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wolfssl/wolfcrypt/src/random.c
Daniel Pouzzner 7048fa80d4 wolfcrypt/src/random.c and wolfssl/wolfcrypt/settings.h: fixes from CI and peer review: 
* in wc_GenerateSeed_IntelRD(), use stack/register allocation for sanity_word{1,2}, and
* don't set WC_VERBOSE_RNG if WOLFSSL_DEBUG_PRINTF is missing.
2026-01-20 16:48:21 -06:00

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/* random.c
*
* Copyright (C) 2006-2025 wolfSSL Inc.
*
* This file is part of wolfSSL.
*
* wolfSSL is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 3 of the License, or
* (at your option) any later version.
*
* wolfSSL 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1335, USA
*/
/*
DESCRIPTION
This library contains implementation for the random number generator.
*/
/* Possible defines:
* ENTROPY_NUM_UPDATE default: 18
* Number of updates to perform. A hash is created and memory accessed
* based on the hash values in each update of a sample.
* More updates will result in better entropy quality but longer sample
* times.
* ENTROPY_NUM_UPDATES_BITS default: 5
* Number of bits needed to represent ENTROPY_NUM_UPDATE.
* = upper(log2(ENTROPY_NUM_UPDATE))
* ENTROPY_NUM_WORDS_BITS default: 14
* State has 2^ENTROPY_NUMN_WORDS_BITS entries. Range: 8-30
* The value should be based on the cache sizes.
* Use a value that is at least as large as the L1 cache if possible.
* The higher the value, the more likely there will be cache misses and
* better the entropy quality.
* A larger value will use more static memory.
*/
#include <wolfssl/wolfcrypt/libwolfssl_sources.h>
/* on HPUX 11 you may need to install /dev/random see
http://h20293.www2.hp.com/portal/swdepot/displayProductInfo.do?productNumber=KRNG11I
*/
#if defined(ESP_IDF_VERSION_MAJOR) && ESP_IDF_VERSION_MAJOR >= 5
#include <esp_random.h>
#endif
#if defined(HAVE_FIPS) && \
defined(HAVE_FIPS_VERSION) && (HAVE_FIPS_VERSION >= 2)
/* set NO_WRAPPERS before headers, use direct internal f()s not wrappers */
#define FIPS_NO_WRAPPERS
#ifdef USE_WINDOWS_API
#pragma code_seg(".fipsA$i")
#pragma const_seg(".fipsB$i")
#endif
#endif
#include <wolfssl/wolfcrypt/random.h>
#ifdef WC_RNG_BANK_SUPPORT
#include <wolfssl/wolfcrypt/rng_bank.h>
#endif
#include <wolfssl/wolfcrypt/cpuid.h>
#ifndef WC_NO_RNG /* if not FIPS and RNG is disabled then do not compile */
#include <wolfssl/wolfcrypt/sha256.h>
#ifdef WOLF_CRYPTO_CB
#include <wolfssl/wolfcrypt/cryptocb.h>
#endif
#ifdef NO_INLINE
#include <wolfssl/wolfcrypt/misc.h>
#else
#define WOLFSSL_MISC_INCLUDED
#include <wolfcrypt/src/misc.c>
#endif
#if defined(WOLFSSL_SGX)
#include <sgx_trts.h>
#elif defined(USE_WINDOWS_API)
#ifndef _WIN32_WINNT
#define _WIN32_WINNT 0x0400
#endif
#define _WINSOCKAPI_ /* block inclusion of winsock.h header file */
#include <windows.h>
#include <wincrypt.h>
#undef _WINSOCKAPI_ /* undefine it for MINGW winsock2.h header file */
#elif defined(HAVE_WNR)
#include <wnr.h>
wolfSSL_Mutex wnr_mutex WOLFSSL_MUTEX_INITIALIZER_CLAUSE(wnr_mutex); /* global netRandom mutex */
int wnr_timeout = 0; /* entropy timeout, milliseconds */
#ifndef WOLFSSL_MUTEX_INITIALIZER
int wnr_mutex_inited = 0; /* flag for mutex init */
#endif
int wnr_inited = 0; /* flag for whether wc_InitNetRandom() has been called */
wnr_context* wnr_ctx; /* global netRandom context */
#elif defined(FREESCALE_KSDK_2_0_TRNG)
#include "fsl_trng.h"
#elif defined(FREESCALE_KSDK_2_0_RNGA)
#include "fsl_rnga.h"
#elif defined(WOLFSSL_WICED)
#include "wiced_crypto.h"
#elif defined(WOLFSSL_NETBURNER)
#include <predef.h>
#include <basictypes.h>
#include <random.h>
#elif defined(WOLFSSL_XILINX_CRYPT_VERSAL)
#include "wolfssl/wolfcrypt/port/xilinx/xil-versal-trng.h"
#elif defined(WOLFSSL_RPIPICO)
#include "wolfssl/wolfcrypt/port/rpi_pico/pico.h"
#elif defined(NO_DEV_RANDOM)
#elif defined(CUSTOM_RAND_GENERATE)
#elif defined(CUSTOM_RAND_GENERATE_BLOCK)
#elif defined(CUSTOM_RAND_GENERATE_SEED)
#elif defined(WOLFSSL_GENSEED_FORTEST)
#elif defined(WOLFSSL_MDK_ARM)
#elif defined(WOLFSSL_IAR_ARM)
#elif defined(WOLFSSL_ROWLEY_ARM)
#elif defined(WOLFSSL_EMBOS)
#elif defined(WOLFSSL_DEOS)
#elif defined(MICRIUM)
#elif defined(WOLFSSL_NUCLEUS)
#elif defined(WOLFSSL_PB)
#elif defined(WOLFSSL_ZEPHYR)
#elif defined(WOLFSSL_TELIT_M2MB)
#elif defined(WOLFSSL_RENESAS_TSIP)
/* for wc_tsip_GenerateRandBlock */
#include "wolfssl/wolfcrypt/port/Renesas/renesas_tsip_internal.h"
#elif defined(WOLFSSL_SCE) && !defined(WOLFSSL_SCE_NO_TRNG)
#elif defined(WOLFSSL_IMXRT1170_CAAM)
#elif defined(CY_USING_HAL) && defined(COMPONENT_WOLFSSL)
#include "cyhal_trng.h" /* Infineon/Cypress HAL RNG implementation */
#elif defined(WOLFSSL_MAX3266X) || defined(WOLFSSL_MAX3266X_OLD)
#include "wolfssl/wolfcrypt/port/maxim/max3266x.h"
#else
#if defined(WOLFSSL_GETRANDOM) || defined(HAVE_GETRANDOM)
#include <errno.h>
#include <sys/random.h>
#endif
/* include headers that may be needed to get good seed */
#include <fcntl.h>
#ifndef EBSNET
#include <unistd.h>
#endif
#endif
#if defined(WOLFSSL_SILABS_SE_ACCEL)
#include <wolfssl/wolfcrypt/port/silabs/silabs_random.h>
#endif
#if defined(WOLFSSL_IOTSAFE) && defined(HAVE_IOTSAFE_HWRNG)
#include <wolfssl/wolfcrypt/port/iotsafe/iotsafe.h>
#endif
#if defined(WOLFSSL_HAVE_PSA) && !defined(WOLFSSL_PSA_NO_RNG)
#include <wolfssl/wolfcrypt/port/psa/psa.h>
#endif
#if FIPS_VERSION3_GE(6,0,0)
const unsigned int wolfCrypt_FIPS_drbg_ro_sanity[2] =
{ 0x1a2b3c4d, 0x00000011 };
int wolfCrypt_FIPS_DRBG_sanity(void)
{
return 0;
}
#endif
#if defined(HAVE_INTEL_RDRAND) || defined(HAVE_INTEL_RDSEED) || \
defined(HAVE_AMD_RDSEED)
static cpuid_flags_t intel_flags = WC_CPUID_INITIALIZER;
static void wc_InitRng_IntelRD(void)
{
cpuid_get_flags_ex(&intel_flags);
}
#if defined(HAVE_INTEL_RDSEED) || defined(HAVE_AMD_RDSEED)
static int wc_GenerateSeed_IntelRD(OS_Seed* os, byte* output, word32 sz);
#endif
#ifdef HAVE_INTEL_RDRAND
static int wc_GenerateRand_IntelRD(OS_Seed* os, byte* output, word32 sz);
#endif
#ifdef USE_WINDOWS_API
#define USE_INTEL_INTRINSICS
#elif !defined __GNUC__ || defined __clang__ || __GNUC__ > 4
#define USE_INTEL_INTRINSICS
#else
#undef USE_INTEL_INTRINSICS
#endif
#ifdef USE_INTEL_INTRINSICS
#include <immintrin.h>
/* Before clang 7 or GCC 9, immintrin.h did not define _rdseed64_step() */
#ifndef HAVE_INTEL_RDSEED
#elif defined __clang__ && __clang_major__ > 6
#elif !defined __GNUC__
#elif __GNUC__ > 8
#else
#ifndef __clang__
#pragma GCC push_options
#pragma GCC target("rdseed")
#else
#define __RDSEED__
#endif
#include <x86intrin.h>
#ifndef __clang__
#pragma GCC pop_options
#endif
#endif
#endif /* USE_WINDOWS_API */
#endif
/* Start NIST DRBG code */
#ifdef HAVE_HASHDRBG
#define OUTPUT_BLOCK_LEN (WC_SHA256_DIGEST_SIZE)
#define MAX_REQUEST_LEN (0x10000)
#ifdef WC_RNG_SEED_CB
#ifndef HAVE_FIPS
static wc_RngSeed_Cb seedCb = wc_GenerateSeed;
#else
static wc_RngSeed_Cb seedCb = NULL;
#endif
int wc_SetSeed_Cb(wc_RngSeed_Cb cb)
{
seedCb = cb;
return 0;
}
#endif
/* Internal return codes */
#define DRBG_SUCCESS 0
#define DRBG_FAILURE 1
#define DRBG_NEED_RESEED 2
#define DRBG_CONT_FAILURE 3
#define DRBG_NO_SEED_CB 4
/* RNG health states */
#define DRBG_NOT_INIT WC_DRBG_NOT_INIT
#define DRBG_OK WC_DRBG_OK
#define DRBG_FAILED WC_DRBG_FAILED
#define DRBG_CONT_FAILED WC_DRBG_CONT_FAILED
#define SEED_SZ WC_DRBG_SEED_SZ
#define MAX_SEED_SZ WC_DRBG_MAX_SEED_SZ
/* Verify max gen block len */
#if RNG_MAX_BLOCK_LEN > MAX_REQUEST_LEN
#error RNG_MAX_BLOCK_LEN is larger than NIST DBRG max request length
#endif
enum {
drbgInitC = 0,
drbgReseed = 1,
drbgGenerateW = 2,
drbgGenerateH = 3,
drbgInitV = 4
};
typedef struct DRBG_internal DRBG_internal;
static int wc_RNG_HealthTestLocal(WC_RNG* rng, int reseed, void* heap,
int devId);
/* Hash Derivation Function */
/* Returns: DRBG_SUCCESS or DRBG_FAILURE */
static int Hash_df(DRBG_internal* drbg, byte* out, word32 outSz, byte type,
const byte* inA, word32 inASz,
const byte* inB, word32 inBSz)
{
int ret = DRBG_FAILURE;
byte ctr;
word32 i;
word32 len;
word32 bits = (outSz * 8); /* reverse byte order */
#ifdef WOLFSSL_SMALL_STACK_CACHE
wc_Sha256* sha = &drbg->sha256;
#else
wc_Sha256 sha[1];
#endif
#if defined(WOLFSSL_SMALL_STACK_CACHE)
byte* digest = drbg->digest_scratch;
#elif defined(WOLFSSL_SMALL_STACK)
byte* digest;
#else
byte digest[WC_SHA256_DIGEST_SIZE];
#endif
if (drbg == NULL) {
return DRBG_FAILURE;
}
#if defined(WOLFSSL_SMALL_STACK) && !defined(WOLFSSL_SMALL_STACK_CACHE)
digest = (byte*)XMALLOC(WC_SHA256_DIGEST_SIZE, drbg->heap,
DYNAMIC_TYPE_DIGEST);
if (digest == NULL)
return DRBG_FAILURE;
#endif
#ifdef LITTLE_ENDIAN_ORDER
bits = ByteReverseWord32(bits);
#endif
len = (outSz / OUTPUT_BLOCK_LEN)
+ ((outSz % OUTPUT_BLOCK_LEN) ? 1 : 0);
ctr = 1;
for (i = 0; i < len; i++) {
#ifndef WOLFSSL_SMALL_STACK_CACHE
#if defined(WOLFSSL_ASYNC_CRYPT) || defined(WOLF_CRYPTO_CB)
ret = wc_InitSha256_ex(sha, drbg->heap, drbg->devId);
#else
ret = wc_InitSha256(sha);
#endif
if (ret != 0)
break;
#endif
ret = wc_Sha256Update(sha, &ctr, sizeof(ctr));
if (ret == 0) {
ctr++;
ret = wc_Sha256Update(sha, (byte*)&bits, sizeof(bits));
}
if (ret == 0) {
/* churning V is the only string that doesn't have the type added */
if (type != drbgInitV)
ret = wc_Sha256Update(sha, &type, sizeof(type));
}
if (ret == 0)
ret = wc_Sha256Update(sha, inA, inASz);
if (ret == 0) {
if (inB != NULL && inBSz > 0)
ret = wc_Sha256Update(sha, inB, inBSz);
}
if (ret == 0)
ret = wc_Sha256Final(sha, digest);
#ifndef WOLFSSL_SMALL_STACK_CACHE
wc_Sha256Free(sha);
#endif
if (ret == 0) {
if (outSz > OUTPUT_BLOCK_LEN) {
XMEMCPY(out, digest, OUTPUT_BLOCK_LEN);
outSz -= OUTPUT_BLOCK_LEN;
out += OUTPUT_BLOCK_LEN;
}
else {
XMEMCPY(out, digest, outSz);
}
}
}
ForceZero(digest, WC_SHA256_DIGEST_SIZE);
#if defined(WOLFSSL_SMALL_STACK) && !defined(WOLFSSL_SMALL_STACK_CACHE)
XFREE(digest, drbg->heap, DYNAMIC_TYPE_DIGEST);
#endif
#ifdef WC_VERBOSE_RNG
if (ret != 0)
WOLFSSL_DEBUG_PRINTF("ERROR: %s failed with err = %d", __FUNCTION__,
ret);
#endif
return (ret == 0) ? DRBG_SUCCESS : DRBG_FAILURE;
}
/* Returns: DRBG_SUCCESS or DRBG_FAILURE */
static int Hash_DRBG_Reseed(DRBG_internal* drbg, const byte* seed, word32 seedSz)
{
int ret;
WC_DECLARE_VAR(newV, byte, DRBG_SEED_LEN, 0);
if (drbg == NULL) {
return DRBG_FAILURE;
}
#ifdef WOLFSSL_SMALL_STACK_CACHE
newV = drbg->seed_scratch;
#else
WC_ALLOC_VAR_EX(newV, byte, DRBG_SEED_LEN, drbg->heap,
DYNAMIC_TYPE_TMP_BUFFER, return MEMORY_E);
#endif
XMEMSET(newV, 0, DRBG_SEED_LEN);
ret = Hash_df(drbg, newV, DRBG_SEED_LEN, drbgReseed,
drbg->V, sizeof(drbg->V), seed, seedSz);
if (ret == DRBG_SUCCESS) {
XMEMCPY(drbg->V, newV, sizeof(drbg->V));
ForceZero(newV, DRBG_SEED_LEN);
ret = Hash_df(drbg, drbg->C, sizeof(drbg->C), drbgInitC, drbg->V,
sizeof(drbg->V), NULL, 0);
}
if (ret == DRBG_SUCCESS) {
drbg->reseedCtr = 1;
}
#ifndef WOLFSSL_SMALL_STACK_CACHE
WC_FREE_VAR_EX(newV, drbg->heap, DYNAMIC_TYPE_TMP_BUFFER);
#endif
#ifdef WC_VERBOSE_RNG
if (ret != 0)
WOLFSSL_DEBUG_PRINTF("ERROR: Hash_DRBG_Reseed failed with err %d.",
ret);
#endif
return ret;
}
/* Returns: DRBG_SUCCESS and DRBG_FAILURE or BAD_FUNC_ARG on fail */
int wc_RNG_DRBG_Reseed(WC_RNG* rng, const byte* seed, word32 seedSz)
{
if (rng == NULL || seed == NULL) {
return BAD_FUNC_ARG;
}
if (rng->drbg == NULL) {
#if defined(HAVE_INTEL_RDSEED) || defined(HAVE_INTEL_RDRAND)
if (IS_INTEL_RDRAND(intel_flags)) {
/* using RDRAND not DRBG, so return success */
return 0;
}
return BAD_FUNC_ARG;
#endif
}
return Hash_DRBG_Reseed((DRBG_internal *)rng->drbg, seed, seedSz);
}
static WC_INLINE void array_add_one(byte* data, word32 dataSz)
{
int i;
for (i = (int)dataSz - 1; i >= 0; i--) {
data[i]++;
if (data[i] != 0) break;
}
}
/* Returns: DRBG_SUCCESS or DRBG_FAILURE */
static int Hash_gen(DRBG_internal* drbg, byte* out, word32 outSz, const byte* V)
{
int ret = DRBG_FAILURE;
word32 i;
word32 len;
#if defined(WOLFSSL_SMALL_STACK_CACHE)
wc_Sha256* sha = &drbg->sha256;
byte* data = drbg->seed_scratch;
byte* digest = drbg->digest_scratch;
#elif defined(WOLFSSL_SMALL_STACK)
wc_Sha256 sha[1];
byte* data = NULL;
byte* digest = NULL;
#else
wc_Sha256 sha[1];
byte data[DRBG_SEED_LEN];
byte digest[WC_SHA256_DIGEST_SIZE];
#endif
if (drbg == NULL) {
return DRBG_FAILURE;
}
#if defined(WOLFSSL_SMALL_STACK) && !defined(WOLFSSL_SMALL_STACK_CACHE)
data = (byte*)XMALLOC(DRBG_SEED_LEN, drbg->heap, DYNAMIC_TYPE_TMP_BUFFER);
digest = (byte*)XMALLOC(WC_SHA256_DIGEST_SIZE, drbg->heap,
DYNAMIC_TYPE_DIGEST);
if (data == NULL || digest == NULL) {
XFREE(digest, drbg->heap, DYNAMIC_TYPE_DIGEST);
XFREE(data, drbg->heap, DYNAMIC_TYPE_TMP_BUFFER);
return DRBG_FAILURE;
}
#endif
/* Special case: outSz is 0 and out is NULL. wc_Generate a block to save for
* the continuous test. */
if (outSz == 0) {
outSz = 1;
}
len = (outSz / OUTPUT_BLOCK_LEN) + ((outSz % OUTPUT_BLOCK_LEN) ? 1 : 0);
XMEMCPY(data, V, DRBG_SEED_LEN);
for (i = 0; i < len; i++) {
#ifndef WOLFSSL_SMALL_STACK_CACHE
#if defined(WOLFSSL_ASYNC_CRYPT) || defined(WOLF_CRYPTO_CB)
ret = wc_InitSha256_ex(sha, drbg->heap, drbg->devId);
#else
ret = wc_InitSha256(sha);
#endif
if (ret == 0)
#endif
ret = wc_Sha256Update(sha, data, DRBG_SEED_LEN);
if (ret == 0)
ret = wc_Sha256Final(sha, digest);
#ifndef WOLFSSL_SMALL_STACK_CACHE
wc_Sha256Free(sha);
#endif
if (ret == 0) {
if (out != NULL && outSz != 0) {
if (outSz >= OUTPUT_BLOCK_LEN) {
XMEMCPY(out, digest, OUTPUT_BLOCK_LEN);
outSz -= OUTPUT_BLOCK_LEN;
out += OUTPUT_BLOCK_LEN;
array_add_one(data, DRBG_SEED_LEN);
}
else {
XMEMCPY(out, digest, outSz);
outSz = 0;
}
}
}
else {
/* wc_Sha256Update or wc_Sha256Final returned error */
break;
}
}
ForceZero(data, DRBG_SEED_LEN);
#ifndef WOLFSSL_SMALL_STACK_CACHE
WC_FREE_VAR_EX(digest, drbg->heap, DYNAMIC_TYPE_DIGEST);
WC_FREE_VAR_EX(data, drbg->heap, DYNAMIC_TYPE_TMP_BUFFER);
#endif
#ifdef WC_VERBOSE_RNG
if ((ret != DRBG_SUCCESS) && (ret != DRBG_FAILURE)) {
/* Note, if we're just going to return DRBG_FAILURE to the caller, then
* there's no point printing it out here because (1) the lower-level
* code that was remapped to DRBG_FAILURE already got printed before the
* remapping, so a DRBG_FAILURE message would just be spamming the log,
* and (2) the caller will actually see the DRBG_FAILURE code, and is
* free to (and probably will) log it itself.
*/
WOLFSSL_DEBUG_PRINTF("ERROR: Hash_gen failed with err %d.", ret);
}
#endif
return (ret == 0) ? DRBG_SUCCESS : DRBG_FAILURE;
}
static WC_INLINE void array_add(byte* d, word32 dLen, const byte* s, word32 sLen)
{
if (dLen > 0 && sLen > 0 && dLen >= sLen) {
int sIdx, dIdx;
word16 carry = 0;
dIdx = (int)dLen - 1;
for (sIdx = (int)sLen - 1; sIdx >= 0; sIdx--) {
carry = (word16)(carry + d[dIdx] + s[sIdx]);
d[dIdx] = (byte)carry;
carry >>= 8;
dIdx--;
}
for (; dIdx >= 0; dIdx--) {
carry = (word16)(carry + d[dIdx]);
d[dIdx] = (byte)carry;
carry >>= 8;
}
}
}
/* Returns: DRBG_SUCCESS, DRBG_NEED_RESEED, or DRBG_FAILURE */
static int Hash_DRBG_Generate(DRBG_internal* drbg, byte* out, word32 outSz)
{
int ret;
#ifdef WOLFSSL_SMALL_STACK_CACHE
wc_Sha256* sha = &drbg->sha256;
#else
wc_Sha256 sha[1];
#endif
byte type;
#ifdef WORD64_AVAILABLE
word64 reseedCtr;
#else
word32 reseedCtr;
#endif
if (drbg == NULL) {
return DRBG_FAILURE;
}
if (drbg->reseedCtr >= WC_RESEED_INTERVAL) {
#if (defined(DEBUG_WOLFSSL) || defined(DEBUG_DRBG_RESEEDS)) && \
defined(WOLFSSL_DEBUG_PRINTF)
WOLFSSL_DEBUG_PRINTF("DRBG reseed triggered, reseedCtr == %lu",
(unsigned long)drbg->reseedCtr);
#endif
return DRBG_NEED_RESEED;
}
else {
#if defined(WOLFSSL_SMALL_STACK_CACHE)
byte* digest = drbg->digest_scratch;
#elif defined(WOLFSSL_SMALL_STACK)
byte* digest = (byte*)XMALLOC(WC_SHA256_DIGEST_SIZE, drbg->heap,
DYNAMIC_TYPE_DIGEST);
if (digest == NULL)
return DRBG_FAILURE;
#else
byte digest[WC_SHA256_DIGEST_SIZE];
#endif
type = drbgGenerateH;
reseedCtr = drbg->reseedCtr;
ret = Hash_gen(drbg, out, outSz, drbg->V);
if (ret == DRBG_SUCCESS) {
#ifndef WOLFSSL_SMALL_STACK_CACHE
#if defined(WOLFSSL_ASYNC_CRYPT) || defined(WOLF_CRYPTO_CB)
ret = wc_InitSha256_ex(sha, drbg->heap, drbg->devId);
#else
ret = wc_InitSha256(sha);
#endif
if (ret == 0)
#endif
ret = wc_Sha256Update(sha, &type, sizeof(type));
if (ret == 0)
ret = wc_Sha256Update(sha, drbg->V, sizeof(drbg->V));
if (ret == 0)
ret = wc_Sha256Final(sha, digest);
#ifndef WOLFSSL_SMALL_STACK_CACHE
wc_Sha256Free(sha);
#endif
if (ret == 0) {
array_add(drbg->V, sizeof(drbg->V), digest, WC_SHA256_DIGEST_SIZE);
array_add(drbg->V, sizeof(drbg->V), drbg->C, sizeof(drbg->C));
#ifdef LITTLE_ENDIAN_ORDER
#ifdef WORD64_AVAILABLE
reseedCtr = ByteReverseWord64(reseedCtr);
#else
reseedCtr = ByteReverseWord32(reseedCtr);
#endif
#endif
array_add(drbg->V, sizeof(drbg->V),
(byte*)&reseedCtr, sizeof(reseedCtr));
ret = DRBG_SUCCESS;
}
drbg->reseedCtr++;
}
ForceZero(digest, WC_SHA256_DIGEST_SIZE);
#if defined(WOLFSSL_SMALL_STACK) && !defined(WOLFSSL_SMALL_STACK_CACHE)
XFREE(digest, drbg->heap, DYNAMIC_TYPE_DIGEST);
#endif
}
#ifdef WC_VERBOSE_RNG
if ((ret != DRBG_SUCCESS) && (ret != DRBG_FAILURE)) {
/* see note above regarding log spam reduction */
WOLFSSL_DEBUG_PRINTF("ERROR: Hash_DRBG_Generate failed with err %d.",
ret);
}
#endif
return (ret == 0) ? DRBG_SUCCESS : DRBG_FAILURE;
}
/* Returns: DRBG_SUCCESS or DRBG_FAILURE */
static int Hash_DRBG_Init(DRBG_internal* drbg, const byte* seed, word32 seedSz,
const byte* nonce, word32 nonceSz)
{
if (seed == NULL)
return DRBG_FAILURE;
if (Hash_df(drbg, drbg->V, sizeof(drbg->V), drbgInitV, seed, seedSz,
nonce, nonceSz) == DRBG_SUCCESS &&
Hash_df(drbg, drbg->C, sizeof(drbg->C), drbgInitC, drbg->V,
sizeof(drbg->V), NULL, 0) == DRBG_SUCCESS) {
drbg->reseedCtr = 1;
return DRBG_SUCCESS;
}
else {
return DRBG_FAILURE;
}
}
/* Returns: DRBG_SUCCESS or DRBG_FAILURE */
static int Hash_DRBG_Instantiate(DRBG_internal* drbg, const byte* seed, word32 seedSz,
const byte* nonce, word32 nonceSz,
void* heap, int devId)
{
int ret = DRBG_FAILURE;
XMEMSET(drbg, 0, sizeof(DRBG_internal));
drbg->heap = heap;
#if defined(WOLFSSL_ASYNC_CRYPT) || defined(WOLF_CRYPTO_CB)
drbg->devId = devId;
#else
(void)devId;
#endif
#ifdef WOLFSSL_SMALL_STACK_CACHE
#if defined(WOLFSSL_ASYNC_CRYPT) || defined(WOLF_CRYPTO_CB)
ret = wc_InitSha256_ex(&drbg->sha256, drbg->heap, drbg->devId);
#else
ret = wc_InitSha256(&drbg->sha256);
#endif
if (ret != 0)
return ret;
#endif
if (seed != NULL)
ret = Hash_DRBG_Init(drbg, seed, seedSz, nonce, nonceSz);
return ret;
}
/* Returns: DRBG_SUCCESS or DRBG_FAILURE */
static int Hash_DRBG_Uninstantiate(DRBG_internal* drbg)
{
word32 i;
int compareSum = 0;
byte* compareDrbg = (byte*)drbg;
#ifdef WOLFSSL_SMALL_STACK_CACHE
wc_Sha256Free(&drbg->sha256);
#endif
ForceZero(drbg, sizeof(DRBG_internal));
for (i = 0; i < sizeof(DRBG_internal); i++) {
compareSum |= compareDrbg[i] ^ 0;
}
return (compareSum == 0) ? DRBG_SUCCESS : DRBG_FAILURE;
}
int wc_RNG_TestSeed(const byte* seed, word32 seedSz)
{
int ret = 0;
/* Check the seed for duplicate words. */
word32 seedIdx = 0;
word32 scratchSz = min(SEED_BLOCK_SZ, seedSz - SEED_BLOCK_SZ);
while (seedIdx < seedSz - SEED_BLOCK_SZ) {
if (ConstantCompare(seed + seedIdx,
seed + seedIdx + scratchSz,
(int)scratchSz) == 0) {
ret = DRBG_CONT_FAILURE;
}
seedIdx += SEED_BLOCK_SZ;
scratchSz = min(SEED_BLOCK_SZ, (seedSz - seedIdx));
}
return ret;
}
#endif /* HAVE_HASHDRBG */
/* End NIST DRBG Code */
static int _InitRng(WC_RNG* rng, byte* nonce, word32 nonceSz,
void* heap, int devId)
{
int ret = 0;
#ifdef HAVE_HASHDRBG
#if !defined(HAVE_FIPS) && defined(WOLFSSL_RNG_USE_FULL_SEED)
word32 seedSz = SEED_SZ;
#else
word32 seedSz = SEED_SZ + SEED_BLOCK_SZ;
WC_DECLARE_VAR(seed, byte, MAX_SEED_SZ, rng->heap);
#ifdef WOLFSSL_SMALL_STACK_CACHE
int drbg_scratch_instantiated = 0;
#endif
#endif
#endif
(void)nonce;
(void)nonceSz;
if (rng == NULL)
return BAD_FUNC_ARG;
if (nonce == NULL && nonceSz != 0)
return BAD_FUNC_ARG;
XMEMSET(rng, 0, sizeof(*rng));
#ifdef WOLFSSL_HEAP_TEST
rng->heap = (void*)WOLFSSL_HEAP_TEST;
(void)heap;
#else
rng->heap = heap;
#endif
#if defined(HAVE_GETPID) && !defined(WOLFSSL_NO_GETPID)
rng->pid = getpid();
#endif
#if defined(WOLFSSL_ASYNC_CRYPT) || defined(WOLF_CRYPTO_CB)
rng->devId = devId;
#if defined(WOLF_CRYPTO_CB)
rng->seed.devId = devId;
#endif
#else
(void)devId;
#endif
#ifdef HAVE_HASHDRBG
/* init the DBRG to known values */
rng->drbg = NULL;
#ifdef WOLFSSL_SMALL_STACK_CACHE
rng->drbg_scratch = NULL;
#endif
rng->status = DRBG_NOT_INIT;
#endif
#if defined(HAVE_INTEL_RDSEED) || defined(HAVE_INTEL_RDRAND) || \
defined(HAVE_AMD_RDSEED)
/* init the intel RD seed and/or rand */
wc_InitRng_IntelRD();
#endif
/* configure async RNG source if available */
#ifdef WOLFSSL_ASYNC_CRYPT
ret = wolfAsync_DevCtxInit(&rng->asyncDev, WOLFSSL_ASYNC_MARKER_RNG,
rng->heap, rng->devId);
if (ret != 0) {
#ifdef HAVE_HASHDRBG
rng->status = DRBG_OK;
#endif
return ret;
}
#endif
#ifdef HAVE_INTEL_RDRAND
/* if CPU supports RDRAND, use it directly and by-pass DRBG init */
if (IS_INTEL_RDRAND(intel_flags)) {
#ifdef HAVE_HASHDRBG
rng->status = DRBG_OK;
#endif
return 0;
}
#endif
#ifdef WOLFSSL_XILINX_CRYPT_VERSAL
ret = wc_VersalTrngInit(nonce, nonceSz);
if (ret) {
#ifdef HAVE_HASHDRBG
rng->status = DRBG_OK;
#endif
return ret;
}
#endif
#if defined(WOLFSSL_KEEP_RNG_SEED_FD_OPEN) && !defined(USE_WINDOWS_API)
if (!rng->seed.seedFdOpen)
rng->seed.fd = XBADFD;
#endif
#ifdef CUSTOM_RAND_GENERATE_BLOCK
ret = 0; /* success */
#else
/* not CUSTOM_RAND_GENERATE_BLOCK follows */
#ifdef HAVE_HASHDRBG
if (nonceSz == 0) {
seedSz = MAX_SEED_SZ;
}
#if !defined(WOLFSSL_NO_MALLOC) || defined(WOLFSSL_STATIC_MEMORY)
rng->drbg =
(struct DRBG*)XMALLOC(sizeof(DRBG_internal), rng->heap,
DYNAMIC_TYPE_RNG);
if (rng->drbg == NULL) {
#if defined(DEBUG_WOLFSSL)
WOLFSSL_MSG_EX("_InitRng XMALLOC failed to allocate %d bytes",
sizeof(DRBG_internal));
#endif
ret = MEMORY_E;
rng->status = DRBG_FAILED;
}
#else
rng->drbg = (struct DRBG*)&rng->drbg_data;
#endif /* WOLFSSL_NO_MALLOC or WOLFSSL_STATIC_MEMORY */
#ifdef WOLFSSL_SMALL_STACK_CACHE
if (ret == 0) {
rng->drbg_scratch =
(DRBG_internal *)XMALLOC(sizeof(DRBG_internal), rng->heap,
DYNAMIC_TYPE_RNG);
if (rng->drbg_scratch == NULL) {
#if defined(DEBUG_WOLFSSL)
WOLFSSL_MSG_EX("_InitRng XMALLOC failed to allocate %d bytes",
sizeof(DRBG_internal));
#endif
ret = MEMORY_E;
rng->status = DRBG_FAILED;
}
}
if (ret == 0) {
ret = Hash_DRBG_Instantiate((DRBG_internal *)rng->drbg_scratch,
NULL /* seed */, 0, NULL /* nonce */, 0, rng->heap, devId);
if (ret == 0)
drbg_scratch_instantiated = 1;
}
if (ret == 0) {
rng->health_check_scratch =
(byte *)XMALLOC(RNG_HEALTH_TEST_CHECK_SIZE, rng->heap,
DYNAMIC_TYPE_TMP_BUFFER);
if (rng->health_check_scratch == NULL) {
ret = MEMORY_E;
rng->status = DRBG_FAILED;
}
}
if (ret == 0) {
rng->newSeed_buf = (byte*)XMALLOC(SEED_SZ + SEED_BLOCK_SZ, rng->heap,
DYNAMIC_TYPE_SEED);
if (rng->newSeed_buf == NULL) {
ret = MEMORY_E;
rng->status = DRBG_FAILED;
}
}
#endif /* WOLFSSL_SMALL_STACK_CACHE */
if (ret == 0) {
ret = wc_RNG_HealthTestLocal(rng, 0, rng->heap, devId);
if (ret != 0) {
#if defined(DEBUG_WOLFSSL)
WOLFSSL_MSG_EX("wc_RNG_HealthTestLocal failed err = %d", ret);
#endif
ret = DRBG_CONT_FAILURE;
}
}
#ifdef WOLFSSL_SMALL_STACK
if (ret == 0) {
WC_ALLOC_VAR_EX(seed, byte, MAX_SEED_SZ, rng->heap, DYNAMIC_TYPE_SEED, WC_DO_NOTHING);
if (seed == NULL) {
ret = MEMORY_E;
rng->status = DRBG_FAILED;
}
}
#endif
if (ret != 0) {
#if defined(DEBUG_WOLFSSL)
WOLFSSL_MSG_EX("_InitRng failed. err = %d", ret);
#endif
}
else {
#ifdef WC_RNG_SEED_CB
if (seedCb == NULL) {
ret = DRBG_NO_SEED_CB;
}
else {
ret = seedCb(&rng->seed, seed, seedSz);
if (ret != 0) {
#ifdef WC_VERBOSE_RNG
WOLFSSL_DEBUG_PRINTF(
"ERROR: seedCb in _InitRng() failed with err = %d",
ret);
#endif
ret = DRBG_FAILURE;
}
}
#else
ret = wc_GenerateSeed(&rng->seed, seed, seedSz);
#endif /* WC_RNG_SEED_CB */
if (ret != 0) {
#if defined(DEBUG_WOLFSSL)
WOLFSSL_MSG_EX("Seed generation failed... %d", ret);
#elif defined(WC_VERBOSE_RNG)
WOLFSSL_DEBUG_PRINTF(
"ERROR: wc_GenerateSeed() in _InitRng() failed with err %d",
ret);
#endif
ret = DRBG_FAILURE;
rng->status = DRBG_FAILED;
}
if (ret == 0)
ret = wc_RNG_TestSeed(seed, seedSz);
#if defined(DEBUG_WOLFSSL)
if (ret != 0) {
WOLFSSL_MSG_EX("wc_RNG_TestSeed failed... %d", ret);
}
#elif defined(WC_VERBOSE_RNG)
if (ret != DRBG_SUCCESS) {
WOLFSSL_DEBUG_PRINTF(
"ERROR: wc_RNG_TestSeed() in _InitRng() returned err %d.",
ret);
}
#endif
if (ret == DRBG_SUCCESS)
ret = Hash_DRBG_Instantiate((DRBG_internal *)rng->drbg,
#if defined(HAVE_FIPS) || !defined(WOLFSSL_RNG_USE_FULL_SEED)
seed + SEED_BLOCK_SZ, seedSz - SEED_BLOCK_SZ,
#else
seed, seedSz,
#endif
nonce, nonceSz, rng->heap, devId);
} /* ret == 0 */
#ifdef WOLFSSL_SMALL_STACK
if (seed)
#endif
{
ForceZero(seed, seedSz);
}
WC_FREE_VAR_EX(seed, rng->heap, DYNAMIC_TYPE_SEED);
if (ret != DRBG_SUCCESS) {
#if !defined(WOLFSSL_NO_MALLOC) || defined(WOLFSSL_STATIC_MEMORY)
XFREE(rng->drbg, rng->heap, DYNAMIC_TYPE_RNG);
#endif
rng->drbg = NULL;
#ifdef WOLFSSL_SMALL_STACK_CACHE
XFREE(rng->health_check_scratch, rng->heap, DYNAMIC_TYPE_TMP_BUFFER);
rng->health_check_scratch = NULL;
XFREE(rng->newSeed_buf, rng->heap, DYNAMIC_TYPE_TMP_BUFFER);
rng->newSeed_buf = NULL;
if (drbg_scratch_instantiated)
(void)Hash_DRBG_Uninstantiate((DRBG_internal *)rng->drbg_scratch);
XFREE(rng->drbg_scratch, rng->heap, DYNAMIC_TYPE_RNG);
rng->drbg_scratch = NULL;
#endif
}
/* else swc_RNG_HealthTestLocal was successful */
if (ret == DRBG_SUCCESS) {
#ifdef WOLFSSL_CHECK_MEM_ZERO
#ifdef HAVE_HASHDRBG
struct DRBG_internal* drbg = (struct DRBG_internal*)rng->drbg;
wc_MemZero_Add("DRBG V", &drbg->V, sizeof(drbg->V));
wc_MemZero_Add("DRBG C", &drbg->C, sizeof(drbg->C));
#endif
#endif
rng->status = DRBG_OK;
ret = 0;
}
else if (ret == DRBG_CONT_FAILURE) {
rng->status = DRBG_CONT_FAILED;
ret = DRBG_CONT_FIPS_E;
}
else if (ret == DRBG_FAILURE) {
rng->status = DRBG_FAILED;
ret = RNG_FAILURE_E;
}
else {
rng->status = DRBG_FAILED;
}
#endif /* HAVE_HASHDRBG */
#endif /* CUSTOM_RAND_GENERATE_BLOCK */
return ret;
}
WOLFSSL_ABI
WC_RNG* wc_rng_new(byte* nonce, word32 nonceSz, void* heap)
{
int ret = 0;
WC_RNG* rng = NULL;
/* Assume if WC_USE_DEVID it is intended for default usage */
#ifdef WC_USE_DEVID
ret = wc_rng_new_ex(&rng, nonce, nonceSz, heap, WC_USE_DEVID);
#else
ret = wc_rng_new_ex(&rng, nonce, nonceSz, heap, INVALID_DEVID);
#endif
if (ret != 0) {
return NULL;
}
return rng;
}
int wc_rng_new_ex(WC_RNG **rng, byte* nonce, word32 nonceSz,
void* heap, int devId)
{
int ret;
*rng = (WC_RNG*)XMALLOC(sizeof(WC_RNG), heap, DYNAMIC_TYPE_RNG);
if (*rng == NULL) {
return MEMORY_E;
}
ret = _InitRng(*rng, nonce, nonceSz, heap, devId);
if (ret != 0) {
XFREE(*rng, heap, DYNAMIC_TYPE_RNG);
*rng = NULL;
}
return ret;
}
WOLFSSL_ABI
void wc_rng_free(WC_RNG* rng)
{
if (rng) {
void* heap = rng->heap;
wc_FreeRng(rng);
ForceZero(rng, sizeof(WC_RNG));
XFREE(rng, heap, DYNAMIC_TYPE_RNG);
(void)heap;
}
}
WOLFSSL_ABI
int wc_InitRng(WC_RNG* rng)
{
return _InitRng(rng, NULL, 0, NULL, INVALID_DEVID);
}
int wc_InitRng_ex(WC_RNG* rng, void* heap, int devId)
{
return _InitRng(rng, NULL, 0, heap, devId);
}
int wc_InitRngNonce(WC_RNG* rng, byte* nonce, word32 nonceSz)
{
return _InitRng(rng, nonce, nonceSz, NULL, INVALID_DEVID);
}
int wc_InitRngNonce_ex(WC_RNG* rng, byte* nonce, word32 nonceSz,
void* heap, int devId)
{
return _InitRng(rng, nonce, nonceSz, heap, devId);
}
#ifdef HAVE_HASHDRBG
static int PollAndReSeed(WC_RNG* rng)
{
int ret = DRBG_NEED_RESEED;
int devId = INVALID_DEVID;
#if defined(WOLFSSL_ASYNC_CRYPT) || defined(WOLF_CRYPTO_CB)
devId = rng->devId;
#endif
if (wc_RNG_HealthTestLocal(rng, 1, rng->heap, devId) == 0) {
#if defined(WOLFSSL_SMALL_STACK_CACHE)
byte* newSeed = rng->newSeed_buf;
ret = DRBG_SUCCESS;
#elif defined(WOLFSSL_SMALL_STACK)
byte* newSeed = (byte*)XMALLOC(SEED_SZ + SEED_BLOCK_SZ, rng->heap,
DYNAMIC_TYPE_SEED);
ret = (newSeed == NULL) ? MEMORY_E : DRBG_SUCCESS;
#else
byte newSeed[SEED_SZ + SEED_BLOCK_SZ];
ret = DRBG_SUCCESS;
#endif
if (ret == DRBG_SUCCESS) {
#ifdef WC_RNG_SEED_CB
if (seedCb == NULL) {
ret = DRBG_NO_SEED_CB;
}
else {
ret = seedCb(&rng->seed, newSeed, SEED_SZ + SEED_BLOCK_SZ);
if (ret != 0) {
#ifdef WC_VERBOSE_RNG
WOLFSSL_DEBUG_PRINTF("ERROR: seedCb() in PollAndReSeed() "
"failed with err %d", ret);
#endif
ret = DRBG_FAILURE;
}
}
#else
ret = wc_GenerateSeed(&rng->seed, newSeed,
SEED_SZ + SEED_BLOCK_SZ);
if (ret != 0) {
#ifdef WC_VERBOSE_RNG
WOLFSSL_DEBUG_PRINTF(
"ERROR: wc_GenerateSeed() in PollAndReSeed() failed with "
"err %d", ret);
#endif
ret = DRBG_FAILURE;
}
#endif
}
if (ret == DRBG_SUCCESS) {
ret = wc_RNG_TestSeed(newSeed, SEED_SZ + SEED_BLOCK_SZ);
#ifdef WC_VERBOSE_RNG
if (ret != DRBG_SUCCESS)
WOLFSSL_DEBUG_PRINTF(
"ERROR: wc_RNG_TestSeed() in PollAndReSeed() returned "
"err %d.", ret);
#endif
}
if (ret == DRBG_SUCCESS)
ret = Hash_DRBG_Reseed((DRBG_internal *)rng->drbg,
newSeed + SEED_BLOCK_SZ, SEED_SZ);
#if defined(WOLFSSL_SMALL_STACK) && !defined(WOLFSSL_SMALL_STACK_CACHE)
if (newSeed != NULL) {
ForceZero(newSeed, SEED_SZ + SEED_BLOCK_SZ);
}
XFREE(newSeed, rng->heap, DYNAMIC_TYPE_SEED);
#else
ForceZero(newSeed, sizeof(newSeed));
#endif
}
else {
ret = DRBG_CONT_FAILURE;
}
return ret;
}
#endif
/* place a generated block in output */
#ifdef WC_RNG_BANK_SUPPORT
static int wc_local_RNG_GenerateBlock(WC_RNG* rng, byte* output, word32 sz)
#else
WOLFSSL_ABI
int wc_RNG_GenerateBlock(WC_RNG* rng, byte* output, word32 sz)
#endif
{
int ret;
if (rng == NULL || output == NULL)
return BAD_FUNC_ARG;
if (sz == 0)
return 0;
#ifdef WOLF_CRYPTO_CB
#ifndef WOLF_CRYPTO_CB_FIND
if (rng->devId != INVALID_DEVID)
#endif
{
ret = wc_CryptoCb_RandomBlock(rng, output, sz);
if (ret != WC_NO_ERR_TRACE(CRYPTOCB_UNAVAILABLE))
return ret;
/* fall-through when unavailable */
}
#endif
#ifdef HAVE_INTEL_RDRAND
if (IS_INTEL_RDRAND(intel_flags))
return wc_GenerateRand_IntelRD(NULL, output, sz);
#endif
#if defined(WOLFSSL_SILABS_SE_ACCEL) && defined(WOLFSSL_SILABS_TRNG)
return silabs_GenerateRand(output, sz);
#endif
#if defined(WOLFSSL_ASYNC_CRYPT)
if (rng->asyncDev.marker == WOLFSSL_ASYNC_MARKER_RNG) {
/* these are blocking */
#ifdef HAVE_CAVIUM
return NitroxRngGenerateBlock(rng, output, sz);
#elif defined(HAVE_INTEL_QA) && defined(QAT_ENABLE_RNG)
return IntelQaDrbg(&rng->asyncDev, output, sz);
#else
/* simulator not supported */
#endif
}
#endif
#ifdef CUSTOM_RAND_GENERATE_BLOCK
XMEMSET(output, 0, sz);
ret = (int)CUSTOM_RAND_GENERATE_BLOCK(output, sz);
#ifdef WC_VERBOSE_RNG
if (ret != 0)
WOLFSSL_DEBUG_PRINTF(
"ERROR: CUSTOM_RAND_GENERATE_BLOCK failed with err %d.", ret);
#endif
#else
#ifdef HAVE_HASHDRBG
if (sz > RNG_MAX_BLOCK_LEN)
return BAD_FUNC_ARG;
if (rng->status != DRBG_OK)
return RNG_FAILURE_E;
#if defined(HAVE_GETPID) && !defined(WOLFSSL_NO_GETPID)
if (rng->pid != getpid()) {
rng->pid = getpid();
ret = PollAndReSeed(rng);
if (ret != DRBG_SUCCESS) {
rng->status = DRBG_FAILED;
return RNG_FAILURE_E;
}
}
#endif
ret = Hash_DRBG_Generate((DRBG_internal *)rng->drbg, output, sz);
if (ret == DRBG_NEED_RESEED) {
ret = PollAndReSeed(rng);
if (ret == DRBG_SUCCESS)
ret = Hash_DRBG_Generate((DRBG_internal *)rng->drbg, output, sz);
}
if (ret == DRBG_SUCCESS) {
ret = 0;
}
else if (ret == DRBG_CONT_FAILURE) {
ret = DRBG_CONT_FIPS_E;
rng->status = DRBG_CONT_FAILED;
}
else {
ret = RNG_FAILURE_E;
rng->status = DRBG_FAILED;
}
#else
/* if we get here then there is an RNG configuration error */
ret = RNG_FAILURE_E;
#endif /* HAVE_HASHDRBG */
#endif /* CUSTOM_RAND_GENERATE_BLOCK */
return ret;
}
#ifdef WC_RNG_BANK_SUPPORT
WOLFSSL_ABI
int wc_RNG_GenerateBlock(WC_RNG* rng, byte* output, word32 sz)
{
if (rng == NULL)
return BAD_FUNC_ARG;
if (rng->status == WC_DRBG_BANKREF) {
int ret;
struct wc_rng_bank_inst *bank_inst = NULL;
ret = wc_local_rng_bank_checkout_for_bankref(rng->bankref, &bank_inst);
if (ret != 0)
return ret;
if (bank_inst == NULL)
return BAD_STATE_E;
ret = wc_local_RNG_GenerateBlock(WC_RNG_BANK_INST_TO_RNG(bank_inst),
output, sz);
{
int checkin_ret = wc_rng_bank_checkin(rng->bankref, &bank_inst);
if (checkin_ret != 0) {
#ifdef WC_VERBOSE_RNG
WOLFSSL_DEBUG_PRINTF(
"ERROR: wc_RNG_GenerateBlock() wc_rng_bank_checkin() "
"failed with err %d.", checkin_ret);
#endif
if (ret == 0)
ret = checkin_ret;
}
}
return ret;
}
else
return wc_local_RNG_GenerateBlock(rng, output, sz);
}
#endif
int wc_RNG_GenerateByte(WC_RNG* rng, byte* b)
{
return wc_RNG_GenerateBlock(rng, b, 1);
}
int wc_FreeRng(WC_RNG* rng)
{
int ret = 0;
if (rng == NULL)
return BAD_FUNC_ARG;
#ifdef WC_RNG_BANK_SUPPORT
if (rng->status == WC_DRBG_BANKREF)
return wc_BankRef_Release(rng);
#endif /* WC_RNG_BANK_SUPPORT */
#if defined(WOLFSSL_ASYNC_CRYPT)
wolfAsync_DevCtxFree(&rng->asyncDev, WOLFSSL_ASYNC_MARKER_RNG);
#endif
#ifdef HAVE_HASHDRBG
if (rng->drbg != NULL) {
if (Hash_DRBG_Uninstantiate((DRBG_internal *)rng->drbg) != DRBG_SUCCESS)
ret = RNG_FAILURE_E;
#if !defined(WOLFSSL_NO_MALLOC) || defined(WOLFSSL_STATIC_MEMORY)
XFREE(rng->drbg, rng->heap, DYNAMIC_TYPE_RNG);
#elif defined(WOLFSSL_CHECK_MEM_ZERO)
wc_MemZero_Check(rng->drbg, sizeof(DRBG_internal));
#endif
rng->drbg = NULL;
}
#ifdef WOLFSSL_SMALL_STACK_CACHE
if (rng->drbg_scratch != NULL) {
if (Hash_DRBG_Uninstantiate((DRBG_internal *)rng->drbg_scratch) != DRBG_SUCCESS)
ret = RNG_FAILURE_E;
XFREE(rng->drbg_scratch, rng->heap, DYNAMIC_TYPE_RNG);
rng->drbg_scratch = NULL;
}
XFREE(rng->health_check_scratch, rng->heap, DYNAMIC_TYPE_RNG);
rng->health_check_scratch = NULL;
XFREE(rng->newSeed_buf, rng->heap, DYNAMIC_TYPE_RNG);
rng->newSeed_buf = NULL;
#endif
rng->status = DRBG_NOT_INIT;
#endif /* HAVE_HASHDRBG */
#ifdef WOLFSSL_XILINX_CRYPT_VERSAL
/* don't overwrite previously set error */
if (wc_VersalTrngReset() && !ret)
ret = WC_HW_E;
#endif
#if defined(WOLFSSL_KEEP_RNG_SEED_FD_OPEN) && defined(XCLOSE) && \
!defined(USE_WINDOWS_API)
if(rng->seed.seedFdOpen && rng->seed.fd != XBADFD) {
XCLOSE(rng->seed.fd);
rng->seed.fd = XBADFD;
rng->seed.seedFdOpen = 0;
}
#endif
return ret;
}
#ifdef HAVE_HASHDRBG
int wc_RNG_HealthTest(int reseed, const byte* seedA, word32 seedASz,
const byte* seedB, word32 seedBSz,
byte* output, word32 outputSz)
{
return wc_RNG_HealthTest_ex(reseed, NULL, 0,
seedA, seedASz, seedB, seedBSz,
output, outputSz,
NULL, INVALID_DEVID);
}
static int wc_RNG_HealthTest_ex_internal(DRBG_internal* drbg,
int reseed, const byte* nonce, word32 nonceSz,
const byte* seedA, word32 seedASz,
const byte* seedB, word32 seedBSz,
byte* output, word32 outputSz,
void* heap, int devId)
{
int ret = -1;
if (seedA == NULL || output == NULL) {
return BAD_FUNC_ARG;
}
if (reseed != 0 && seedB == NULL) {
return BAD_FUNC_ARG;
}
if (outputSz != RNG_HEALTH_TEST_CHECK_SIZE) {
return ret;
}
#ifdef WOLFSSL_SMALL_STACK_CACHE
(void)heap;
(void)devId;
if (Hash_DRBG_Init(drbg, seedA, seedASz, nonce, nonceSz) != 0) {
goto exit_rng_ht;
}
#else
if (Hash_DRBG_Instantiate(drbg, seedA, seedASz, nonce, nonceSz,
heap, devId) != 0) {
goto exit_rng_ht;
}
#endif
if (reseed) {
if (Hash_DRBG_Reseed(drbg, seedB, seedBSz) != 0) {
goto exit_rng_ht;
}
}
/* This call to generate is prescribed by the NIST DRBGVS
* procedure. The results are thrown away. The known
* answer test checks the second block of DRBG out of
* the generator to ensure the internal state is updated
* as expected. */
if (Hash_DRBG_Generate(drbg, output, outputSz) != 0) {
goto exit_rng_ht;
}
if (Hash_DRBG_Generate(drbg, output, outputSz) != 0) {
goto exit_rng_ht;
}
/* Mark success */
ret = 0;
exit_rng_ht:
#ifndef WOLFSSL_SMALL_STACK_CACHE
/* This is safe to call even if Hash_DRBG_Instantiate fails */
if (Hash_DRBG_Uninstantiate(drbg) != 0) {
ret = -1;
}
#endif
return ret;
}
int wc_RNG_HealthTest_ex(int reseed, const byte* nonce, word32 nonceSz,
const byte* seedA, word32 seedASz,
const byte* seedB, word32 seedBSz,
byte* output, word32 outputSz,
void* heap, int devId)
{
int ret = -1;
DRBG_internal* drbg;
#ifndef WOLFSSL_SMALL_STACK
DRBG_internal drbg_var;
#endif
#ifdef WOLFSSL_SMALL_STACK
drbg = (DRBG_internal*)XMALLOC(sizeof(DRBG_internal), heap,
DYNAMIC_TYPE_RNG);
if (drbg == NULL) {
return MEMORY_E;
}
#else
drbg = &drbg_var;
#endif
#ifdef WOLFSSL_SMALL_STACK_CACHE
ret = Hash_DRBG_Instantiate(drbg,
NULL /* seed */, 0, NULL /* nonce */, 0, heap, devId);
if (ret == 0)
#endif
{
ret = wc_RNG_HealthTest_ex_internal(
drbg, reseed, nonce, nonceSz, seedA, seedASz,
seedB, seedBSz, output, outputSz, heap, devId);
#ifdef WOLFSSL_SMALL_STACK_CACHE
Hash_DRBG_Uninstantiate(drbg);
#endif
}
WC_FREE_VAR_EX(drbg, heap, DYNAMIC_TYPE_RNG);
return ret;
}
const FLASH_QUALIFIER byte seedA_data[] = {
0x63, 0x36, 0x33, 0x77, 0xe4, 0x1e, 0x86, 0x46, 0x8d, 0xeb, 0x0a, 0xb4,
0xa8, 0xed, 0x68, 0x3f, 0x6a, 0x13, 0x4e, 0x47, 0xe0, 0x14, 0xc7, 0x00,
0x45, 0x4e, 0x81, 0xe9, 0x53, 0x58, 0xa5, 0x69, 0x80, 0x8a, 0xa3, 0x8f,
0x2a, 0x72, 0xa6, 0x23, 0x59, 0x91, 0x5a, 0x9f, 0x8a, 0x04, 0xca, 0x68
};
const FLASH_QUALIFIER byte reseedSeedA_data[] = {
0xe6, 0x2b, 0x8a, 0x8e, 0xe8, 0xf1, 0x41, 0xb6, 0x98, 0x05, 0x66, 0xe3,
0xbf, 0xe3, 0xc0, 0x49, 0x03, 0xda, 0xd4, 0xac, 0x2c, 0xdf, 0x9f, 0x22,
0x80, 0x01, 0x0a, 0x67, 0x39, 0xbc, 0x83, 0xd3
};
const FLASH_QUALIFIER byte outputA_data[] = {
0x04, 0xee, 0xc6, 0x3b, 0xb2, 0x31, 0xdf, 0x2c, 0x63, 0x0a, 0x1a, 0xfb,
0xe7, 0x24, 0x94, 0x9d, 0x00, 0x5a, 0x58, 0x78, 0x51, 0xe1, 0xaa, 0x79,
0x5e, 0x47, 0x73, 0x47, 0xc8, 0xb0, 0x56, 0x62, 0x1c, 0x18, 0xbd, 0xdc,
0xdd, 0x8d, 0x99, 0xfc, 0x5f, 0xc2, 0xb9, 0x20, 0x53, 0xd8, 0xcf, 0xac,
0xfb, 0x0b, 0xb8, 0x83, 0x12, 0x05, 0xfa, 0xd1, 0xdd, 0xd6, 0xc0, 0x71,
0x31, 0x8a, 0x60, 0x18, 0xf0, 0x3b, 0x73, 0xf5, 0xed, 0xe4, 0xd4, 0xd0,
0x71, 0xf9, 0xde, 0x03, 0xfd, 0x7a, 0xea, 0x10, 0x5d, 0x92, 0x99, 0xb8,
0xaf, 0x99, 0xaa, 0x07, 0x5b, 0xdb, 0x4d, 0xb9, 0xaa, 0x28, 0xc1, 0x8d,
0x17, 0x4b, 0x56, 0xee, 0x2a, 0x01, 0x4d, 0x09, 0x88, 0x96, 0xff, 0x22,
0x82, 0xc9, 0x55, 0xa8, 0x19, 0x69, 0xe0, 0x69, 0xfa, 0x8c, 0xe0, 0x07,
0xa1, 0x80, 0x18, 0x3a, 0x07, 0xdf, 0xae, 0x17
};
const FLASH_QUALIFIER byte seedB_data[] = {
0xa6, 0x5a, 0xd0, 0xf3, 0x45, 0xdb, 0x4e, 0x0e, 0xff, 0xe8, 0x75, 0xc3,
0xa2, 0xe7, 0x1f, 0x42, 0xc7, 0x12, 0x9d, 0x62, 0x0f, 0xf5, 0xc1, 0x19,
0xa9, 0xef, 0x55, 0xf0, 0x51, 0x85, 0xe0, 0xfb, /* nonce next */
0x85, 0x81, 0xf9, 0x31, 0x75, 0x17, 0x27, 0x6e, 0x06, 0xe9, 0x60, 0x7d,
0xdb, 0xcb, 0xcc, 0x2e
};
const FLASH_QUALIFIER byte outputB_data[] = {
0xd3, 0xe1, 0x60, 0xc3, 0x5b, 0x99, 0xf3, 0x40, 0xb2, 0x62, 0x82, 0x64,
0xd1, 0x75, 0x10, 0x60, 0xe0, 0x04, 0x5d, 0xa3, 0x83, 0xff, 0x57, 0xa5,
0x7d, 0x73, 0xa6, 0x73, 0xd2, 0xb8, 0xd8, 0x0d, 0xaa, 0xf6, 0xa6, 0xc3,
0x5a, 0x91, 0xbb, 0x45, 0x79, 0xd7, 0x3f, 0xd0, 0xc8, 0xfe, 0xd1, 0x11,
0xb0, 0x39, 0x13, 0x06, 0x82, 0x8a, 0xdf, 0xed, 0x52, 0x8f, 0x01, 0x81,
0x21, 0xb3, 0xfe, 0xbd, 0xc3, 0x43, 0xe7, 0x97, 0xb8, 0x7d, 0xbb, 0x63,
0xdb, 0x13, 0x33, 0xde, 0xd9, 0xd1, 0xec, 0xe1, 0x77, 0xcf, 0xa6, 0xb7,
0x1f, 0xe8, 0xab, 0x1d, 0xa4, 0x66, 0x24, 0xed, 0x64, 0x15, 0xe5, 0x1c,
0xcd, 0xe2, 0xc7, 0xca, 0x86, 0xe2, 0x83, 0x99, 0x0e, 0xea, 0xeb, 0x91,
0x12, 0x04, 0x15, 0x52, 0x8b, 0x22, 0x95, 0x91, 0x02, 0x81, 0xb0, 0x2d,
0xd4, 0x31, 0xf4, 0xc9, 0xf7, 0x04, 0x27, 0xdf
};
static int wc_RNG_HealthTestLocal(WC_RNG* rng, int reseed, void* heap,
int devId)
{
int ret = 0;
#ifdef WOLFSSL_SMALL_STACK_CACHE
byte *check = rng->health_check_scratch;
DRBG_internal* drbg = (DRBG_internal *)rng->drbg_scratch;
#else
WC_DECLARE_VAR(check, byte, RNG_HEALTH_TEST_CHECK_SIZE, 0);
WC_DECLARE_VAR(drbg, DRBG_internal, 1, 0);
(void)rng;
WC_ALLOC_VAR_EX(check, byte, RNG_HEALTH_TEST_CHECK_SIZE, heap,
DYNAMIC_TYPE_TMP_BUFFER, return MEMORY_E);
WC_ALLOC_VAR_EX(drbg, DRBG_internal, sizeof(DRBG_internal), heap,
DYNAMIC_TYPE_TMP_BUFFER, WC_DO_NOTHING);
#ifdef WC_DECLARE_VAR_IS_HEAP_ALLOC
if (drbg == NULL) {
WC_FREE_VAR_EX(check, heap, DYNAMIC_TYPE_TMP_BUFFER);
return MEMORY_E;
}
#endif
#endif
if (reseed) {
#ifdef WOLFSSL_USE_FLASHMEM
byte* seedA = (byte*)XMALLOC(sizeof(seedA_data), heap,
DYNAMIC_TYPE_TMP_BUFFER);
byte* reseedSeedA = (byte*)XMALLOC(sizeof(reseedSeedA_data), heap,
DYNAMIC_TYPE_TMP_BUFFER);
byte* outputA = (byte*)XMALLOC(sizeof(outputA_data), heap,
DYNAMIC_TYPE_TMP_BUFFER);
if (!seedA || !reseedSeedA || !outputA) {
XFREE(seedA, heap, DYNAMIC_TYPE_TMP_BUFFER);
XFREE(reseedSeedA, heap, DYNAMIC_TYPE_TMP_BUFFER);
XFREE(outputA, heap, DYNAMIC_TYPE_TMP_BUFFER);
ret = MEMORY_E;
}
else {
XMEMCPY_P(seedA, seedA_data, sizeof(seedA_data));
XMEMCPY_P(reseedSeedA, reseedSeedA_data, sizeof(reseedSeedA_data));
XMEMCPY_P(outputA, outputA_data, sizeof(outputA_data));
#else
const byte* seedA = seedA_data;
const byte* reseedSeedA = reseedSeedA_data;
const byte* outputA = outputA_data;
#endif
ret = wc_RNG_HealthTest_ex_internal(drbg, 1, NULL, 0,
seedA, sizeof(seedA_data),
reseedSeedA, sizeof(reseedSeedA_data),
check, RNG_HEALTH_TEST_CHECK_SIZE,
heap, devId);
if (ret == 0) {
if (ConstantCompare(check, outputA,
RNG_HEALTH_TEST_CHECK_SIZE) != 0)
ret = -1;
}
#ifdef WOLFSSL_USE_FLASHMEM
XFREE(seedA, NULL, DYNAMIC_TYPE_TMP_BUFFER);
XFREE(reseedSeedA, NULL, DYNAMIC_TYPE_TMP_BUFFER);
XFREE(outputA, NULL, DYNAMIC_TYPE_TMP_BUFFER);
}
#endif
}
else {
#ifdef WOLFSSL_USE_FLASHMEM
byte* seedB = (byte*)XMALLOC(sizeof(seedB_data), heap,
DYNAMIC_TYPE_TMP_BUFFER);
byte* outputB = (byte*)XMALLOC(sizeof(outputB_data), heap,
DYNAMIC_TYPE_TMP_BUFFER);
if (!seedB || !outputB) {
XFREE(seedB, heap, DYNAMIC_TYPE_TMP_BUFFER);
XFREE(outputB, heap, DYNAMIC_TYPE_TMP_BUFFER);
ret = MEMORY_E;
}
else {
XMEMCPY_P(seedB, seedB_data, sizeof(seedB_data));
XMEMCPY_P(outputB, outputB_data, sizeof(outputB_data));
#else
const byte* seedB = seedB_data;
const byte* outputB = outputB_data;
#endif
#if defined(DEBUG_WOLFSSL)
WOLFSSL_MSG_EX("RNG_HEALTH_TEST_CHECK_SIZE = %d",
RNG_HEALTH_TEST_CHECK_SIZE);
WOLFSSL_MSG_EX("sizeof(seedB_data) = %d",
(int)sizeof(outputB_data));
#endif
ret = wc_RNG_HealthTest_ex_internal(drbg, 0, NULL, 0,
seedB, sizeof(seedB_data),
NULL, 0,
check, RNG_HEALTH_TEST_CHECK_SIZE,
heap, devId);
if (ret != 0) {
#if defined(DEBUG_WOLFSSL)
WOLFSSL_MSG_EX("RNG_HealthTest failed: err = %d", ret);
#endif
}
else {
ret = ConstantCompare(check, outputB,
RNG_HEALTH_TEST_CHECK_SIZE);
if (ret != 0) {
#if defined(DEBUG_WOLFSSL)
WOLFSSL_MSG_EX("Random ConstantCompare failed: err = %d", ret);
#endif
ret = -1;
}
}
/* The previous test cases use a large seed instead of a seed and nonce.
* seedB is actually from a test case with a seed and nonce, and
* just concatenates them. The pivot point between seed and nonce is
* byte 32, feed them into the health test separately. */
if (ret == 0) {
ret = wc_RNG_HealthTest_ex_internal(drbg, 0,
seedB + 32, sizeof(seedB_data) - 32,
seedB, 32,
NULL, 0,
check, RNG_HEALTH_TEST_CHECK_SIZE,
heap, devId);
if (ret == 0) {
if (ConstantCompare(check, outputB, sizeof(outputB_data)) != 0)
ret = -1;
}
}
#ifdef WOLFSSL_USE_FLASHMEM
XFREE(seedB, heap, DYNAMIC_TYPE_TMP_BUFFER);
XFREE(outputB, heap, DYNAMIC_TYPE_TMP_BUFFER);
}
#endif
}
#ifndef WOLFSSL_SMALL_STACK_CACHE
WC_FREE_VAR_EX(check, heap, DYNAMIC_TYPE_TMP_BUFFER);
WC_FREE_VAR_EX(drbg, heap, DYNAMIC_TYPE_TMP_BUFFER);
#endif
return ret;
}
#endif /* HAVE_HASHDRBG */
#ifdef HAVE_WNR
/*
* Init global Whitewood netRandom context
* Returns 0 on success, negative on error
*/
int wc_InitNetRandom(const char* configFile, wnr_hmac_key hmac_cb, int timeout)
{
int ret;
if (configFile == NULL || timeout < 0)
return BAD_FUNC_ARG;
#ifndef WOLFSSL_MUTEX_INITIALIZER
if (wnr_mutex_inited > 0) {
WOLFSSL_MSG("netRandom context already created, skipping");
return 0;
}
if (wc_InitMutex(&wnr_mutex) != 0) {
WOLFSSL_MSG("Bad Init Mutex wnr_mutex");
return BAD_MUTEX_E;
}
wnr_mutex_inited = 1;
#endif
if (wnr_inited > 0) {
WOLFSSL_MSG("netRandom context already created, skipping");
return 0;
}
if (wc_LockMutex(&wnr_mutex) != 0) {
WOLFSSL_MSG("Bad Lock Mutex wnr_mutex");
return BAD_MUTEX_E;
}
/* store entropy timeout */
wnr_timeout = timeout;
/* create global wnr_context struct */
if (wnr_create(&wnr_ctx) != WNR_ERROR_NONE) {
WOLFSSL_MSG("Error creating global netRandom context");
ret = RNG_FAILURE_E;
goto out;
}
/* load config file */
if (wnr_config_loadf(wnr_ctx, (char*)configFile) != WNR_ERROR_NONE) {
WOLFSSL_MSG("Error loading config file into netRandom context");
wnr_destroy(wnr_ctx);
wnr_ctx = NULL;
ret = RNG_FAILURE_E;
goto out;
}
/* create/init polling mechanism */
if (wnr_poll_create() != WNR_ERROR_NONE) {
WOLFSSL_MSG("Error initializing netRandom polling mechanism");
wnr_destroy(wnr_ctx);
wnr_ctx = NULL;
ret = RNG_FAILURE_E;
goto out;
}
/* validate config, set HMAC callback (optional) */
if (wnr_setup(wnr_ctx, hmac_cb) != WNR_ERROR_NONE) {
WOLFSSL_MSG("Error setting up netRandom context");
wnr_destroy(wnr_ctx);
wnr_ctx = NULL;
wnr_poll_destroy();
ret = RNG_FAILURE_E;
goto out;
}
wnr_inited = 1;
out:
wc_UnLockMutex(&wnr_mutex);
return ret;
}
/*
* Free global Whitewood netRandom context
* Returns 0 on success, negative on error
*/
int wc_FreeNetRandom(void)
{
if (wnr_inited > 0) {
if (wc_LockMutex(&wnr_mutex) != 0) {
WOLFSSL_MSG("Bad Lock Mutex wnr_mutex");
return BAD_MUTEX_E;
}
if (wnr_ctx != NULL) {
wnr_destroy(wnr_ctx);
wnr_ctx = NULL;
}
wnr_poll_destroy();
wc_UnLockMutex(&wnr_mutex);
#ifndef WOLFSSL_MUTEX_INITIALIZER
wc_FreeMutex(&wnr_mutex);
wnr_mutex_inited = 0;
#endif
wnr_inited = 0;
}
return 0;
}
#endif /* HAVE_WNR */
#if defined(HAVE_INTEL_RDRAND) || defined(HAVE_INTEL_RDSEED) || \
defined(HAVE_AMD_RDSEED)
#ifdef WOLFSSL_ASYNC_CRYPT
/* need more retries if multiple cores */
#define INTELRD_RETRY (32 * 8)
#else
#define INTELRD_RETRY 32
#endif
#if defined(HAVE_INTEL_RDSEED) || defined(HAVE_AMD_RDSEED)
#ifndef USE_INTEL_INTRINSICS
/* return 0 on success */
static WC_INLINE int IntelRDseed64(word64* seed)
{
unsigned char ok;
__asm__ volatile("rdseed %0; setc %1":"=r"(*seed), "=qm"(ok));
return (ok) ? 0 : -1;
}
#else /* USE_INTEL_INTRINSICS */
/* The compiler Visual Studio uses does not allow inline assembly.
* It does allow for Intel intrinsic functions. */
/* return 0 on success */
# ifdef __GNUC__
__attribute__((target("rdseed")))
# endif
static WC_INLINE int IntelRDseed64(word64* seed)
{
int ok;
ok = _rdseed64_step((unsigned long long*) seed);
return (ok) ? 0 : -1;
}
#endif /* USE_INTEL_INTRINSICS */
/* return 0 on success */
static WC_INLINE int IntelRDseed64_r(word64* rnd)
{
int i;
for (i = 0; i < INTELRD_RETRY; i++) {
if (IntelRDseed64(rnd) == 0)
return 0;
}
return -1;
}
/* return 0 on success */
static int wc_GenerateSeed_IntelRD(OS_Seed* os, byte* output, word32 sz)
{
int ret;
word64 rndTmp;
static int rdseed_sanity_status = 0;
(void)os;
if (!IS_INTEL_RDSEED(intel_flags))
return -1;
/* Note, access to rdseed_sanity_status is benignly racey on multithreaded
* targets.
*/
if (rdseed_sanity_status == 0) {
word64 sanity_word1 = 0, sanity_word2 = 0;
ret = IntelRDseed64_r(&sanity_word1);
if (ret != 0)
return ret;
ret = IntelRDseed64_r(&sanity_word2);
if (ret != 0)
return ret;
if (sanity_word1 == sanity_word2) {
ret = IntelRDseed64_r(&sanity_word1);
if (ret != 0)
return ret;
if (sanity_word1 == sanity_word2) {
#ifdef WC_VERBOSE_RNG
WOLFSSL_DEBUG_PRINTF(
"WARNING: disabling RDSEED due to repeating word 0x%lx -- "
"check CPU microcode version.", sanity_word2);
#endif
rdseed_sanity_status = -1;
return -1;
}
}
rdseed_sanity_status = 1;
}
else if (rdseed_sanity_status < 0) {
return -1;
}
for (; (sz / sizeof(word64)) > 0; sz -= sizeof(word64),
output += sizeof(word64)) {
ret = IntelRDseed64_r((word64*)output);
if (ret != 0)
return ret;
}
if (sz == 0)
return 0;
/* handle unaligned remainder */
ret = IntelRDseed64_r(&rndTmp);
if (ret != 0)
return ret;
XMEMCPY(output, &rndTmp, sz);
ForceZero(&rndTmp, sizeof(rndTmp));
return 0;
}
#endif /* HAVE_INTEL_RDSEED || HAVE_AMD_RDSEED */
#ifdef HAVE_INTEL_RDRAND
#ifndef USE_INTEL_INTRINSICS
/* return 0 on success */
static WC_INLINE int IntelRDrand64(word64 *rnd)
{
unsigned char ok;
__asm__ volatile("rdrand %0; setc %1":"=r"(*rnd), "=qm"(ok));
return (ok) ? 0 : -1;
}
#else /* USE_INTEL_INTRINSICS */
/* The compiler Visual Studio uses does not allow inline assembly.
* It does allow for Intel intrinsic functions. */
/* return 0 on success */
# ifdef __GNUC__
__attribute__((target("rdrnd")))
# endif
static WC_INLINE int IntelRDrand64(word64 *rnd)
{
int ok;
ok = _rdrand64_step((unsigned long long*) rnd);
return (ok) ? 0 : -1;
}
#endif /* USE_INTEL_INTRINSICS */
/* return 0 on success */
static WC_INLINE int IntelRDrand64_r(word64 *rnd)
{
int i;
for (i = 0; i < INTELRD_RETRY; i++) {
if (IntelRDrand64(rnd) == 0)
return 0;
}
return -1;
}
/* return 0 on success */
static int wc_GenerateRand_IntelRD(OS_Seed* os, byte* output, word32 sz)
{
int ret;
word64 rndTmp;
(void)os;
if (!IS_INTEL_RDRAND(intel_flags))
return -1;
for (; (sz / sizeof(word64)) > 0; sz -= sizeof(word64),
output += sizeof(word64)) {
ret = IntelRDrand64_r((word64 *)output);
if (ret != 0)
return ret;
}
if (sz == 0)
return 0;
/* handle unaligned remainder */
ret = IntelRDrand64_r(&rndTmp);
if (ret != 0)
return ret;
XMEMCPY(output, &rndTmp, sz);
return 0;
}
#endif /* HAVE_INTEL_RDRAND */
#endif /* HAVE_INTEL_RDRAND || HAVE_INTEL_RDSEED || HAVE_AMD_RDSEED */
/* Begin wc_GenerateSeed Implementations */
#if defined(CUSTOM_RAND_GENERATE_SEED)
/* Implement your own random generation function
* Return 0 to indicate success
* int rand_gen_seed(byte* output, word32 sz);
* #define CUSTOM_RAND_GENERATE_SEED rand_gen_seed */
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
(void)os; /* Suppress unused arg warning */
return CUSTOM_RAND_GENERATE_SEED(output, sz);
}
#elif defined(CUSTOM_RAND_GENERATE_SEED_OS)
/* Implement your own random generation function,
* which includes OS_Seed.
* Return 0 to indicate success
* int rand_gen_seed(OS_Seed* os, byte* output, word32 sz);
* #define CUSTOM_RAND_GENERATE_SEED_OS rand_gen_seed */
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
return CUSTOM_RAND_GENERATE_SEED_OS(os, output, sz);
}
#elif defined(CUSTOM_RAND_GENERATE)
/* Implement your own random generation function
* word32 rand_gen(void);
* #define CUSTOM_RAND_GENERATE rand_gen */
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
word32 i = 0;
(void)os;
while (i < sz)
{
/* If not aligned or there is odd/remainder */
if( (i + sizeof(CUSTOM_RAND_TYPE)) > sz ||
((wc_ptr_t)&output[i] % sizeof(CUSTOM_RAND_TYPE)) != 0
) {
/* Single byte at a time */
output[i++] = (byte)CUSTOM_RAND_GENERATE();
}
else {
/* Use native 8, 16, 32 or 64 copy instruction */
*((CUSTOM_RAND_TYPE*)&output[i]) = CUSTOM_RAND_GENERATE();
i += sizeof(CUSTOM_RAND_TYPE);
}
}
return 0;
}
#elif defined(WOLFSSL_SGX)
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int ret = !SGX_SUCCESS;
int i, read_max = 10;
for (i = 0; i < read_max && ret != SGX_SUCCESS; i++) {
ret = sgx_read_rand(output, sz);
}
(void)os;
return (ret == SGX_SUCCESS) ? 0 : 1;
}
#elif defined(USE_WINDOWS_API)
#ifdef WIN_REUSE_CRYPT_HANDLE
/* shared crypt handle for RNG use */
static ProviderHandle gHandle = 0;
int wc_WinCryptHandleInit(void)
{
int ret = 0;
if (gHandle == 0) {
if(!CryptAcquireContext(&gHandle, 0, 0, PROV_RSA_FULL,
CRYPT_VERIFYCONTEXT)) {
DWORD dw = GetLastError();
WOLFSSL_MSG("CryptAcquireContext failed!");
WOLFSSL_ERROR((int)dw);
ret = WINCRYPT_E;
}
}
return ret;
}
void wc_WinCryptHandleCleanup(void)
{
if (gHandle != 0) {
CryptReleaseContext(gHandle, 0);
gHandle = 0;
}
}
#endif /* WIN_REUSE_CRYPT_HANDLE */
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
#ifdef WOLF_CRYPTO_CB
int ret;
if (os != NULL
#ifndef WOLF_CRYPTO_CB_FIND
&& os->devId != INVALID_DEVID)
#endif
{
ret = wc_CryptoCb_RandomSeed(os, output, sz);
if (ret != WC_NO_ERR_TRACE(CRYPTOCB_UNAVAILABLE))
return ret;
/* fall-through when unavailable */
}
#endif
#ifdef HAVE_INTEL_RDSEED
if (IS_INTEL_RDSEED(intel_flags)) {
if (!wc_GenerateSeed_IntelRD(NULL, output, sz)) {
/* success, we're done */
return 0;
}
#ifdef FORCE_FAILURE_RDSEED
/* don't fall back to CryptoAPI */
return READ_RAN_E;
#endif
}
#endif /* HAVE_INTEL_RDSEED */
#ifdef WIN_REUSE_CRYPT_HANDLE
/* Check that handle was initialized.
* Note: initialization should be done through:
* wolfSSL_Init -> wolfCrypt_Init -> wc_WinCryptHandleInit
*/
if (wc_WinCryptHandleInit() != 0) {
return WINCRYPT_E;
}
if (!CryptGenRandom(gHandle, sz, output))
return CRYPTGEN_E;
#else
if (!CryptAcquireContext(&os->handle, 0, 0, PROV_RSA_FULL,
CRYPT_VERIFYCONTEXT)) {
return WINCRYPT_E;
}
if (!CryptGenRandom(os->handle, sz, output)) {
return CRYPTGEN_E;
}
CryptReleaseContext(os->handle, 0);
os->handle = 0;
#endif
return 0;
}
#elif defined(HAVE_RTP_SYS) || defined(EBSNET)
#include "rtprand.h" /* rtp_rand () */
#if (defined(HAVE_RTP_SYS) || (defined(RTPLATFORM) && (RTPLATFORM != 0)))
#include "rtptime.h" /* rtp_get_system_msec() */
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
word32 i;
rtp_srand(rtp_get_system_msec());
for (i = 0; i < sz; i++ ) {
output[i] = rtp_rand() % 256;
}
return 0;
}
#else
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
word32 i;
KS_SEED(ks_get_ticks());
for (i = 0; i < sz; i++ ) {
output[i] = KS_RANDOM() % 256;
}
return 0;
}
#endif /* defined(HAVE_RTP_SYS) || (defined(RTPLATFORM) && (RTPLATFORM != 0)) */
#elif (defined(WOLFSSL_ATMEL) || defined(WOLFSSL_ATECC_RNG)) && \
!defined(WOLFSSL_PIC32MZ_RNG)
/* enable ATECC RNG unless using PIC32MZ one instead */
#include <wolfssl/wolfcrypt/port/atmel/atmel.h>
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int ret = 0;
(void)os;
if (output == NULL) {
return BUFFER_E;
}
ret = atmel_get_random_number(sz, output);
return ret;
}
#elif defined(MICROCHIP_PIC32) || defined(MICROCHIP_MPLAB_HARMONY)
#ifdef MICROCHIP_MPLAB_HARMONY
#ifdef MICROCHIP_MPLAB_HARMONY_3
#include "system/time/sys_time.h"
#define PIC32_SEED_COUNT SYS_TIME_CounterGet
#else
#define PIC32_SEED_COUNT _CP0_GET_COUNT
#endif
#else
#if !defined(WOLFSSL_MICROCHIP_PIC32MZ)
#include <peripheral/timer.h>
#endif
extern word32 ReadCoreTimer(void);
#define PIC32_SEED_COUNT ReadCoreTimer
#endif
#ifdef WOLFSSL_PIC32MZ_RNG
#include "xc.h"
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int i;
byte rnd[8];
word32 *rnd32 = (word32 *)rnd;
word32 size = sz;
byte* op = output;
#if ((__PIC32_FEATURE_SET0 == 'E') && (__PIC32_FEATURE_SET1 == 'C'))
RNGNUMGEN1 = _CP0_GET_COUNT();
RNGPOLY1 = _CP0_GET_COUNT();
RNGPOLY2 = _CP0_GET_COUNT();
RNGNUMGEN2 = _CP0_GET_COUNT();
#else
/* All others can be seeded from the TRNG */
RNGCONbits.TRNGMODE = 1;
RNGCONbits.TRNGEN = 1;
while (RNGCNT < 64);
RNGCONbits.LOAD = 1;
while (RNGCONbits.LOAD == 1);
while (RNGCNT < 64);
RNGPOLY2 = RNGSEED2;
RNGPOLY1 = RNGSEED1;
#endif
RNGCONbits.PLEN = 0x40;
RNGCONbits.PRNGEN = 1;
for (i=0; i<5; i++) { /* wait for RNGNUMGEN ready */
volatile int x, y;
x = RNGNUMGEN1;
y = RNGNUMGEN2;
(void)x;
(void)y;
}
do {
rnd32[0] = RNGNUMGEN1;
rnd32[1] = RNGNUMGEN2;
for(i=0; i<8; i++, op++) {
*op = rnd[i];
size --;
if(size==0)break;
}
} while(size);
return 0;
}
#else /* WOLFSSL_PIC32MZ_RNG */
/* uses the core timer, in nanoseconds to seed srand */
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int i;
srand(PIC32_SEED_COUNT() * 25);
for (i = 0; i < sz; i++ ) {
output[i] = rand() % 256;
if ( (i % 8) == 7)
srand(PIC32_SEED_COUNT() * 25);
}
return 0;
}
#endif /* WOLFSSL_PIC32MZ_RNG */
#elif defined(FREESCALE_K70_RNGA) || defined(FREESCALE_RNGA)
/*
* wc_Generates a RNG seed using the Random Number Generator Accelerator
* on the Kinetis K70. Documentation located in Chapter 37 of
* K70 Sub-Family Reference Manual (see Note 3 in the README for link).
*/
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
word32 i;
/* turn on RNGA module */
#if defined(SIM_SCGC3_RNGA_MASK)
SIM_SCGC3 |= SIM_SCGC3_RNGA_MASK;
#endif
#if defined(SIM_SCGC6_RNGA_MASK)
/* additionally needed for at least K64F */
SIM_SCGC6 |= SIM_SCGC6_RNGA_MASK;
#endif
/* set SLP bit to 0 - "RNGA is not in sleep mode" */
RNG_CR &= ~RNG_CR_SLP_MASK;
/* set HA bit to 1 - "security violations masked" */
RNG_CR |= RNG_CR_HA_MASK;
/* set GO bit to 1 - "output register loaded with data" */
RNG_CR |= RNG_CR_GO_MASK;
for (i = 0; i < sz; i++) {
/* wait for RNG FIFO to be full */
while((RNG_SR & RNG_SR_OREG_LVL(0xF)) == 0) {}
/* get value */
output[i] = RNG_OR;
}
return 0;
}
#elif defined(FREESCALE_K53_RNGB) || defined(FREESCALE_RNGB)
/*
* wc_Generates a RNG seed using the Random Number Generator (RNGB)
* on the Kinetis K53. Documentation located in Chapter 33 of
* K53 Sub-Family Reference Manual (see note in the README for link).
*/
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int i;
/* turn on RNGB module */
SIM_SCGC3 |= SIM_SCGC3_RNGB_MASK;
/* reset RNGB */
RNG_CMD |= RNG_CMD_SR_MASK;
/* FIFO generate interrupt, return all zeros on underflow,
* set auto reseed */
RNG_CR |= (RNG_CR_FUFMOD_MASK | RNG_CR_AR_MASK);
/* gen seed, clear interrupts, clear errors */
RNG_CMD |= (RNG_CMD_GS_MASK | RNG_CMD_CI_MASK | RNG_CMD_CE_MASK);
/* wait for seeding to complete */
while ((RNG_SR & RNG_SR_SDN_MASK) == 0) {}
for (i = 0; i < sz; i++) {
/* wait for a word to be available from FIFO */
while((RNG_SR & RNG_SR_FIFO_LVL_MASK) == 0) {}
/* get value */
output[i] = RNG_OUT;
}
return 0;
}
#elif defined(FREESCALE_KSDK_2_0_TRNG)
#ifndef TRNG0
#define TRNG0 TRNG
#endif
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
status_t status;
status = TRNG_GetRandomData(TRNG0, output, sz);
(void)os;
if (status == kStatus_Success)
{
return(0);
}
return RAN_BLOCK_E;
}
#elif defined(FREESCALE_KSDK_2_0_RNGA)
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
status_t status;
status = RNGA_GetRandomData(RNG, output, sz);
(void)os;
if (status == kStatus_Success)
{
return(0);
}
return RAN_BLOCK_E;
}
#elif defined(FREESCALE_RNGA)
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
status_t status;
status = RNGA_GetRandomData(RNG, output, sz);
(void)os;
if (status == kStatus_Success)
{
return(0);
}
return RAN_BLOCK_E;
}
#elif !defined(WOLFSSL_CAAM) && \
(defined(FREESCALE_MQX) || defined(FREESCALE_KSDK_MQX) || \
defined(FREESCALE_KSDK_BM) || defined(FREESCALE_FREE_RTOS))
/*
* Fallback to USE_TEST_GENSEED if a FREESCALE platform did not match any
* of the TRNG/RNGA/RNGB support
*/
#define USE_TEST_GENSEED
#elif defined(WOLFSSL_SILABS_SE_ACCEL)
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
(void)os;
return silabs_GenerateRand(output, sz);
}
#elif defined(STM32_RNG)
/* Generate a RNG seed using the hardware random number generator
* on the STM32F2/F4/F7/L4. */
#ifdef WOLFSSL_STM32_CUBEMX
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int ret;
RNG_HandleTypeDef hrng;
word32 i = 0;
(void)os;
ret = wolfSSL_CryptHwMutexLock();
if (ret != 0) {
return ret;
}
/* enable RNG clock source */
__HAL_RCC_RNG_CLK_ENABLE();
/* enable RNG peripheral */
XMEMSET(&hrng, 0, sizeof(hrng));
hrng.Instance = RNG;
HAL_RNG_Init(&hrng);
while (i < sz) {
/* If not aligned or there is odd/remainder */
if( (i + sizeof(word32)) > sz ||
((wc_ptr_t)&output[i] % sizeof(word32)) != 0
) {
/* Single byte at a time */
uint32_t tmpRng = 0;
if (HAL_RNG_GenerateRandomNumber(&hrng, &tmpRng) != HAL_OK) {
wolfSSL_CryptHwMutexUnLock();
return RAN_BLOCK_E;
}
output[i++] = (byte)tmpRng;
}
else {
/* Use native 32 instruction */
if (HAL_RNG_GenerateRandomNumber(&hrng, (uint32_t*)&output[i]) != HAL_OK) {
wolfSSL_CryptHwMutexUnLock();
return RAN_BLOCK_E;
}
i += sizeof(word32);
}
}
HAL_RNG_DeInit(&hrng);
wolfSSL_CryptHwMutexUnLock();
return 0;
}
#elif defined(WOLFSSL_STM32F427_RNG) || defined(WOLFSSL_STM32_RNG_NOLIB) \
|| defined(STM32_NUTTX_RNG)
#ifdef STM32_NUTTX_RNG
#include "hardware/stm32_rng.h"
/* Set CONFIG_STM32U5_RNG in NuttX to enable the RCC */
#define WC_RNG_CR *((volatile uint32_t*)(STM32_RNG_CR))
#define WC_RNG_SR *((volatile uint32_t*)(STM32_RNG_SR))
#define WC_RNG_DR *((volatile uint32_t*)(STM32_RNG_DR))
#else
/* Comes from "stm32xxxx_hal.h" */
#define WC_RNG_CR RNG->CR
#define WC_RNG_SR RNG->SR
#define WC_RNG_DR RNG->DR
#endif
/* Generate a RNG seed using the hardware RNG on the STM32F427
* directly, following steps outlined in STM32F4 Reference
* Manual (Chapter 24) for STM32F4xx family. */
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int ret;
word32 i;
(void)os;
ret = wolfSSL_CryptHwMutexLock();
if (ret != 0) {
return ret;
}
#ifndef STM32_NUTTX_RNG
/* enable RNG peripheral clock */
RCC->AHB2ENR |= RCC_AHB2ENR_RNGEN;
#endif
/* enable RNG interrupt, set IE bit in RNG->CR register */
WC_RNG_CR |= RNG_CR_IE;
/* enable RNG, set RNGEN bit in RNG->CR. Activates RNG,
* RNG_LFSR, and error detector */
WC_RNG_CR |= RNG_CR_RNGEN;
/* verify no errors, make sure SEIS and CEIS bits are 0
* in RNG->SR register */
if (WC_RNG_SR & (RNG_SR_SECS | RNG_SR_CECS)) {
wolfSSL_CryptHwMutexUnLock();
return RNG_FAILURE_E;
}
for (i = 0; i < sz; i++) {
/* wait until RNG number is ready */
while ((WC_RNG_SR & RNG_SR_DRDY) == 0) { }
/* get value */
output[i] = WC_RNG_DR;
}
wolfSSL_CryptHwMutexUnLock();
return 0;
}
#else
/* Generate a RNG seed using the STM32 Standard Peripheral Library */
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int ret;
word32 i;
(void)os;
ret = wolfSSL_CryptHwMutexLock();
if (ret != 0) {
return ret;
}
/* enable RNG clock source */
RCC_AHB2PeriphClockCmd(RCC_AHB2Periph_RNG, ENABLE);
/* reset RNG */
RNG_DeInit();
/* enable RNG peripheral */
RNG_Cmd(ENABLE);
/* verify no errors with RNG_CLK or Seed */
if (RNG_GetFlagStatus(RNG_FLAG_SECS | RNG_FLAG_CECS) != RESET) {
wolfSSL_CryptHwMutexUnLock();
return RNG_FAILURE_E;
}
for (i = 0; i < sz; i++) {
/* wait until RNG number is ready */
while (RNG_GetFlagStatus(RNG_FLAG_DRDY) == RESET) { }
/* get value */
output[i] = RNG_GetRandomNumber();
}
wolfSSL_CryptHwMutexUnLock();
return 0;
}
#endif /* WOLFSSL_STM32_CUBEMX */
#elif defined(WOLFSSL_TIRTOS)
#warning "potential for not enough entropy, currently being used for testing"
#include <xdc/runtime/Timestamp.h>
#include <stdlib.h>
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int i;
srand(xdc_runtime_Timestamp_get32());
for (i = 0; i < sz; i++ ) {
output[i] = rand() % 256;
if ((i % 8) == 7) {
srand(xdc_runtime_Timestamp_get32());
}
}
return 0;
}
#elif defined(WOLFSSL_PB)
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
word32 i;
for (i = 0; i < sz; i++)
output[i] = UTL_Rand();
(void)os;
return 0;
}
#elif defined(WOLFSSL_NUCLEUS)
#include "nucleus.h"
#include "kernel/plus_common.h"
#warning "potential for not enough entropy, currently being used for testing"
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int i;
srand(NU_Get_Time_Stamp());
for (i = 0; i < sz; i++ ) {
output[i] = rand() % 256;
if ((i % 8) == 7) {
srand(NU_Get_Time_Stamp());
}
}
return 0;
}
#elif defined(WOLFSSL_DEOS) && !defined(CUSTOM_RAND_GENERATE)
#include "stdlib.h"
#warning "potential for not enough entropy, currently being used for testing Deos"
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int i;
int seed = XTIME(0);
(void)os;
for (i = 0; i < sz; i++ ) {
output[i] = rand_r(&seed) % 256;
if ((i % 8) == 7) {
seed = XTIME(0);
rand_r(&seed);
}
}
return 0;
}
#elif defined(WOLFSSL_VXWORKS)
#ifdef WOLFSSL_VXWORKS_6_x
#include "stdlib.h"
#warning "potential for not enough entropy, currently being used for testing"
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int i;
unsigned int seed = (unsigned int)XTIME(0);
(void)os;
for (i = 0; i < sz; i++ ) {
output[i] = rand_r(&seed) % 256;
if ((i % 8) == 7) {
seed = (unsigned int)XTIME(0);
rand_r(&seed);
}
}
return 0;
}
#else
#include <randomNumGen.h>
#include <tickLib.h>
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz) {
STATUS status = ERROR;
RANDOM_NUM_GEN_STATUS r_status = RANDOM_NUM_GEN_ERROR;
_Vx_ticks_t seed = 0;
#ifdef VXWORKS_SIM
/* cannot generate true entropy with VxWorks simulator */
#warning "not enough entropy, simulator for testing only"
int i = 0;
for (i = 0; i < 1000; i++) {
randomAddTimeStamp();
}
#endif
/*
wolfSSL can request 52 Bytes of random bytes. We need to add
buffer to the entropy pool to ensure we can get more than 32 Bytes.
Because VxWorks has entropy limits (ENTROPY_MIN and ENTROPY_MAX)
defined as 256 and 1024 bits, see randomSWNumGenLib.c.
randStatus() can return the following status:
RANDOM_NUM_GEN_NO_ENTROPY when entropy is 0
RANDOM_NUM_GEN_ERROR, entropy is not initialized
RANDOM_NUM_GEN_NOT_ENOUGH_ENTROPY if entropy < 32 Bytes
RANDOM_NUM_GEN_ENOUGH_ENTROPY if entropy is between 32 and 128 Bytes
RANDOM_NUM_GEN_MAX_ENTROPY if entropy is greater than 128 Bytes
*/
do {
seed = tickGet();
status = randAdd(&seed, sizeof(_Vx_ticks_t), 2);
if (status == OK)
r_status = randStatus();
} while (r_status != RANDOM_NUM_GEN_MAX_ENTROPY &&
r_status != RANDOM_NUM_GEN_ERROR && status == OK);
if (r_status == RANDOM_NUM_GEN_ERROR)
return RNG_FAILURE_E;
status = randBytes (output, sz);
if (status == ERROR) {
return RNG_FAILURE_E;
}
return 0;
}
#endif
#elif defined(WOLFSSL_NRF51) || defined(WOLFSSL_NRF5x)
#include "app_error.h"
#include "nrf_drv_rng.h"
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int remaining = sz, pos = 0;
word32 err_code;
byte available;
static byte initialized = 0;
(void)os;
/* Make sure RNG is running */
if (!initialized) {
err_code = nrf_drv_rng_init(NULL);
if (err_code != NRF_SUCCESS && err_code != NRF_ERROR_INVALID_STATE
#ifdef NRF_ERROR_MODULE_ALREADY_INITIALIZED
&& err_code != NRF_ERROR_MODULE_ALREADY_INITIALIZED
#endif
) {
return -1;
}
initialized = 1;
}
while (remaining > 0) {
int length;
available = 0;
nrf_drv_rng_bytes_available(&available); /* void func */
length = (remaining < available) ? remaining : available;
if (length > 0) {
err_code = nrf_drv_rng_rand(&output[pos], length);
if (err_code != NRF_SUCCESS) {
break;
}
remaining -= length;
pos += length;
}
}
return (err_code == NRF_SUCCESS) ? 0 : -1;
}
#elif defined(HAVE_WNR)
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
if (os == NULL || output == NULL || wnr_ctx == NULL ||
wnr_timeout < 0) {
return BAD_FUNC_ARG;
}
if (wnr_mutex_init == 0) {
WOLFSSL_MSG("netRandom context must be created before use");
return RNG_FAILURE_E;
}
if (wc_LockMutex(&wnr_mutex) != 0) {
WOLFSSL_MSG("Bad Lock Mutex wnr_mutex");
return BAD_MUTEX_E;
}
if (wnr_get_entropy(wnr_ctx, wnr_timeout, output, sz, sz) !=
WNR_ERROR_NONE)
return RNG_FAILURE_E;
wc_UnLockMutex(&wnr_mutex);
return 0;
}
#elif defined(INTIME_RTOS)
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
uint32_t randval;
word32 len;
if (output == NULL) {
return BUFFER_E;
}
#ifdef INTIMEVER
/* If INTIMEVER exists then it is INTIME RTOS v6 or later */
#define INTIME_RAND_FUNC arc4random
len = 4;
#else
/* v5 and older */
#define INTIME_RAND_FUNC rand
srand(time(0));
len = 2; /* don't use all 31 returned bits */
#endif
while (sz > 0) {
if (sz < len)
len = sz;
randval = INTIME_RAND_FUNC();
XMEMCPY(output, &randval, len);
output += len;
sz -= len;
}
(void)os;
return 0;
}
#elif defined(WOLFSSL_WICED)
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int ret;
(void)os;
if (output == NULL || UINT16_MAX < sz) {
return BUFFER_E;
}
if ((ret = wiced_crypto_get_random((void*) output, sz) )
!= WICED_SUCCESS) {
return ret;
}
return ret;
}
#elif defined(WOLFSSL_NETBURNER)
#warning using NetBurner pseudo random GetRandomByte for seed
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
word32 i;
(void)os;
if (output == NULL) {
return BUFFER_E;
}
for (i = 0; i < sz; i++) {
output[i] = GetRandomByte();
/* check if was a valid random number */
if (!RandomValid())
return RNG_FAILURE_E;
}
return 0;
}
#elif defined(IDIRECT_DEV_RANDOM)
extern int getRandom( int sz, unsigned char *output );
int GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int num_bytes_returned = 0;
num_bytes_returned = getRandom( (int) sz, (unsigned char *) output );
return 0;
}
#elif defined(WOLFSSL_CAAM)
#include <wolfssl/wolfcrypt/port/caam/wolfcaam.h>
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
unsigned int args[4] = {0};
CAAM_BUFFER buf[1];
int ret = 0;
int times = 1000, i; /* 1000 is an arbitrary number chosen */
word32 idx = 0;
(void)os;
if (output == NULL) {
return BUFFER_E;
}
/* Check Waiting to make sure entropy is ready */
for (i = 0; i < times; i++) {
buf[0].BufferType = DataBuffer | LastBuffer;
buf[0].TheAddress = (CAAM_ADDRESS)(output + idx);
buf[0].Length = ((sz - idx) < WC_CAAM_MAX_ENTROPY)?
sz - idx : WC_CAAM_MAX_ENTROPY;
args[0] = buf[0].Length;
ret = wc_caamAddAndWait(buf, 1, args, CAAM_ENTROPY);
if (ret == 0) {
idx += buf[0].Length;
if (idx == sz)
break;
}
/* driver could be waiting for entropy */
if (ret != WC_NO_ERR_TRACE(RAN_BLOCK_E) && ret != 0) {
return ret;
}
#ifndef WOLFSSL_IMXRT1170_CAAM
usleep(100);
#endif
}
if (i == times && ret != 0) {
return RNG_FAILURE_E;
}
else { /* Success case */
ret = 0;
}
return ret;
}
#elif defined(WOLFSSL_APACHE_MYNEWT)
#include <stdlib.h>
#include "os/os_time.h"
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int i;
srand(os_time_get());
for (i = 0; i < sz; i++ ) {
output[i] = rand() % 256;
if ((i % 8) == 7) {
srand(os_time_get());
}
}
return 0;
}
#elif defined(ARDUINO)
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int ret = 0;
word32 rand;
while (sz > 0) {
word32 len = sizeof(rand);
if (sz < len)
len = sz;
/* Get an Arduino framework random number */
#if defined(ARDUINO_SAMD_NANO_33_IOT) || \
defined(ARDUINO_ARCH_RP2040)
/* Known, tested boards working with random() */
rand = random();
#elif defined(ARDUINO_SAM_DUE)
/* See: https://github.com/avrxml/asf/tree/master/sam/utils/cmsis/sam3x/include */
#if defined(__SAM3A4C__)
#ifndef TRNG
#define TRNG (0x400BC000U)
#endif
#elif defined(__SAM3A8C__)
#ifndef TRNG
#define TRNG (0x400BC000U)
#endif
#elif defined(__SAM3X4C__)
#ifndef TRNG
#define TRNG (0x400BC000U)
#endif
#elif defined(__SAM3X4E__)
#ifndef TRNG
#define TRNG (0x400BC000U)
#endif
#elif defined(__SAM3X8C__)
#ifndef TRNG
#define TRNG (0x400BC000U)
#endif
#elif defined(__SAM3X8E__)
/* This is the Arduino Due */
#ifndef TRNG
#define TRNG (0x400BC000U)
#endif
#elif defined(__SAM3A8H__)
#ifndef TRNG
#define TRNG (0x400BC000U)
#endif
#else
#ifndef TRNG
#error "Unknown TRNG for this device"
#endif
#endif
srand(analogRead(0));
rand = trng_read_output_data(TRNG);
#elif defined(__STM32__)
/* TODO: confirm this is proper random number on Arduino STM32 */
#warning "Not yet tested on STM32 targets"
rand = random();
#else
/* TODO: Pull requests appreciated for new targets.
* Do *all* other Arduino boards support random()?
* Probably not 100%, but most will likely work: */
rand = random();
#endif
XMEMCPY(output, &rand, len);
output += len;
sz -= len;
}
return ret;
}
#elif defined(WOLFSSL_ESPIDF)
/* Espressif */
#if defined(WOLFSSL_ESP32) || defined(WOLFSSL_ESPWROOM32SE)
/* Espressif ESP32 */
#include <esp_system.h>
#if defined(CONFIG_IDF_TARGET_ESP32S2) || \
defined(CONFIG_IDF_TARGET_ESP32S3)
#include <esp_random.h>
#endif
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
word32 rand;
while (sz > 0) {
word32 len = sizeof(rand);
if (sz < len)
len = sz;
/* Get one random 32-bit word from hw RNG */
rand = esp_random( );
XMEMCPY(output, &rand, len);
output += len;
sz -= len;
}
return 0;
}
#elif defined(WOLFSSL_ESP8266)
/* Espressif ESP8266 */
#include <esp_system.h>
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
#if defined(DEBUG_WOLFSSL)
WOLFSSL_ENTER("ESP8266 Random");
#endif
word32 rand;
while (sz > 0) {
word32 len = sizeof(rand);
if (sz < len)
len = sz;
/* Get one random 32-bit word from hw RNG */
rand = esp_random( );
XMEMCPY(output, &rand, len);
output += len;
sz -= len;
}
return 0;
}
#endif /* end WOLFSSL_ESPIDF */
#elif defined(WOLFSSL_LINUXKM)
#ifndef LINUXKM_LKCAPI_REGISTER_HASH_DRBG_DEFAULT
#include <linux/random.h>
#endif
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
(void)os;
int ret;
#ifdef HAVE_ENTROPY_MEMUSE
ret = wc_Entropy_Get(MAX_ENTROPY_BITS, output, sz);
if (ret == 0)
return 0;
#ifdef ENTROPY_MEMUSE_FORCE_FAILURE
return ret;
#endif
#endif
#if defined(HAVE_INTEL_RDSEED) || defined(HAVE_AMD_RDSEED)
if (IS_INTEL_RDSEED(intel_flags)) {
ret = wc_GenerateSeed_IntelRD(NULL, output, sz);
if (ret == 0)
return 0;
#ifdef FORCE_FAILURE_RDSEED
return ret;
#endif
}
#endif /* HAVE_INTEL_RDSEED || HAVE_AMD_RDSEED */
#ifdef LINUXKM_LKCAPI_REGISTER_HASH_DRBG_DEFAULT
#if !defined(HAVE_ENTROPY_MEMUSE) && \
!defined(HAVE_INTEL_RDSEED) && \
!defined(HAVE_AMD_RDSEED)
#error LINUXKM_LKCAPI_REGISTER_HASH_DRBG_DEFAULT requires an intrinsic entropy source.
#else
return ret;
#endif
#else
(void)ret;
get_random_bytes(output, sz);
return 0;
#endif
}
#elif defined(WOLFSSL_BSDKM)
#include <sys/random.h>
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
(void)os;
int ret;
#ifdef HAVE_ENTROPY_MEMUSE
ret = wc_Entropy_Get(MAX_ENTROPY_BITS, output, sz);
if (ret == 0) {
return 0;
}
#ifdef ENTROPY_MEMUSE_FORCE_FAILURE
/* Don't fallback to /dev/urandom. */
return ret;
#endif
#endif
#if defined(HAVE_INTEL_RDSEED) || defined(HAVE_AMD_RDSEED)
if (IS_INTEL_RDSEED(intel_flags)) {
ret = wc_GenerateSeed_IntelRD(NULL, output, sz);
#ifndef FORCE_FAILURE_RDSEED
if (ret == 0)
#endif
{
return ret;
}
}
#endif /* HAVE_INTEL_RDSEED || HAVE_AMD_RDSEED */
(void)ret;
arc4random_buf(output, sz);
return 0;
}
#elif defined(WOLFSSL_RENESAS_TSIP)
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
(void)os;
return wc_tsip_GenerateRandBlock(output, sz);
}
#elif defined(WOLFSSL_SCE) && !defined(WOLFSSL_SCE_NO_TRNG)
#include "hal_data.h"
#ifndef WOLFSSL_SCE_TRNG_HANDLE
#define WOLFSSL_SCE_TRNG_HANDLE g_sce_trng
#endif
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
word32 ret;
word32 blocks;
word32 len = sz;
ret = WOLFSSL_SCE_TRNG_HANDLE.p_api->open(WOLFSSL_SCE_TRNG_HANDLE.p_ctrl,
WOLFSSL_SCE_TRNG_HANDLE.p_cfg);
if (ret != SSP_SUCCESS && ret != SSP_ERR_CRYPTO_ALREADY_OPEN) {
/* error opening TRNG driver */
return -1;
}
blocks = sz / sizeof(word32);
if (blocks > 0) {
ret = WOLFSSL_SCE_TRNG_HANDLE.p_api->read(WOLFSSL_SCE_TRNG_HANDLE.p_ctrl,
(word32*)output, blocks);
if (ret != SSP_SUCCESS) {
return -1;
}
}
len = len - (blocks * sizeof(word32));
if (len > 0) {
word32 tmp;
if (len > sizeof(word32)) {
return -1;
}
ret = WOLFSSL_SCE_TRNG_HANDLE.p_api->read(WOLFSSL_SCE_TRNG_HANDLE.p_ctrl,
(word32*)&tmp, 1);
if (ret != SSP_SUCCESS) {
return -1;
}
XMEMCPY(output + (blocks * sizeof(word32)), (byte*)&tmp, len);
}
ret = WOLFSSL_SCE_TRNG_HANDLE.p_api->close(WOLFSSL_SCE_TRNG_HANDLE.p_ctrl);
if (ret != SSP_SUCCESS) {
/* error opening TRNG driver */
return -1;
}
return 0;
}
#elif defined(CUSTOM_RAND_GENERATE_BLOCK)
/* #define CUSTOM_RAND_GENERATE_BLOCK myRngFunc
* extern int myRngFunc(byte* output, word32 sz);
*/
#elif defined(__MICROBLAZE__)
#warning weak source of entropy
#define LPD_SCNTR_BASE_ADDRESS 0xFF250000
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
word32* cnt;
word32 i;
/* using current time with srand */
cnt = (word32*)LPD_SCNTR_BASE_ADDRESS;
srand(*cnt | *(cnt+1));
for (i = 0; i < sz; i++)
output[i] = rand();
(void)os;
return 0;
}
#elif defined(WOLFSSL_ZEPHYR)
#include <version.h>
#if KERNEL_VERSION_NUMBER >= 0x30500
#include <zephyr/random/random.h>
#else
#if KERNEL_VERSION_NUMBER >= 0x30100
#include <zephyr/random/rand32.h>
#else
#include <random/rand32.h>
#endif
#endif
#ifndef _POSIX_C_SOURCE
#if KERNEL_VERSION_NUMBER >= 0x30100
#include <zephyr/posix/time.h>
#else
#include <posix/time.h>
#endif
#else
#include <time.h>
#endif
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
sys_rand_get(output, sz);
return 0;
}
#elif defined(WOLFSSL_TELIT_M2MB)
#include "stdlib.h"
static long get_timestamp(void) {
long myTime = 0;
INT32 fd = m2mb_rtc_open("/dev/rtc0", 0);
if (fd >= 0) {
M2MB_RTC_TIMEVAL_T timeval;
m2mb_rtc_ioctl(fd, M2MB_RTC_IOCTL_GET_TIMEVAL, &timeval);
myTime = timeval.msec;
m2mb_rtc_close(fd);
}
return myTime;
}
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int i;
srand(get_timestamp());
for (i = 0; i < sz; i++ ) {
output[i] = rand() % 256;
if ((i % 8) == 7) {
srand(get_timestamp());
}
}
return 0;
}
#elif defined(WOLFSSL_SE050) && !defined(WOLFSSL_SE050_NO_TRNG)
#include <wolfssl/wolfcrypt/port/nxp/se050_port.h>
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz){
int ret = 0;
(void)os;
if (output == NULL) {
return BUFFER_E;
}
ret = wolfSSL_CryptHwMutexLock();
if (ret == 0) {
ret = se050_get_random_number(sz, output);
wolfSSL_CryptHwMutexUnLock();
}
return ret;
}
#elif defined(DOLPHIN_EMULATOR) || defined (WOLFSSL_NDS)
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
word32 i;
(void)os;
srand(time(NULL));
for (i = 0; i < sz; i++)
output[i] = (byte)rand();
return 0;
}
#elif defined(WOLFSSL_MAXQ108X) || defined(WOLFSSL_MAXQ1065)
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
(void)os;
return maxq10xx_random(output, sz);
}
#elif defined(MAX3266X_RNG)
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
#ifdef WOLFSSL_MAX3266X
int status;
#endif /* WOLFSSL_MAX3266X */
static int initDone = 0;
(void)os;
if (initDone == 0) {
#ifdef WOLFSSL_MAX3266X
status = wolfSSL_HwRngMutexLock();
if (status != 0) {
return status;
}
#endif /* WOLFSSL_MAX3266X */
if(MXC_TRNG_HealthTest() != 0) {
#ifdef DEBUG_WOLFSSL
WOLFSSL_MSG("TRNG HW Health Test Failed");
#endif /* DEBUG_WOLFSSL */
#ifdef WOLFSSL_MAX3266X
wolfSSL_HwRngMutexUnLock();
#endif /* WOLFSSL_MAX3266X */
return WC_HW_E;
}
#ifdef WOLFSSL_MAX3266X
wolfSSL_HwRngMutexUnLock();
#endif /* WOLFSSL_MAX3266X */
initDone = 1;
}
return wc_MXC_TRNG_Random(output, sz);
}
#elif defined(CY_USING_HAL) && defined(COMPONENT_WOLFSSL)
/* Infineon/Cypress HAL RNG implementation */
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
cyhal_trng_t obj;
cy_rslt_t result;
uint32_t val;
word32 i = 0;
(void)os;
result = cyhal_trng_init(&obj);
if (result == CY_RSLT_SUCCESS) {
while (i < sz) {
/* If not aligned or there is odd/remainder add single byte */
if( (i + sizeof(word32)) > sz ||
((wc_ptr_t)&output[i] % sizeof(word32)) != 0
) {
val = cyhal_trng_generate(&obj);
output[i++] = (byte)val;
}
else {
/* Use native 32 instruction */
val = cyhal_trng_generate(&obj);
*((uint32_t*)&output[i]) = val;
i += sizeof(word32);
}
}
cyhal_trng_free(&obj);
}
return 0;
}
#elif defined(WOLFSSL_SAFERTOS) || defined(WOLFSSL_LEANPSK) || \
defined(WOLFSSL_IAR_ARM) || defined(WOLFSSL_MDK_ARM) || \
defined(WOLFSSL_uITRON4) || defined(WOLFSSL_uTKERNEL2) || \
defined(WOLFSSL_LPC43xx) || defined(NO_STM32_RNG) || \
defined(MBED) || defined(WOLFSSL_EMBOS) || \
defined(WOLFSSL_GENSEED_FORTEST) || defined(WOLFSSL_CHIBIOS) || \
defined(WOLFSSL_CONTIKI) || defined(WOLFSSL_AZSPHERE)
/* these platforms do not have a default random seed and
you'll need to implement your own wc_GenerateSeed or define via
CUSTOM_RAND_GENERATE_BLOCK */
#define USE_TEST_GENSEED
#elif defined(NO_DEV_RANDOM)
/* Allow bare-metal targets to use cryptoCb as seed provider */
#if defined(WOLF_CRYPTO_CB)
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int ret = WC_NO_ERR_TRACE(WC_HW_E);
#ifndef WOLF_CRYPTO_CB_FIND
if (os->devId != INVALID_DEVID)
#endif
{
ret = wc_CryptoCb_RandomSeed(os, output, sz);
if (ret == WC_NO_ERR_TRACE(CRYPTOCB_UNAVAILABLE)) {
ret = WC_HW_E;
}
}
return ret;
}
#else /* defined(WOLF_CRYPTO_CB)*/
#error "you need to write an os specific wc_GenerateSeed() here"
/*
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
return 0;
}
*/
#endif /* !defined(WOLF_CRYPTO_CB) */
#else
/* may block */
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
int ret = 0;
if (os == NULL) {
return BAD_FUNC_ARG;
}
#ifdef WOLF_CRYPTO_CB
#ifndef WOLF_CRYPTO_CB_FIND
if (os->devId != INVALID_DEVID)
#endif
{
ret = wc_CryptoCb_RandomSeed(os, output, sz);
if (ret != WC_NO_ERR_TRACE(CRYPTOCB_UNAVAILABLE))
return ret;
/* fall-through when unavailable */
ret = 0; /* reset error code */
}
#endif
#ifdef HAVE_ENTROPY_MEMUSE
ret = wc_Entropy_Get(MAX_ENTROPY_BITS, output, sz);
if (ret == 0) {
/* success, we're done */
return ret;
}
#ifdef ENTROPY_MEMUSE_FORCE_FAILURE
/* Don't fall back to /dev/urandom. */
return ret;
#else
/* Reset error and fall back to using /dev/urandom. */
ret = 0;
#endif
#endif
#if !defined(HAVE_ENTROPY_MEMUSE) || !defined(ENTROPY_MEMUSE_FORCE_FAILURE)
#if defined(HAVE_INTEL_RDSEED) || defined(HAVE_AMD_RDSEED)
if (IS_INTEL_RDSEED(intel_flags)) {
ret = wc_GenerateSeed_IntelRD(NULL, output, sz);
if (ret == 0) {
/* success, we're done */
return ret;
}
#ifdef FORCE_FAILURE_RDSEED
/* Don't fall back to /dev/urandom. */
return ret;
#else
/* Reset error and fall back to using /dev/urandom. */
ret = 0;
#endif
}
#ifdef FORCE_FAILURE_RDSEED
else {
/* Don't fall back to /dev/urandom */
return MISSING_RNG_E;
}
#endif
#endif /* HAVE_INTEL_RDSEED || HAVE_AMD_RDSEED */
#if (!defined(HAVE_INTEL_RDSEED) && !defined(HAVE_AMD_RDSEED)) || \
!defined(FORCE_FAILURE_RDSEED)
#if defined(WOLFSSL_GETRANDOM) || defined(HAVE_GETRANDOM)
{
word32 grSz = sz;
byte* grOutput = output;
while (grSz) {
ssize_t len;
errno = 0;
len = getrandom(grOutput, grSz, 0);
if (len == -1) {
if (errno == EINTR) {
/* interrupted, call getrandom again */
continue;
}
else {
ret = READ_RAN_E;
}
break;
}
grSz -= (word32)len;
grOutput += len;
}
if (ret == 0)
return ret;
#ifdef FORCE_FAILURE_GETRANDOM
/* don't fall back to /dev/urandom */
return ret;
#elif !defined(NO_FILESYSTEM)
/* reset error and fall back to using /dev/urandom if filesystem
* support is compiled in */
ret = 0;
#endif
}
#endif
#ifndef NO_FILESYSTEM
#ifdef WOLFSSL_KEEP_RNG_SEED_FD_OPEN
if (!os->seedFdOpen)
{
#ifndef NO_DEV_URANDOM /* way to disable use of /dev/urandom */
os->fd = open("/dev/urandom", O_RDONLY);
#if defined(DEBUG_WOLFSSL)
WOLFSSL_MSG("opened /dev/urandom.");
#endif /* DEBUG_WOLFSSL */
if (os->fd == XBADFD)
#endif /* NO_DEV_URANDOM */
{
/* may still have /dev/random */
os->fd = open("/dev/random", O_RDONLY);
#if defined(DEBUG_WOLFSSL)
WOLFSSL_MSG("opened /dev/random.");
#endif /* DEBUG_WOLFSSL */
if (os->fd == XBADFD)
return OPEN_RAN_E;
else {
os->keepSeedFdOpen = 0;
os->seedFdOpen = 1;
}
}
else {
os->keepSeedFdOpen = 1;
os->seedFdOpen = 1;
}
}
#else /* WOLFSSL_KEEP_RNG_SEED_FD_OPEN */
#ifndef NO_DEV_URANDOM /* way to disable use of /dev/urandom */
os->fd = open("/dev/urandom", O_RDONLY);
#if defined(DEBUG_WOLFSSL)
WOLFSSL_MSG("opened /dev/urandom.");
#endif /* DEBUG_WOLFSSL */
if (os->fd == XBADFD)
#endif /* !NO_DEV_URANDOM */
{
/* may still have /dev/random */
os->fd = open("/dev/random", O_RDONLY);
#if defined(DEBUG_WOLFSSL)
WOLFSSL_MSG("opened /dev/random.");
#endif /* DEBUG_WOLFSSL */
if (os->fd == XBADFD)
return OPEN_RAN_E;
}
#endif /* WOLFSSL_KEEP_RNG_SEED_FD_OPEN */
#if defined(DEBUG_WOLFSSL)
WOLFSSL_MSG("rnd read...");
#endif /* DEBUG_WOLFSSL */
while (sz) {
int len = (int)read(os->fd, output, sz);
if (len == -1) {
ret = READ_RAN_E;
break;
}
sz -= (word32)len;
output += len;
if (sz) {
#if defined(BLOCKING) || defined(WC_RNG_BLOCKING)
sleep(0); /* context switch */
#else
ret = RAN_BLOCK_E;
break;
#endif /* BLOCKING || WC_RNG_BLOCKING */
}
}
#ifdef WOLFSSL_KEEP_RNG_SEED_FD_OPEN
if (!os->keepSeedFdOpen && os->seedFdOpen)
{
close(os->fd);
os->fd = -1;
os->seedFdOpen = 0;
}
#else
close(os->fd);
#endif /* WOLFSSL_KEEP_RNG_SEED_FD_OPEN */
#else /* NO_FILESYSTEM */
(void)output;
(void)sz;
ret = NOT_COMPILED_IN;
#endif /* NO_FILESYSTEM */
return ret;
#endif /* (!HAVE_INTEL_RDSEED && !HAVE_AMD_RDSEED) || !FORCE_FAILURE_RDSEED */
#endif /*!HAVE_ENTROPY_MEMUSE || !ENTROPY_MEMUSE_FORCE_FAILURE */
}
#endif
#ifdef USE_TEST_GENSEED
#ifndef _MSC_VER
#warning "write a real random seed!!!!, just for testing now"
#else
#pragma message("Warning: write a real random seed!!!!, just for testing now")
#endif
int wc_GenerateSeed(OS_Seed* os, byte* output, word32 sz)
{
word32 i;
for (i = 0; i < sz; i++ )
output[i] = (byte)i;
(void)os;
return 0;
}
#endif
/* End wc_GenerateSeed */
#if defined(CUSTOM_RAND_GENERATE_BLOCK) && defined(WOLFSSL_KCAPI)
#include <fcntl.h>
int wc_hwrng_generate_block(byte *output, word32 sz)
{
int fd;
int ret = 0;
fd = open("/dev/hwrng", O_RDONLY);
if (fd == -1)
return OPEN_RAN_E;
while(sz)
{
int len = (int)read(fd, output, sz);
if (len == -1)
{
ret = READ_RAN_E;
break;
}
sz -= len;
output += len;
}
close(fd);
return ret;
}
#endif
#endif /* WC_NO_RNG */
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