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0200020bc2
Freescale's SEC block has built-in Data Encryption Key(DEK) Blob Protocol which provides a method for protecting a DEK for non-secure memory storage. SEC block protects data in a data structure called a Secret Key Blob, which provides both confidentiality and integrity protection. Every time the blob encapsulation is executed, a AES-256 key is randomly generated to encrypt the DEK. This key is encrypted with the OTP Secret key from SoC. The resulting blob consists of the encrypted AES-256 key, the encrypted DEK, and a 16-bit MAC. During decapsulation, the reverse process is performed to get back the original DEK. A caveat to the blob decapsulation process, is that the DEK is decrypted in secure-memory and can only be read by FSL SEC HW. The DEK is used to decrypt data during encrypted boot. Commands added -------------- dek_blob - encapsulating DEK as a cryptgraphic blob Commands Syntax --------------- dek_blob src dst len Encapsulate and create blob of a len-bits DEK at address src and store the result at address dst. Signed-off-by: Raul Cardenas <Ulises.Cardenas@freescale.com> Signed-off-by: Nitin Garg <nitin.garg@freescale.com> Signed-off-by: Ulises Cardenas <ulises.cardenas@freescale.com> Signed-off-by: Ulises Cardenas-B45798 <Ulises.Cardenas@freescale.com>
298 lines
8.7 KiB
C
298 lines
8.7 KiB
C
/*
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* SEC Descriptor Construction Library
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* Basic job descriptor construction
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*
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* Copyright 2014 Freescale Semiconductor, Inc.
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*
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* SPDX-License-Identifier: GPL-2.0+
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*
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*/
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#include <common.h>
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#include <fsl_sec.h>
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#include "desc_constr.h"
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#include "jobdesc.h"
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#include "rsa_caam.h"
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#ifdef CONFIG_MX6
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/*!
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* Secure memory run command
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*
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* @param sec_mem_cmd Secure memory command register
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* @return cmd_status Secure memory command status register
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*/
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uint32_t secmem_set_cmd(uint32_t sec_mem_cmd)
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{
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uint32_t temp_reg;
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sec_out32(CAAM_SMCJR0, sec_mem_cmd);
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do {
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temp_reg = sec_in32(CAAM_SMCSJR0);
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} while (temp_reg & CMD_COMPLETE);
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return temp_reg;
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}
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/*!
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* CAAM page allocation:
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* Allocates a partition from secure memory, with the id
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* equal to partion_num. This will de-allocate the page
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* if it is already allocated. The partition will have
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* full access permissions. The permissions are set before,
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* running a job descriptor. A memory page of secure RAM
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* is allocated for the partition.
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*
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* @param page Number of the page to allocate.
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* @param partition Number of the partition to allocate.
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* @return 0 on success, ERROR_IN_PAGE_ALLOC otherwise
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*/
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int caam_page_alloc(uint8_t page_num, uint8_t partition_num)
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{
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uint32_t temp_reg;
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/*
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* De-Allocate partition_num if already allocated to ARM core
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*/
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if (sec_in32(CAAM_SMPO_0) & PARTITION_OWNER(partition_num)) {
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temp_reg = secmem_set_cmd(PARTITION(partition_num) |
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CMD_PART_DEALLOC);
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if (temp_reg & SMCSJR_AERR) {
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printf("Error: De-allocation status 0x%X\n", temp_reg);
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return ERROR_IN_PAGE_ALLOC;
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}
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}
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/* set the access rights to allow full access */
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sec_out32(CAAM_SMAG1JR0(partition_num), 0xF);
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sec_out32(CAAM_SMAG2JR0(partition_num), 0xF);
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sec_out32(CAAM_SMAPJR0(partition_num), 0xFF);
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/* Now need to allocate partition_num of secure RAM. */
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/* De-Allocate page_num by starting with a page inquiry command */
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temp_reg = secmem_set_cmd(PAGE(page_num) | CMD_INQUIRY);
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/* if the page is owned, de-allocate it */
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if ((temp_reg & SMCSJR_PO) == PAGE_OWNED) {
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temp_reg = secmem_set_cmd(PAGE(page_num) | CMD_PAGE_DEALLOC);
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if (temp_reg & SMCSJR_AERR) {
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printf("Error: Allocation status 0x%X\n", temp_reg);
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return ERROR_IN_PAGE_ALLOC;
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}
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}
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/* Allocate page_num to partition_num */
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temp_reg = secmem_set_cmd(PAGE(page_num) | PARTITION(partition_num)
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| CMD_PAGE_ALLOC);
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if (temp_reg & SMCSJR_AERR) {
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printf("Error: Allocation status 0x%X\n", temp_reg);
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return ERROR_IN_PAGE_ALLOC;
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}
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/* page inquiry command to ensure that the page was allocated */
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temp_reg = secmem_set_cmd(PAGE(page_num) | CMD_INQUIRY);
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/* if the page is not owned => problem */
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if ((temp_reg & SMCSJR_PO) != PAGE_OWNED) {
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printf("Allocation of page %d in partition %d failed 0x%X\n",
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temp_reg, page_num, partition_num);
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return ERROR_IN_PAGE_ALLOC;
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}
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return 0;
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}
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int inline_cnstr_jobdesc_blob_dek(uint32_t *desc, const uint8_t *plain_txt,
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uint8_t *dek_blob, uint32_t in_sz)
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{
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uint32_t ret = 0;
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u32 aad_w1, aad_w2;
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/* output blob will have 32 bytes key blob in beginning and
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* 16 byte HMAC identifier at end of data blob */
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uint32_t out_sz = in_sz + KEY_BLOB_SIZE + MAC_SIZE;
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/* Setting HDR for blob */
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uint8_t wrapped_key_hdr[8] = {HDR_TAG, 0x00, WRP_HDR_SIZE + out_sz,
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HDR_PAR, HAB_MOD, HAB_ALG, in_sz, HAB_FLG};
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/* initialize the blob array */
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memset(dek_blob, 0, out_sz + 8);
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/* Copy the header into the DEK blob buffer */
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memcpy(dek_blob, wrapped_key_hdr, sizeof(wrapped_key_hdr));
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/* allocating secure memory */
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ret = caam_page_alloc(PAGE_1, PARTITION_1);
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if (ret)
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return ret;
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/* Write DEK to secure memory */
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memcpy((uint32_t *)SEC_MEM_PAGE1, (uint32_t *)plain_txt, in_sz);
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unsigned long start = (unsigned long)SEC_MEM_PAGE1 &
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~(ARCH_DMA_MINALIGN - 1);
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unsigned long end = ALIGN(start + 0x1000, ARCH_DMA_MINALIGN);
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flush_dcache_range(start, end);
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/* Now configure the access rights of the partition */
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sec_out32(CAAM_SMAG1JR0(PARTITION_1), KS_G1); /* set group 1 */
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sec_out32(CAAM_SMAG2JR0(PARTITION_1), 0); /* clear group 2 */
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sec_out32(CAAM_SMAPJR0(PARTITION_1), PERM); /* set perm & locks */
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/* construct aad for AES */
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aad_w1 = (in_sz << OP_ALG_ALGSEL_SHIFT) | KEY_AES_SRC | LD_CCM_MODE;
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aad_w2 = 0x0;
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init_job_desc(desc, 0);
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append_cmd(desc, CMD_LOAD | CLASS_2 | KEY_IMM | KEY_ENC |
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(0x0c << LDST_OFFSET_SHIFT) | 0x08);
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append_u32(desc, aad_w1);
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append_u32(desc, aad_w2);
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append_cmd_ptr(desc, (dma_addr_t)SEC_MEM_PAGE1, in_sz, CMD_SEQ_IN_PTR);
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append_cmd_ptr(desc, (dma_addr_t)dek_blob + 8, out_sz, CMD_SEQ_OUT_PTR);
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append_operation(desc, OP_TYPE_ENCAP_PROTOCOL | OP_PCLID_BLOB |
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OP_PCLID_SECMEM);
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return ret;
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}
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#endif
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void inline_cnstr_jobdesc_hash(uint32_t *desc,
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const uint8_t *msg, uint32_t msgsz, uint8_t *digest,
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u32 alg_type, uint32_t alg_size, int sg_tbl)
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{
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/* SHA 256 , output is of length 32 words */
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uint32_t storelen = alg_size;
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u32 options;
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dma_addr_t dma_addr_in, dma_addr_out;
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dma_addr_in = virt_to_phys((void *)msg);
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dma_addr_out = virt_to_phys((void *)digest);
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init_job_desc(desc, 0);
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append_operation(desc, OP_TYPE_CLASS2_ALG |
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OP_ALG_AAI_HASH | OP_ALG_AS_INITFINAL |
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OP_ALG_ENCRYPT | OP_ALG_ICV_OFF | alg_type);
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options = LDST_CLASS_2_CCB | FIFOLD_TYPE_MSG | FIFOLD_TYPE_LAST2;
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if (sg_tbl)
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options |= FIFOLDST_SGF;
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if (msgsz > 0xffff) {
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options |= FIFOLDST_EXT;
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append_fifo_load(desc, dma_addr_in, 0, options);
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append_cmd(desc, msgsz);
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} else {
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append_fifo_load(desc, dma_addr_in, msgsz, options);
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}
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append_store(desc, dma_addr_out, storelen,
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LDST_CLASS_2_CCB | LDST_SRCDST_BYTE_CONTEXT);
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}
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void inline_cnstr_jobdesc_blob_encap(uint32_t *desc, uint8_t *key_idnfr,
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uint8_t *plain_txt, uint8_t *enc_blob,
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uint32_t in_sz)
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{
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dma_addr_t dma_addr_key_idnfr, dma_addr_in, dma_addr_out;
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uint32_t key_sz = KEY_IDNFR_SZ_BYTES;
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/* output blob will have 32 bytes key blob in beginning and
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* 16 byte HMAC identifier at end of data blob */
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uint32_t out_sz = in_sz + KEY_BLOB_SIZE + MAC_SIZE;
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dma_addr_key_idnfr = virt_to_phys((void *)key_idnfr);
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dma_addr_in = virt_to_phys((void *)plain_txt);
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dma_addr_out = virt_to_phys((void *)enc_blob);
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init_job_desc(desc, 0);
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append_key(desc, dma_addr_key_idnfr, key_sz, CLASS_2);
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append_seq_in_ptr(desc, dma_addr_in, in_sz, 0);
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append_seq_out_ptr(desc, dma_addr_out, out_sz, 0);
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append_operation(desc, OP_TYPE_ENCAP_PROTOCOL | OP_PCLID_BLOB);
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}
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void inline_cnstr_jobdesc_blob_decap(uint32_t *desc, uint8_t *key_idnfr,
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uint8_t *enc_blob, uint8_t *plain_txt,
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uint32_t out_sz)
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{
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dma_addr_t dma_addr_key_idnfr, dma_addr_in, dma_addr_out;
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uint32_t key_sz = KEY_IDNFR_SZ_BYTES;
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uint32_t in_sz = out_sz + KEY_BLOB_SIZE + MAC_SIZE;
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dma_addr_key_idnfr = virt_to_phys((void *)key_idnfr);
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dma_addr_in = virt_to_phys((void *)enc_blob);
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dma_addr_out = virt_to_phys((void *)plain_txt);
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init_job_desc(desc, 0);
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append_key(desc, dma_addr_key_idnfr, key_sz, CLASS_2);
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append_seq_in_ptr(desc, dma_addr_in, in_sz, 0);
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append_seq_out_ptr(desc, dma_addr_out, out_sz, 0);
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append_operation(desc, OP_TYPE_DECAP_PROTOCOL | OP_PCLID_BLOB);
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}
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/*
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* Descriptor to instantiate RNG State Handle 0 in normal mode and
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* load the JDKEK, TDKEK and TDSK registers
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*/
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void inline_cnstr_jobdesc_rng_instantiation(uint32_t *desc)
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{
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u32 *jump_cmd;
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init_job_desc(desc, 0);
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/* INIT RNG in non-test mode */
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append_operation(desc, OP_TYPE_CLASS1_ALG | OP_ALG_ALGSEL_RNG |
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OP_ALG_AS_INIT);
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/* wait for done */
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jump_cmd = append_jump(desc, JUMP_CLASS_CLASS1);
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set_jump_tgt_here(desc, jump_cmd);
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/*
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* load 1 to clear written reg:
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* resets the done interrrupt and returns the RNG to idle.
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*/
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append_load_imm_u32(desc, 1, LDST_SRCDST_WORD_CLRW);
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/* generate secure keys (non-test) */
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append_operation(desc, OP_TYPE_CLASS1_ALG | OP_ALG_ALGSEL_RNG |
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OP_ALG_RNG4_SK);
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}
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/* Change key size to bytes form bits in calling function*/
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void inline_cnstr_jobdesc_pkha_rsaexp(uint32_t *desc,
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struct pk_in_params *pkin, uint8_t *out,
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uint32_t out_siz)
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{
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dma_addr_t dma_addr_e, dma_addr_a, dma_addr_n, dma_addr_out;
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dma_addr_e = virt_to_phys((void *)pkin->e);
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dma_addr_a = virt_to_phys((void *)pkin->a);
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dma_addr_n = virt_to_phys((void *)pkin->n);
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dma_addr_out = virt_to_phys((void *)out);
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init_job_desc(desc, 0);
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append_key(desc, dma_addr_e, pkin->e_siz, KEY_DEST_PKHA_E | CLASS_1);
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append_fifo_load(desc, dma_addr_a,
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pkin->a_siz, LDST_CLASS_1_CCB | FIFOLD_TYPE_PK_A);
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append_fifo_load(desc, dma_addr_n,
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pkin->n_siz, LDST_CLASS_1_CCB | FIFOLD_TYPE_PK_N);
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append_operation(desc, OP_TYPE_PK | OP_ALG_PK | OP_ALG_PKMODE_MOD_EXPO);
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append_fifo_store(desc, dma_addr_out, out_siz,
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LDST_CLASS_1_CCB | FIFOST_TYPE_PKHA_B);
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}
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