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|
/*
* Copyright (c) 2024 Vaughn Nugent
*
* Package: noscrypt
* File: noscrypt.c
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public License
* as published by the Free Software Foundation; either version 2.1
* of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with noscrypt. If not, see http://www.gnu.org/licenses/.
*/
#include "noscrypt.h"
#include "nc-util.h"
#include "nc-crypto.h"
#include <secp256k1/secp256k1_ecdh.h>
#include <secp256k1/secp256k1_schnorrsig.h>
/*
* Local macro for secure zero buffer fill
*/
#define ZERO_FILL(x, size) ncCryptoSecureZero(x, size)
/* Include string for memmove */
#include <string.h>
#define MEMMOV(dst, src, size) memmove(dst, src, size)
/*
* Validation macros
*/
#ifndef NC_INPUT_VALIDATION_OFF
#define CHECK_INVALID_ARG(x, argPos) if(x == NULL) return NCResultWithArgPosition(E_INVALID_ARG, argPos);
#define CHECK_NULL_ARG(x, argPos) if(x == NULL) return NCResultWithArgPosition(E_NULL_PTR, argPos);
#define CHECK_ARG_RANGE(x, min, max, argPos) if(x < min || x > max) return NCResultWithArgPosition(E_ARGUMENT_OUT_OF_RANGE, argPos);
#define CHECK_CONTEXT_STATE(ctx, argPos) CHECK_INVALID_ARG(ctx->secpCtx, argPos)
#else
/* empty macros */
#define CHECK_INVALID_ARG(x)
#define CHECK_NULL_ARG(x, argPos)
#define CHECK_ARG_RANGE(x, min, max, argPos)
#endif /* !NC_DISABLE_INPUT_VALIDATION */
/*
* Actual, private defintion of the NCContext structure
* to allow for future development and ABI backords
* compatability.
*/
struct nc_ctx_struct {
void* secpCtx;
};
/*
* The Nip44 constant salt
* https://github.com/nostr-protocol/nips/blob/master/44.md#encryption
*/
static const uint8_t Nip44ConstantSalt[8] = { 0x6e, 0x69, 0x70, 0x34, 0x34, 0x2d, 0x76, 0x32 };
static struct nc_ctx_struct _ncSharedCtx;
struct shared_secret {
uint8_t value[NC_SHARED_SEC_SIZE];
};
struct conversation_key {
uint8_t value[NC_CONV_KEY_SIZE];
};
struct message_key {
uint8_t value[NC_MESSAGE_KEY_SIZE];
};
/*
* The following struct layout is exactly the same as
* the message key, they may be typecasted to each other.
* as long as the size is the same.
*/
struct nc_expand_keys {
uint8_t chacha_key[CHACHA_KEY_SIZE];
uint8_t chacha_nonce[CHACHA_NONCE_SIZE];
uint8_t hmac_key[NC_HMAC_KEY_SIZE];
};
/* Pointer typecast must work between expanded keys
* and message key, size must be identical to work
*/
STATIC_ASSERT(sizeof(struct nc_expand_keys) == sizeof(struct message_key), "Expected struct nc_expand_keys to be the same size as struct message_key")
/*
* Check that the fallback hkdf extract internal buffer is large enough
* for full converstation key buffers
*/
STATIC_ASSERT(HKDF_IN_BUF_SIZE >= NC_CONV_KEY_SIZE + 8, "HKDF Buffer size is too small for Safe HKDF operations")
/*
* Internal helper functions to do common structure conversions
*/
static _nc_fn_inline int _convertToXonly(const NCContext* ctx, const NCPublicKey* compressedPubKey, secp256k1_xonly_pubkey* xonly)
{
DEBUG_ASSERT2(ctx != NULL, "Expected valid context")
DEBUG_ASSERT2(compressedPubKey != NULL, "Expected a valid public 32byte key structure")
DEBUG_ASSERT2(xonly != NULL, "Expected valid X-only secp256k1 public key structure ")
/* Parse the public key into the x-only structure */
return secp256k1_xonly_pubkey_parse(ctx->secpCtx, xonly, compressedPubKey->key);
}
static int _convertToPubKey(const NCContext* ctx, const NCPublicKey* compressedPubKey, secp256k1_pubkey* pubKey)
{
int result;
uint8_t compressed[sizeof(NCPublicKey) + 1];
DEBUG_ASSERT2(ctx != NULL, "Expected valid context")
DEBUG_ASSERT2(compressedPubKey != NULL, "Expected a valid public 32byte key structure")
DEBUG_ASSERT2(pubKey != NULL, "Expected valid secp256k1 public key structure")
/* Set the first byte to 0x02 to indicate a compressed public key */
compressed[0] = BIP340_PUBKEY_HEADER_BYTE;
/* Copy the compressed public key data into a new buffer (offset by 1 to store the header byte) */
MEMMOV((compressed + 1), compressedPubKey, sizeof(NCPublicKey));
result = secp256k1_ec_pubkey_parse(ctx->secpCtx, pubKey, compressed, sizeof(compressed));
ZERO_FILL(compressed, sizeof(compressed));
return result;
}
static _nc_fn_inline int _convertFromXonly(
const NCContext* ctx,
const secp256k1_xonly_pubkey* xonly,
NCPublicKey* compressedPubKey
)
{
DEBUG_ASSERT2(ctx != NULL, "Expected valid context")
DEBUG_ASSERT2(xonly != NULL, "Expected valid X-only secp256k1 public key structure.")
DEBUG_ASSERT2(compressedPubKey != NULL, "Expected a valid public 32byte pubkey structure")
return secp256k1_xonly_pubkey_serialize(ctx->secpCtx, compressedPubKey->key, xonly);
}
/*
* IMPL NOTES:
* This callback function will be invoked by the ecdh function to hash the shared point.
*
* For nostr, this operation is defined in the new NIP-44 spec here:
* https://github.com/nostr-protocol/nips/blob/master/44.md#encryption
*
* The x coordinate of the shared point is copied directly into the output buffer. No hashing is
* performed here. The y coordinate is not used, and for this implementation, there is no data
* pointer.
*/
static int _edhHashFuncInternal(
unsigned char* output,
const uint8_t* x32,
const uint8_t* y32,
void* data
)
{
((void)y32); /* unused for nostr */
((void)data);
DEBUG_ASSERT2(output != NULL, "Expected valid output buffer")
DEBUG_ASSERT2(x32 != NULL, "Expected a valid public 32byte x-coodinate buffer")
/* Copy the x coordinate of the shared point into the output buffer */
MEMMOV(output, x32, 32);
return 32; /* Return the number of bytes written to the output buffer */
}
static NCResult _computeSharedSecret(
const NCContext* ctx,
const NCSecretKey* sk,
const NCPublicKey* otherPk,
struct shared_secret* sharedPoint
)
{
int result;
secp256k1_pubkey pubKey;
DEBUG_ASSERT(ctx != NULL)
DEBUG_ASSERT(sk != NULL)
DEBUG_ASSERT(otherPk != NULL)
DEBUG_ASSERT(sharedPoint != NULL)
/* Recover pubkey from compressed public key data */
if (_convertToPubKey(ctx, otherPk, &pubKey) != 1)
{
return E_INVALID_ARG;
}
/*
* Compute the shared point using the ecdh function.
*
* The above callback is invoked to "compute" the hash (it
* copies the x coord) and it does not use the data pointer
* so it is set to NULL.
*/
result = secp256k1_ecdh(
ctx->secpCtx,
(uint8_t*)sharedPoint,
&pubKey,
sk->key,
&_edhHashFuncInternal,
NULL
);
ZERO_FILL(&pubKey, sizeof(pubKey));
/* Result should be 1 on success */
return result == 1 ? NC_SUCCESS : E_OPERATION_FAILED;
}
static _nc_fn_inline NCResult _computeConversationKey(
const NCContext* ctx,
const struct shared_secret* sharedSecret,
struct conversation_key* ck
)
{
cspan_t saltSpan, ikmSpan;
DEBUG_ASSERT2(ctx != NULL, "Expected valid context")
DEBUG_ASSERT2(sharedSecret != NULL, "Expected a valid shared-point")
DEBUG_ASSERT2(ck != NULL, "Expected a valid conversation key")
ncSpanInitC(&saltSpan, Nip44ConstantSalt, sizeof(Nip44ConstantSalt));
ncSpanInitC(&ikmSpan, sharedSecret->value, NC_SHARED_SEC_SIZE);
return ncCryptoSha256HkdfExtract(&saltSpan, &ikmSpan, ck->value) == CSTATUS_OK ? NC_SUCCESS : E_OPERATION_FAILED;
}
/*
* Explode the hkdf into the chacha key, chacha nonce, and hmac key.
*/
static _nc_fn_inline const struct nc_expand_keys* _expandKeysFromHkdf(const struct message_key* hkdf)
{
return (const struct nc_expand_keys*)hkdf;
}
static cstatus_t _chachaEncipher(const struct nc_expand_keys* keys, NCEncryptionArgs* args)
{
DEBUG_ASSERT2(keys != NULL, "Expected valid keys")
DEBUG_ASSERT2(args != NULL, "Expected valid encryption args")
return ncCryptoChacha20(
keys->chacha_key,
keys->chacha_nonce,
args->inputData, /* Input data */
args->outputData, /* Output data */
args->dataSize /* Data size (input and output are assumed to be the same size) */
);
}
static _nc_fn_inline cstatus_t _getMessageKey(
const struct conversation_key* converstationKey,
const cspan_t* nonce,
struct message_key* messageKey
)
{
cspan_t prkSpan;
span_t okmSpan;
DEBUG_ASSERT2(nonce != NULL, "Expected valid nonce buffer")
DEBUG_ASSERT2(converstationKey != NULL, "Expected valid conversation key")
DEBUG_ASSERT2(messageKey != NULL, "Expected valid message key buffer")
ncSpanInitC(&prkSpan, converstationKey->value, sizeof(struct conversation_key)); /* Conversation key is the input key */
ncSpanInit(&okmSpan, messageKey->value, sizeof(struct message_key)); /* Output produces a message key (write it directly to struct memory) */
/* Nonce is the info */
return ncCryptoSha256HkdfExpand(&prkSpan, nonce, &okmSpan);
}
static _nc_fn_inline NCResult _encryptEx(
const NCContext* ctx,
const struct conversation_key* ck,
uint8_t* hmacKey,
NCEncryptionArgs* args
)
{
NCResult result;
cspan_t nonceSpan;
struct message_key messageKey;
const struct nc_expand_keys* expandedKeys;
DEBUG_ASSERT2(ctx != NULL, "Expected valid context")
DEBUG_ASSERT2(ck != NULL, "Expected valid conversation key")
DEBUG_ASSERT2(args != NULL, "Expected valid encryption args")
DEBUG_ASSERT2(hmacKey != NULL, "Expected valid hmac key buffer")
result = NC_SUCCESS;
ncSpanInitC(&nonceSpan, args->nonce32, NC_ENCRYPTION_NONCE_SIZE);
/* Message key will be derrived on every encryption call */
if (_getMessageKey(ck, &nonceSpan, &messageKey) != CSTATUS_OK)
{
result = E_OPERATION_FAILED;
goto Cleanup;
}
/* Split apart the message key into it's expanded form so components can be extracted */
expandedKeys = _expandKeysFromHkdf(&messageKey);
/* Copy the hmac key into the args */
MEMMOV(hmacKey, expandedKeys->hmac_key, NC_HMAC_KEY_SIZE);
/* CHACHA20 (the result will be 0 on success) */
if (_chachaEncipher(expandedKeys, args) != CSTATUS_OK)
{
result = E_OPERATION_FAILED;
}
Cleanup:
ZERO_FILL(&messageKey, sizeof(messageKey));
return result;
}
static _nc_fn_inline NCResult _decryptEx(const NCContext* ctx, const struct conversation_key* ck, NCEncryptionArgs* args)
{
NCResult result;
cspan_t nonceSpan;
struct message_key messageKey;
const struct nc_expand_keys* cipherKeys;
DEBUG_ASSERT2(ctx != NULL, "Expected valid context")
DEBUG_ASSERT2(ck != NULL, "Expected valid conversation key")
DEBUG_ASSERT2(args != NULL, "Expected valid encryption args")
result = NC_SUCCESS;
ncSpanInitC(&nonceSpan, args->nonce32, NC_ENCRYPTION_NONCE_SIZE);
if (_getMessageKey(ck, &nonceSpan, &messageKey) != CSTATUS_OK)
{
result = E_OPERATION_FAILED;
goto Cleanup;
}
/* Expand the keys from the hkdf so we can use them in the cipher */
cipherKeys = _expandKeysFromHkdf(&messageKey);
/* CHACHA20 (the result will be 0 on success) */
if (_chachaEncipher(cipherKeys, args) != CSTATUS_OK)
{
result = E_OPERATION_FAILED;
}
Cleanup:
ZERO_FILL(&messageKey, sizeof(messageKey));
return result;
}
static _nc_fn_inline cstatus_t _computeHmac(const uint8_t key[NC_HMAC_KEY_SIZE], const cspan_t* payload, sha256_t hmacOut)
{
cspan_t keySpan;
DEBUG_ASSERT2(key != NULL, "Expected valid hmac key")
DEBUG_ASSERT2(payload != NULL, "Expected valid mac verification args")
DEBUG_ASSERT2(hmacOut != NULL, "Expected valid hmac output buffer")
ncSpanInitC(&keySpan, key, NC_HMAC_KEY_SIZE);
return ncCryptoHmacSha256(&keySpan, payload, hmacOut);
}
static NCResult _verifyMacEx(
const NCContext* ctx,
const uint8_t conversationKey[NC_CONV_KEY_SIZE],
NCMacVerifyArgs* args
)
{
NCResult result;
cspan_t payloadSpan, nonceSpan;
sha256_t hmacOut;
const struct nc_expand_keys* keys;
struct message_key messageKey;
DEBUG_ASSERT2(ctx != NULL, "Expected valid context")
DEBUG_ASSERT2(conversationKey != NULL, "Expected valid conversation key")
DEBUG_ASSERT2(args != NULL, "Expected valid mac verification args")
ncSpanInitC(&nonceSpan, args->nonce32, NC_ENCRYPTION_NONCE_SIZE);
ncSpanInitC(&payloadSpan, args->payload, args->payloadSize);
/*
* Message key is again required for the hmac verification
*/
if (_getMessageKey((struct conversation_key*)conversationKey, &nonceSpan, &messageKey) != CSTATUS_OK)
{
result = E_OPERATION_FAILED;
goto Cleanup;
}
/* Expand keys to get the hmac-key */
keys = _expandKeysFromHkdf(&messageKey);
/*
* Compute the hmac of the data using the computed hmac key
*/
if (_computeHmac(keys->hmac_key, &payloadSpan, hmacOut) != CSTATUS_OK)
{
result = E_OPERATION_FAILED;
goto Cleanup;
}
/* constant time compare the macs */
result = ncCryptoFixedTimeComp(hmacOut, args->mac32, NC_ENCRYPTION_MAC_SIZE) == 0 ? NC_SUCCESS : E_OPERATION_FAILED;
Cleanup:
ZERO_FILL(&messageKey, sizeof(messageKey));
ZERO_FILL(hmacOut, sizeof(hmacOut));
return result;
}
/*
* EXTERNAL API FUNCTIONS
*/
NC_EXPORT uint32_t NC_CC NCGetContextStructSize(void)
{
return sizeof(NCContext);
}
NC_EXPORT NCContext* NC_CC NCGetSharedContext(void)
{
/*Return the global address of the shared context structure */
return &_ncSharedCtx;
}
NC_EXPORT NCResult NC_CC NCInitContext(
NCContext* ctx,
const uint8_t entropy[NC_CONTEXT_ENTROPY_SIZE]
)
{
CHECK_NULL_ARG(ctx, 0)
CHECK_NULL_ARG(entropy, 1)
ctx->secpCtx = secp256k1_context_create(SECP256K1_CONTEXT_NONE);
/*
* Randomize once on init, users can call reinit to
* randomize again as needed.
*/
return secp256k1_context_randomize(ctx->secpCtx, entropy) ? NC_SUCCESS : E_INVALID_ARG;
}
NC_EXPORT NCResult NC_CC NCReInitContext(
NCContext* ctx,
const uint8_t entropy[NC_CONTEXT_ENTROPY_SIZE]
)
{
CHECK_NULL_ARG(ctx, 0)
CHECK_NULL_ARG(entropy, 1)
CHECK_CONTEXT_STATE(ctx, 0)
/* Only randomize again */
return secp256k1_context_randomize(ctx->secpCtx, entropy) ? NC_SUCCESS : E_INVALID_ARG;
}
NC_EXPORT NCResult NC_CC NCDestroyContext(NCContext* ctx)
{
CHECK_NULL_ARG(ctx, 0)
CHECK_CONTEXT_STATE(ctx, 0)
/* Destroy secp256k1 context */
secp256k1_context_destroy(ctx->secpCtx);
/* Wipe the context */
ZERO_FILL(ctx, sizeof(NCContext));
return NC_SUCCESS;
}
/* KEY Functions */
NC_EXPORT NCResult NC_CC NCGetPublicKey(
const NCContext* ctx,
const NCSecretKey* sk,
NCPublicKey* pk
)
{
int result;
secp256k1_keypair keyPair;
secp256k1_xonly_pubkey xonly;
CHECK_NULL_ARG(ctx, 0)
CHECK_CONTEXT_STATE(ctx, 0)
CHECK_NULL_ARG(sk, 1)
CHECK_NULL_ARG(pk, 2)
if (secp256k1_keypair_create(ctx->secpCtx, &keyPair, sk->key) != 1)
{
return E_INVALID_ARG;
}
/* Generate the x-only public key, docs say this should always return 1 */
result = secp256k1_keypair_xonly_pub(ctx->secpCtx, &xonly, NULL, &keyPair);
DEBUG_ASSERT2(result == 1, "Expected x-only kepair to ALWAYS return 1")
/* Convert to compressed pubkey */
result = _convertFromXonly(ctx, &xonly, pk);
DEBUG_ASSERT2(result == 1, "Expected x-only pubkey serialize to return 1")
/* Clean out keypair */
ZERO_FILL(&keyPair, sizeof(keyPair));
ZERO_FILL(&xonly, sizeof(xonly));
return NC_SUCCESS;
}
NC_EXPORT NCResult NC_CC NCValidateSecretKey(const NCContext* ctx, const NCSecretKey* sk)
{
CHECK_NULL_ARG(ctx, 0)
CHECK_NULL_ARG(sk, 1)
CHECK_CONTEXT_STATE(ctx, 0)
/* Validate the secret key */
return secp256k1_ec_seckey_verify(ctx->secpCtx, sk->key);
}
/* Ecdsa Functions */
NC_EXPORT NCResult NC_CC NCSignDigest(
const NCContext* ctx,
const NCSecretKey* sk,
const uint8_t random32[32],
const uint8_t digest32[32],
uint8_t sig64[64]
)
{
int result;
secp256k1_keypair keyPair;
secp256k1_xonly_pubkey xonly;
/* Validate arguments */
CHECK_NULL_ARG(ctx, 0)
CHECK_CONTEXT_STATE(ctx, 0)
CHECK_NULL_ARG(sk, 1)
CHECK_NULL_ARG(random32, 2)
CHECK_NULL_ARG(digest32, 3)
CHECK_NULL_ARG(sig64, 4)
/* Fill keypair structure from the callers secret key */
if (secp256k1_keypair_create(ctx->secpCtx, &keyPair, sk->key) != 1)
{
return E_INVALID_ARG;
}
/* Sign the digest */
result = secp256k1_schnorrsig_sign32(ctx->secpCtx, sig64, digest32, &keyPair, random32);
DEBUG_ASSERT2(result == 1, "Expected schnorr signature to return 1");
/* x-only public key from keypair so the signature can be verified */
result = secp256k1_keypair_xonly_pub(ctx->secpCtx, &xonly, NULL, &keyPair);
DEBUG_ASSERT2(result == 1, "Expected x-only public key to ALWAYS return 1");
/* Verify the signature is valid */
result = secp256k1_schnorrsig_verify(ctx->secpCtx, sig64, digest32, 32, &xonly);
ZERO_FILL(&keyPair, sizeof(keyPair));
ZERO_FILL(&xonly, sizeof(xonly));
return result == 1 ? NC_SUCCESS : E_INVALID_ARG;
}
NC_EXPORT NCResult NC_CC NCSignData(
const NCContext* ctx,
const NCSecretKey* sk,
const uint8_t random32[32],
const uint8_t* data,
uint32_t dataSize,
uint8_t sig64[64]
)
{
cspan_t dataSpan;
sha256_t digest;
/* Double check is required because arg position differs */
CHECK_NULL_ARG(ctx, 0)
CHECK_NULL_ARG(sk, 1)
CHECK_NULL_ARG(random32, 2)
CHECK_NULL_ARG(data, 3)
CHECK_ARG_RANGE(dataSize, 1, UINT32_MAX, 4)
CHECK_NULL_ARG(sig64, 5)
ncSpanInitC(&dataSpan, data, dataSize);
/* Compute sha256 of the data before signing */
if(ncCryptoDigestSha256(&dataSpan, digest) != CSTATUS_OK)
{
return E_INVALID_ARG;
}
/* Sign the freshly computed digest */
return NCSignDigest(ctx, sk, random32, digest, sig64);
}
NC_EXPORT NCResult NC_CC NCVerifyDigest(
const NCContext* ctx,
const NCPublicKey* pk,
const uint8_t digest32[32],
const uint8_t sig64[64]
)
{
int result;
secp256k1_xonly_pubkey xonly;
CHECK_NULL_ARG(ctx, 0)
CHECK_CONTEXT_STATE(ctx, 0)
CHECK_NULL_ARG(pk, 1)
CHECK_NULL_ARG(digest32, 2)
CHECK_NULL_ARG(sig64, 3)
/* recover the x-only key from a compressed public key */
if(_convertToXonly(ctx, pk, &xonly) != 1)
{
return E_INVALID_ARG;
}
/* Verify the signature */
result = secp256k1_schnorrsig_verify(ctx->secpCtx, sig64, digest32, 32, &xonly);
ZERO_FILL(&xonly, sizeof(xonly));
return result == 1 ? NC_SUCCESS : E_INVALID_ARG;
}
NC_EXPORT NCResult NC_CC NCVerifyData(
const NCContext* ctx,
const NCPublicKey* pk,
const uint8_t* data,
const uint32_t dataSize,
const uint8_t sig64[64]
)
{
sha256_t digest;
cspan_t dataSpan;
CHECK_NULL_ARG(ctx, 0)
CHECK_NULL_ARG(pk, 1)
CHECK_NULL_ARG(data, 2)
CHECK_ARG_RANGE(dataSize, 1, UINT32_MAX, 3)
CHECK_NULL_ARG(sig64, 4)
ncSpanInitC(&dataSpan, data, dataSize);
/* Compute sha256 of the data before verifying */
if (ncCryptoDigestSha256(&dataSpan, digest) != CSTATUS_OK)
{
return E_INVALID_ARG;
}
/* Verify the freshly computed digest */
return NCVerifyDigest(ctx, pk, digest, sig64);
}
/* ECDH Functions */
NC_EXPORT NCResult NC_CC NCGetSharedSecret(
const NCContext* ctx,
const NCSecretKey* sk,
const NCPublicKey* otherPk,
uint8_t sharedPoint[NC_SHARED_SEC_SIZE]
)
{
CHECK_NULL_ARG(ctx, 0)
CHECK_CONTEXT_STATE(ctx, 0)
CHECK_NULL_ARG(sk, 1)
CHECK_NULL_ARG(otherPk, 2)
CHECK_NULL_ARG(sharedPoint, 3)
return _computeSharedSecret(ctx, sk, otherPk, (struct shared_secret*)sharedPoint);
}
NC_EXPORT NCResult NC_CC NCGetConversationKeyEx(
const NCContext* ctx,
const uint8_t sharedPoint[NC_SHARED_SEC_SIZE],
uint8_t conversationKey[NC_CONV_KEY_SIZE]
)
{
CHECK_NULL_ARG(ctx, 0)
CHECK_CONTEXT_STATE(ctx, 0)
CHECK_NULL_ARG(sharedPoint, 1)
CHECK_NULL_ARG(conversationKey, 2)
/* Cast the shared point to the shared secret type */
return _computeConversationKey(
ctx,
(struct shared_secret*)sharedPoint,
(struct conversation_key*)conversationKey
);
}
NC_EXPORT NCResult NC_CC NCGetConversationKey(
const NCContext* ctx,
const NCSecretKey* sk,
const NCPublicKey* pk,
uint8_t conversationKey[NC_CONV_KEY_SIZE]
)
{
NCResult result;
struct shared_secret sharedSecret;
CHECK_NULL_ARG(ctx, 0)
CHECK_CONTEXT_STATE(ctx, 0)
CHECK_NULL_ARG(sk, 1)
CHECK_NULL_ARG(pk, 2)
CHECK_NULL_ARG(conversationKey, 3)
/* Compute the shared point */
if ((result = _computeSharedSecret(ctx, sk, pk, &sharedSecret)) != NC_SUCCESS)
{
goto Cleanup;
}
result = _computeConversationKey(ctx, &sharedSecret, (struct conversation_key*)conversationKey);
Cleanup:
/* Clean up sensitive data */
ZERO_FILL(&sharedSecret, sizeof(sharedSecret));
return result;
}
NC_EXPORT NCResult NC_CC NCEncryptEx(
const NCContext* ctx,
const uint8_t conversationKey[NC_CONV_KEY_SIZE],
NCEncryptionArgs* args
)
{
CHECK_NULL_ARG(ctx, 0)
CHECK_CONTEXT_STATE(ctx, 0)
CHECK_NULL_ARG(conversationKey, 1)
CHECK_NULL_ARG(args, 2)
/* Validte ciphertext/plaintext */
CHECK_INVALID_ARG(args->inputData, 2)
CHECK_INVALID_ARG(args->outputData, 2)
CHECK_INVALID_ARG(args->nonce32, 2)
CHECK_INVALID_ARG(args->hmacKeyOut32, 2)
CHECK_ARG_RANGE(args->dataSize, NIP44_MIN_ENC_MESSAGE_SIZE, NIP44_MAX_ENC_MESSAGE_SIZE, 2)
return _encryptEx(ctx, (struct conversation_key*)conversationKey, args->hmacKeyOut32, args);
}
NC_EXPORT NCResult NC_CC NCEncrypt(
const NCContext* ctx,
const NCSecretKey* sk,
const NCPublicKey* pk,
NCEncryptionArgs* args
)
{
NCResult result;
struct shared_secret sharedSecret;
struct conversation_key conversationKey;
CHECK_NULL_ARG(ctx, 0)
CHECK_CONTEXT_STATE(ctx, 0)
CHECK_NULL_ARG(sk, 1)
CHECK_NULL_ARG(pk, 2)
CHECK_NULL_ARG(args, 3)
/* Validate input/output data */
CHECK_INVALID_ARG(args->inputData, 3)
CHECK_INVALID_ARG(args->outputData, 3)
CHECK_INVALID_ARG(args->nonce32, 3)
CHECK_INVALID_ARG(args->hmacKeyOut32, 3)
CHECK_ARG_RANGE(args->dataSize, NIP44_MIN_ENC_MESSAGE_SIZE, NIP44_MAX_ENC_MESSAGE_SIZE, 3)
switch(args->version)
{
case NC_ENC_VERSION_NIP44:
break; /* Allow nip44 */
/* At the moment nip04 compatability is not supported */
case NC_ENC_VERSION_NIP04:
default:
return E_VERSION_NOT_SUPPORTED;
}
/* Compute the shared point */
if ((result = _computeSharedSecret(ctx, sk, pk, &sharedSecret)) != NC_SUCCESS)
{
goto Cleanup;
}
/* Compute the conversation key from secret and pubkic keys */
if ((result = _computeConversationKey(ctx, &sharedSecret, &conversationKey)) != NC_SUCCESS)
{
goto Cleanup;
}
result = _encryptEx(ctx, &conversationKey, args->hmacKeyOut32, args);
Cleanup:
/* Clean up sensitive data */
ZERO_FILL(&sharedSecret, sizeof(sharedSecret));
ZERO_FILL(&conversationKey, sizeof(conversationKey));
return result;
}
NC_EXPORT NCResult NC_CC NCDecryptEx(
const NCContext* ctx,
const uint8_t conversationKey[NC_CONV_KEY_SIZE],
NCEncryptionArgs* args
)
{
CHECK_NULL_ARG(ctx, 0)
CHECK_CONTEXT_STATE(ctx, 0)
CHECK_NULL_ARG(conversationKey, 1)
CHECK_NULL_ARG(args, 2)
/* Validte ciphertext/plaintext */
CHECK_INVALID_ARG(args->inputData, 2)
CHECK_INVALID_ARG(args->outputData, 2)
CHECK_INVALID_ARG(args->nonce32, 2)
CHECK_ARG_RANGE(args->dataSize, NIP44_MIN_ENC_MESSAGE_SIZE, NIP44_MAX_ENC_MESSAGE_SIZE, 2)
return _decryptEx(ctx, (struct conversation_key*)conversationKey, args);
}
NC_EXPORT NCResult NC_CC NCDecrypt(
const NCContext* ctx,
const NCSecretKey* sk,
const NCPublicKey* pk,
NCEncryptionArgs* args
)
{
NCResult result;
struct shared_secret sharedSecret;
struct conversation_key conversationKey;
CHECK_NULL_ARG(ctx, 0)
CHECK_CONTEXT_STATE(ctx, 0)
CHECK_NULL_ARG(sk, 1)
CHECK_NULL_ARG(pk, 2)
CHECK_NULL_ARG(args, 3)
/* Validte ciphertext/plaintext */
CHECK_INVALID_ARG(args->inputData, 3)
CHECK_INVALID_ARG(args->outputData, 3)
CHECK_INVALID_ARG(args->nonce32, 3)
CHECK_ARG_RANGE(args->dataSize, NIP44_MIN_ENC_MESSAGE_SIZE, NIP44_MAX_ENC_MESSAGE_SIZE, 3)
if ((result = _computeSharedSecret(ctx, sk, pk, &sharedSecret)) != NC_SUCCESS)
{
goto Cleanup;
}
if ((result = _computeConversationKey(ctx, &sharedSecret, &conversationKey)) != NC_SUCCESS)
{
goto Cleanup;
}
result = _decryptEx(ctx, &conversationKey, args);
Cleanup:
/* Clean up sensitive data */
ZERO_FILL(&sharedSecret, sizeof(sharedSecret));
ZERO_FILL(&conversationKey, sizeof(conversationKey));
return result;
}
NC_EXPORT NCResult NCComputeMac(
const NCContext* ctx,
const uint8_t hmacKey[NC_HMAC_KEY_SIZE],
const uint8_t* payload,
uint32_t payloadSize,
uint8_t hmacOut[NC_ENCRYPTION_MAC_SIZE]
)
{
cspan_t payloadSpan;
CHECK_NULL_ARG(ctx, 0)
CHECK_CONTEXT_STATE(ctx, 0)
CHECK_NULL_ARG(hmacKey, 1)
CHECK_NULL_ARG(payload, 2)
CHECK_ARG_RANGE(payloadSize, 1, UINT32_MAX, 3)
CHECK_NULL_ARG(hmacOut, 4)
ncSpanInitC(&payloadSpan, payload, payloadSize);
/*
* Compute the hmac of the data using the supplied hmac key
*/
return _computeHmac(hmacKey, &payloadSpan, hmacOut) == CSTATUS_OK ? NC_SUCCESS : E_OPERATION_FAILED;
}
NC_EXPORT NCResult NC_CC NCVerifyMacEx(
const NCContext* ctx,
const uint8_t conversationKey[NC_CONV_KEY_SIZE],
NCMacVerifyArgs* args
)
{
CHECK_NULL_ARG(ctx, 0)
CHECK_CONTEXT_STATE(ctx, 0)
CHECK_NULL_ARG(conversationKey, 1)
CHECK_NULL_ARG(args, 2)
CHECK_INVALID_ARG(args->mac32, 2)
CHECK_INVALID_ARG(args->payload, 2)
CHECK_INVALID_ARG(args->nonce32, 2)
CHECK_ARG_RANGE(args->payloadSize, NIP44_MIN_ENC_MESSAGE_SIZE, NIP44_MAX_ENC_MESSAGE_SIZE, 2)
return _verifyMacEx(ctx, conversationKey, args);
}
NC_EXPORT NCResult NC_CC NCVerifyMac(
const NCContext* ctx,
const NCSecretKey* sk,
const NCPublicKey* pk,
NCMacVerifyArgs* args
)
{
NCResult result;
struct shared_secret sharedSecret;
struct conversation_key conversationKey;
CHECK_NULL_ARG(ctx, 0)
CHECK_CONTEXT_STATE(ctx, 0)
CHECK_NULL_ARG(sk, 1)
CHECK_NULL_ARG(pk, 2)
CHECK_NULL_ARG(args, 3)
CHECK_INVALID_ARG(args->mac32, 3)
CHECK_INVALID_ARG(args->payload, 3)
CHECK_INVALID_ARG(args->nonce32, 3)
CHECK_ARG_RANGE(args->payloadSize, NIP44_MIN_ENC_MESSAGE_SIZE, NIP44_MAX_ENC_MESSAGE_SIZE, 3)
/* Computed the shared point so we can get the converstation key */
if ((result = _computeSharedSecret(ctx, sk, pk, &sharedSecret)) != NC_SUCCESS)
{
goto Cleanup;
}
if ((result = _computeConversationKey(ctx, &sharedSecret, &conversationKey)) != NC_SUCCESS)
{
goto Cleanup;
}
result = _verifyMacEx(ctx, conversationKey.value, args);
Cleanup:
/* Clean up sensitive data */
ZERO_FILL(&sharedSecret, sizeof(sharedSecret));
ZERO_FILL(&conversationKey, sizeof(conversationKey));
return result;
}
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