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gerrit.openbmc.org / openbmc / google-misc / 7a33704c7ac7972f0ff05f99ec243a5f1fe020d8 / . / subprojects / libcr51sign / libcr51sign.c
blob: 5546f86e1e3f14eb3335f0581eae982a3ccee162 [file] [log] [blame]
/*
* Copyright 2021 Google LLC
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "libcr51sign.h"
#include <assert.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#ifdef __cplusplus
extern "C"
{
#endif
#ifndef USER_PRINT
#define CPRINTS(ctx, format, args...) printf(format, ##args)
#endif
#define MEMBER_SIZE(type, field) sizeof(((type*)0)->field)
// True of x is a power of two
#define POWER_OF_TWO(x) ((x) && !((x) & ((x)-1)))
// Maximum version supported. Major revisions are not backwards compatible.
#define MAX_MAJOR_VERSION 1
#define MAX_REGION_COUNT 16
// Descriptor alignment on the external EEPROM.
#define DESCRIPTOR_ALIGNMENT (64 * 1024)
// SPS EEPROM sector size is 4KiB, since this is the smallest erasable size.
#define IMAGE_REGION_ALIGNMENT 4096
#define MAX_READ_SIZE 1024
#ifndef ARRAY_SIZE
#define ARRAY_SIZE(t) (sizeof(t) / sizeof(t[0]))
#endif
// Values of SIGNATURE_OFFSET shuold be same for all sig types (2048,3072,4096)
#define SIGNATURE_OFFSET offsetof(struct signature_rsa3072_pkcs15, modulus)
#ifndef BUILD_ASSERT
#define BUILD_ASSERT(cond) ((void)sizeof(char[1 - 2 * !(cond)]))
#endif
typedef enum libcr51sign_validation_failure_reason failure_reason;
// Returns the bytes size of keys used in the given signature_scheme.
// Return error if signature_scheme is invalid.
//
static failure_reason get_key_size(enum signature_scheme signature_scheme,
uint16_t* key_size)
{
switch (signature_scheme)
{
case SIGNATURE_RSA2048_PKCS15:
*key_size = 256;
return LIBCR51SIGN_SUCCESS;
case SIGNATURE_RSA3072_PKCS15:
*key_size = 384;
return LIBCR51SIGN_SUCCESS;
case SIGNATURE_RSA4096_PKCS15:
case SIGNATURE_RSA4096_PKCS15_SHA512:
*key_size = 512;
return LIBCR51SIGN_SUCCESS;
default:
return LIBCR51SIGN_ERROR_INVALID_SIG_SCHEME;
}
}
// Returns the hash_type for a given signature scheme
// Returns error if scheme is invalid.
failure_reason get_hash_type_from_signature(enum signature_scheme scheme,
enum hash_type* type)
{
switch (scheme)
{
case SIGNATURE_RSA2048_PKCS15:
case SIGNATURE_RSA3072_PKCS15:
case SIGNATURE_RSA4096_PKCS15:
*type = HASH_SHA2_256;
return LIBCR51SIGN_SUCCESS;
case SIGNATURE_RSA4096_PKCS15_SHA512:
*type = HASH_SHA2_512;
return LIBCR51SIGN_SUCCESS;
default:
return LIBCR51SIGN_ERROR_INVALID_SIG_SCHEME;
}
}
// Check if the given hash_type is supported.
// Returns error if hash_type is not supported.
static failure_reason is_hash_type_supported(enum hash_type type)
{
switch (type)
{
case HASH_SHA2_256:
case HASH_SHA2_512:
return LIBCR51SIGN_SUCCESS;
default:
return LIBCR51SIGN_ERROR_INVALID_HASH_TYPE;
}
}
// Determines digest size for a given hash_type.
// Returns error if hash_type is not supported.
static failure_reason get_hash_digest_size(enum hash_type type,
uint32_t* size)
{
switch (type)
{
case HASH_SHA2_256:
*size = SHA256_DIGEST_SIZE;
return LIBCR51SIGN_SUCCESS;
case HASH_SHA2_512:
*size = SHA512_DIGEST_SIZE;
return LIBCR51SIGN_SUCCESS;
default:
return LIBCR51SIGN_ERROR_INVALID_HASH_TYPE;
}
}
// Determines hash struct size for a given hash_type.
// Returns error if hash_type is not supported.
static failure_reason get_hash_struct_size(enum hash_type type,
uint32_t* size)
{
switch (type)
{
case HASH_SHA2_256:
*size = sizeof(struct hash_sha256);
return LIBCR51SIGN_SUCCESS;
case HASH_SHA2_512:
*size = sizeof(struct hash_sha256);
return LIBCR51SIGN_SUCCESS;
default:
return LIBCR51SIGN_ERROR_INVALID_HASH_TYPE;
}
}
// Checks that:
// - The signing key is trusted
// - The target version is not denylisted
// If validating a staged update, also checks that:
// - The target image family matches the current image family
// - The image type transition is legal (i.e. dev -> *|| prod -> prod) or
// alternatively that the hardware ID is allowlisted
// Assuming the caller has performed following:
// board_get_base_key_index();
// board_get_key_array
// Possible return codes:
// LIBCR51SIGN_SUCCESS = 0,
// LIBCR51SIGN_ERROR_RUNTIME_FAILURE = 1,
// LIBCR51SIGN_ERROR_INVALID_DESCRIPTOR = 3,
// LIBCR51SIGN_ERROR_INVALID_IMAGE_FAMILY = 4,
// LIBCR51SIGN_ERROR_IMAGE_TYPE_DISALLOWED = 5,
static failure_reason
validate_transition(const struct libcr51sign_ctx* ctx,
const struct libcr51sign_intf* intf,
uint32_t signature_struct_offset)
{
BUILD_ASSERT((offsetof(struct signature_rsa2048_pkcs15, modulus) ==
SIGNATURE_OFFSET &&
offsetof(struct signature_rsa3072_pkcs15, modulus) ==
SIGNATURE_OFFSET &&
offsetof(struct signature_rsa4096_pkcs15, modulus) ==
SIGNATURE_OFFSET));
// Read up to the modulus.
const uint32_t read_len = SIGNATURE_OFFSET;
uint8_t buffer[read_len];
// "modulus" & "signature" will not be indexed.
struct signature_rsa4096_pkcs15* sig_data = (void*)&buffer;
int rv;
rv = intf->read(ctx, signature_struct_offset, read_len, buffer);
if (rv != LIBCR51SIGN_SUCCESS)
{
CPRINTS(ctx,
"validate_transition: failed to read signature struct");
return LIBCR51SIGN_ERROR_RUNTIME_FAILURE;
}
if (sig_data->signature_magic != SIGNATURE_MAGIC)
{
CPRINTS(ctx, "validate_transition: bad signature magic");
return LIBCR51SIGN_ERROR_INVALID_DESCRIPTOR;
}
if (ctx->descriptor.image_family != ctx->current_image_family &&
ctx->descriptor.image_family != IMAGE_FAMILY_ALL &&
ctx->current_image_family != IMAGE_FAMILY_ALL)
{
CPRINTS(ctx, "validate_transition: invalid image family");
return LIBCR51SIGN_ERROR_INVALID_IMAGE_FAMILY;
}
if (!intf->is_production_mode)
{
CPRINTS(ctx, "validate_transition: missing is_production_mode");
return LIBCR51SIGN_ERROR_INVALID_INTERFACE;
}
if (intf->is_production_mode() &&
(ctx->descriptor.image_type == IMAGE_DEV))
{
CPRINTS(ctx, "validate_transition: checking exemption allowlist");
if (!intf->prod_to_dev_downgrade_allowed)
{
return LIBCR51SIGN_SUCCESS;
}
else if (!intf->prod_to_dev_downgrade_allowed())
{
CPRINTS(ctx, "validate_transition: illegal image type");
return LIBCR51SIGN_ERROR_DEV_DOWNGRADE_DISALLOWED;
}
}
return LIBCR51SIGN_SUCCESS;
}
// If caller had provided read_and_hash_update call that, otherwise call
// read and then update.
static failure_reason
read_and_hash_update(const struct libcr51sign_ctx* ctx,
const struct libcr51sign_intf* intf,
uint32_t offset, uint32_t size)
{
uint8_t read_buffer[MAX_READ_SIZE];
int rv;
int read_size;
if (intf->read_and_hash_update)
{
rv = intf->read_and_hash_update((void*)ctx, offset, size);
}
else
{
if (!intf->hash_update)
{
CPRINTS(ctx, "read_and_hash_update: missing hash_update");
return LIBCR51SIGN_ERROR_INVALID_INTERFACE;
}
do
{
read_size = size < MAX_READ_SIZE ? size : MAX_READ_SIZE;
rv = intf->read((void*)ctx, offset, read_size, read_buffer);
if (rv != LIBCR51SIGN_SUCCESS)
{
return LIBCR51SIGN_ERROR_RUNTIME_FAILURE;
}
rv = intf->hash_update((void*)ctx, read_buffer, read_size);
if (rv != LIBCR51SIGN_SUCCESS)
{
return LIBCR51SIGN_ERROR_RUNTIME_FAILURE;
}
offset += read_size;
size -= read_size;
} while (size > 0);
}
return rv;
}
// Validates the image_region array, namely that:
// - The regions are aligned, contiguous & exhaustive
// - That the image descriptor resides in a static region
//
// If the array is consistent, proceeds to hash the static regions and
// validates the hash. d_offset is the absolute image descriptor offset
static failure_reason
validate_payload_regions(const struct libcr51sign_ctx* ctx,
struct libcr51sign_intf* intf,
uint32_t d_offset)
{
// Allocate buffer to accomodate largest supported hash-type(SHA512)
uint8_t magic_and_digest[MEMBER_SIZE(struct hash_sha512, hash_magic) +
SHA512_DIGEST_SIZE];
uint8_t dcrypto_digest[SHA512_DIGEST_SIZE];
struct image_region regions[MAX_REGION_COUNT];
uint32_t byte_count, region_count, image_size, hash_offset, digest_size;
uint8_t d_region_num = 0;
int i, rv;
BUILD_ASSERT((MEMBER_SIZE(struct hash_sha256, hash_magic) ==
MEMBER_SIZE(struct hash_sha512, hash_magic)));
image_size = ctx->descriptor.image_size;
region_count = ctx->descriptor.region_count;
hash_offset = d_offset + sizeof(struct image_descriptor) +
region_count * sizeof(struct image_region);
// Read the image_region array.
rv = intf->read(
ctx, d_offset + offsetof(struct image_descriptor, image_regions),
region_count * sizeof(struct image_region), (uint8_t*)&regions);
if (rv != LIBCR51SIGN_SUCCESS)
{
CPRINTS(ctx,
"validate_payload_regions: failed to read region array");
return LIBCR51SIGN_ERROR_RUNTIME_FAILURE;
}
// Validate that the regions are contiguous & exhaustive.
for (i = 0, byte_count = 0; i < region_count; i++)
{
CPRINTS(ctx,
"validate_payload_regions: region #%d \"%s\" (%x - %x)", i,
regions[i].region_name, regions[i].region_offset,
regions[i].region_offset + regions[i].region_size);
if ((regions[i].region_offset % IMAGE_REGION_ALIGNMENT) != 0 ||
(regions[i].region_size % IMAGE_REGION_ALIGNMENT) != 0)
{
CPRINTS(
ctx,
"validate_payload_regions: regions must be sector aligned");
return LIBCR51SIGN_ERROR_INVALID_DESCRIPTOR;
}
if (regions[i].region_offset != byte_count ||
regions[i].region_size > image_size - byte_count)
{
CPRINTS(ctx, "validate_payload_regions: invalid region array");
return LIBCR51SIGN_ERROR_INVALID_DESCRIPTOR;
}
byte_count += regions[i].region_size;
// The image descriptor must be part of a static region.
if (d_offset >= regions[i].region_offset && d_offset < byte_count)
{
d_region_num = i;
CPRINTS(
ctx,
"validate_payload_regions: image descriptor in region %d",
i);
// The descriptor can't span regions.
if (ctx->descriptor.descriptor_area_size > byte_count ||
!(regions[i].region_attributes & IMAGE_REGION_STATIC))
{
CPRINTS(
ctx,
"validate_payload_regions: descriptor must reside in "
"static region");
return LIBCR51SIGN_ERROR_INVALID_DESCRIPTOR;
}
}
}
if (byte_count != image_size)
{
CPRINTS(ctx, "validate_payload_regions: invalid image size");
return LIBCR51SIGN_ERROR_INVALID_DESCRIPTOR;
}
rv = get_hash_digest_size(ctx->descriptor.hash_type, &digest_size);
if (rv != LIBCR51SIGN_SUCCESS)
{
return rv;
}
rv = intf->read(ctx, hash_offset,
MEMBER_SIZE(struct hash_sha256, hash_magic) +
digest_size,
magic_and_digest);
if (rv != LIBCR51SIGN_SUCCESS)
{
CPRINTS(ctx,
"validate_payload_regions: failed to read hash from flash");
return LIBCR51SIGN_ERROR_RUNTIME_FAILURE;
}
if (*(uint32_t*)magic_and_digest != HASH_MAGIC)
{
CPRINTS(ctx, "validate_payload_regions: bad hash magic");
return LIBCR51SIGN_ERROR_INVALID_DESCRIPTOR;
}
rv = intf->hash_init(ctx, ctx->descriptor.hash_type);
if (rv != LIBCR51SIGN_SUCCESS)
{
CPRINTS(ctx, "validate_payload_regions: hash_init failed");
return LIBCR51SIGN_ERROR_RUNTIME_FAILURE;
}
for (i = 0; i < region_count; i++)
{
uint32_t hash_start, hash_size;
if (!(regions[i].region_attributes & IMAGE_REGION_STATIC))
{
continue;
}
hash_start = regions[i].region_offset;
hash_size = regions[i].region_size;
// Skip the descriptor.
do
{
if (i == d_region_num)
{
hash_size = d_offset - hash_start;
}
if (!hash_size)
{
hash_start += ctx->descriptor.descriptor_area_size;
hash_size = (regions[i].region_offset +
regions[i].region_size - hash_start);
}
CPRINTS("validate_payload_regions: hashing %s (%x - %x)",
regions[i].region_name, hash_start,
hash_start + hash_size);
// Read the image_region array.
rv = read_and_hash_update(ctx, intf, hash_start, hash_size);
if (rv != LIBCR51SIGN_SUCCESS)
{
return rv;
}
hash_start += hash_size;
} while (hash_start !=
regions[i].region_offset + regions[i].region_size);
}
rv = intf->hash_final((void*)ctx, (uint8_t*)dcrypto_digest);
if (rv != LIBCR51SIGN_SUCCESS)
{
return LIBCR51SIGN_ERROR_RUNTIME_FAILURE;
}
if (memcmp(magic_and_digest +
MEMBER_SIZE(struct hash_sha256, hash_magic),
dcrypto_digest, digest_size))
{
CPRINTS(ctx, "validate_payload_regions: invalid hash");
return LIBCR51SIGN_ERROR_INVALID_HASH;
}
// Image is valid.
return LIBCR51SIGN_SUCCESS;
}
// Check if the given signature_scheme is supported.
// Returns nonzero on error, zero on success
static failure_reason
is_signature_scheme_supported(enum signature_scheme scheme)
{
switch (scheme)
{
case SIGNATURE_RSA2048_PKCS15:
case SIGNATURE_RSA3072_PKCS15:
case SIGNATURE_RSA4096_PKCS15:
case SIGNATURE_RSA4096_PKCS15_SHA512:
return LIBCR51SIGN_SUCCESS;
default:
return LIBCR51SIGN_ERROR_INVALID_SIG_SCHEME;
}
}
// Returns size of signature struct size in |size|
// Returns nonzero on error, zero on success
static failure_reason
get_signature_struct_size(enum signature_scheme scheme, uint32_t* size)
{
switch (scheme)
{
case SIGNATURE_RSA2048_PKCS15:
*size = sizeof(struct signature_rsa2048_pkcs15);
return LIBCR51SIGN_SUCCESS;
case SIGNATURE_RSA3072_PKCS15:
*size = sizeof(struct signature_rsa3072_pkcs15);
return LIBCR51SIGN_SUCCESS;
case SIGNATURE_RSA4096_PKCS15:
case SIGNATURE_RSA4096_PKCS15_SHA512:
*size = sizeof(struct signature_rsa4096_pkcs15);
return LIBCR51SIGN_SUCCESS;
default:
return LIBCR51SIGN_ERROR_INVALID_SIG_SCHEME;
}
}
static failure_reason
get_signature_field_offset(enum signature_scheme scheme,
uint32_t* offset)
{
switch (scheme)
{
case SIGNATURE_RSA2048_PKCS15:
*offset = offsetof(struct signature_rsa2048_pkcs15, signature);
return LIBCR51SIGN_SUCCESS;
case SIGNATURE_RSA3072_PKCS15:
*offset = offsetof(struct signature_rsa3072_pkcs15, signature);
return LIBCR51SIGN_SUCCESS;
case SIGNATURE_RSA4096_PKCS15:
case SIGNATURE_RSA4096_PKCS15_SHA512:
*offset = offsetof(struct signature_rsa4096_pkcs15, signature);
return LIBCR51SIGN_SUCCESS;
default:
return LIBCR51SIGN_ERROR_INVALID_SIG_SCHEME;
}
}
// Validates the signature (of type scheme) read from "device" at
//"raw_signature_offset" with "public_key" over a SHA256/SHA512 digest of
// EEPROM area "data_offset:data_size".
static failure_reason validate_signature(
const struct libcr51sign_ctx* ctx, const struct libcr51sign_intf* intf,
uint32_t data_offset, uint32_t data_size, enum signature_scheme scheme,
uint32_t raw_signature_offset)
{
uint8_t signature[MAX_SIGNATURE_SIZE];
uint16_t key_size;
uint32_t digest_size;
uint8_t dcrypto_digest[SHA512_DIGEST_SIZE];
int rv;
enum hash_type hash_type;
if (!intf->hash_init)
{
CPRINTS(ctx, "validate_signature: missing hash_init");
return LIBCR51SIGN_ERROR_INVALID_INTERFACE;
}
rv = get_hash_type_from_signature(scheme, &hash_type);
if (rv != LIBCR51SIGN_SUCCESS)
{
CPRINTS(
ctx,
"validate_payload_regions: hash_type from signature failed");
return rv;
}
rv = intf->hash_init(ctx, hash_type);
if (rv != LIBCR51SIGN_SUCCESS)
{
CPRINTS(ctx, "validate_payload_regions: hash_init failed");
return LIBCR51SIGN_ERROR_RUNTIME_FAILURE;
}
rv = read_and_hash_update(ctx, intf, data_offset, data_size);
if (rv != LIBCR51SIGN_SUCCESS)
{
CPRINTS(ctx, "validate_signature: hash_update failed");
return rv;
}
if (!intf->hash_final)
{
CPRINTS(ctx, "validate_signature: missing hash_final");
return LIBCR51SIGN_ERROR_INVALID_INTERFACE;
}
rv = intf->hash_final((void*)ctx, dcrypto_digest);
if (rv != LIBCR51SIGN_SUCCESS)
{
CPRINTS(ctx, "validate_signature: hash_final failed (status = %d)",
rv);
return LIBCR51SIGN_ERROR_RUNTIME_FAILURE;
}
rv = get_key_size(scheme, &key_size);
if (rv != LIBCR51SIGN_SUCCESS)
{
return rv;
}
rv = intf->read(ctx, raw_signature_offset, key_size, signature);
if (rv != LIBCR51SIGN_SUCCESS)
{
CPRINTS(
ctx,
"validate_signature: failed to read signature (status = %d)",
rv);
return LIBCR51SIGN_ERROR_RUNTIME_FAILURE;
}
if (!intf->verify_signature)
{
CPRINTS(ctx, "validate_signature: missing verify_signature");
return LIBCR51SIGN_ERROR_INVALID_INTERFACE;
}
rv = get_hash_digest_size(hash_type, &digest_size);
if (rv != LIBCR51SIGN_SUCCESS)
{
return rv;
}
rv = intf->verify_signature(ctx, scheme, signature, key_size,
dcrypto_digest, digest_size);
if (rv != LIBCR51SIGN_SUCCESS)
{
CPRINTS(ctx,
"validate_signature: verification failed (status = %d)",
rv);
return LIBCR51SIGN_ERROR_INVALID_SIGNATURE;
}
CPRINTS(ctx, "validate_signature: verification succeeded");
return LIBCR51SIGN_SUCCESS;
}
// Sanity checks the image descriptor & validates its signature.
// This function does not validate the image_region array or image hash.
//
//@param[in] ctx context which describes the image and holds opaque private
// data for the user of the library
//@param[in] intf function pointers which interface to the current system
// and environment
//@param offset Absolute image descriptor flash offset.
//@param relative_offset Image descriptor offset relative to image start.
//@param image_size Image size in bytes.
//@param descriptor Output pointer to an image_descriptor struct
static failure_reason validate_descriptor(
const struct libcr51sign_ctx* ctx, const struct libcr51sign_intf* intf,
uint32_t offset, uint32_t relative_offset, uint32_t image_size)
{
uint32_t max_descriptor_size, signed_size, signature_scheme,
signature_offset;
uint32_t signature_struct_offset, signature_struct_size,
hash_struct_size;
int rv;
max_descriptor_size = image_size - relative_offset;
if (image_size < relative_offset ||
max_descriptor_size < sizeof(struct image_descriptor))
{
CPRINTS(ctx, "validate_descriptor: invalid arguments");
return LIBCR51SIGN_ERROR_INVALID_DESCRIPTOR;
}
rv = intf->read(ctx, offset, sizeof(ctx->descriptor),
(uint8_t*)&ctx->descriptor);
if (rv != LIBCR51SIGN_SUCCESS)
{
CPRINTS(ctx, "validate_descriptor: failed to read descriptor");
return LIBCR51SIGN_ERROR_RUNTIME_FAILURE;
}
if (ctx->descriptor.descriptor_magic != DESCRIPTOR_MAGIC ||
ctx->descriptor.descriptor_offset != relative_offset ||
ctx->descriptor.region_count == 0 ||
ctx->descriptor.descriptor_area_size > max_descriptor_size ||
ctx->descriptor.image_size != image_size)
{
CPRINTS(ctx, "validate_descriptor: invalid descriptor");
return LIBCR51SIGN_ERROR_INVALID_DESCRIPTOR;
}
if (ctx->descriptor.image_type != IMAGE_DEV &&
ctx->descriptor.image_type != IMAGE_PROD &&
ctx->descriptor.image_type != IMAGE_BREAKOUT &&
ctx->descriptor.image_type != IMAGE_TEST &&
ctx->descriptor.image_type != IMAGE_SELF)
{
CPRINTS(ctx, "validate_descriptor: bad image type");
return LIBCR51SIGN_ERROR_INVALID_DESCRIPTOR;
}
// Although the image_descriptor struct supports unauthenticated
// images, Haven will not allow it.
// Haven only supports SHA256 + RSA2048/RSA3072_PKCS15 currently.
signature_scheme = ctx->descriptor.signature_scheme;
rv = is_signature_scheme_supported(signature_scheme);
if (rv != LIBCR51SIGN_SUCCESS)
{
return rv;
}
rv = is_hash_type_supported(ctx->descriptor.hash_type);
if (rv != LIBCR51SIGN_SUCCESS)
{
CPRINTS(ctx, "validate_payload_regions: invalid hash type");
return rv;
}
if (ctx->descriptor.descriptor_major > MAX_MAJOR_VERSION ||
ctx->descriptor.region_count > MAX_REGION_COUNT)
{
CPRINTS(ctx, "validate_descriptor: unsupported descriptor");
return LIBCR51SIGN_ERROR_UNSUPPORTED_DESCRIPTOR;
}
rv =
get_signature_struct_size(signature_scheme, &signature_struct_size);
if (rv != LIBCR51SIGN_SUCCESS)
{
return rv;
}
// Compute the size of the signed portion of the image descriptor.
signed_size =
sizeof(struct image_descriptor) +
ctx->descriptor.region_count * sizeof(struct image_region);
rv = get_hash_struct_size(ctx->descriptor.hash_type, &hash_struct_size);
if (rv != LIBCR51SIGN_SUCCESS)
{
return rv;
}
signed_size += hash_struct_size;
if (ctx->descriptor.denylist_size)
{
signed_size += sizeof(struct denylist);
signed_size +=
ctx->descriptor.denylist_size * sizeof(struct denylist_record);
}
if (ctx->descriptor.blob_size)
{
signed_size += sizeof(struct blob);
// Previous additions are guaranteed not to overflow.
if (ctx->descriptor.blob_size >
ctx->descriptor.descriptor_area_size - signed_size)
{
CPRINTS(ctx, "validate_descriptor: invalid blob size (0x%x)",
ctx->descriptor.blob_size);
return LIBCR51SIGN_ERROR_INVALID_DESCRIPTOR;
}
signed_size += ctx->descriptor.blob_size;
}
if (signature_struct_size >
ctx->descriptor.descriptor_area_size - signed_size)
{
CPRINTS(ctx,
"validate_descriptor: invalid descriptor area size "
"(expected = 0x%x, actual = 0x%x)",
ctx->descriptor.descriptor_area_size,
signed_size + signature_struct_size);
return LIBCR51SIGN_ERROR_INVALID_DESCRIPTOR;
}
signature_struct_offset = signed_size;
// Omit the actual signature.
rv = get_signature_field_offset(signature_scheme, &signature_offset);
if (rv != LIBCR51SIGN_SUCCESS)
{
return rv;
}
signed_size += signature_offset;
// Lookup key & validate transition.
rv = validate_transition(ctx, intf, offset + signature_struct_offset);
if (rv != LIBCR51SIGN_SUCCESS)
{
return rv;
}
return validate_signature(ctx, intf, offset, signed_size,
signature_scheme, offset + signed_size);
}
// Scans the external EEPROM for a magic value at "alignment" boundaries.
//
//@param device Handle to the external EEPROM.
//@param magic 8-byte pattern to search for.
//@param start_offset Offset to begin searching at.
//@param limit Exclusive address (e.g. EEPROM size).
//@param alignment Alignment boundaries (POW2) to search on.
//@param header_offset Location to place the new header offset.
//@return LIBCR51SIGN_SUCCESS (or non-zero on error).
int scan_for_magic_8(const struct libcr51sign_ctx* ctx,
const struct libcr51sign_intf* intf, uint64_t magic,
uint32_t start_offset, uint32_t limit,
uint32_t alignment, uint32_t* header_offset)
{
uint64_t read_data;
uint32_t offset;
int rv;
if (limit <= start_offset || limit > ctx->end_offset ||
limit < sizeof(magic) || !POWER_OF_TWO(alignment))
{
return LIBCR51SIGN_ERROR_INVALID_ARGUMENT;
}
if (!intf->read)
{
CPRINTS(ctx, "scan_for_magic_8: missing intf->read");
return LIBCR51SIGN_ERROR_INVALID_INTERFACE;
}
// Align start_offset to the next valid boundary.
start_offset = ((start_offset - 1) & ~(alignment - 1)) + alignment;
for (offset = start_offset; offset < limit - sizeof(magic);
offset += alignment)
{
rv = intf->read((void*)ctx, offset, sizeof(read_data),
(uint8_t*)&read_data);
if (rv != LIBCR51SIGN_SUCCESS)
{
return rv;
}
if (read_data == magic)
{
if (header_offset)
{
*header_offset = offset;
}
return LIBCR51SIGN_SUCCESS;
}
}
// Failed to locate magic.
return LIBCR51SIGN_ERROR_FAILED_TO_LOCATE_MAGIC;
}
// Check whether the signature on the image is valid.
// Validates the authenticity of an EEPROM image. Scans for & validates the
// signature on the image descriptor. If the descriptor validates, hashes
// the rest of the image to verify its integrity.
//
// @param[in] ctx - context which describes the image and holds opaque
// private
// data for the user of the library
// @param[in] intf - function pointers which interface to the current system
// and environment
//
// @return nonzero on error, zero on success
failure_reason libcr51sign_validate(const struct libcr51sign_ctx* ctx,
struct libcr51sign_intf* intf)
{
uint32_t image_limit = 0;
int rv, rv_first_desc = LIBCR51SIGN_SUCCESS;
uint32_t descriptor_offset;
if (!ctx)
{
CPRINTS(ctx, "MIssing context");
return LIBCR51SIGN_ERROR_INVALID_CONTEXT;
}
else if (!intf)
{
CPRINTS(ctx, "Missing interface");
return LIBCR51SIGN_ERROR_INVALID_INTERFACE;
}
rv = scan_for_magic_8(ctx, intf, DESCRIPTOR_MAGIC, ctx->start_offset,
ctx->end_offset, DESCRIPTOR_ALIGNMENT,
&descriptor_offset);
while (rv == LIBCR51SIGN_SUCCESS)
{
CPRINTS(ctx, "validate: potential image descriptor found @%x ",
descriptor_offset);
// Validation is split into 2 functions to minimize
// stack usage.
rv = validate_descriptor(ctx, intf, descriptor_offset,
descriptor_offset - ctx->start_offset,
ctx->end_offset - ctx->start_offset);
if (rv != LIBCR51SIGN_SUCCESS)
{
CPRINTS(ctx, "validate: validate_descriptor() failed ec%d ",
rv);
}
if (rv == LIBCR51SIGN_SUCCESS)
{
rv = validate_payload_regions(ctx, intf, descriptor_offset);
if (rv == LIBCR51SIGN_SUCCESS)
{
CPRINTS(ctx, "validate: success!");
return rv;
}
CPRINTS(ctx,
"validate: validate_payload_regions() failed ec%d ",
rv);
}
// Store the first desc fail reason if any
if (rv != LIBCR51SIGN_SUCCESS &&
rv_first_desc == LIBCR51SIGN_SUCCESS)
rv_first_desc = rv;
// scan_for_magic_8() will round up to the next aligned boundary.
descriptor_offset++;
image_limit = ctx->end_offset - ctx->start_offset;
rv = scan_for_magic_8(ctx, intf, DESCRIPTOR_MAGIC,
descriptor_offset, image_limit,
DESCRIPTOR_ALIGNMENT, &descriptor_offset);
}
CPRINTS(ctx, "validate: failed to validate image ec%d ", rv);
// If desc validation failed for some reason then return that reason
if (rv_first_desc != LIBCR51SIGN_SUCCESS)
return rv_first_desc;
else
return rv;
}
// @func to returns the libcr51sign error code as a string
// @param[in] ec - Error code
// @return error code in string format
const char* libcr51sign_errorcode_to_string(failure_reason ec)
{
switch (ec)
{
case LIBCR51SIGN_SUCCESS:
return "Success";
case LIBCR51SIGN_ERROR_RUNTIME_FAILURE:
return "Runtime Error Failure";
case LIBCR51SIGN_ERROR_UNSUPPORTED_DESCRIPTOR:
return "Unsupported descriptor";
case LIBCR51SIGN_ERROR_INVALID_DESCRIPTOR:
return "Invalid descriptor";
case LIBCR51SIGN_ERROR_INVALID_IMAGE_FAMILY:
return "Invalid image family";
case LIBCR51SIGN_ERROR_IMAGE_TYPE_DISALLOWED:
return "Image type disallowed";
case LIBCR51SIGN_ERROR_DEV_DOWNGRADE_DISALLOWED:
return "Dev downgrade disallowed";
case LIBCR51SIGN_ERROR_UNTRUSTED_KEY:
return "Untrusted key";
case LIBCR51SIGN_ERROR_INVALID_SIGNATURE:
return "Invalid signature";
case LIBCR51SIGN_ERROR_INVALID_HASH:
return "Invalid hash";
case LIBCR51SIGN_ERROR_INVALID_HASH_TYPE:
return "Invalid hash type";
case LIBCR51SIGN_ERROR_INVALID_ARGUMENT:
return "Invalid Argument";
case LIBCR51SIGN_ERROR_FAILED_TO_LOCATE_MAGIC:
return "Failed to locate descriptor";
case LIBCR51SIGN_ERROR_INVALID_CONTEXT:
return "Invalid context";
case LIBCR51SIGN_ERROR_INVALID_INTERFACE:
return "Invalid interface";
case LIBCR51SIGN_ERROR_INVALID_SIG_SCHEME:
return "Invalid signature scheme";
default:
return "Unknown error";
}
}
#ifdef __cplusplus
} // extern "C"
#endif