/* -*- Mode: C; tab-width: 4 -*-
*
* Copyright (c) 2011-2013 Apple Inc. All rights reserved.
*
* 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.
*/
// ***************************************************************************
// CryptoSupport.c
// Supporting routines for DNSSEC crypto
// ***************************************************************************
#include "mDNSEmbeddedAPI.h"
#include <CommonCrypto/CommonDigest.h> // For Hash algorithms SHA1 etc.
#include <dispatch/dispatch.h> // For Base32/Base64 encoding/decoding
#include <dispatch/private.h> // dispatch_data_create_with_transform
#include "CryptoAlg.h"
#include "CryptoSupport.h"
#include "dnssec.h"
#include "DNSSECSupport.h"
#if TARGET_OS_IPHONE
#include "SecRSAKey.h" // For RSA_SHA1 etc. verification
#else
#include <Security/Security.h>
#endif
#if !TARGET_OS_IPHONE
mDNSlocal SecKeyRef SecKeyCreateRSAPublicKey_OSX(unsigned char *asn1, int length);
#endif
typedef struct
{
dispatch_data_t encData;
dispatch_data_t encMap;
dispatch_data_t encNULL;
}encContext;
mDNSlocal mStatus enc_create(AlgContext *ctx)
{
encContext *ptr;
switch (ctx->alg)
{
case ENC_BASE32:
case ENC_BASE64:
ptr = (encContext *)mDNSPlatformMemAllocate(sizeof(encContext));
if (!ptr) return mStatus_NoMemoryErr;
break;
default:
LogMsg("enc_create: Unsupported algorithm %d", ctx->alg);
return mStatus_BadParamErr;
}
ptr->encData = NULL;
ptr->encMap = NULL;
// The encoded data is not NULL terminated. So, we concatenate a null byte later when we encode and map
// the real data.
ptr->encNULL = dispatch_data_create("", 1, dispatch_get_global_queue(0, 0), ^{});
if (!ptr->encNULL)
{
mDNSPlatformMemFree(ptr);
return mStatus_NoMemoryErr;
}
ctx->context = ptr;
return mStatus_NoError;
}
mDNSlocal mStatus enc_destroy(AlgContext *ctx)
{
encContext *ptr = (encContext *)ctx->context;
if (ptr->encData) dispatch_release(ptr->encData);
if (ptr->encMap) dispatch_release(ptr->encMap);
if (ptr->encNULL) dispatch_release(ptr->encNULL);
mDNSPlatformMemFree(ptr);
return mStatus_NoError;
}
mDNSlocal mStatus enc_add(AlgContext *ctx, const void *data, mDNSu32 len)
{
switch (ctx->alg)
{
case ENC_BASE32:
case ENC_BASE64:
{
encContext *ptr = (encContext *)ctx->context;
dispatch_data_t src_data = dispatch_data_create(data, len, dispatch_get_global_queue(0, 0), ^{});
if (!src_data)
{
LogMsg("enc_add: dispatch_data_create src failed");
return mStatus_BadParamErr;
}
dispatch_data_t dest_data = dispatch_data_create_with_transform(src_data, DISPATCH_DATA_FORMAT_TYPE_NONE,
(ctx->alg == ENC_BASE32 ? DISPATCH_DATA_FORMAT_TYPE_BASE32HEX : DISPATCH_DATA_FORMAT_TYPE_BASE64));
dispatch_release(src_data);
if (!dest_data)
{
LogMsg("enc_add: dispatch_data_create dst failed");
return mStatus_BadParamErr;
}
ptr->encData = dest_data;
return mStatus_NoError;
}
default:
LogMsg("enc_add: Unsupported algorithm %d", ctx->alg);
return mStatus_BadParamErr;
}
}
mDNSlocal mDNSu8* enc_encode(AlgContext *ctx)
{
const void *result = NULL;
switch (ctx->alg)
{
case ENC_BASE32:
case ENC_BASE64:
{
encContext *ptr = (encContext *)ctx->context;
size_t size;
dispatch_data_t dest_data = ptr->encData;
dispatch_data_t data = dispatch_data_create_concat(dest_data, ptr->encNULL);
if (!data)
{
LogMsg("enc_encode: cannot concatenate");
return NULL;
}
dispatch_data_t map = dispatch_data_create_map(data, &result, &size);
if (!map)
{
LogMsg("enc_encode: cannot create map %d", ctx->alg);
return NULL;
}
dispatch_release(dest_data);
ptr->encData = data;
ptr->encMap = map;
return (mDNSu8 *)result;
}
default:
LogMsg("enc_encode: Unsupported algorithm %d", ctx->alg);
return mDNSNULL;
}
}
mDNSlocal mStatus sha_create(AlgContext *ctx)
{
mDNSu8 *ptr;
switch (ctx->alg)
{
case SHA1_DIGEST_TYPE:
ptr = mDNSPlatformMemAllocate(sizeof(CC_SHA1_CTX));
if (!ptr) return mStatus_NoMemoryErr;
CC_SHA1_Init((CC_SHA1_CTX *)ptr);
break;
case SHA256_DIGEST_TYPE:
ptr = mDNSPlatformMemAllocate(sizeof(CC_SHA256_CTX));
if (!ptr) return mStatus_NoMemoryErr;
CC_SHA256_Init((CC_SHA256_CTX *)ptr);
break;
default:
LogMsg("sha_create: Unsupported algorithm %d", ctx->alg);
return mStatus_BadParamErr;
}
ctx->context = ptr;
return mStatus_NoError;
}
mDNSlocal mStatus sha_destroy(AlgContext *ctx)
{
mDNSPlatformMemFree(ctx->context);
return mStatus_NoError;
}
mDNSlocal mDNSu32 sha_len(AlgContext *ctx)
{
switch (ctx->alg)
{
case SHA1_DIGEST_TYPE:
return CC_SHA1_DIGEST_LENGTH;
case SHA256_DIGEST_TYPE:
return CC_SHA256_DIGEST_LENGTH;
default:
LogMsg("sha_len: Unsupported algorithm %d", ctx->alg);
return mStatus_BadParamErr;
}
}
mDNSlocal mStatus sha_add(AlgContext *ctx, const void *data, mDNSu32 len)
{
switch (ctx->alg)
{
case SHA1_DIGEST_TYPE:
CC_SHA1_Update((CC_SHA1_CTX *)ctx->context, data, len);
break;
case SHA256_DIGEST_TYPE:
CC_SHA256_Update((CC_SHA256_CTX *)ctx->context, data, len);
break;
default:
LogMsg("sha_add: Unsupported algorithm %d", ctx->alg);
return mStatus_BadParamErr;
}
return mStatus_NoError;
}
mDNSlocal mStatus sha_verify(AlgContext *ctx, mDNSu8 *key, mDNSu32 keylen, mDNSu8 *digestIn, mDNSu32 dlen)
{
mDNSu8 digest[CC_SHA512_DIGEST_LENGTH];
mDNSu32 digestLen;
(void) key; //unused
(void)keylen; //unused
switch (ctx->alg)
{
case SHA1_DIGEST_TYPE:
digestLen = CC_SHA1_DIGEST_LENGTH;
CC_SHA1_Final(digest, (CC_SHA1_CTX *)ctx->context);
break;
case SHA256_DIGEST_TYPE:
digestLen = CC_SHA256_DIGEST_LENGTH;
CC_SHA256_Final(digest, (CC_SHA256_CTX *)ctx->context);
break;
default:
LogMsg("sha_verify: Unsupported algorithm %d", ctx->alg);
return mStatus_BadParamErr;
}
if (dlen != digestLen)
{
LogMsg("sha_verify(Alg %d): digest len mismatch len %u, expected %u", ctx->alg, (unsigned int)dlen, (unsigned int)digestLen);
return mStatus_BadParamErr;
}
if (!memcmp(digest, digestIn, digestLen))
return mStatus_NoError;
else
return mStatus_NoAuth;
}
mDNSlocal mStatus sha_final(AlgContext *ctx, void *digestOut, mDNSu32 dlen)
{
mDNSu8 digest[CC_SHA512_DIGEST_LENGTH];
mDNSu32 digestLen;
switch (ctx->alg)
{
case SHA1_DIGEST_TYPE:
digestLen = CC_SHA1_DIGEST_LENGTH;
CC_SHA1_Final(digest, (CC_SHA1_CTX *)ctx->context);
break;
case SHA256_DIGEST_TYPE:
digestLen = CC_SHA256_DIGEST_LENGTH;
CC_SHA256_Final(digest, (CC_SHA256_CTX *)ctx->context);
break;
default:
LogMsg("sha_final: Unsupported algorithm %d", ctx->alg);
return mStatus_BadParamErr;
}
if (dlen != digestLen)
{
LogMsg("sha_final(Alg %d): digest len mismatch len %u, expected %u", ctx->alg, (unsigned int)dlen, (unsigned int)digestLen);
return mStatus_BadParamErr;
}
memcpy(digestOut, digest, digestLen);
return mStatus_NoError;
}
mDNSlocal mStatus rsa_sha_create(AlgContext *ctx)
{
mDNSu8 *ptr;
switch (ctx->alg)
{
case CRYPTO_RSA_NSEC3_SHA1:
case CRYPTO_RSA_SHA1:
ptr = mDNSPlatformMemAllocate(sizeof(CC_SHA1_CTX));
if (!ptr) return mStatus_NoMemoryErr;
CC_SHA1_Init((CC_SHA1_CTX *)ptr);
break;
case CRYPTO_RSA_SHA256:
ptr = mDNSPlatformMemAllocate(sizeof(CC_SHA256_CTX));
if (!ptr) return mStatus_NoMemoryErr;
CC_SHA256_Init((CC_SHA256_CTX *)ptr);
break;
case CRYPTO_RSA_SHA512:
ptr = mDNSPlatformMemAllocate(sizeof(CC_SHA512_CTX));
if (!ptr) return mStatus_NoMemoryErr;
CC_SHA512_Init((CC_SHA512_CTX *)ptr);
break;
default:
LogMsg("rsa_sha_create: Unsupported algorithm %d", ctx->alg);
return mStatus_BadParamErr;
}
ctx->context = ptr;
return mStatus_NoError;
}
mDNSlocal mStatus rsa_sha_destroy(AlgContext *ctx)
{
mDNSPlatformMemFree(ctx->context);
return mStatus_NoError;
}
mDNSlocal mDNSu32 rsa_sha_len(AlgContext *ctx)
{
switch (ctx->alg)
{
case CRYPTO_RSA_NSEC3_SHA1:
case CRYPTO_RSA_SHA1:
return CC_SHA1_DIGEST_LENGTH;
case CRYPTO_RSA_SHA256:
return CC_SHA256_DIGEST_LENGTH;
case CRYPTO_RSA_SHA512:
return CC_SHA512_DIGEST_LENGTH;
default:
LogMsg("rsa_sha_len: Unsupported algorithm %d", ctx->alg);
return mStatus_BadParamErr;
}
}
mDNSlocal mStatus rsa_sha_add(AlgContext *ctx, const void *data, mDNSu32 len)
{
switch (ctx->alg)
{
case CRYPTO_RSA_NSEC3_SHA1:
case CRYPTO_RSA_SHA1:
CC_SHA1_Update((CC_SHA1_CTX *)ctx->context, data, len);
break;
case CRYPTO_RSA_SHA256:
CC_SHA256_Update((CC_SHA256_CTX *)ctx->context, data, len);
break;
case CRYPTO_RSA_SHA512:
CC_SHA512_Update((CC_SHA512_CTX *)ctx->context, data, len);
break;
default:
LogMsg("rsa_sha_add: Unsupported algorithm %d", ctx->alg);
return mStatus_BadParamErr;
}
return mStatus_NoError;
}
mDNSlocal SecKeyRef rfc3110_import(const mDNSu8 *data, const mDNSu32 len)
{
static const int max_modulus_bytes = 512; // Modulus is limited to 4096 bits (512 octets) in length.
static const int max_exp_bytes = 512; // Exponent is limited to 4096 bits (512 octets) in length.
static const int asn1_type_bytes = 3; // Since there is an ASN1 SEQ and two INTs.
static const int asn1_max_len_bytes = 3 * 3; // Capped at 3 due to max payload size.
unsigned char asn1[max_modulus_bytes + 1 + max_exp_bytes + asn1_type_bytes + asn1_max_len_bytes]; // +1 is for leading 0 for non negative asn1 number
const mDNSu8 *modulus;
unsigned int modulus_length;
const mDNSu8 *exponent;
unsigned int exp_length;
unsigned int num_length_bytes;
mDNSu32 index = 0;
mDNSu32 asn1_length = 0;
// Validate Input
if (!data)
return NULL;
// we have to have at least 1 byte for the length
if (len < 1)
return NULL;
// Parse Modulus and Exponent
// If the first byte is zero, then the exponent length is in the three-byte format, otherwise the length is in the first byte.
if (data[0] == 0)
{
if (len < 3)
return NULL;
exp_length = (data[1] << 8) | data[2];
num_length_bytes = 3;
}
else
{
exp_length = data[0];
num_length_bytes = 1;
}
// RFC3110 limits the exponent length to 4096 bits (512 octets).
if (exp_length > 512)
return NULL;
// We have to have at least len bytes + size of exponent.
if (len < (num_length_bytes + exp_length))
return NULL;
// The modulus is the remaining space.
modulus_length = len - (num_length_bytes + exp_length);
// RFC3110 limits the modulus length to 4096 bits (512 octets).
if (modulus_length > 512)
return NULL;
if (modulus_length < 1)
return NULL;
// add 1 to modulus length for pre-ceding 0 t make ASN1 value non-negative
++modulus_length;
exponent = &data[num_length_bytes];
modulus = &data[num_length_bytes + exp_length];
// 2 bytes for commands since first doesn't count
// 2 bytes for min 1 byte length field
asn1_length = modulus_length + exp_length + 2 + 2;
// Account for modulus length causing INT length field to grow.
if (modulus_length >= 128)
{
if (modulus_length > 255)
asn1_length += 2;
else
asn1_length += 1;
}
// Account for exponent length causing INT length field to grow.
if (exp_length >= 128)
{
if (exp_length > 255)
asn1_length += 2;
else
asn1_length += 1;
}
// Construct ASN1 formatted public key
// Write ASN1 SEQ byte
asn1[index++] = 0x30;
// Write ASN1 length for SEQ
if (asn1_length < 128)
{
asn1[index++] = asn1_length & 0xFF;
}
else
{
asn1[index++] = (0x80 | ((asn1_length > 255) ? 2 : 1));
if (asn1_length > 255)
asn1[index++] = (asn1_length & 0xFF00) >> 8;
asn1[index++] = asn1_length & 0xFF;
}
// Write ASN1 INT for modulus
asn1[index++] = 0x02;
// Write ASN1 length for INT
if (modulus_length < 128)
{
asn1[index++] = modulus_length & 0xFF;
}
else
{
asn1[index++] = 0x80 | ((modulus_length > 255) ? 2 : 1);
if (modulus_length > 255)
asn1[index++] = (modulus_length & 0xFF00) >> 8;
asn1[index++] = modulus_length & 0xFF;
}
// Write preceding 0 so our integer isn't negative
asn1[index++] = 0x00;
// Write actual modulus (-1 for preceding 0)
memcpy(&asn1[index], modulus, modulus_length - 1);
index += (modulus_length - 1);
// Write ASN1 INT for exponent
asn1[index++] = 0x02;
// Write ASN1 length for INT
if (exp_length < 128)
{
asn1[index++] = exp_length & 0xFF;
}
else
{
asn1[index++] = 0x80 | ((exp_length > 255) ? 2 : 1);
if (exp_length > 255)
asn1[index++] = (exp_length & 0xFF00) >> 8;
asn1[index++] = exp_length & 0xFF;
}
// Write exponent bytes
memcpy(&asn1[index], exponent, exp_length);
index += exp_length;
#if TARGET_OS_IPHONE
// index contains bytes written, use it for length
return (SecKeyCreateRSAPublicKey(NULL, asn1, index, kSecKeyEncodingPkcs1));
#else
return (SecKeyCreateRSAPublicKey_OSX(asn1, index));
#endif
}
#if TARGET_OS_IPHONE
mDNSlocal mStatus rsa_sha_verify(AlgContext *ctx, mDNSu8 *key, mDNSu32 keylen, mDNSu8 *signature, mDNSu32 siglen)
{
SecKeyRef keyref;
OSStatus result;
mDNSu8 digest[CC_SHA512_DIGEST_LENGTH];
int digestlen;
int cryptoAlg;
switch (ctx->alg)
{
case CRYPTO_RSA_NSEC3_SHA1:
case CRYPTO_RSA_SHA1:
cryptoAlg = kSecPaddingPKCS1SHA1;
digestlen = CC_SHA1_DIGEST_LENGTH;
CC_SHA1_Final(digest, (CC_SHA1_CTX *)ctx->context);
break;
case CRYPTO_RSA_SHA256:
cryptoAlg = kSecPaddingPKCS1SHA256;
digestlen = CC_SHA256_DIGEST_LENGTH;
CC_SHA256_Final(digest, (CC_SHA256_CTX *)ctx->context);
break;
case CRYPTO_RSA_SHA512:
cryptoAlg = kSecPaddingPKCS1SHA512;
digestlen = CC_SHA512_DIGEST_LENGTH;
CC_SHA512_Final(digest, (CC_SHA512_CTX *)ctx->context);
break;
default:
LogMsg("rsa_sha_verify: Unsupported algorithm %d", ctx->alg);
return mStatus_BadParamErr;
}
keyref = rfc3110_import(key, keylen);
if (!keyref)
{
LogMsg("rsa_sha_verify: Error decoding rfc3110 key data");
return mStatus_NoMemoryErr;
}
result = SecKeyRawVerify(keyref, cryptoAlg, digest, digestlen, signature, siglen);
CFRelease(keyref);
if (result != noErr)
{
LogMsg("rsa_sha_verify: Failed for alg %d", ctx->alg);
return mStatus_BadParamErr;
}
else
{
LogInfo("rsa_sha_verify: Passed for alg %d", ctx->alg);
return mStatus_NoError;
}
}
#else // TARGET_OS_IPHONE
mDNSlocal SecKeyRef SecKeyCreateRSAPublicKey_OSX(unsigned char *asn1, int length)
{
SecKeyRef result = NULL;
SecExternalFormat extFormat = kSecFormatBSAFE;
SecExternalItemType itemType = kSecItemTypePublicKey;
CFArrayRef outArray = NULL;
CFDataRef keyData = CFDataCreate(NULL, asn1, length);
if (!keyData)
return NULL;
OSStatus err = SecItemImport(keyData, NULL, &extFormat, &itemType, 0, NULL, NULL, &outArray);
CFRelease(keyData);
if (noErr != err || outArray == NULL)
{
if (outArray)
CFRelease(outArray);
return NULL;
}
result = (SecKeyRef)CFArrayGetValueAtIndex(outArray, 0);
if (result == NULL)
{
CFRelease(outArray);
return NULL;
}
CFRetain(result);
CFRelease(outArray);
return result;
}
mDNSlocal Boolean VerifyData(SecKeyRef key, CFStringRef digestStr, mDNSu8 *digest, int dlen, int digestlenAttr, mDNSu8 *sig, int siglen, CFStringRef digest_type)
{
CFErrorRef error;
Boolean ret;
CFDataRef signature = CFDataCreate(NULL, sig, siglen);
if (!signature)
return false;
SecTransformRef verifyXForm = SecVerifyTransformCreate(key, signature, &error);
CFRelease(signature);
if (verifyXForm == NULL)
{
return false;
}
// tell the transform what type of data it is geting
if (!SecTransformSetAttribute(verifyXForm, kSecInputIsAttributeName, digest_type, &error))
{
LogMsg("VerifyData: SecTransformSetAttribute digest_type");
goto err;
}
if (!SecTransformSetAttribute(verifyXForm, kSecDigestTypeAttribute, digestStr, &error))
{
LogMsg("VerifyData: SecTransformSetAttribute digestStr");
goto err;
}
CFNumberRef digestLengthRef = CFNumberCreate(kCFAllocatorDefault, kCFNumberCFIndexType, &digestlenAttr);
if (digestLengthRef == NULL)
{
LogMsg("VerifyData: CFNumberCreate failed");
goto err;
}
ret = SecTransformSetAttribute(verifyXForm, kSecDigestLengthAttribute, digestLengthRef, &error);
CFRelease(digestLengthRef);
if (!ret)
{
LogMsg("VerifyData: SecTransformSetAttribute digestLengthRef");
goto err;
}
CFDataRef dataToSign = CFDataCreate(NULL, digest, dlen);
if (dataToSign == NULL)
{
LogMsg("VerifyData: CFDataCreate failed");
goto err;
}
ret = SecTransformSetAttribute(verifyXForm, kSecTransformInputAttributeName, dataToSign, &error);
CFRelease(dataToSign);
if (!ret)
{
LogMsg("VerifyData: SecTransformSetAttribute TransformAttributeName");
goto err;
}
CFBooleanRef boolRef = SecTransformExecute(verifyXForm, &error);
ret = boolRef ? CFBooleanGetValue(boolRef) : false;
if (boolRef) CFRelease(boolRef);
CFRelease(verifyXForm);
if (error != NULL)
{
CFStringRef errStr = CFErrorCopyDescription(error);
char errorbuf[128];
errorbuf[0] = 0;
if (errStr != NULL)
{
if (!CFStringGetCString(errStr, errorbuf, sizeof(errorbuf), kCFStringEncodingUTF8))
{
LogMsg("VerifyData: CFStringGetCString failed");
}
CFRelease(errStr);
}
LogMsg("VerifyData: SecTransformExecute failed with %s", errorbuf);
return false;
}
return ret;
err:
CFRelease(verifyXForm);
return false;
}
mDNSlocal mStatus rsa_sha_verify(AlgContext *ctx, mDNSu8 *key, mDNSu32 keylen, mDNSu8 *signature, mDNSu32 siglen)
{
SecKeyRef keyref;
mDNSu8 digest[CC_SHA512_DIGEST_LENGTH];
int digestlen;
int digestlenAttr;
CFStringRef digestStr;
mDNSBool ret;
switch (ctx->alg)
{
case CRYPTO_RSA_NSEC3_SHA1:
case CRYPTO_RSA_SHA1:
digestStr = kSecDigestSHA1;
digestlen = CC_SHA1_DIGEST_LENGTH;
digestlenAttr = 0;
CC_SHA1_Final(digest, (CC_SHA1_CTX *)ctx->context);
break;
case CRYPTO_RSA_SHA256:
digestStr = kSecDigestSHA2;
digestlen = CC_SHA256_DIGEST_LENGTH;
digestlenAttr = 256;
CC_SHA256_Final(digest, (CC_SHA256_CTX *)ctx->context);
break;
case CRYPTO_RSA_SHA512:
digestStr = kSecDigestSHA2;
digestlen = CC_SHA512_DIGEST_LENGTH;
digestlenAttr = 512;
CC_SHA512_Final(digest, (CC_SHA512_CTX *)ctx->context);
break;
default:
LogMsg("rsa_sha_verify: Unsupported algorithm %d", ctx->alg);
return mStatus_BadParamErr;
}
keyref = rfc3110_import(key, keylen);
if (!keyref)
{
LogMsg("rsa_sha_verify: Error decoding rfc3110 key data");
return mStatus_NoMemoryErr;
}
ret = VerifyData(keyref, digestStr, digest, digestlen, digestlenAttr, signature, siglen, kSecInputIsDigest);
CFRelease(keyref);
if (!ret)
{
LogMsg("rsa_sha_verify: Failed for alg %d", ctx->alg);
return mStatus_BadParamErr;
}
else
{
LogInfo("rsa_sha_verify: Passed for alg %d", ctx->alg);
return mStatus_NoError;
}
}
#endif // TARGET_OS_IPHONE
AlgFuncs sha_funcs = {sha_create, sha_destroy, sha_len, sha_add, sha_verify, mDNSNULL, sha_final};
AlgFuncs rsa_sha_funcs = {rsa_sha_create, rsa_sha_destroy, rsa_sha_len, rsa_sha_add, rsa_sha_verify, mDNSNULL, mDNSNULL};
AlgFuncs enc_funcs = {enc_create, enc_destroy, mDNSNULL, enc_add, mDNSNULL, enc_encode, mDNSNULL};
#ifndef DNSSEC_DISABLED
mDNSexport mStatus DNSSECCryptoInit(mDNS *const m)
{
mStatus result;
result = DigestAlgInit(SHA1_DIGEST_TYPE, &sha_funcs);
if (result != mStatus_NoError)
return result;
result = DigestAlgInit(SHA256_DIGEST_TYPE, &sha_funcs);
if (result != mStatus_NoError)
return result;
result = CryptoAlgInit(CRYPTO_RSA_SHA1, &rsa_sha_funcs);
if (result != mStatus_NoError)
return result;
result = CryptoAlgInit(CRYPTO_RSA_NSEC3_SHA1, &rsa_sha_funcs);
if (result != mStatus_NoError)
return result;
result = CryptoAlgInit(CRYPTO_RSA_SHA256, &rsa_sha_funcs);
if (result != mStatus_NoError)
return result;
result = CryptoAlgInit(CRYPTO_RSA_SHA512, &rsa_sha_funcs);
if (result != mStatus_NoError)
return result;
result = EncAlgInit(ENC_BASE32, &enc_funcs);
if (result != mStatus_NoError)
return result;
result = EncAlgInit(ENC_BASE64, &enc_funcs);
if (result != mStatus_NoError)
return result;
result = DNSSECPlatformInit(m);
return result;
}
#else // !DNSSEC_DISABLED
mDNSexport mStatus DNSSECCryptoInit(mDNS *const m)
{
(void) m;
return mStatus_NoError;
}
#endif // !DNSSEC_DISABLED