blob: 022fcc16630536a09bb991358245ab2b14f54ed4 [file] [log] [blame]
/** \file Encrypt.c
* Contains implementation of the functions related to HCOSE_ENVELOPED handle
* objects.
*/
#include <stdlib.h>
#ifndef __MBED__
#include <memory.h>
#else
#include <stddef.h>
#endif
#include <stdio.h>
#include <assert.h>
#include "cose/cose.h"
#include "cose_int.h"
#include "cose/cose_configure.h"
#include "crypto.h"
#if INCLUDE_ENCRYPT || INCLUDE_MAC
COSE *EnvelopedRoot = NULL;
#endif
#if INCLUDE_ENCRYPT
/*! \private
* @brief Test if a HCOSE_ENVELOPED handle is valid
*
* Internal function to test if a enveloped message handle is valid.
* This will start returning invalid results and cause the code to
* crash if handles are not released before the memory that underlies them
* is deallocated. This is an issue of a block allocator is used since
* in that case it is common to allocate memory but never to de-allocate it
* and just do that in a single big block.
*
* @param h handle to be validated
* @returns result of check
*/
bool IsValidEnvelopedHandle(HCOSE_ENVELOPED h)
{
COSE_Enveloped *p = (COSE_Enveloped *)h;
return _COSE_IsInList(EnvelopedRoot, (COSE *)p);
}
/*!
* @brief Allocate and initialize an object for creation of an Enveloped message
* object
*
* Allocate and initialize the object used to create a COSE Enveloped message
* object. Supported flags are: COSE_INIT_FLAG_DETACHED_CONTENT - content is not
* part of the message COSE_INIT_NO_CBOR_FLAG - Do not emit the leading CBOR tag
* on the message.
*
* See the notes on the memory model for the use of the context variable.
* Applications need to free the returned handle before deallocating the
* memory block that it was wrapped in for correct handle checking.
*
* @param flags Set of initialization flags from the COSE_INIT_FLAGS enum
* @param context CN_CBOR context allocator struture
* @param perr Location to return error specific information
* @returns handle to the newly allocated object
*/
HCOSE_ENVELOPED COSE_Enveloped_Init(COSE_INIT_FLAGS flags,
CBOR_CONTEXT_COMMA cose_errback *perr)
{
COSE_Enveloped *pobj =
(COSE_Enveloped *)COSE_CALLOC(1, sizeof(COSE_Enveloped), context);
CHECK_CONDITION(pobj != NULL, COSE_ERR_OUT_OF_MEMORY);
if (!_COSE_Init(flags, &pobj->m_message, COSE_enveloped_object,
CBOR_CONTEXT_PARAM_COMMA perr)) {
_COSE_Enveloped_Release(pobj);
COSE_FREE(pobj, context);
return NULL;
}
_COSE_InsertInList(&EnvelopedRoot, &pobj->m_message);
return (HCOSE_ENVELOPED)pobj;
errorReturn:
return NULL;
}
#endif
#if INCLUDE_ENCRYPT || INCLUDE_MAC
HCOSE_ENVELOPED _COSE_Enveloped_Init_From_Object(cn_cbor *cbor,
COSE_Enveloped *pIn,
CBOR_CONTEXT_COMMA cose_errback *perr)
{
COSE_Enveloped *pobj = pIn;
cn_cbor *pRecipients = NULL;
cose_errback error = {0};
if (perr == NULL) {
perr = &error;
}
if (pobj == NULL) {
pobj =
(COSE_Enveloped *)COSE_CALLOC(1, sizeof(COSE_Enveloped), context);
}
if (pobj == NULL) {
perr->err = COSE_ERR_OUT_OF_MEMORY;
errorReturn:
if (pIn == NULL && pobj != NULL) {
_COSE_Enveloped_Release(pobj);
COSE_FREE(pobj, context);
}
return NULL;
}
if (!_COSE_Init_From_Object(
&pobj->m_message, cbor, CBOR_CONTEXT_PARAM_COMMA perr)) {
goto errorReturn;
}
pRecipients = _COSE_arrayget_int(&pobj->m_message, INDEX_RECIPIENTS);
if (pRecipients != NULL) {
CHECK_CONDITION(
pRecipients->type == CN_CBOR_ARRAY, COSE_ERR_INVALID_PARAMETER);
pRecipients = pRecipients->first_child;
while (pRecipients != NULL) {
COSE_RecipientInfo *pInfo = _COSE_Recipient_Init_From_Object(
pRecipients, CBOR_CONTEXT_PARAM_COMMA perr);
CHECK_CONDITION(pInfo != NULL, COSE_ERR_OUT_OF_MEMORY);
pInfo->m_recipientNext = pobj->m_recipientFirst;
pobj->m_recipientFirst = pInfo;
pRecipients = pRecipients->next;
}
}
if (pIn == NULL) {
_COSE_InsertInList(&EnvelopedRoot, &pobj->m_message);
}
return (HCOSE_ENVELOPED)pobj;
}
#endif
#if INCLUDE_ENCRYPT
bool COSE_Enveloped_Free(HCOSE_ENVELOPED h)
{
#ifdef USE_CBOR_CONTEXT
cn_cbor_context *context;
#endif
COSE_Enveloped *p = (COSE_Enveloped *)h;
if (!IsValidEnvelopedHandle(h)) {
return false;
}
if (p->m_message.m_refCount > 1) {
p->m_message.m_refCount--;
return true;
}
#ifdef USE_CBOR_CONTEXT
context = &((COSE_Enveloped *)h)->m_message.m_allocContext;
#endif
_COSE_RemoveFromList(&EnvelopedRoot, &p->m_message);
_COSE_Enveloped_Release((COSE_Enveloped *)h);
COSE_FREE((COSE_Enveloped *)h, context);
return true;
}
#endif
#if INCLUDE_ENCRYPT || INCLUDE_MAC
void _COSE_Enveloped_Release(COSE_Enveloped *p)
{
COSE_RecipientInfo *pRecipient1;
COSE_RecipientInfo *pRecipient2;
if (p->pbContent != NULL) {
COSE_FREE((void *)p->pbContent, &p->m_message.m_allocContext);
}
// if (p->pbIV != NULL) COSE_FREE(p->pbIV, &p->m_message.m_allocContext);
for (pRecipient1 = p->m_recipientFirst; pRecipient1 != NULL;
pRecipient1 = pRecipient2) {
pRecipient2 = pRecipient1->m_recipientNext;
COSE_Recipient_Free((HCOSE_RECIPIENT)pRecipient1);
}
_COSE_Release(&p->m_message);
}
#endif
#if INCLUDE_ENCRYPT
bool COSE_Enveloped_decrypt(HCOSE_ENVELOPED h,
HCOSE_RECIPIENT hRecip,
cose_errback *perr)
{
COSE_Enveloped *pcose = (COSE_Enveloped *)h;
COSE_RecipientInfo *pRecip = (COSE_RecipientInfo *)hRecip;
bool f = false;
CHECK_CONDITION(IsValidEnvelopedHandle(h), COSE_ERR_INVALID_HANDLE);
CHECK_CONDITION(IsValidRecipientHandle(hRecip), COSE_ERR_INVALID_HANDLE);
CHECK_CONDITION(
pcose->m_recipientFirst != NULL, COSE_ERR_INVALID_PARAMETER);
f = _COSE_Enveloped_decrypt(pcose, pRecip, NULL, 0, "Encrypt", perr);
errorReturn:
return f;
}
#endif
#if INCLUDE_ENCRYPT || INCLUDE_ENCRYPT0
bool _COSE_Enveloped_decrypt(COSE_Enveloped *pcose,
COSE_RecipientInfo *pRecip,
const byte *pbKeyIn,
size_t cbKeyIn,
const char *szContext,
cose_errback *perr)
{
int alg;
const cn_cbor *cn = NULL;
byte *pbKeyNew = NULL;
const byte *pbKey = NULL;
size_t cbitKey = 0;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context *context;
#endif
byte *pbAuthData = NULL;
size_t cbAuthData;
#ifdef USE_CBOR_CONTEXT
context = &pcose->m_message.m_allocContext;
#endif
CHECK_CONDITION(
!((pRecip != NULL) && (pbKeyIn != NULL)), COSE_ERR_INTERNAL);
cn = _COSE_map_get_int(
&pcose->m_message, COSE_Header_Algorithm, COSE_BOTH, perr);
if (cn == NULL) {
error:
errorReturn:
if (pbAuthData != NULL) {
COSE_FREE(pbAuthData, context);
}
if (pbKeyNew != NULL) {
memset(pbKeyNew, 0xff, cbitKey / 8);
COSE_FREE(pbKeyNew, context);
}
return false;
}
CHECK_CONDITION((cn->type == CN_CBOR_UINT) || (cn->type == CN_CBOR_INT),
COSE_ERR_INVALID_PARAMETER);
alg = (int)cn->v.uint;
switch (alg) {
#ifdef USE_AES_CCM_16_64_128
case COSE_Algorithm_AES_CCM_16_64_128:
cbitKey = 128;
break;
#endif
#ifdef USE_AES_CCM_16_128_128
case COSE_Algorithm_AES_CCM_16_128_128:
cbitKey = 128;
break;
#endif
#ifdef USE_AES_CCM_64_64_128
case COSE_Algorithm_AES_CCM_64_64_128:
cbitKey = 128;
break;
#endif
#ifdef USE_AES_CCM_64_128_128
case COSE_Algorithm_AES_CCM_64_128_128:
cbitKey = 128;
break;
#endif
#ifdef USE_AES_CCM_64_64_256
case COSE_Algorithm_AES_CCM_64_64_256:
cbitKey = 256;
break;
#endif
#ifdef USE_AES_CCM_16_128_256
case COSE_Algorithm_AES_CCM_16_128_256:
cbitKey = 256;
break;
#endif
#ifdef USE_AES_CCM_64_128_256
case COSE_Algorithm_AES_CCM_64_128_256:
cbitKey = 256;
break;
#endif
#ifdef USE_AES_CCM_16_64_256
case COSE_Algorithm_AES_CCM_16_64_256:
cbitKey = 256;
break;
#endif
#ifdef USE_AES_GCM_128
case COSE_Algorithm_AES_GCM_128:
cbitKey = 128;
break;
#endif
#ifdef USE_AES_GCM_192
case COSE_Algorithm_AES_GCM_192:
cbitKey = 192;
break;
#endif
#ifdef USE_AES_GCM_256
case COSE_Algorithm_AES_GCM_256:
cbitKey = 256;
break;
#endif
default:
FAIL_CONDITION(COSE_ERR_UNKNOWN_ALGORITHM);
break;
}
//
// We are doing the enveloped item - so look for the passed in recipient
//
if (pbKeyIn != NULL) {
CHECK_CONDITION(cbKeyIn == cbitKey / 8, COSE_ERR_INVALID_PARAMETER);
pbKey = pbKeyIn;
}
#ifdef INCLUDE_ENCRYPT
else {
// Allocate the key if we have not already done so
if (pbKeyNew == NULL) {
pbKeyNew = COSE_CALLOC(cbitKey / 8, 1, context);
CHECK_CONDITION(pbKeyNew != NULL, COSE_ERR_OUT_OF_MEMORY);
pbKey = pbKeyNew;
}
// If there is a recipient - ask it for the key
if (pRecip != NULL) {
COSE_RecipientInfo *pRecipX;
for (pRecipX = pcose->m_recipientFirst; pRecipX != NULL;
pRecipX = pRecipX->m_recipientNext) {
if (pRecipX == pRecip) {
if (!_COSE_Recipient_decrypt(
pRecipX, pRecip, alg, cbitKey, pbKeyNew, perr)) {
goto errorReturn;
}
break;
}
else if (pRecipX->m_encrypt.m_recipientFirst != NULL) {
if (_COSE_Recipient_decrypt(
pRecipX, pRecip, alg, cbitKey, pbKeyNew, perr)) {
break;
}
}
}
CHECK_CONDITION(pRecipX != NULL, COSE_ERR_NO_RECIPIENT_FOUND);
}
else {
for (pRecip = pcose->m_recipientFirst; pRecip != NULL;
pRecip = pRecip->m_recipientNext) {
if (_COSE_Recipient_decrypt(
pRecip, NULL, alg, cbitKey, pbKeyNew, perr)) {
break;
}
}
CHECK_CONDITION(pRecip != NULL, COSE_ERR_NO_RECIPIENT_FOUND);
}
}
#endif // INCLUDE_ENCRYPT
// Build authenticated data
if (!_COSE_Encrypt_Build_AAD(
&pcose->m_message, &pbAuthData, &cbAuthData, szContext, perr)) {
goto errorReturn;
}
cn = _COSE_arrayget_int(&pcose->m_message, INDEX_BODY);
CHECK_CONDITION(cn != NULL, COSE_ERR_INVALID_PARAMETER);
switch (alg) {
#ifdef USE_AES_CCM_16_64_128
case COSE_Algorithm_AES_CCM_16_64_128:
if (!AES_CCM_Decrypt(pcose, 64, 16, pbKey, cbitKey / 8, cn->v.bytes,
cn->length, pbAuthData, cbAuthData, perr)) {
goto error;
}
break;
#endif
#ifdef USE_AES_CCM_16_64_256
case COSE_Algorithm_AES_CCM_16_64_256:
if (!AES_CCM_Decrypt(pcose, 64, 16, pbKey, cbitKey / 8, cn->v.bytes,
cn->length, pbAuthData, cbAuthData, perr)) {
goto error;
}
break;
#endif
#ifdef USE_AES_CCM_16_128_128
case COSE_Algorithm_AES_CCM_16_128_128:
if (!AES_CCM_Decrypt(pcose, 128, 16, pbKey, cbitKey / 8,
cn->v.bytes, cn->length, pbAuthData, cbAuthData, perr)) {
goto error;
}
break;
#endif
#ifdef USE_AES_CCM_16_128_256
case COSE_Algorithm_AES_CCM_16_128_256:
if (!AES_CCM_Decrypt(pcose, 128, 16, pbKey, cbitKey / 8,
cn->v.bytes, cn->length, pbAuthData, cbAuthData, perr)) {
goto error;
}
break;
#endif
#ifdef USE_AES_CCM_64_64_128
case COSE_Algorithm_AES_CCM_64_64_128:
if (!AES_CCM_Decrypt(pcose, 64, 64, pbKey, cbitKey / 8, cn->v.bytes,
cn->length, pbAuthData, cbAuthData, perr)) {
goto error;
}
break;
#endif
#ifdef USE_AES_CCM_64_64_256
case COSE_Algorithm_AES_CCM_64_64_256:
if (!AES_CCM_Decrypt(pcose, 64, 64, pbKey, cbitKey / 8, cn->v.bytes,
cn->length, pbAuthData, cbAuthData, perr)) {
goto error;
}
break;
#endif
#ifdef USE_AES_CCM_64_128_128
case COSE_Algorithm_AES_CCM_64_128_128:
if (!AES_CCM_Decrypt(pcose, 128, 64, pbKey, cbitKey / 8,
cn->v.bytes, cn->length, pbAuthData, cbAuthData, perr)) {
goto error;
}
break;
#endif
#ifdef USE_AES_CCM_64_128_256
case COSE_Algorithm_AES_CCM_64_128_256:
if (!AES_CCM_Decrypt(pcose, 128, 64, pbKey, cbitKey / 8,
cn->v.bytes, cn->length, pbAuthData, cbAuthData, perr)) {
goto error;
}
break;
#endif
#ifdef USE_AES_GCM_128
case COSE_Algorithm_AES_GCM_128:
if (!AES_GCM_Decrypt(pcose, pbKey, cbitKey / 8, cn->v.bytes,
cn->length, pbAuthData, cbAuthData, perr)) {
goto error;
}
break;
#endif
#ifdef USE_AES_GCM_192
case COSE_Algorithm_AES_GCM_192:
if (!AES_GCM_Decrypt(pcose, pbKey, cbitKey / 8, cn->v.bytes,
cn->length, pbAuthData, cbAuthData, perr)) {
goto error;
}
break;
#endif
#ifdef USE_AES_GCM_256
case COSE_Algorithm_AES_GCM_256:
if (!AES_GCM_Decrypt(pcose, pbKey, cbitKey / 8, cn->v.bytes,
cn->length, pbAuthData, cbAuthData, perr)) {
goto error;
}
break;
#endif
default:
FAIL_CONDITION(COSE_ERR_UNKNOWN_ALGORITHM);
break;
}
if (pbAuthData != NULL) {
COSE_FREE(pbAuthData, context);
}
if (pbKeyNew != NULL) {
COSE_FREE(pbKeyNew, context);
}
if (perr != NULL) {
perr->err = COSE_ERR_NONE;
}
return true;
}
#endif
#if INCLUDE_ENCRYPT
bool COSE_Enveloped_encrypt(HCOSE_ENVELOPED h, cose_errback *perr)
{
COSE_Enveloped *pcose = (COSE_Enveloped *)h;
CHECK_CONDITION(IsValidEnvelopedHandle(h), COSE_ERR_INVALID_HANDLE);
CHECK_CONDITION(pcose->m_recipientFirst != NULL, COSE_ERR_INVALID_HANDLE);
return _COSE_Enveloped_encrypt(pcose, NULL, 0, "Encrypt", perr);
errorReturn:
return false;
}
#endif
#if INCLUDE_ENCRYPT || INCLUDE_ENCRYPT0
bool _COSE_Enveloped_encrypt(COSE_Enveloped *pcose,
const byte *pbKeyIn,
size_t cbKeyIn,
const char *szContext,
cose_errback *perr)
{
int alg;
int t;
COSE_RecipientInfo *pri;
const cn_cbor *cn_Alg = NULL;
byte *pbAuthData = NULL;
size_t cbitKey;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context *context = &pcose->m_message.m_allocContext;
#endif
bool fRet = false;
byte *pbKeyNew = NULL;
const byte *pbKey = NULL;
size_t cbKey = 0;
cn_Alg = _COSE_map_get_int(
&pcose->m_message, COSE_Header_Algorithm, COSE_BOTH, perr);
if (cn_Alg == NULL) {
goto errorReturn;
}
CHECK_CONDITION((cn_Alg->type != CN_CBOR_TEXT), COSE_ERR_UNKNOWN_ALGORITHM);
CHECK_CONDITION(
(cn_Alg->type == CN_CBOR_UINT) || (cn_Alg->type == CN_CBOR_INT),
COSE_ERR_INVALID_PARAMETER);
alg = (int)cn_Alg->v.uint;
// Get the key size
switch (alg) {
#ifdef USE_AES_CCM_64_64_128
case COSE_Algorithm_AES_CCM_64_64_128:
cbitKey = 128;
break;
#endif
#ifdef USE_AES_CCM_16_128_128
case COSE_Algorithm_AES_CCM_16_128_128:
cbitKey = 128;
break;
#endif
#ifdef USE_AES_CCM_64_128_128
case COSE_Algorithm_AES_CCM_64_128_128:
cbitKey = 128;
break;
#endif
#ifdef USE_AES_CCM_16_64_128
case COSE_Algorithm_AES_CCM_16_64_128:
cbitKey = 128;
break;
#endif
#ifdef USE_AES_CCM_64_64_256
case COSE_Algorithm_AES_CCM_64_64_256:
cbitKey = 256;
break;
#endif
#ifdef USE_AES_CCM_16_128_256
case COSE_Algorithm_AES_CCM_16_128_256:
cbitKey = 256;
break;
#endif
#ifdef USE_AES_CCM_64_128_256
case COSE_Algorithm_AES_CCM_64_128_256:
cbitKey = 256;
break;
#endif
#ifdef USE_AES_CCM_16_64_256
case COSE_Algorithm_AES_CCM_16_64_256:
cbitKey = 256;
break;
#endif
#ifdef USE_AES_GCM_128
case COSE_Algorithm_AES_GCM_128:
cbitKey = 128;
break;
#endif
#ifdef USE_AES_GCM_192
case COSE_Algorithm_AES_GCM_192:
cbitKey = 192;
break;
#endif
#ifdef USE_AES_GCM_256
case COSE_Algorithm_AES_GCM_256:
cbitKey = 256;
break;
#endif
default:
FAIL_CONDITION(COSE_ERR_UNKNOWN_ALGORITHM);
}
// Enveloped or Encrypted?
if (pbKeyIn != NULL) {
CHECK_CONDITION(cbKeyIn == cbitKey / 8, COSE_ERR_INVALID_PARAMETER);
pbKey = pbKeyIn;
cbKey = cbKeyIn;
}
#ifdef INCLUDE_ENCRYPT
else {
// If we are doing direct encryption - then recipient generates the key
t = 0;
for (pri = pcose->m_recipientFirst; pri != NULL;
pri = pri->m_recipientNext) {
if (pri->m_encrypt.m_message.m_flags & 1) {
CHECK_CONDITION(pbKey == NULL, COSE_ERR_INVALID_PARAMETER);
t |= 1;
pbKeyNew =
_COSE_RecipientInfo_generateKey(pri, alg, cbitKey, perr);
cbKey = cbitKey / 8;
if (pbKeyNew == NULL) {
goto errorReturn;
}
}
else {
t |= 2;
}
}
CHECK_CONDITION(t != 3, COSE_ERR_INVALID_PARAMETER);
if (t == 2) {
pbKeyNew = (byte *)COSE_CALLOC(cbitKey / 8, 1, context);
CHECK_CONDITION(pbKeyNew != NULL, COSE_ERR_OUT_OF_MEMORY);
cbKey = cbitKey / 8;
rand_bytes(pbKeyNew, cbKey);
}
pbKey = pbKeyNew;
}
#endif // INCLUDE_ENCRYPT
// Build protected headers
const cn_cbor *cbProtected =
_COSE_encode_protected(&pcose->m_message, perr);
if (cbProtected == NULL) {
goto errorReturn;
}
// Build authenticated data
size_t cbAuthData = 0;
if (!_COSE_Encrypt_Build_AAD(
&pcose->m_message, &pbAuthData, &cbAuthData, szContext, perr)) {
goto errorReturn;
}
switch (alg) {
#ifdef USE_AES_CCM_16_64_128
case COSE_Algorithm_AES_CCM_16_64_128:
if (!AES_CCM_Encrypt(pcose, 64, 16, pbKey, cbKey, pbAuthData,
cbAuthData, perr)) {
goto errorReturn;
}
break;
#endif
#ifdef USE_AES_CCM_16_64_256
case COSE_Algorithm_AES_CCM_16_64_256:
if (!AES_CCM_Encrypt(pcose, 64, 16, pbKey, cbKey, pbAuthData,
cbAuthData, perr)) {
goto errorReturn;
}
break;
#endif
#ifdef USE_AES_CCM_16_128_128
case COSE_Algorithm_AES_CCM_16_128_128:
if (!AES_CCM_Encrypt(pcose, 128, 16, pbKey, cbKey, pbAuthData,
cbAuthData, perr)) {
goto errorReturn;
}
break;
#endif
#ifdef USE_AES_CCM_16_128_256
case COSE_Algorithm_AES_CCM_16_128_256:
if (!AES_CCM_Encrypt(pcose, 128, 16, pbKey, cbKey, pbAuthData,
cbAuthData, perr)) {
goto errorReturn;
}
break;
#endif
#ifdef USE_AES_CCM_64_64_128
case COSE_Algorithm_AES_CCM_64_64_128:
if (!AES_CCM_Encrypt(pcose, 64, 64, pbKey, cbKey, pbAuthData,
cbAuthData, perr)) {
goto errorReturn;
}
break;
#endif
#ifdef USE_AES_CCM_64_64_256
case COSE_Algorithm_AES_CCM_64_64_256:
if (!AES_CCM_Encrypt(pcose, 64, 64, pbKey, cbKey, pbAuthData,
cbAuthData, perr)) {
goto errorReturn;
}
break;
#endif
#ifdef USE_AES_CCM_64_128_128
case COSE_Algorithm_AES_CCM_64_128_128:
if (!AES_CCM_Encrypt(pcose, 128, 64, pbKey, cbKey, pbAuthData,
cbAuthData, perr)) {
goto errorReturn;
}
break;
#endif
#ifdef USE_AES_CCM_64_128_256
case COSE_Algorithm_AES_CCM_64_128_256:
if (!AES_CCM_Encrypt(pcose, 128, 64, pbKey, cbKey, pbAuthData,
cbAuthData, perr)) {
goto errorReturn;
}
break;
#endif
#ifdef USE_AES_GCM_128
case COSE_Algorithm_AES_GCM_128:
if (!AES_GCM_Encrypt(
pcose, pbKey, cbKey, pbAuthData, cbAuthData, perr)) {
goto errorReturn;
}
break;
#endif
#ifdef USE_AES_GCM_192
case COSE_Algorithm_AES_GCM_192:
if (!AES_GCM_Encrypt(
pcose, pbKey, cbKey, pbAuthData, cbAuthData, perr)) {
goto errorReturn;
}
break;
#endif
#ifdef USE_AES_GCM_256
case COSE_Algorithm_AES_GCM_256:
if (!AES_GCM_Encrypt(
pcose, pbKey, cbKey, pbAuthData, cbAuthData, perr)) {
goto errorReturn;
}
break;
#endif
default:
FAIL_CONDITION(COSE_ERR_UNKNOWN_ALGORITHM);
}
#if INCLUDE_ENCRYPT
for (pri = pcose->m_recipientFirst; pri != NULL;
pri = pri->m_recipientNext) {
if (!_COSE_Recipient_encrypt(pri, pbKey, cbKey, perr)) {
goto errorReturn;
}
}
#endif // INCLUDE_ENCRYPT
#if INCLUDE_COUNTERSIGNATURE
if (pcose->m_message.m_counterSigners != NULL) {
if (!_COSE_CounterSign_Sign(
&pcose->m_message, CBOR_CONTEXT_PARAM_COMMA perr)) {
goto errorReturn;
}
}
#endif
// Figure out the clean up
fRet = true;
errorReturn:
if (pbAuthData != NULL) {
COSE_FREE(pbAuthData, context);
}
if (pbKeyNew != NULL) {
memset(pbKeyNew, 0, cbKey);
COSE_FREE(pbKeyNew, context);
}
return fRet;
}
#endif
#if INCLUDE_ENCRYPT
bool COSE_Enveloped_SetContent(HCOSE_ENVELOPED h,
const byte *rgb,
size_t cb,
cose_errback *perr)
{
CHECK_CONDITION(IsValidEnvelopedHandle(h), COSE_ERR_INVALID_HANDLE);
CHECK_CONDITION(rgb != NULL, COSE_ERR_INVALID_PARAMETER);
return _COSE_Enveloped_SetContent((COSE_Enveloped *)h, rgb, cb, perr);
errorReturn:
return false;
}
/*!
* @brief Set the application external data for authentication
*
* Enveloped data objects support the authentication of external application
* supplied data. This function is provided to supply that data to the library.
*
* The external data is not copied, nor will be it freed when the handle is
* released.
*
* @param hcose Handle for the COSE Enveloped data object
* @param pbEternalData point to the external data
* @param cbExternalData size of the external data
* @param perr location to return errors
* @return result of the operation.
*/
bool COSE_Enveloped_SetExternal(HCOSE_ENVELOPED hcose,
const byte *pbExternalData,
size_t cbExternalData,
cose_errback *perr)
{
CHECK_CONDITION(IsValidEnvelopedHandle(hcose), COSE_ERR_INVALID_HANDLE)
CHECK_CONDITION((pbExternalData != NULL) || (cbExternalData == 0),
COSE_ERR_INVALID_PARAMETER);
return _COSE_SetExternal(&((COSE_Enveloped *)hcose)->m_message,
pbExternalData, cbExternalData, perr);
errorReturn:
return false;
}
bool _COSE_Enveloped_SetContent(COSE_Enveloped *cose,
const byte *rgb,
size_t cb,
cose_errback *perror)
{
byte *pb;
cose->pbContent = pb =
(byte *)COSE_CALLOC(cb, 1, &cose->m_message.m_allocContext);
if (cose->pbContent == NULL) {
if (perror != NULL) {
perror->err = COSE_ERR_INVALID_PARAMETER;
}
return false;
}
memcpy(pb, rgb, cb);
cose->cbContent = cb;
return true;
}
/*! brief Retrieve header parameter from an enveloped message structure
*
* Retrieve a header parameter from the message.
* Retrieved object is the same as the one in the message - do not delete it
*
* @param[in] h Handle of recipient object
* @param[in] key Key to look for
* @param[in] flags What buckets should we look for the message
* @param[out] perror Location to return error codes
* @return Object which is found or NULL
*/
cn_cbor *COSE_Enveloped_map_get_int(HCOSE_ENVELOPED h,
int key,
int flags,
cose_errback *perror)
{
if (!IsValidEnvelopedHandle(h)) {
if (perror != NULL) {
perror->err = COSE_ERR_INVALID_HANDLE;
}
return NULL;
}
return _COSE_map_get_int(
&((COSE_Enveloped *)h)->m_message, key, flags, perror);
}
bool COSE_Enveloped_map_put_int(HCOSE_ENVELOPED h,
int key,
cn_cbor *value,
int flags,
cose_errback *perr)
{
CHECK_CONDITION(IsValidEnvelopedHandle(h), COSE_ERR_INVALID_HANDLE);
CHECK_CONDITION(value != NULL, COSE_ERR_INVALID_PARAMETER);
return _COSE_map_put(
&((COSE_Enveloped *)h)->m_message, key, value, flags, perr);
errorReturn:
return false;
}
bool COSE_Enveloped_AddRecipient(HCOSE_ENVELOPED hEnc,
HCOSE_RECIPIENT hRecip,
cose_errback *perr)
{
COSE_RecipientInfo *pRecip;
COSE_Enveloped *pEncrypt;
cn_cbor *pRecipients = NULL;
#ifdef USE_CBOR_CONTEXT
cn_cbor_context *context;
#endif
cn_cbor_errback cbor_error;
CHECK_CONDITION(IsValidEnvelopedHandle(hEnc), COSE_ERR_INVALID_HANDLE);
CHECK_CONDITION(IsValidRecipientHandle(hRecip), COSE_ERR_INVALID_HANDLE);
pEncrypt = (COSE_Enveloped *)hEnc;
pRecip = (COSE_RecipientInfo *)hRecip;
#ifdef USE_CBOR_CONTEXT
context = &pEncrypt->m_message.m_allocContext;
#endif // USE_CBOR_CONTEXT
pRecip->m_recipientNext = pEncrypt->m_recipientFirst;
pEncrypt->m_recipientFirst = pRecip;
pRecipients = _COSE_arrayget_int(&pEncrypt->m_message, INDEX_RECIPIENTS);
if (pRecipients == NULL) {
pRecipients =
cn_cbor_array_create(CBOR_CONTEXT_PARAM_COMMA & cbor_error);
CHECK_CONDITION_CBOR(pRecipients != NULL, cbor_error);
if (!_COSE_array_replace(&pEncrypt->m_message, pRecipients,
INDEX_RECIPIENTS, CBOR_CONTEXT_PARAM_COMMA & cbor_error)) {
CN_CBOR_FREE(pRecipients, context);
if (perr != NULL) {
perr->err = _MapFromCBOR(cbor_error);
}
goto errorReturn;
}
}
CHECK_CONDITION_CBOR(cn_cbor_array_append(pRecipients,
pRecip->m_encrypt.m_message.m_cbor, &cbor_error),
cbor_error);
pRecip->m_encrypt.m_message.m_refCount++;
return true;
errorReturn:
return false;
}
#endif
#if INCLUDE_ENCRYPT || INCLUDE_ENCRYPT0 || INCLUDE_MAC || INCLUDE_MAC0
bool _COSE_Encrypt_Build_AAD(COSE *pMessage,
byte **ppbAAD,
size_t *pcbAAD,
const char *szContext,
cose_errback *perr)
{
#ifdef USE_CBOR_CONTEXT
cn_cbor_context *context = &pMessage->m_allocContext;
#endif
cn_cbor_errback cbor_error;
byte *pbAuthData = NULL;
size_t cbAuthData;
cn_cbor *pAuthData = NULL;
cn_cbor *pItem = NULL;
cn_cbor *ptmp = NULL;
// Build authenticated data
pAuthData = cn_cbor_array_create(CBOR_CONTEXT_PARAM_COMMA & cbor_error);
CHECK_CONDITION_CBOR(pAuthData != NULL, cbor_error);
ptmp =
cn_cbor_string_create(szContext, CBOR_CONTEXT_PARAM_COMMA & cbor_error);
CHECK_CONDITION_CBOR(ptmp != NULL, cbor_error);
CHECK_CONDITION_CBOR(
cn_cbor_array_append(pAuthData, ptmp, &cbor_error), cbor_error);
ptmp = NULL;
pItem = _COSE_arrayget_int(pMessage, INDEX_PROTECTED);
CHECK_CONDITION(pItem != NULL, COSE_ERR_INVALID_PARAMETER);
if ((pItem->length == 1) && (pItem->v.bytes[0] == 0xa0)) {
ptmp =
cn_cbor_data_create(NULL, 0, CBOR_CONTEXT_PARAM_COMMA & cbor_error);
}
else {
ptmp = cn_cbor_data_create(pItem->v.bytes, (int)pItem->length,
CBOR_CONTEXT_PARAM_COMMA & cbor_error);
}
CHECK_CONDITION_CBOR(ptmp != NULL, cbor_error);
CHECK_CONDITION_CBOR(
cn_cbor_array_append(pAuthData, ptmp, &cbor_error), cbor_error);
ptmp = NULL;
ptmp = cn_cbor_data_create(pMessage->m_pbExternal,
(int)pMessage->m_cbExternal, CBOR_CONTEXT_PARAM_COMMA & cbor_error);
CHECK_CONDITION_CBOR(ptmp != NULL, cbor_error);
CHECK_CONDITION_CBOR(
cn_cbor_array_append(pAuthData, ptmp, &cbor_error), cbor_error);
ptmp = NULL;
cbAuthData = cn_cbor_encode_size(pAuthData);
pbAuthData = (byte *)COSE_CALLOC(cbAuthData, 1, context);
CHECK_CONDITION(pbAuthData != NULL, COSE_ERR_OUT_OF_MEMORY);
CHECK_CONDITION((size_t)cn_cbor_encoder_write(
pbAuthData, 0, cbAuthData, pAuthData) == cbAuthData,
COSE_ERR_CBOR);
*ppbAAD = pbAuthData;
*pcbAAD = cbAuthData;
#if 0
{
printf("Encrypt* AAD = ");
int iX;
for (iX=0; iX < cbAuthData; iX++) {
printf("%02x ", pbAuthData[iX]);
}
printf("\n");
}
#endif
return true;
errorReturn:
if (pbAuthData != NULL) {
COSE_FREE(pbAuthData, context);
}
if (ptmp != NULL) {
CN_CBOR_FREE(ptmp, NULL);
}
if (pAuthData != NULL) {
CN_CBOR_FREE(pAuthData, context);
}
return false;
}
#endif
#if INCLUDE_ENCRYPT
HCOSE_RECIPIENT COSE_Enveloped_GetRecipient(HCOSE_ENVELOPED cose,
int iRecipient,
cose_errback *perr)
{
int i;
COSE_RecipientInfo *p = NULL;
CHECK_CONDITION(IsValidEnvelopedHandle(cose), COSE_ERR_INVALID_HANDLE);
CHECK_CONDITION(iRecipient >= 0, COSE_ERR_INVALID_PARAMETER);
p = ((COSE_Enveloped *)cose)->m_recipientFirst;
for (i = 0; i < iRecipient; i++) {
CHECK_CONDITION(p != NULL, COSE_ERR_INVALID_PARAMETER);
p = p->m_recipientNext;
}
if (p != NULL) {
p->m_encrypt.m_message.m_refCount++;
}
errorReturn:
return (HCOSE_RECIPIENT)p;
}
#endif