, DMA_FROM_DEVICE); if (ret) goto e_src; op.soc = 1; op.src.u.dma.address = src.dma.address; op.src.u.dma.offset = 0; op.src.u.dma.length = src.length; op.dst.u.dma.address = dst.dma.address; op.dst.u.dma.offset = 0; op.dst.u.dma.length = dst.length; op.u.ecc.function = cmd->u.ecc.function; ret = ccp_perform_ecc(&op); if (ret) { cmd->engine_error = cmd_q->cmd_error; goto e_dst; } ecc->ecc_result = le16_to_cpup( (const __le16 *)(dst.address + CCP_ECC_RESULT_OFFSET)); if (!(ecc->ecc_result & CCP_ECC_RESULT_SUCCESS)) { ret = -EIO; goto e_dst; } /* Save the workarea address since it is updated as we walk through * to copy the point math result */ save = dst.address; /* Save the ECC result X and Y coordinates */ ccp_reverse_get_dm_area(&dst, ecc->u.pm.result.x, CCP_ECC_MODULUS_BYTES); dst.address += CCP_ECC_OUTPUT_SIZE; ccp_reverse_get_dm_area(&dst, ecc->u.pm.result.y, CCP_ECC_MODULUS_BYTES); dst.address += CCP_ECC_OUTPUT_SIZE; /* Restore the workarea address */ dst.address = save; e_dst: ccp_dm_free(&dst); e_src: ccp_dm_free(&src); return ret; } static int ccp_run_ecc_cmd(struct ccp_cmd_queue *cmd_q, struct ccp_cmd *cmd) { struct ccp_ecc_engine *ecc = &cmd->u.ecc; ecc->ecc_result = 0; if (!ecc->mod || (ecc->mod_len > CCP_ECC_MODULUS_BYTES)) return -EINVAL; switch (ecc->function) { case CCP_ECC_FUNCTION_MMUL_384BIT: case CCP_ECC_FUNCTION_MADD_384BIT: case CCP_ECC_FUNCTION_MINV_384BIT: return ccp_run_ecc_mm_cmd(cmd_q, cmd); case CCP_ECC_FUNCTION_PADD_384BIT: case CCP_ECC_FUNCTION_PMUL_384BIT: case CCP_ECC_FUNCTION_PDBL_384BIT: return ccp_run_ecc_pm_cmd(cmd_q, cmd); default: return -EINVAL; } } int ccp_run_cmd(struct ccp_cmd_queue *cmd_q, struct ccp_cmd *cmd) { int ret; cmd->engine_error = 0; cmd_q->cmd_error = 0; cmd_q->int_rcvd = 0; cmd_q->free_slots = CMD_Q_DEPTH(ioread32(cmd_q->reg_status)); switch (cmd->engine) { case CCP_ENGINE_AES: ret = ccp_run_aes_cmd(cmd_q, cmd); break; case CCP_ENGINE_XTS_AES_128: ret = ccp_run_xts_aes_cmd(cmd_q, cmd); break; case CCP_ENGINE_SHA: ret = ccp_run_sha_cmd(cmd_q, cmd); break; case CCP_ENGINE_RSA: ret = ccp_run_rsa_cmd(cmd_q, cmd); break; case CCP_ENGINE_PASSTHRU: ret = ccp_run_passthru_cmd(cmd_q, cmd); break; case CCP_ENGINE_ECC: ret = ccp_run_ecc_cmd(cmd_q, cmd); break; default: ret = -EINVAL; } return ret; }