linux/drivers/crypto/ccp/ccp-ops.c

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/*
* AMD Cryptographic Coprocessor (CCP) driver
*
* Copyright (C) 2013,2017 Advanced Micro Devices, Inc.
*
* Author: Tom Lendacky <thomas.lendacky@amd.com>
* Author: Gary R Hook <gary.hook@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/interrupt.h>
#include <crypto/scatterwalk.h>
#include <crypto/des.h>
#include <linux/ccp.h>
#include "ccp-dev.h"
/* SHA initial context values */
static const __be32 ccp_sha1_init[SHA1_DIGEST_SIZE / 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),
};
static const __be32 ccp_sha224_init[SHA256_DIGEST_SIZE / 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[SHA256_DIGEST_SIZE / 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),
};
static const __be64 ccp_sha384_init[SHA512_DIGEST_SIZE / sizeof(__be64)] = {
cpu_to_be64(SHA384_H0), cpu_to_be64(SHA384_H1),
cpu_to_be64(SHA384_H2), cpu_to_be64(SHA384_H3),
cpu_to_be64(SHA384_H4), cpu_to_be64(SHA384_H5),
cpu_to_be64(SHA384_H6), cpu_to_be64(SHA384_H7),
};
static const __be64 ccp_sha512_init[SHA512_DIGEST_SIZE / sizeof(__be64)] = {
cpu_to_be64(SHA512_H0), cpu_to_be64(SHA512_H1),
cpu_to_be64(SHA512_H2), cpu_to_be64(SHA512_H3),
cpu_to_be64(SHA512_H4), cpu_to_be64(SHA512_H5),
cpu_to_be64(SHA512_H6), cpu_to_be64(SHA512_H7),
};
#define CCP_NEW_JOBID(ccp) ((ccp->vdata->version == CCP_VERSION(3, 0)) ? \
ccp_gen_jobid(ccp) : 0)
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_for_len(sg, len);
if (wa->nents < 0)
return wa->nents;
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 (dma_mapping_error(wa->dev, wa->dma.address))
return -ENOMEM;
wa->dma.length = len;
}
wa->dma.dir = dir;
return 0;
}
static int 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);
if (len > (wa->length - wa_offset))
return -EINVAL;
scatterwalk_map_and_copy(wa->address + wa_offset, sg, sg_offset, len,
0);
return 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 int ccp_reverse_set_dm_area(struct ccp_dm_workarea *wa,
unsigned int wa_offset,
struct scatterlist *sg,
unsigned int sg_offset,
unsigned int len)
{
u8 *p, *q;
int rc;
rc = ccp_set_dm_area(wa, wa_offset, sg, sg_offset, len);
if (rc)
return rc;
p = wa->address + wa_offset;
q = p + len - 1;
while (p < q) {
*p = *p ^ *q;
*q = *p ^ *q;
*p = *p ^ *q;
p++;
q--;
}
return 0;
}
static void ccp_reverse_get_dm_area(struct ccp_dm_workarea *wa,
unsigned int wa_offset,
struct scatterlist *sg,
unsigned int sg_offset,
unsigned int len)
{
u8 *p, *q;
p = wa->address + wa_offset;
q = p + len - 1;
while (p < q) {
*p = *p ^ *q;
*q = *p ^ *q;
*p = *p ^ *q;
p++;
q--;
}
ccp_get_dm_area(wa, wa_offset, sg, sg_offset, 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_sb(struct ccp_cmd_queue *cmd_q,
struct ccp_dm_workarea *wa, u32 jobid, u32 sb,
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_SB;
op.src.u.sb = sb;
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_SB;
op.dst.u.sb = sb;
}
op.u.passthru.byte_swap = byte_swap;
return cmd_q->ccp->vdata->perform->passthru(&op);
}
static int ccp_copy_to_sb(struct ccp_cmd_queue *cmd_q,
struct ccp_dm_workarea *wa, u32 jobid, u32 sb,
u32 byte_swap)
{
return ccp_copy_to_from_sb(cmd_q, wa, jobid, sb, byte_swap, false);
}
static int ccp_copy_from_sb(struct ccp_cmd_queue *cmd_q,
struct ccp_dm_workarea *wa, u32 jobid, u32 sb,
u32 byte_swap)
{
return ccp_copy_to_from_sb(cmd_q, wa, jobid, sb, 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_SB_COUNT != 1);
BUILD_BUG_ON(CCP_AES_CTX_SB_COUNT != 1);
ret = -EIO;
memset(&op, 0, sizeof(op));
op.cmd_q = cmd_q;
op.jobid = CCP_NEW_JOBID(cmd_q->ccp);
op.sb_key = cmd_q->sb_key;
op.sb_ctx = cmd_q->sb_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) SB 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_SB_COUNT * CCP_SB_BYTES,
DMA_TO_DEVICE);
if (ret)
return ret;
dm_offset = CCP_SB_BYTES - aes->key_len;
ret = ccp_set_dm_area(&key, dm_offset, aes->key, 0, aes->key_len);
if (ret)
goto e_key;
ret = ccp_copy_to_sb(cmd_q, &key, op.jobid, op.sb_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) SB 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_SB_COUNT * CCP_SB_BYTES,
DMA_BIDIRECTIONAL);
if (ret)
goto e_key;
dm_offset = CCP_SB_BYTES - AES_BLOCK_SIZE;
ret = ccp_set_dm_area(&ctx, dm_offset, aes->iv, 0, aes->iv_len);
if (ret)
goto e_ctx;
ret = ccp_copy_to_sb(cmd_q, &ctx, op.jobid, op.sb_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_sb(cmd_q, &ctx, op.jobid,
op.sb_ctx,
CCP_PASSTHRU_BYTESWAP_256BIT);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_src;
}
ret = ccp_set_dm_area(&ctx, 0, aes->cmac_key, 0,
aes->cmac_key_len);
if (ret)
goto e_src;
ret = ccp_copy_to_sb(cmd_q, &ctx, op.jobid, op.sb_ctx,
CCP_PASSTHRU_BYTESWAP_256BIT);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_src;
}
}
ret = cmd_q->ccp->vdata->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_sb(cmd_q, &ctx, op.jobid, op.sb_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_SB_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_gcm_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, final_wa, tag;
struct ccp_data src, dst;
struct ccp_data aad;
struct ccp_op op;
unsigned long long *final;
unsigned int dm_offset;
unsigned int ilen;
bool in_place = true; /* Default value */
int ret;
struct scatterlist *p_inp, sg_inp[2];
struct scatterlist *p_tag, sg_tag[2];
struct scatterlist *p_outp, sg_outp[2];
struct scatterlist *p_aad;
if (!aes->iv)
return -EINVAL;
if (!((aes->key_len == AES_KEYSIZE_128) ||
(aes->key_len == AES_KEYSIZE_192) ||
(aes->key_len == AES_KEYSIZE_256)))
return -EINVAL;
if (!aes->key) /* Gotta have a key SGL */
return -EINVAL;
/* First, decompose the source buffer into AAD & PT,
* and the destination buffer into AAD, CT & tag, or
* the input into CT & tag.
* It is expected that the input and output SGs will
* be valid, even if the AAD and input lengths are 0.
*/
p_aad = aes->src;
p_inp = scatterwalk_ffwd(sg_inp, aes->src, aes->aad_len);
p_outp = scatterwalk_ffwd(sg_outp, aes->dst, aes->aad_len);
if (aes->action == CCP_AES_ACTION_ENCRYPT) {
ilen = aes->src_len;
p_tag = scatterwalk_ffwd(sg_tag, p_outp, ilen);
} else {
/* Input length for decryption includes tag */
ilen = aes->src_len - AES_BLOCK_SIZE;
p_tag = scatterwalk_ffwd(sg_tag, p_inp, ilen);
}
memset(&op, 0, sizeof(op));
op.cmd_q = cmd_q;
op.jobid = CCP_NEW_JOBID(cmd_q->ccp);
op.sb_key = cmd_q->sb_key; /* Pre-allocated */
op.sb_ctx = cmd_q->sb_ctx; /* Pre-allocated */
op.init = 1;
op.u.aes.type = aes->type;
/* Copy the key to the LSB */
ret = ccp_init_dm_workarea(&key, cmd_q,
CCP_AES_CTX_SB_COUNT * CCP_SB_BYTES,
DMA_TO_DEVICE);
if (ret)
return ret;
dm_offset = CCP_SB_BYTES - aes->key_len;
ret = ccp_set_dm_area(&key, dm_offset, aes->key, 0, aes->key_len);
if (ret)
goto e_key;
ret = ccp_copy_to_sb(cmd_q, &key, op.jobid, op.sb_key,
CCP_PASSTHRU_BYTESWAP_256BIT);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_key;
}
/* Copy the context (IV) to the LSB.
* There is an assumption here that the IV is 96 bits in length, plus
* a nonce of 32 bits. If no IV is present, use a zeroed buffer.
*/
ret = ccp_init_dm_workarea(&ctx, cmd_q,
CCP_AES_CTX_SB_COUNT * CCP_SB_BYTES,
DMA_BIDIRECTIONAL);
if (ret)
goto e_key;
dm_offset = CCP_AES_CTX_SB_COUNT * CCP_SB_BYTES - aes->iv_len;
ret = ccp_set_dm_area(&ctx, dm_offset, aes->iv, 0, aes->iv_len);
if (ret)
goto e_ctx;
ret = ccp_copy_to_sb(cmd_q, &ctx, op.jobid, op.sb_ctx,
CCP_PASSTHRU_BYTESWAP_256BIT);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_ctx;
}
op.init = 1;
if (aes->aad_len > 0) {
/* Step 1: Run a GHASH over the Additional Authenticated Data */
ret = ccp_init_data(&aad, cmd_q, p_aad, aes->aad_len,
AES_BLOCK_SIZE,
DMA_TO_DEVICE);
if (ret)
goto e_ctx;
op.u.aes.mode = CCP_AES_MODE_GHASH;
op.u.aes.action = CCP_AES_GHASHAAD;
while (aad.sg_wa.bytes_left) {
ccp_prepare_data(&aad, NULL, &op, AES_BLOCK_SIZE, true);
ret = cmd_q->ccp->vdata->perform->aes(&op);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_aad;
}
ccp_process_data(&aad, NULL, &op);
op.init = 0;
}
}
op.u.aes.mode = CCP_AES_MODE_GCTR;
op.u.aes.action = aes->action;
if (ilen > 0) {
/* Step 2: Run a GCTR over the plaintext */
in_place = (sg_virt(p_inp) == sg_virt(p_outp)) ? true : false;
ret = ccp_init_data(&src, cmd_q, p_inp, ilen,
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, p_outp, ilen,
AES_BLOCK_SIZE, DMA_FROM_DEVICE);
if (ret)
goto e_src;
}
op.soc = 0;
op.eom = 0;
op.init = 1;
while (src.sg_wa.bytes_left) {
ccp_prepare_data(&src, &dst, &op, AES_BLOCK_SIZE, true);
if (!src.sg_wa.bytes_left) {
unsigned int nbytes = aes->src_len
% AES_BLOCK_SIZE;
if (nbytes) {
op.eom = 1;
op.u.aes.size = (nbytes * 8) - 1;
}
}
ret = cmd_q->ccp->vdata->perform->aes(&op);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_dst;
}
ccp_process_data(&src, &dst, &op);
op.init = 0;
}
}
/* Step 3: Update the IV portion of the context with the original IV */
ret = ccp_copy_from_sb(cmd_q, &ctx, op.jobid, op.sb_ctx,
CCP_PASSTHRU_BYTESWAP_256BIT);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_dst;
}
ret = ccp_set_dm_area(&ctx, dm_offset, aes->iv, 0, aes->iv_len);
if (ret)
goto e_dst;
ret = ccp_copy_to_sb(cmd_q, &ctx, op.jobid, op.sb_ctx,
CCP_PASSTHRU_BYTESWAP_256BIT);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_dst;
}
/* Step 4: Concatenate the lengths of the AAD and source, and
* hash that 16 byte buffer.
*/
ret = ccp_init_dm_workarea(&final_wa, cmd_q, AES_BLOCK_SIZE,
DMA_BIDIRECTIONAL);
if (ret)
goto e_dst;
final = (unsigned long long *) final_wa.address;
final[0] = cpu_to_be64(aes->aad_len * 8);
final[1] = cpu_to_be64(ilen * 8);
op.u.aes.mode = CCP_AES_MODE_GHASH;
op.u.aes.action = CCP_AES_GHASHFINAL;
op.src.type = CCP_MEMTYPE_SYSTEM;
op.src.u.dma.address = final_wa.dma.address;
op.src.u.dma.length = AES_BLOCK_SIZE;
op.dst.type = CCP_MEMTYPE_SYSTEM;
op.dst.u.dma.address = final_wa.dma.address;
op.dst.u.dma.length = AES_BLOCK_SIZE;
op.eom = 1;
op.u.aes.size = 0;
ret = cmd_q->ccp->vdata->perform->aes(&op);
if (ret)
goto e_dst;
if (aes->action == CCP_AES_ACTION_ENCRYPT) {
/* Put the ciphered tag after the ciphertext. */
ccp_get_dm_area(&final_wa, 0, p_tag, 0, AES_BLOCK_SIZE);
} else {
/* Does this ciphered tag match the input? */
ret = ccp_init_dm_workarea(&tag, cmd_q, AES_BLOCK_SIZE,
DMA_BIDIRECTIONAL);
if (ret)
goto e_tag;
ret = ccp_set_dm_area(&tag, 0, p_tag, 0, AES_BLOCK_SIZE);
if (ret)
goto e_tag;
ret = memcmp(tag.address, final_wa.address, AES_BLOCK_SIZE);
ccp_dm_free(&tag);
}
e_tag:
ccp_dm_free(&final_wa);
e_dst:
if (aes->src_len && !in_place)
ccp_free_data(&dst, cmd_q);
e_src:
if (aes->src_len)
ccp_free_data(&src, cmd_q);
e_aad:
if (aes->aad_len)
ccp_free_data(&aad, 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->mode == CCP_AES_MODE_GCM)
return ccp_run_aes_gcm_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_SB_COUNT != 1);
BUILD_BUG_ON(CCP_AES_CTX_SB_COUNT != 1);
ret = -EIO;
memset(&op, 0, sizeof(op));
op.cmd_q = cmd_q;
op.jobid = CCP_NEW_JOBID(cmd_q->ccp);
op.sb_key = cmd_q->sb_key;
op.sb_ctx = cmd_q->sb_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) SB 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_SB_COUNT * CCP_SB_BYTES,
DMA_TO_DEVICE);
if (ret)
return ret;
dm_offset = CCP_SB_BYTES - aes->key_len;
ret = ccp_set_dm_area(&key, dm_offset, aes->key, 0, aes->key_len);
if (ret)
goto e_key;
ret = ccp_copy_to_sb(cmd_q, &key, op.jobid, op.sb_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) SB 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_SB_COUNT * CCP_SB_BYTES,
DMA_BIDIRECTIONAL);
if (ret)
goto e_key;
if (aes->mode != CCP_AES_MODE_ECB) {
/* Load the AES context - convert to LE */
dm_offset = CCP_SB_BYTES - AES_BLOCK_SIZE;
ret = ccp_set_dm_area(&ctx, dm_offset, aes->iv, 0, aes->iv_len);
if (ret)
goto e_ctx;
ret = ccp_copy_to_sb(cmd_q, &ctx, op.jobid, op.sb_ctx,
CCP_PASSTHRU_BYTESWAP_256BIT);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_ctx;
}
}
switch (aes->mode) {
case CCP_AES_MODE_CFB: /* CFB128 only */
case CCP_AES_MODE_CTR:
op.u.aes.size = AES_BLOCK_SIZE * BITS_PER_BYTE - 1;
break;
default:
op.u.aes.size = 0;
}
/* 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 = cmd_q->ccp->vdata->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_sb(cmd_q, &ctx, op.jobid, op.sb_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_SB_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;
unsigned int sb_count;
enum ccp_aes_type aestype;
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)
aestype = CCP_AES_TYPE_128;
else if (xts->key_len == AES_KEYSIZE_256)
aestype = CCP_AES_TYPE_256;
else
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_SB_COUNT != 1);
BUILD_BUG_ON(CCP_XTS_AES_CTX_SB_COUNT != 1);
ret = -EIO;
memset(&op, 0, sizeof(op));
op.cmd_q = cmd_q;
op.jobid = CCP_NEW_JOBID(cmd_q->ccp);
op.sb_key = cmd_q->sb_key;
op.sb_ctx = cmd_q->sb_ctx;
op.init = 1;
op.u.xts.type = aestype;
op.u.xts.action = xts->action;
op.u.xts.unit_size = xts->unit_size;
/* A version 3 device only supports 128-bit keys, which fits into a
* single SB entry. A version 5 device uses a 512-bit vector, so two
* SB entries.
*/
if (cmd_q->ccp->vdata->version == CCP_VERSION(3, 0))
sb_count = CCP_XTS_AES_KEY_SB_COUNT;
else
sb_count = CCP5_XTS_AES_KEY_SB_COUNT;
ret = ccp_init_dm_workarea(&key, cmd_q,
sb_count * CCP_SB_BYTES,
DMA_TO_DEVICE);
if (ret)
return ret;
if (cmd_q->ccp->vdata->version == CCP_VERSION(3, 0)) {
/* All supported key sizes must be in little endian format.
* Use the 256-bit byte swap passthru option to convert from
* big endian to little endian.
*/
dm_offset = CCP_SB_BYTES - AES_KEYSIZE_128;
ret = ccp_set_dm_area(&key, dm_offset, xts->key, 0, xts->key_len);
if (ret)
goto e_key;
ret = ccp_set_dm_area(&key, 0, xts->key, xts->key_len, xts->key_len);
if (ret)
goto e_key;
} else {
/* Version 5 CCPs use a 512-bit space for the key: each portion
* occupies 256 bits, or one entire slot, and is zero-padded.
*/
unsigned int pad;
dm_offset = CCP_SB_BYTES;
pad = dm_offset - xts->key_len;
ret = ccp_set_dm_area(&key, pad, xts->key, 0, xts->key_len);
if (ret)
goto e_key;
ret = ccp_set_dm_area(&key, dm_offset + pad, xts->key,
xts->key_len, xts->key_len);
if (ret)
goto e_key;
}
ret = ccp_copy_to_sb(cmd_q, &key, op.jobid, op.sb_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) SB 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_SB_COUNT * CCP_SB_BYTES,
DMA_BIDIRECTIONAL);
if (ret)
goto e_key;
ret = ccp_set_dm_area(&ctx, 0, xts->iv, 0, xts->iv_len);
if (ret)
goto e_ctx;
ret = ccp_copy_to_sb(cmd_q, &ctx, op.jobid, op.sb_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 = cmd_q->ccp->vdata->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_sb(cmd_q, &ctx, op.jobid, op.sb_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_SB_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_des3_cmd(struct ccp_cmd_queue *cmd_q, struct ccp_cmd *cmd)
{
struct ccp_des3_engine *des3 = &cmd->u.des3;
struct ccp_dm_workarea key, ctx;
struct ccp_data src, dst;
struct ccp_op op;
unsigned int dm_offset;
unsigned int len_singlekey;
bool in_place = false;
int ret;
/* Error checks */
if (!cmd_q->ccp->vdata->perform->des3)
return -EINVAL;
if (des3->key_len != DES3_EDE_KEY_SIZE)
return -EINVAL;
if (((des3->mode == CCP_DES3_MODE_ECB) ||
(des3->mode == CCP_DES3_MODE_CBC)) &&
(des3->src_len & (DES3_EDE_BLOCK_SIZE - 1)))
return -EINVAL;
if (!des3->key || !des3->src || !des3->dst)
return -EINVAL;
if (des3->mode != CCP_DES3_MODE_ECB) {
if (des3->iv_len != DES3_EDE_BLOCK_SIZE)
return -EINVAL;
if (!des3->iv)
return -EINVAL;
}
ret = -EIO;
/* Zero out all the fields of the command desc */
memset(&op, 0, sizeof(op));
/* Set up the Function field */
op.cmd_q = cmd_q;
op.jobid = CCP_NEW_JOBID(cmd_q->ccp);
op.sb_key = cmd_q->sb_key;
op.init = (des3->mode == CCP_DES3_MODE_ECB) ? 0 : 1;
op.u.des3.type = des3->type;
op.u.des3.mode = des3->mode;
op.u.des3.action = des3->action;
/*
* All supported key sizes fit in a single (32-byte) KSB entry and
* (like AES) 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_DES3_KEY_SB_COUNT * CCP_SB_BYTES,
DMA_TO_DEVICE);
if (ret)
return ret;
/*
* The contents of the key triplet are in the reverse order of what
* is required by the engine. Copy the 3 pieces individually to put
* them where they belong.
*/
dm_offset = CCP_SB_BYTES - des3->key_len; /* Basic offset */
len_singlekey = des3->key_len / 3;
ret = ccp_set_dm_area(&key, dm_offset + 2 * len_singlekey,
des3->key, 0, len_singlekey);
if (ret)
goto e_key;
ret = ccp_set_dm_area(&key, dm_offset + len_singlekey,
des3->key, len_singlekey, len_singlekey);
if (ret)
goto e_key;
ret = ccp_set_dm_area(&key, dm_offset,
des3->key, 2 * len_singlekey, len_singlekey);
if (ret)
goto e_key;
/* Copy the key to the SB */
ret = ccp_copy_to_sb(cmd_q, &key, op.jobid, op.sb_key,
CCP_PASSTHRU_BYTESWAP_256BIT);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_key;
}
/*
* The DES3 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.
*/
if (des3->mode != CCP_DES3_MODE_ECB) {
u32 load_mode;
op.sb_ctx = cmd_q->sb_ctx;
ret = ccp_init_dm_workarea(&ctx, cmd_q,
CCP_DES3_CTX_SB_COUNT * CCP_SB_BYTES,
DMA_BIDIRECTIONAL);
if (ret)
goto e_key;
/* Load the context into the LSB */
dm_offset = CCP_SB_BYTES - des3->iv_len;
ret = ccp_set_dm_area(&ctx, dm_offset, des3->iv, 0,
des3->iv_len);
if (ret)
goto e_ctx;
if (cmd_q->ccp->vdata->version == CCP_VERSION(3, 0))
load_mode = CCP_PASSTHRU_BYTESWAP_NOOP;
else
load_mode = CCP_PASSTHRU_BYTESWAP_256BIT;
ret = ccp_copy_to_sb(cmd_q, &ctx, op.jobid, op.sb_ctx,
load_mode);
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(des3->src) == sg_virt(des3->dst))
in_place = true;
ret = ccp_init_data(&src, cmd_q, des3->src, des3->src_len,
DES3_EDE_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, des3->dst, des3->src_len,
DES3_EDE_BLOCK_SIZE, DMA_FROM_DEVICE);
if (ret)
goto e_src;
}
/* Send data to the CCP DES3 engine */
while (src.sg_wa.bytes_left) {
ccp_prepare_data(&src, &dst, &op, DES3_EDE_BLOCK_SIZE, true);
if (!src.sg_wa.bytes_left) {
op.eom = 1;
/* Since we don't retrieve the context in ECB mode
* we have to wait for the operation to complete
* on the last piece of data
*/
op.soc = 0;
}
ret = cmd_q->ccp->vdata->perform->des3(&op);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_dst;
}
ccp_process_data(&src, &dst, &op);
}
if (des3->mode != CCP_DES3_MODE_ECB) {
/* Retrieve the context and make BE */
ret = ccp_copy_from_sb(cmd_q, &ctx, op.jobid, op.sb_ctx,
CCP_PASSTHRU_BYTESWAP_256BIT);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_dst;
}
/* ...but we only need the last DES3_EDE_BLOCK_SIZE bytes */
if (cmd_q->ccp->vdata->version == CCP_VERSION(3, 0))
dm_offset = CCP_SB_BYTES - des3->iv_len;
else
dm_offset = 0;
ccp_get_dm_area(&ctx, dm_offset, des3->iv, 0,
DES3_EDE_BLOCK_SIZE);
}
e_dst:
if (!in_place)
ccp_free_data(&dst, cmd_q);
e_src:
ccp_free_data(&src, cmd_q);
e_ctx:
if (des3->mode != CCP_DES3_MODE_ECB)
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;
unsigned int ioffset, ooffset;
unsigned int digest_size;
int sb_count;
const void *init;
u64 block_size;
int ctx_size;
int ret;
switch (sha->type) {
case CCP_SHA_TYPE_1:
if (sha->ctx_len < SHA1_DIGEST_SIZE)
return -EINVAL;
block_size = SHA1_BLOCK_SIZE;
break;
case CCP_SHA_TYPE_224:
if (sha->ctx_len < SHA224_DIGEST_SIZE)
return -EINVAL;
block_size = SHA224_BLOCK_SIZE;
break;
case CCP_SHA_TYPE_256:
if (sha->ctx_len < SHA256_DIGEST_SIZE)
return -EINVAL;
block_size = SHA256_BLOCK_SIZE;
break;
case CCP_SHA_TYPE_384:
if (cmd_q->ccp->vdata->version < CCP_VERSION(4, 0)
|| sha->ctx_len < SHA384_DIGEST_SIZE)
return -EINVAL;
block_size = SHA384_BLOCK_SIZE;
break;
case CCP_SHA_TYPE_512:
if (cmd_q->ccp->vdata->version < CCP_VERSION(4, 0)
|| sha->ctx_len < SHA512_DIGEST_SIZE)
return -EINVAL;
block_size = SHA512_BLOCK_SIZE;
break;
default:
return -EINVAL;
}
if (!sha->ctx)
return -EINVAL;
if (!sha->final && (sha->src_len & (block_size - 1)))
return -EINVAL;
/* The version 3 device can't handle zero-length input */
if (cmd_q->ccp->vdata->version == CCP_VERSION(3, 0)) {
if (!sha->src_len) {
unsigned int digest_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;
/* 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.
*/
switch (sha->type) {
case CCP_SHA_TYPE_1:
sha_zero = sha1_zero_message_hash;
digest_len = SHA1_DIGEST_SIZE;
break;
case CCP_SHA_TYPE_224:
sha_zero = sha224_zero_message_hash;
digest_len = SHA224_DIGEST_SIZE;
break;
case CCP_SHA_TYPE_256:
sha_zero = sha256_zero_message_hash;
digest_len = SHA256_DIGEST_SIZE;
break;
default:
return -EINVAL;
}
scatterwalk_map_and_copy((void *)sha_zero, sha->ctx, 0,
digest_len, 1);
return 0;
}
}
/* Set variables used throughout */
switch (sha->type) {
case CCP_SHA_TYPE_1:
digest_size = SHA1_DIGEST_SIZE;
init = (void *) ccp_sha1_init;
ctx_size = SHA1_DIGEST_SIZE;
sb_count = 1;
if (cmd_q->ccp->vdata->version != CCP_VERSION(3, 0))
ooffset = ioffset = CCP_SB_BYTES - SHA1_DIGEST_SIZE;
else
ooffset = ioffset = 0;
break;
case CCP_SHA_TYPE_224:
digest_size = SHA224_DIGEST_SIZE;
init = (void *) ccp_sha224_init;
ctx_size = SHA256_DIGEST_SIZE;
sb_count = 1;
ioffset = 0;
if (cmd_q->ccp->vdata->version != CCP_VERSION(3, 0))
ooffset = CCP_SB_BYTES - SHA224_DIGEST_SIZE;
else
ooffset = 0;
break;
case CCP_SHA_TYPE_256:
digest_size = SHA256_DIGEST_SIZE;
init = (void *) ccp_sha256_init;
ctx_size = SHA256_DIGEST_SIZE;
sb_count = 1;
ooffset = ioffset = 0;
break;
case CCP_SHA_TYPE_384:
digest_size = SHA384_DIGEST_SIZE;
init = (void *) ccp_sha384_init;
ctx_size = SHA512_DIGEST_SIZE;
sb_count = 2;
ioffset = 0;
ooffset = 2 * CCP_SB_BYTES - SHA384_DIGEST_SIZE;
break;
case CCP_SHA_TYPE_512:
digest_size = SHA512_DIGEST_SIZE;
init = (void *) ccp_sha512_init;
ctx_size = SHA512_DIGEST_SIZE;
sb_count = 2;
ooffset = ioffset = 0;
break;
default:
ret = -EINVAL;
goto e_data;
}
/* For zero-length plaintext the src pointer is ignored;
* otherwise both parts must be valid
*/
if (sha->src_len && !sha->src)
return -EINVAL;
memset(&op, 0, sizeof(op));
op.cmd_q = cmd_q;
op.jobid = CCP_NEW_JOBID(cmd_q->ccp);
op.sb_ctx = cmd_q->sb_ctx; /* Pre-allocated */
op.u.sha.type = sha->type;
op.u.sha.msg_bits = sha->msg_bits;
/* For SHA1/224/256 the context fits in a single (32-byte) SB entry;
* SHA384/512 require 2 adjacent SB slots, with the right half in the
* first slot, and the left half in the second. Each portion must then
* be in little endian format: use the 256-bit byte swap option.
*/
ret = ccp_init_dm_workarea(&ctx, cmd_q, sb_count * CCP_SB_BYTES,
DMA_BIDIRECTIONAL);
if (ret)
return ret;
if (sha->first) {
switch (sha->type) {
case CCP_SHA_TYPE_1:
case CCP_SHA_TYPE_224:
case CCP_SHA_TYPE_256:
memcpy(ctx.address + ioffset, init, ctx_size);
break;
case CCP_SHA_TYPE_384:
case CCP_SHA_TYPE_512:
memcpy(ctx.address + ctx_size / 2, init,
ctx_size / 2);
memcpy(ctx.address, init + ctx_size / 2,
ctx_size / 2);
break;
default:
ret = -EINVAL;
goto e_ctx;
}
} else {
/* Restore the context */
ret = ccp_set_dm_area(&ctx, 0, sha->ctx, 0,
sb_count * CCP_SB_BYTES);
if (ret)
goto e_ctx;
}
ret = ccp_copy_to_sb(cmd_q, &ctx, op.jobid, op.sb_ctx,
CCP_PASSTHRU_BYTESWAP_256BIT);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_ctx;
}
if (sha->src) {
/* Send data to the CCP SHA engine; block_size is set above */
ret = ccp_init_data(&src, cmd_q, sha->src, sha->src_len,
block_size, DMA_TO_DEVICE);
if (ret)
goto e_ctx;
while (src.sg_wa.bytes_left) {
ccp_prepare_data(&src, NULL, &op, block_size, false);
if (sha->final && !src.sg_wa.bytes_left)
op.eom = 1;
ret = cmd_q->ccp->vdata->perform->sha(&op);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_data;
}
ccp_process_data(&src, NULL, &op);
}
} else {
op.eom = 1;
ret = cmd_q->ccp->vdata->perform->sha(&op);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_data;
}
}
/* Retrieve the SHA context - convert from LE to BE using
* 32-byte (256-bit) byteswapping to BE
*/
ret = ccp_copy_from_sb(cmd_q, &ctx, op.jobid, op.sb_ctx,
CCP_PASSTHRU_BYTESWAP_256BIT);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_data;
}
if (sha->final) {
/* Finishing up, so get the digest */
switch (sha->type) {
case CCP_SHA_TYPE_1:
case CCP_SHA_TYPE_224:
case CCP_SHA_TYPE_256:
ccp_get_dm_area(&ctx, ooffset,
sha->ctx, 0,
digest_size);
break;
case CCP_SHA_TYPE_384:
case CCP_SHA_TYPE_512:
ccp_get_dm_area(&ctx, 0,
sha->ctx, LSB_ITEM_SIZE - ooffset,
LSB_ITEM_SIZE);
ccp_get_dm_area(&ctx, LSB_ITEM_SIZE + ooffset,
sha->ctx, 0,
LSB_ITEM_SIZE - ooffset);
break;
default:
ret = -EINVAL;
goto e_ctx;
}
} else {
/* Stash the context */
ccp_get_dm_area(&ctx, 0, sha->ctx, 0,
sb_count * CCP_SB_BYTES);
}
if (sha->final && sha->opad) {
/* HMAC operation, recursively perform final SHA */
struct ccp_cmd hmac_cmd;
struct scatterlist sg;
u8 *hmac_buf;
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);
switch (sha->type) {
case CCP_SHA_TYPE_1:
case CCP_SHA_TYPE_224:
case CCP_SHA_TYPE_256:
memcpy(hmac_buf + block_size,
ctx.address + ooffset,
digest_size);
break;
case CCP_SHA_TYPE_384:
case CCP_SHA_TYPE_512:
memcpy(hmac_buf + block_size,
ctx.address + LSB_ITEM_SIZE + ooffset,
LSB_ITEM_SIZE);
memcpy(hmac_buf + block_size +
(LSB_ITEM_SIZE - ooffset),
ctx.address,
LSB_ITEM_SIZE);
break;
default:
ret = -EINVAL;
goto e_ctx;
}
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:
if (sha->src)
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, dst;
struct ccp_op op;
unsigned int sb_count, i_len, o_len;
int ret;
/* Check against the maximum allowable size, in bits */
if (rsa->key_size > cmd_q->ccp->vdata->rsamax)
return -EINVAL;
if (!rsa->exp || !rsa->mod || !rsa->src || !rsa->dst)
return -EINVAL;
memset(&op, 0, sizeof(op));
op.cmd_q = cmd_q;
op.jobid = CCP_NEW_JOBID(cmd_q->ccp);
/* 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). Compute o_len, i_len in bytes.
* Buffer sizes must be a multiple of 32 bytes; rounding up may be
* required.
*/
o_len = 32 * ((rsa->key_size + 255) / 256);
i_len = o_len * 2;
sb_count = 0;
if (cmd_q->ccp->vdata->version < CCP_VERSION(5, 0)) {
/* sb_count is the number of storage block slots required
* for the modulus.
*/
sb_count = o_len / CCP_SB_BYTES;
op.sb_key = cmd_q->ccp->vdata->perform->sballoc(cmd_q,
sb_count);
if (!op.sb_key)
return -EIO;
} else {
/* A version 5 device allows a modulus size that will not fit
* in the LSB, so the command will transfer it from memory.
* Set the sb key to the default, even though it's not used.
*/
op.sb_key = cmd_q->sb_key;
}
/* The RSA exponent must be in little endian format. Reverse its
* byte order.
*/
ret = ccp_init_dm_workarea(&exp, cmd_q, o_len, DMA_TO_DEVICE);
if (ret)
goto e_sb;
ret = ccp_reverse_set_dm_area(&exp, 0, rsa->exp, 0, rsa->exp_len);
if (ret)
goto e_exp;
if (cmd_q->ccp->vdata->version < CCP_VERSION(5, 0)) {
/* Copy the exponent to the local storage block, using
* as many 32-byte blocks as were allocated above. It's
* already little endian, so no further change is required.
*/
ret = ccp_copy_to_sb(cmd_q, &exp, op.jobid, op.sb_key,
CCP_PASSTHRU_BYTESWAP_NOOP);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_exp;
}
} else {
/* The exponent can be retrieved from memory via DMA. */
op.exp.u.dma.address = exp.dma.address;
op.exp.u.dma.offset = 0;
}
/* 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;
ret = ccp_reverse_set_dm_area(&src, 0, rsa->mod, 0, rsa->mod_len);
if (ret)
goto e_src;
ret = ccp_reverse_set_dm_area(&src, o_len, rsa->src, 0, rsa->src_len);
if (ret)
goto e_src;
/* Prepare the output area for the operation */
ret = ccp_init_dm_workarea(&dst, cmd_q, 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.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 = cmd_q->ccp->vdata->perform->rsa(&op);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
goto e_dst;
}
ccp_reverse_get_dm_area(&dst, 0, rsa->dst, 0, rsa->mod_len);
e_dst:
ccp_dm_free(&dst);
e_src:
ccp_dm_free(&src);
e_exp:
ccp_dm_free(&exp);
e_sb:
if (sb_count)
cmd_q->ccp->vdata->perform->sbfree(cmd_q, op.sb_key, sb_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 = 0;
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_SB_COUNT != 1);
memset(&op, 0, sizeof(op));
op.cmd_q = cmd_q;
op.jobid = CCP_NEW_JOBID(cmd_q->ccp);
if (pt->bit_mod != CCP_PASSTHRU_BITWISE_NOOP) {
/* Load the mask */
op.sb_key = cmd_q->sb_key;
ret = ccp_init_dm_workarea(&mask, cmd_q,
CCP_PASSTHRU_SB_COUNT *
CCP_SB_BYTES,
DMA_TO_DEVICE);
if (ret)
return ret;
ret = ccp_set_dm_area(&mask, 0, pt->mask, 0, pt->mask_len);
if (ret)
goto e_mask;
ret = ccp_copy_to_sb(cmd_q, &mask, op.jobid, op.sb_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 = cmd_q->ccp->vdata->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_passthru_nomap_cmd(struct ccp_cmd_queue *cmd_q,
struct ccp_cmd *cmd)
{
struct ccp_passthru_nomap_engine *pt = &cmd->u.passthru_nomap;
struct ccp_dm_workarea mask;
struct ccp_op op;
int ret;
if (!pt->final && (pt->src_len & (CCP_PASSTHRU_BLOCKSIZE - 1)))
return -EINVAL;
if (!pt->src_dma || !pt->dst_dma)
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_SB_COUNT != 1);
memset(&op, 0, sizeof(op));
op.cmd_q = cmd_q;
op.jobid = CCP_NEW_JOBID(cmd_q->ccp);
if (pt->bit_mod != CCP_PASSTHRU_BITWISE_NOOP) {
/* Load the mask */
op.sb_key = cmd_q->sb_key;
mask.length = pt->mask_len;
mask.dma.address = pt->mask;
mask.dma.length = pt->mask_len;
ret = ccp_copy_to_sb(cmd_q, &mask, op.jobid, op.sb_key,
CCP_PASSTHRU_BYTESWAP_NOOP);
if (ret) {
cmd->engine_error = cmd_q->cmd_error;
return ret;
}
}
/* Send data to the CCP Passthru engine */
op.eom = 1;
op.soc = 1;
op.src.type = CCP_MEMTYPE_SYSTEM;
op.src.u.dma.address = pt->src_dma;
op.src.u.dma.offset = 0;
op.src.u.dma.length = pt->src_len;
op.dst.type = CCP_MEMTYPE_SYSTEM;
op.dst.u.dma.address = pt->dst_dma;
op.dst.u.dma.offset = 0;
op.dst.u.dma.length = pt->src_len;
ret = cmd_q->ccp->vdata->perform->passthru(&op);
if (ret)
cmd->engine_error = cmd_q->cmd_error;
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_NEW_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 */
ret = ccp_reverse_set_dm_area(&src, 0, ecc->mod, 0, ecc->mod_len);
if (ret)
goto e_src;
src.address += CCP_ECC_OPERAND_SIZE;
/* Copy the first operand */
ret = ccp_reverse_set_dm_area(&src, 0, ecc->u.mm.operand_1, 0,
ecc->u.mm.operand_1_len);
if (ret)
goto e_src;
src.address += CCP_ECC_OPERAND_SIZE;
if (ecc->function != CCP_ECC_FUNCTION_MINV_384BIT) {
/* Copy the second operand */
ret = ccp_reverse_set_dm_area(&src, 0, ecc->u.mm.operand_2, 0,
ecc->u.mm.operand_2_len);
if (ret)
goto e_src;
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 = cmd_q->ccp->vdata->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, 0, ecc->u.mm.result, 0,
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_NEW_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 */
ret = ccp_reverse_set_dm_area(&src, 0, ecc->mod, 0, ecc->mod_len);
if (ret)
goto e_src;
src.address += CCP_ECC_OPERAND_SIZE;
/* Copy the first point X and Y coordinate */
ret = ccp_reverse_set_dm_area(&src, 0, ecc->u.pm.point_1.x, 0,
ecc->u.pm.point_1.x_len);
if (ret)
goto e_src;
src.address += CCP_ECC_OPERAND_SIZE;
ret = ccp_reverse_set_dm_area(&src, 0, ecc->u.pm.point_1.y, 0,
ecc->u.pm.point_1.y_len);
if (ret)
goto e_src;
src.address += CCP_ECC_OPERAND_SIZE;
/* Set the first point Z coordinate 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 */
ret = ccp_reverse_set_dm_area(&src, 0, ecc->u.pm.point_2.x, 0,
ecc->u.pm.point_2.x_len);
if (ret)
goto e_src;
src.address += CCP_ECC_OPERAND_SIZE;
ret = ccp_reverse_set_dm_area(&src, 0, ecc->u.pm.point_2.y, 0,
ecc->u.pm.point_2.y_len);
if (ret)
goto e_src;
src.address += CCP_ECC_OPERAND_SIZE;
/* Set the second point Z coordinate to 1 */
*src.address = 0x01;
src.address += CCP_ECC_OPERAND_SIZE;
} else {
/* Copy the Domain "a" parameter */
ret = ccp_reverse_set_dm_area(&src, 0, ecc->u.pm.domain_a, 0,
ecc->u.pm.domain_a_len);
if (ret)
goto e_src;
src.address += CCP_ECC_OPERAND_SIZE;
if (ecc->function == CCP_ECC_FUNCTION_PMUL_384BIT) {
/* Copy the scalar value */
ret = ccp_reverse_set_dm_area(&src, 0,
ecc->u.pm.scalar, 0,
ecc->u.pm.scalar_len);
if (ret)
goto e_src;
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 = cmd_q->ccp->vdata->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, 0, ecc->u.pm.result.x, 0,
CCP_ECC_MODULUS_BYTES);
dst.address += CCP_ECC_OUTPUT_SIZE;
ccp_reverse_get_dm_area(&dst, 0, ecc->u.pm.result.y, 0,
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->ccp->vdata->perform->get_free_slots(cmd_q);
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_DES3:
ret = ccp_run_des3_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:
if (cmd->flags & CCP_CMD_PASSTHRU_NO_DMA_MAP)
ret = ccp_run_passthru_nomap_cmd(cmd_q, cmd);
else
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;
}