/* * Copyright (c) 2016 Thomas Pornin * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files (the * "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sublicense, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS * BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN * ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. */ #ifndef INNER_H__ #define INNER_H__ #include #include #include "config.h" #include "bearssl.h" /* * On MSVC, disable the warning about applying unary minus on an * unsigned type: it is standard, we do it all the time, and for * good reasons. */ #if _MSC_VER #pragma warning( disable : 4146 ) #endif /* * Maximum size for a RSA modulus (in bits). Allocated stack buffers * depend on that size, so this value should be kept small. Currently, * 2048-bit RSA keys offer adequate security, and should still do so for * the next few decades; however, a number of widespread PKI have * already set their root keys to RSA-4096, so we should be able to * process such keys. * * This value MUST be a multiple of 64. This value MUST NOT exceed 47666 * (some computations in RSA key generation rely on the factor size being * no more than 23833 bits). RSA key sizes beyond 3072 bits don't make a * lot of sense anyway. */ #define BR_MAX_RSA_SIZE 4096 /* * Minimum size for a RSA modulus (in bits); this value is used only to * filter out invalid parameters for key pair generation. Normally, * applications should not use RSA keys smaller than 2048 bits; but some * specific cases might need shorter keys, for legacy or research * purposes. */ #define BR_MIN_RSA_SIZE 512 /* * Maximum size for a RSA factor (in bits). This is for RSA private-key * operations. Default is to support factors up to a bit more than half * the maximum modulus size. * * This value MUST be a multiple of 32. */ #define BR_MAX_RSA_FACTOR ((BR_MAX_RSA_SIZE + 64) >> 1) /* * Maximum size for an EC curve (modulus or order), in bits. Size of * stack buffers depends on that parameter. This size MUST be a multiple * of 8 (so that decoding an integer with that many bytes does not * overflow). */ #define BR_MAX_EC_SIZE 528 /* * Some macros to recognize the current architecture. Right now, we are * interested into automatically recognizing architecture with efficient * 64-bit types so that we may automatically use implementations that * use 64-bit registers in that case. Future versions may detect, e.g., * availability of SSE2 intrinsics. * * If 'unsigned long' is a 64-bit type, then we assume that 64-bit types * are efficient. Otherwise, we rely on macros that depend on compiler, * OS and architecture. In any case, failure to detect the architecture * as 64-bit means that the 32-bit code will be used, and that code * works also on 64-bit architectures (the 64-bit code may simply be * more efficient). * * The test on 'unsigned long' should already catch most cases, the one * notable exception being Windows code where 'unsigned long' is kept to * 32-bit for compatibility with all the legacy code that liberally uses * the 'DWORD' type for 32-bit values. * * Macro names are taken from: http://nadeausoftware.com/articles/2012/02/c_c_tip_how_detect_processor_type_using_compiler_predefined_macros */ #ifndef BR_64 #if ((ULONG_MAX >> 31) >> 31) == 3 #define BR_64 1 #elif defined(__ia64) || defined(__itanium__) || defined(_M_IA64) #define BR_64 1 #elif defined(__powerpc64__) || defined(__ppc64__) || defined(__PPC64__) \ || defined(__64BIT__) || defined(_LP64) || defined(__LP64__) #define BR_64 1 #elif defined(__sparc64__) #define BR_64 1 #elif defined(__x86_64__) || defined(_M_X64) #define BR_64 1 #endif #endif /* * Set BR_LOMUL on platforms where it makes sense. */ #ifndef BR_LOMUL #if BR_ARMEL_CORTEXM_GCC #define BR_LOMUL 1 #endif #endif /* * Architecture detection. */ #ifndef BR_i386 #if __i386__ || _M_IX86 #define BR_i386 1 #endif #endif #ifndef BR_amd64 #if __x86_64__ || _M_X64 #define BR_amd64 1 #endif #endif /* * Compiler brand and version. * * Implementations that use intrinsics need to detect the compiler type * and version because some specific actions may be needed to activate * the corresponding opcodes, both for header inclusion, and when using * them in a function. * * BR_GCC, BR_CLANG and BR_MSC will be set to 1 for, respectively, GCC, * Clang and MS Visual C. For each of them, sub-macros will be defined * for versions; each sub-macro is set whenever the compiler version is * at least as recent as the one corresponding to the macro. */ /* * GCC thresholds are on versions 4.4 to 4.9 and 5.0. */ #ifndef BR_GCC #if __GNUC__ && !__clang__ #define BR_GCC 1 #if __GNUC__ > 4 #define BR_GCC_5_0 1 #elif __GNUC__ == 4 && __GNUC_MINOR__ >= 9 #define BR_GCC_4_9 1 #elif __GNUC__ == 4 && __GNUC_MINOR__ >= 8 #define BR_GCC_4_8 1 #elif __GNUC__ == 4 && __GNUC_MINOR__ >= 7 #define BR_GCC_4_7 1 #elif __GNUC__ == 4 && __GNUC_MINOR__ >= 6 #define BR_GCC_4_6 1 #elif __GNUC__ == 4 && __GNUC_MINOR__ >= 5 #define BR_GCC_4_5 1 #elif __GNUC__ == 4 && __GNUC_MINOR__ >= 4 #define BR_GCC_4_4 1 #endif #if BR_GCC_5_0 #define BR_GCC_4_9 1 #endif #if BR_GCC_4_9 #define BR_GCC_4_8 1 #endif #if BR_GCC_4_8 #define BR_GCC_4_7 1 #endif #if BR_GCC_4_7 #define BR_GCC_4_6 1 #endif #if BR_GCC_4_6 #define BR_GCC_4_5 1 #endif #if BR_GCC_4_5 #define BR_GCC_4_4 1 #endif #endif #endif /* * Clang thresholds are on versions 3.7.0 and 3.8.0. */ #ifndef BR_CLANG #if __clang__ #define BR_CLANG 1 #if __clang_major__ > 3 || (__clang_major__ == 3 && __clang_minor__ >= 8) #define BR_CLANG_3_8 1 #elif __clang_major__ == 3 && __clang_minor__ >= 7 #define BR_CLANG_3_7 1 #endif #if BR_CLANG_3_8 #define BR_CLANG_3_7 1 #endif #endif #endif /* * MS Visual C thresholds are on Visual Studio 2005 to 2015. */ #ifndef BR_MSC #if _MSC_VER #define BR_MSC 1 #if _MSC_VER >= 1900 #define BR_MSC_2015 1 #elif _MSC_VER >= 1800 #define BR_MSC_2013 1 #elif _MSC_VER >= 1700 #define BR_MSC_2012 1 #elif _MSC_VER >= 1600 #define BR_MSC_2010 1 #elif _MSC_VER >= 1500 #define BR_MSC_2008 1 #elif _MSC_VER >= 1400 #define BR_MSC_2005 1 #endif #if BR_MSC_2015 #define BR_MSC_2013 1 #endif #if BR_MSC_2013 #define BR_MSC_2012 1 #endif #if BR_MSC_2012 #define BR_MSC_2010 1 #endif #if BR_MSC_2010 #define BR_MSC_2008 1 #endif #if BR_MSC_2008 #define BR_MSC_2005 1 #endif #endif #endif /* * GCC 4.4+ and Clang 3.7+ allow tagging specific functions with a * 'target' attribute that activates support for specific opcodes. */ #if BR_GCC_4_4 || BR_CLANG_3_7 #define BR_TARGET(x) __attribute__((target(x))) #else #define BR_TARGET(x) #endif /* * AES-NI intrinsics are available on x86 (32-bit and 64-bit) with * GCC 4.8+, Clang 3.7+ and MSC 2012+. */ #ifndef BR_AES_X86NI #if (BR_i386 || BR_amd64) && (BR_GCC_4_8 || BR_CLANG_3_7 || BR_MSC_2012) #define BR_AES_X86NI 1 #endif #endif /* * SSE2 intrinsics are available on x86 (32-bit and 64-bit) with * GCC 4.4+, Clang 3.7+ and MSC 2005+. */ #ifndef BR_SSE2 #if (BR_i386 || BR_amd64) && (BR_GCC_4_4 || BR_CLANG_3_7 || BR_MSC_2005) #define BR_SSE2 1 #endif #endif /* * RDRAND intrinsics are available on x86 (32-bit and 64-bit) with * GCC 4.6+, Clang 3.7+ and MSC 2012+. */ #ifndef BR_RDRAND #if (BR_i386 || BR_amd64) && (BR_GCC_4_6 || BR_CLANG_3_7 || BR_MSC_2012) #define BR_RDRAND 1 #endif #endif /* * Determine type of OS for random number generation. Macro names and * values are documented on: * https://sourceforge.net/p/predef/wiki/OperatingSystems/ * * TODO: enrich the list of detected system. Also add detection for * alternate system calls like getentropy(), which are usually * preferable when available. */ #ifndef BR_USE_URANDOM #if defined _AIX \ || defined __ANDROID__ \ || defined __FreeBSD__ \ || defined __NetBSD__ \ || defined __OpenBSD__ \ || defined __DragonFly__ \ || defined __linux__ \ || (defined __sun && (defined __SVR4 || defined __svr4__)) \ || (defined __APPLE__ && defined __MACH__) #define BR_USE_URANDOM 1 #endif #endif #ifndef BR_USE_WIN32_RAND #if defined _WIN32 || defined _WIN64 #define BR_USE_WIN32_RAND 1 #endif #endif /* * POWER8 crypto support. We rely on compiler macros for the * architecture, since we do not have a reliable, simple way to detect * the required support at runtime (we could try running an opcode, and * trapping the exception or signal on illegal instruction, but this * induces some non-trivial OS dependencies that we would prefer to * avoid if possible). */ #ifndef BR_POWER8 #if __GNUC__ && ((_ARCH_PWR8 || _ARCH_PPC) && __CRYPTO__) #define BR_POWER8 1 #endif #endif /* * Detect endinanness on POWER8. */ #if BR_POWER8 #if defined BR_POWER8_LE #undef BR_POWER8_BE #if BR_POWER8_LE #define BR_POWER8_BE 0 #else #define BR_POWER8_BE 1 #endif #elif defined BR_POWER8_BE #undef BR_POWER8_LE #if BR_POWER8_BE #define BR_POWER8_LE 0 #else #define BR_POWER8_LE 1 #endif #else #if __LITTLE_ENDIAN__ #define BR_POWER8_LE 1 #define BR_POWER8_BE 0 #else #define BR_POWER8_LE 0 #define BR_POWER8_BE 1 #endif #endif #endif /* * Detect support for 128-bit integers. */ #if !defined BR_INT128 && !defined BR_UMUL128 #ifdef __SIZEOF_INT128__ #define BR_INT128 1 #elif _M_X64 #define BR_UMUL128 1 #endif #endif /* * Detect support for unaligned accesses with known endianness. * * x86 (both 32-bit and 64-bit) is little-endian and allows unaligned * accesses. * * POWER/PowerPC allows unaligned accesses when big-endian. POWER8 and * later also allow unaligned accesses when little-endian. */ #if !defined BR_LE_UNALIGNED && !defined BR_BE_UNALIGNED #if __i386 || __i386__ || __x86_64__ || _M_IX86 || _M_X64 #define BR_LE_UNALIGNED 1 #elif BR_POWER8_BE #define BR_BE_UNALIGNED 1 #elif BR_POWER8_LE #define BR_LE_UNALIGNED 1 #elif (__powerpc__ || __powerpc64__ || _M_PPC || _ARCH_PPC || _ARCH_PPC64) \ && __BIG_ENDIAN__ #define BR_BE_UNALIGNED 1 #endif #endif /* * Detect support for an OS-provided time source. */ #ifndef BR_USE_UNIX_TIME #if defined __unix__ || defined __linux__ \ || defined _POSIX_SOURCE || defined _POSIX_C_SOURCE \ || (defined __APPLE__ && defined __MACH__) #define BR_USE_UNIX_TIME 1 #endif #endif #ifndef BR_USE_WIN32_TIME #if defined _WIN32 || defined _WIN64 #define BR_USE_WIN32_TIME 1 #endif #endif /* ==================================================================== */ /* * Encoding/decoding functions. * * 32-bit and 64-bit decoding, both little-endian and big-endian, is * implemented with the inline functions below. * * When allowed by some compile-time options (autodetected or provided), * optimised code is used, to perform direct memory access when the * underlying architecture supports it, both for endianness and * alignment. This, however, may trigger strict aliasing issues; the * code below uses unions to perform (supposedly) safe type punning. * Since the C aliasing rules are relatively complex and were amended, * or at least re-explained with different phrasing, in all successive * versions of the C standard, it is always a bit risky to bet that any * specific version of a C compiler got it right, for some notion of * "right". */ typedef union { uint16_t u; unsigned char b[sizeof(uint16_t)]; } br_union_u16; typedef union { uint32_t u; unsigned char b[sizeof(uint32_t)]; } br_union_u32; typedef union { uint64_t u; unsigned char b[sizeof(uint64_t)]; } br_union_u64; static inline void br_enc16le(void *dst, unsigned x) { #if BR_LE_UNALIGNED ((br_union_u16 *)dst)->u = x; #else unsigned char *buf; buf = dst; buf[0] = (unsigned char)x; buf[1] = (unsigned char)(x >> 8); #endif } static inline void br_enc16be(void *dst, unsigned x) { #if BR_BE_UNALIGNED ((br_union_u16 *)dst)->u = x; #else unsigned char *buf; buf = dst; buf[0] = (unsigned char)(x >> 8); buf[1] = (unsigned char)x; #endif } static inline unsigned br_dec16le(const void *src) { #if BR_LE_UNALIGNED return ((const br_union_u16 *)src)->u; #else const unsigned char *buf; buf = src; return (unsigned)buf[0] | ((unsigned)buf[1] << 8); #endif } static inline unsigned br_dec16be(const void *src) { #if BR_BE_UNALIGNED return ((const br_union_u16 *)src)->u; #else const unsigned char *buf; buf = src; return ((unsigned)buf[0] << 8) | (unsigned)buf[1]; #endif } static inline void br_enc32le(void *dst, uint32_t x) { #if BR_LE_UNALIGNED ((br_union_u32 *)dst)->u = x; #else unsigned char *buf; buf = dst; buf[0] = (unsigned char)x; buf[1] = (unsigned char)(x >> 8); buf[2] = (unsigned char)(x >> 16); buf[3] = (unsigned char)(x >> 24); #endif } static inline void br_enc32be(void *dst, uint32_t x) { #if BR_BE_UNALIGNED ((br_union_u32 *)dst)->u = x; #else unsigned char *buf; buf = dst; buf[0] = (unsigned char)(x >> 24); buf[1] = (unsigned char)(x >> 16); buf[2] = (unsigned char)(x >> 8); buf[3] = (unsigned char)x; #endif } static inline uint32_t br_dec32le(const void *src) { #if BR_LE_UNALIGNED return ((const br_union_u32 *)src)->u; #else const unsigned char *buf; buf = src; return (uint32_t)buf[0] | ((uint32_t)buf[1] << 8) | ((uint32_t)buf[2] << 16) | ((uint32_t)buf[3] << 24); #endif } static inline uint32_t br_dec32be(const void *src) { #if BR_BE_UNALIGNED return ((const br_union_u32 *)src)->u; #else const unsigned char *buf; buf = src; return ((uint32_t)buf[0] << 24) | ((uint32_t)buf[1] << 16) | ((uint32_t)buf[2] << 8) | (uint32_t)buf[3]; #endif } static inline void br_enc64le(void *dst, uint64_t x) { #if BR_LE_UNALIGNED ((br_union_u64 *)dst)->u = x; #else unsigned char *buf; buf = dst; br_enc32le(buf, (uint32_t)x); br_enc32le(buf + 4, (uint32_t)(x >> 32)); #endif } static inline void br_enc64be(void *dst, uint64_t x) { #if BR_BE_UNALIGNED ((br_union_u64 *)dst)->u = x; #else unsigned char *buf; buf = dst; br_enc32be(buf, (uint32_t)(x >> 32)); br_enc32be(buf + 4, (uint32_t)x); #endif } static inline uint64_t br_dec64le(const void *src) { #if BR_LE_UNALIGNED return ((const br_union_u64 *)src)->u; #else const unsigned char *buf; buf = src; return (uint64_t)br_dec32le(buf) | ((uint64_t)br_dec32le(buf + 4) << 32); #endif } static inline uint64_t br_dec64be(const void *src) { #if BR_BE_UNALIGNED return ((const br_union_u64 *)src)->u; #else const unsigned char *buf; buf = src; return ((uint64_t)br_dec32be(buf) << 32) | (uint64_t)br_dec32be(buf + 4); #endif } /* * Range decoding and encoding (for several successive values). */ void br_range_dec16le(uint16_t *v, size_t num, const void *src); void br_range_dec16be(uint16_t *v, size_t num, const void *src); void br_range_enc16le(void *dst, const uint16_t *v, size_t num); void br_range_enc16be(void *dst, const uint16_t *v, size_t num); void br_range_dec32le(uint32_t *v, size_t num, const void *src); void br_range_dec32be(uint32_t *v, size_t num, const void *src); void br_range_enc32le(void *dst, const uint32_t *v, size_t num); void br_range_enc32be(void *dst, const uint32_t *v, size_t num); void br_range_dec64le(uint64_t *v, size_t num, const void *src); void br_range_dec64be(uint64_t *v, size_t num, const void *src); void br_range_enc64le(void *dst, const uint64_t *v, size_t num); void br_range_enc64be(void *dst, const uint64_t *v, size_t num); /* * Byte-swap a 32-bit integer. */ static inline uint32_t br_swap32(uint32_t x) { x = ((x & (uint32_t)0x00FF00FF) << 8) | ((x >> 8) & (uint32_t)0x00FF00FF); return (x << 16) | (x >> 16); } /* ==================================================================== */ /* * Support code for hash functions. */ /* * IV for MD5, SHA-1, SHA-224 and SHA-256. */ extern const uint32_t br_md5_IV[]; extern const uint32_t br_sha1_IV[]; extern const uint32_t br_sha224_IV[]; extern const uint32_t br_sha256_IV[]; /* * Round functions for MD5, SHA-1, SHA-224 and SHA-256 (SHA-224 and * SHA-256 use the same round function). */ void br_md5_round(const unsigned char *buf, uint32_t *val); void br_sha1_round(const unsigned char *buf, uint32_t *val); void br_sha2small_round(const unsigned char *buf, uint32_t *val); /* * The core function for the TLS PRF. It computes * P_hash(secret, label + seed), and XORs the result into the dst buffer. */ void br_tls_phash(void *dst, size_t len, const br_hash_class *dig, const void *secret, size_t secret_len, const char *label, size_t seed_num, const br_tls_prf_seed_chunk *seed); /* * Copy all configured hash implementations from a multihash context * to another. */ static inline void br_multihash_copyimpl(br_multihash_context *dst, const br_multihash_context *src) { memcpy((void *)dst->impl, src->impl, sizeof src->impl); } /* ==================================================================== */ /* * Constant-time primitives. These functions manipulate 32-bit values in * order to provide constant-time comparisons and multiplexers. * * Boolean values (the "ctl" bits) MUST have value 0 or 1. * * Implementation notes: * ===================== * * The uintN_t types are unsigned and with width exactly N bits; the C * standard guarantees that computations are performed modulo 2^N, and * there can be no overflow. Negation (unary '-') works on unsigned types * as well. * * The intN_t types are guaranteed to have width exactly N bits, with no * padding bit, and using two's complement representation. Casting * intN_t to uintN_t really is conversion modulo 2^N. Beware that intN_t * types, being signed, trigger implementation-defined behaviour on * overflow (including raising some signal): with GCC, while modular * arithmetics are usually applied, the optimizer may assume that * overflows don't occur (unless the -fwrapv command-line option is * added); Clang has the additional -ftrapv option to explicitly trap on * integer overflow or underflow. */ /* * Negate a boolean. */ static inline uint32_t NOT(uint32_t ctl) { return ctl ^ 1; } /* * Multiplexer: returns x if ctl == 1, y if ctl == 0. */ static inline uint32_t MUX(uint32_t ctl, uint32_t x, uint32_t y) { return y ^ (-ctl & (x ^ y)); } /* * Equality check: returns 1 if x == y, 0 otherwise. */ static inline uint32_t EQ(uint32_t x, uint32_t y) { uint32_t q; q = x ^ y; return NOT((q | -q) >> 31); } /* * Inequality check: returns 1 if x != y, 0 otherwise. */ static inline uint32_t NEQ(uint32_t x, uint32_t y) { uint32_t q; q = x ^ y; return (q | -q) >> 31; } /* * Comparison: returns 1 if x > y, 0 otherwise. */ static inline uint32_t GT(uint32_t x, uint32_t y) { /* * If both x < 2^31 and x < 2^31, then y-x will have its high * bit set if x > y, cleared otherwise. * * If either x >= 2^31 or y >= 2^31 (but not both), then the * result is the high bit of x. * * If both x >= 2^31 and y >= 2^31, then we can virtually * subtract 2^31 from both, and we are back to the first case. * Since (y-2^31)-(x-2^31) = y-x, the subtraction is already * fine. */ uint32_t z; z = y - x; return (z ^ ((x ^ y) & (x ^ z))) >> 31; } /* * Other comparisons (greater-or-equal, lower-than, lower-or-equal). */ #define GE(x, y) NOT(GT(y, x)) #define LT(x, y) GT(y, x) #define LE(x, y) NOT(GT(x, y)) /* * General comparison: returned value is -1, 0 or 1, depending on * whether x is lower than, equal to, or greater than y. */ static inline int32_t CMP(uint32_t x, uint32_t y) { return (int32_t)GT(x, y) | -(int32_t)GT(y, x); } /* * Returns 1 if x == 0, 0 otherwise. Take care that the operand is signed. */ static inline uint32_t EQ0(int32_t x) { uint32_t q; q = (uint32_t)x; return ~(q | -q) >> 31; } /* * Returns 1 if x > 0, 0 otherwise. Take care that the operand is signed. */ static inline uint32_t GT0(int32_t x) { /* * High bit of -x is 0 if x == 0, but 1 if x > 0. */ uint32_t q; q = (uint32_t)x; return (~q & -q) >> 31; } /* * Returns 1 if x >= 0, 0 otherwise. Take care that the operand is signed. */ static inline uint32_t GE0(int32_t x) { return ~(uint32_t)x >> 31; } /* * Returns 1 if x < 0, 0 otherwise. Take care that the operand is signed. */ static inline uint32_t LT0(int32_t x) { return (uint32_t)x >> 31; } /* * Returns 1 if x <= 0, 0 otherwise. Take care that the operand is signed. */ static inline uint32_t LE0(int32_t x) { uint32_t q; /* * ~-x has its high bit set if and only if -x is nonnegative (as * a signed int), i.e. x is in the -(2^31-1) to 0 range. We must * do an OR with x itself to account for x = -2^31. */ q = (uint32_t)x; return (q | ~-q) >> 31; } /* * Conditional copy: src[] is copied into dst[] if and only if ctl is 1. * dst[] and src[] may overlap completely (but not partially). */ void br_ccopy(uint32_t ctl, void *dst, const void *src, size_t len); #define CCOPY br_ccopy /* * Compute the bit length of a 32-bit integer. Returned value is between 0 * and 32 (inclusive). */ static inline uint32_t BIT_LENGTH(uint32_t x) { uint32_t k, c; k = NEQ(x, 0); c = GT(x, 0xFFFF); x = MUX(c, x >> 16, x); k += c << 4; c = GT(x, 0x00FF); x = MUX(c, x >> 8, x); k += c << 3; c = GT(x, 0x000F); x = MUX(c, x >> 4, x); k += c << 2; c = GT(x, 0x0003); x = MUX(c, x >> 2, x); k += c << 1; k += GT(x, 0x0001); return k; } /* * Compute the minimum of x and y. */ static inline uint32_t MIN(uint32_t x, uint32_t y) { return MUX(GT(x, y), y, x); } /* * Compute the maximum of x and y. */ static inline uint32_t MAX(uint32_t x, uint32_t y) { return MUX(GT(x, y), x, y); } /* * Multiply two 32-bit integers, with a 64-bit result. This default * implementation assumes that the basic multiplication operator * yields constant-time code. */ #define MUL(x, y) ((uint64_t)(x) * (uint64_t)(y)) #if BR_CT_MUL31 /* * Alternate implementation of MUL31, that will be constant-time on some * (old) platforms where the default MUL31 is not. Unfortunately, it is * also substantially slower, and yields larger code, on more modern * platforms, which is why it is deactivated by default. * * MUL31_lo() must do some extra work because on some platforms, the * _signed_ multiplication may return early if the top bits are 1. * Simply truncating (casting) the output of MUL31() would not be * sufficient, because the compiler may notice that we keep only the low * word, and then replace automatically the unsigned multiplication with * a signed multiplication opcode. */ #define MUL31(x, y) ((uint64_t)((x) | (uint32_t)0x80000000) \ * (uint64_t)((y) | (uint32_t)0x80000000) \ - ((uint64_t)(x) << 31) - ((uint64_t)(y) << 31) \ - ((uint64_t)1 << 62)) static inline uint32_t MUL31_lo(uint32_t x, uint32_t y) { uint32_t xl, xh; uint32_t yl, yh; xl = (x & 0xFFFF) | (uint32_t)0x80000000; xh = (x >> 16) | (uint32_t)0x80000000; yl = (y & 0xFFFF) | (uint32_t)0x80000000; yh = (y >> 16) | (uint32_t)0x80000000; return (xl * yl + ((xl * yh + xh * yl) << 16)) & (uint32_t)0x7FFFFFFF; } #else /* * Multiply two 31-bit integers, with a 62-bit result. This default * implementation assumes that the basic multiplication operator * yields constant-time code. * The MUL31_lo() macro returns only the low 31 bits of the product. */ #define MUL31(x, y) ((uint64_t)(x) * (uint64_t)(y)) #define MUL31_lo(x, y) (((uint32_t)(x) * (uint32_t)(y)) & (uint32_t)0x7FFFFFFF) #endif /* * Multiply two words together; the sum of the lengths of the two * operands must not exceed 31 (for instance, one operand may use 16 * bits if the other fits on 15). If BR_CT_MUL15 is non-zero, then the * macro will contain some extra operations that help in making the * operation constant-time on some platforms, where the basic 32-bit * multiplication is not constant-time. */ #if BR_CT_MUL15 #define MUL15(x, y) (((uint32_t)(x) | (uint32_t)0x80000000) \ * ((uint32_t)(y) | (uint32_t)0x80000000) \ & (uint32_t)0x7FFFFFFF) #else #define MUL15(x, y) ((uint32_t)(x) * (uint32_t)(y)) #endif /* * Arithmetic right shift (sign bit is copied). What happens when * right-shifting a negative value is _implementation-defined_, so it * does not trigger undefined behaviour, but it is still up to each * compiler to define (and document) what it does. Most/all compilers * will do an arithmetic shift, the sign bit being used to fill the * holes; this is a native operation on the underlying CPU, and it would * make little sense for the compiler to do otherwise. GCC explicitly * documents that it follows that convention. * * Still, if BR_NO_ARITH_SHIFT is defined (and non-zero), then an * alternate version will be used, that does not rely on such * implementation-defined behaviour. Unfortunately, it is also slower * and yields bigger code, which is why it is deactivated by default. */ #if BR_NO_ARITH_SHIFT #define ARSH(x, n) (((uint32_t)(x) >> (n)) \ | ((-((uint32_t)(x) >> 31)) << (32 - (n)))) #else #define ARSH(x, n) ((*(int32_t *)&(x)) >> (n)) #endif /* * Constant-time division. The dividend hi:lo is divided by the * divisor d; the quotient is returned and the remainder is written * in *r. If hi == d, then the quotient does not fit on 32 bits; * returned value is thus truncated. If hi > d, returned values are * indeterminate. */ uint32_t br_divrem(uint32_t hi, uint32_t lo, uint32_t d, uint32_t *r); /* * Wrapper for br_divrem(); the remainder is returned, and the quotient * is discarded. */ static inline uint32_t br_rem(uint32_t hi, uint32_t lo, uint32_t d) { uint32_t r; br_divrem(hi, lo, d, &r); return r; } /* * Wrapper for br_divrem(); the quotient is returned, and the remainder * is discarded. */ static inline uint32_t br_div(uint32_t hi, uint32_t lo, uint32_t d) { uint32_t r; return br_divrem(hi, lo, d, &r); } /* ==================================================================== */ /* * Integers 'i32' * -------------- * * The 'i32' functions implement computations on big integers using * an internal representation as an array of 32-bit integers. For * an array x[]: * -- x[0] contains the "announced bit length" of the integer * -- x[1], x[2]... contain the value in little-endian order (x[1] * contains the least significant 32 bits) * * Multiplications rely on the elementary 32x32->64 multiplication. * * The announced bit length specifies the number of bits that are * significant in the subsequent 32-bit words. Unused bits in the * last (most significant) word are set to 0; subsequent words are * uninitialized and need not exist at all. * * The execution time and memory access patterns of all computations * depend on the announced bit length, but not on the actual word * values. For modular integers, the announced bit length of any integer * modulo n is equal to the actual bit length of n; thus, computations * on modular integers are "constant-time" (only the modulus length may * leak). */ /* * Compute the actual bit length of an integer. The argument x should * point to the first (least significant) value word of the integer. * The len 'xlen' contains the number of 32-bit words to access. * * CT: value or length of x does not leak. */ uint32_t br_i32_bit_length(uint32_t *x, size_t xlen); /* * Decode an integer from its big-endian unsigned representation. The * "true" bit length of the integer is computed, but all words of x[] * corresponding to the full 'len' bytes of the source are set. * * CT: value or length of x does not leak. */ void br_i32_decode(uint32_t *x, const void *src, size_t len); /* * Decode an integer from its big-endian unsigned representation. The * integer MUST be lower than m[]; the announced bit length written in * x[] will be equal to that of m[]. All 'len' bytes from the source are * read. * * Returned value is 1 if the decode value fits within the modulus, 0 * otherwise. In the latter case, the x[] buffer will be set to 0 (but * still with the announced bit length of m[]). * * CT: value or length of x does not leak. Memory access pattern depends * only of 'len' and the announced bit length of m. Whether x fits or * not does not leak either. */ uint32_t br_i32_decode_mod(uint32_t *x, const void *src, size_t len, const uint32_t *m); /* * Reduce an integer (a[]) modulo another (m[]). The result is written * in x[] and its announced bit length is set to be equal to that of m[]. * * x[] MUST be distinct from a[] and m[]. * * CT: only announced bit lengths leak, not values of x, a or m. */ void br_i32_reduce(uint32_t *x, const uint32_t *a, const uint32_t *m); /* * Decode an integer from its big-endian unsigned representation, and * reduce it modulo the provided modulus m[]. The announced bit length * of the result is set to be equal to that of the modulus. * * x[] MUST be distinct from m[]. */ void br_i32_decode_reduce(uint32_t *x, const void *src, size_t len, const uint32_t *m); /* * Encode an integer into its big-endian unsigned representation. The * output length in bytes is provided (parameter 'len'); if the length * is too short then the integer is appropriately truncated; if it is * too long then the extra bytes are set to 0. */ void br_i32_encode(void *dst, size_t len, const uint32_t *x); /* * Multiply x[] by 2^32 and then add integer z, modulo m[]. This * function assumes that x[] and m[] have the same announced bit * length, and the announced bit length of m[] matches its true * bit length. * * x[] and m[] MUST be distinct arrays. * * CT: only the common announced bit length of x and m leaks, not * the values of x, z or m. */ void br_i32_muladd_small(uint32_t *x, uint32_t z, const uint32_t *m); /* * Extract one word from an integer. The offset is counted in bits. * The word MUST entirely fit within the word elements corresponding * to the announced bit length of a[]. */ static inline uint32_t br_i32_word(const uint32_t *a, uint32_t off) { size_t u; unsigned j; u = (size_t)(off >> 5) + 1; j = (unsigned)off & 31; if (j == 0) { return a[u]; } else { return (a[u] >> j) | (a[u + 1] << (32 - j)); } } /* * Test whether an integer is zero. */ uint32_t br_i32_iszero(const uint32_t *x); /* * Add b[] to a[] and return the carry (0 or 1). If ctl is 0, then a[] * is unmodified, but the carry is still computed and returned. The * arrays a[] and b[] MUST have the same announced bit length. * * a[] and b[] MAY be the same array, but partial overlap is not allowed. */ uint32_t br_i32_add(uint32_t *a, const uint32_t *b, uint32_t ctl); /* * Subtract b[] from a[] and return the carry (0 or 1). If ctl is 0, * then a[] is unmodified, but the carry is still computed and returned. * The arrays a[] and b[] MUST have the same announced bit length. * * a[] and b[] MAY be the same array, but partial overlap is not allowed. */ uint32_t br_i32_sub(uint32_t *a, const uint32_t *b, uint32_t ctl); /* * Compute d+a*b, result in d. The initial announced bit length of d[] * MUST match that of a[]. The d[] array MUST be large enough to * accommodate the full result, plus (possibly) an extra word. The * resulting announced bit length of d[] will be the sum of the announced * bit lengths of a[] and b[] (therefore, it may be larger than the actual * bit length of the numerical result). * * a[] and b[] may be the same array. d[] must be disjoint from both a[] * and b[]. */ void br_i32_mulacc(uint32_t *d, const uint32_t *a, const uint32_t *b); /* * Zeroize an integer. The announced bit length is set to the provided * value, and the corresponding words are set to 0. */ static inline void br_i32_zero(uint32_t *x, uint32_t bit_len) { *x ++ = bit_len; memset(x, 0, ((bit_len + 31) >> 5) * sizeof *x); } /* * Compute -(1/x) mod 2^32. If x is even, then this function returns 0. */ uint32_t br_i32_ninv32(uint32_t x); /* * Convert a modular integer to Montgomery representation. The integer x[] * MUST be lower than m[], but with the same announced bit length. */ void br_i32_to_monty(uint32_t *x, const uint32_t *m); /* * Convert a modular integer back from Montgomery representation. The * integer x[] MUST be lower than m[], but with the same announced bit * length. The "m0i" parameter is equal to -(1/m0) mod 2^32, where m0 is * the least significant value word of m[] (this works only if m[] is * an odd integer). */ void br_i32_from_monty(uint32_t *x, const uint32_t *m, uint32_t m0i); /* * Compute a modular Montgomery multiplication. d[] is filled with the * value of x*y/R modulo m[] (where R is the Montgomery factor). The * array d[] MUST be distinct from x[], y[] and m[]. x[] and y[] MUST be * numerically lower than m[]. x[] and y[] MAY be the same array. The * "m0i" parameter is equal to -(1/m0) mod 2^32, where m0 is the least * significant value word of m[] (this works only if m[] is an odd * integer). */ void br_i32_montymul(uint32_t *d, const uint32_t *x, const uint32_t *y, const uint32_t *m, uint32_t m0i); /* * Compute a modular exponentiation. x[] MUST be an integer modulo m[] * (same announced bit length, lower value). m[] MUST be odd. The * exponent is in big-endian unsigned notation, over 'elen' bytes. The * "m0i" parameter is equal to -(1/m0) mod 2^32, where m0 is the least * significant value word of m[] (this works only if m[] is an odd * integer). The t1[] and t2[] parameters must be temporary arrays, * each large enough to accommodate an integer with the same size as m[]. */ void br_i32_modpow(uint32_t *x, const unsigned char *e, size_t elen, const uint32_t *m, uint32_t m0i, uint32_t *t1, uint32_t *t2); /* ==================================================================== */ /* * Integers 'i31' * -------------- * * The 'i31' functions implement computations on big integers using * an internal representation as an array of 32-bit integers. For * an array x[]: * -- x[0] encodes the array length and the "announced bit length" * of the integer: namely, if the announced bit length is k, * then x[0] = ((k / 31) << 5) + (k % 31). * -- x[1], x[2]... contain the value in little-endian order, 31 * bits per word (x[1] contains the least significant 31 bits). * The upper bit of each word is 0. * * Multiplications rely on the elementary 32x32->64 multiplication. * * The announced bit length specifies the number of bits that are * significant in the subsequent 32-bit words. Unused bits in the * last (most significant) word are set to 0; subsequent words are * uninitialized and need not exist at all. * * The execution time and memory access patterns of all computations * depend on the announced bit length, but not on the actual word * values. For modular integers, the announced bit length of any integer * modulo n is equal to the actual bit length of n; thus, computations * on modular integers are "constant-time" (only the modulus length may * leak). */ /* * Test whether an integer is zero. */ uint32_t br_i31_iszero(const uint32_t *x); /* * Add b[] to a[] and return the carry (0 or 1). If ctl is 0, then a[] * is unmodified, but the carry is still computed and returned. The * arrays a[] and b[] MUST have the same announced bit length. * * a[] and b[] MAY be the same array, but partial overlap is not allowed. */ uint32_t br_i31_add(uint32_t *a, const uint32_t *b, uint32_t ctl); /* * Subtract b[] from a[] and return the carry (0 or 1). If ctl is 0, * then a[] is unmodified, but the carry is still computed and returned. * The arrays a[] and b[] MUST have the same announced bit length. * * a[] and b[] MAY be the same array, but partial overlap is not allowed. */ uint32_t br_i31_sub(uint32_t *a, const uint32_t *b, uint32_t ctl); /* * Compute the ENCODED actual bit length of an integer. The argument x * should point to the first (least significant) value word of the * integer. The len 'xlen' contains the number of 32-bit words to * access. The upper bit of each value word MUST be 0. * Returned value is ((k / 31) << 5) + (k % 31) if the bit length is k. * * CT: value or length of x does not leak. */ uint32_t br_i31_bit_length(uint32_t *x, size_t xlen); /* * Decode an integer from its big-endian unsigned representation. The * "true" bit length of the integer is computed and set in the encoded * announced bit length (x[0]), but all words of x[] corresponding to * the full 'len' bytes of the source are set. * * CT: value or length of x does not leak. */ void br_i31_decode(uint32_t *x, const void *src, size_t len); /* * Decode an integer from its big-endian unsigned representation. The * integer MUST be lower than m[]; the (encoded) announced bit length * written in x[] will be equal to that of m[]. All 'len' bytes from the * source are read. * * Returned value is 1 if the decode value fits within the modulus, 0 * otherwise. In the latter case, the x[] buffer will be set to 0 (but * still with the announced bit length of m[]). * * CT: value or length of x does not leak. Memory access pattern depends * only of 'len' and the announced bit length of m. Whether x fits or * not does not leak either. */ uint32_t br_i31_decode_mod(uint32_t *x, const void *src, size_t len, const uint32_t *m); /* * Zeroize an integer. The announced bit length is set to the provided * value, and the corresponding words are set to 0. The ENCODED bit length * is expected here. */ static inline void br_i31_zero(uint32_t *x, uint32_t bit_len) { *x ++ = bit_len; memset(x, 0, ((bit_len + 31) >> 5) * sizeof *x); } /* * Right-shift an integer. The shift amount must be lower than 31 * bits. */ void br_i31_rshift(uint32_t *x, int count); /* * Reduce an integer (a[]) modulo another (m[]). The result is written * in x[] and its announced bit length is set to be equal to that of m[]. * * x[] MUST be distinct from a[] and m[]. * * CT: only announced bit lengths leak, not values of x, a or m. */ void br_i31_reduce(uint32_t *x, const uint32_t *a, const uint32_t *m); /* * Decode an integer from its big-endian unsigned representation, and * reduce it modulo the provided modulus m[]. The announced bit length * of the result is set to be equal to that of the modulus. * * x[] MUST be distinct from m[]. */ void br_i31_decode_reduce(uint32_t *x, const void *src, size_t len, const uint32_t *m); /* * Multiply x[] by 2^31 and then add integer z, modulo m[]. This * function assumes that x[] and m[] have the same announced bit * length, the announced bit length of m[] matches its true * bit length. * * x[] and m[] MUST be distinct arrays. z MUST fit in 31 bits (upper * bit set to 0). * * CT: only the common announced bit length of x and m leaks, not * the values of x, z or m. */ void br_i31_muladd_small(uint32_t *x, uint32_t z, const uint32_t *m); /* * Encode an integer into its big-endian unsigned representation. The * output length in bytes is provided (parameter 'len'); if the length * is too short then the integer is appropriately truncated; if it is * too long then the extra bytes are set to 0. */ void br_i31_encode(void *dst, size_t len, const uint32_t *x); /* * Compute -(1/x) mod 2^31. If x is even, then this function returns 0. */ uint32_t br_i31_ninv31(uint32_t x); /* * Compute a modular Montgomery multiplication. d[] is filled with the * value of x*y/R modulo m[] (where R is the Montgomery factor). The * array d[] MUST be distinct from x[], y[] and m[]. x[] and y[] MUST be * numerically lower than m[]. x[] and y[] MAY be the same array. The * "m0i" parameter is equal to -(1/m0) mod 2^31, where m0 is the least * significant value word of m[] (this works only if m[] is an odd * integer). */ void br_i31_montymul(uint32_t *d, const uint32_t *x, const uint32_t *y, const uint32_t *m, uint32_t m0i); /* * Convert a modular integer to Montgomery representation. The integer x[] * MUST be lower than m[], but with the same announced bit length. */ void br_i31_to_monty(uint32_t *x, const uint32_t *m); /* * Convert a modular integer back from Montgomery representation. The * integer x[] MUST be lower than m[], but with the same announced bit * length. The "m0i" parameter is equal to -(1/m0) mod 2^32, where m0 is * the least significant value word of m[] (this works only if m[] is * an odd integer). */ void br_i31_from_monty(uint32_t *x, const uint32_t *m, uint32_t m0i); /* * Compute a modular exponentiation. x[] MUST be an integer modulo m[] * (same announced bit length, lower value). m[] MUST be odd. The * exponent is in big-endian unsigned notation, over 'elen' bytes. The * "m0i" parameter is equal to -(1/m0) mod 2^31, where m0 is the least * significant value word of m[] (this works only if m[] is an odd * integer). The t1[] and t2[] parameters must be temporary arrays, * each large enough to accommodate an integer with the same size as m[]. */ void br_i31_modpow(uint32_t *x, const unsigned char *e, size_t elen, const uint32_t *m, uint32_t m0i, uint32_t *t1, uint32_t *t2); /* * Compute a modular exponentiation. x[] MUST be an integer modulo m[] * (same announced bit length, lower value). m[] MUST be odd. The * exponent is in big-endian unsigned notation, over 'elen' bytes. The * "m0i" parameter is equal to -(1/m0) mod 2^31, where m0 is the least * significant value word of m[] (this works only if m[] is an odd * integer). The tmp[] array is used for temporaries, and has size * 'twlen' words; it must be large enough to accommodate at least two * temporary values with the same size as m[] (including the leading * "bit length" word). If there is room for more temporaries, then this * function may use the extra room for window-based optimisation, * resulting in faster computations. * * Returned value is 1 on success, 0 on error. An error is reported if * the provided tmp[] array is too short. */ uint32_t br_i31_modpow_opt(uint32_t *x, const unsigned char *e, size_t elen, const uint32_t *m, uint32_t m0i, uint32_t *tmp, size_t twlen); /* * Compute d+a*b, result in d. The initial announced bit length of d[] * MUST match that of a[]. The d[] array MUST be large enough to * accommodate the full result, plus (possibly) an extra word. The * resulting announced bit length of d[] will be the sum of the announced * bit lengths of a[] and b[] (therefore, it may be larger than the actual * bit length of the numerical result). * * a[] and b[] may be the same array. d[] must be disjoint from both a[] * and b[]. */ void br_i31_mulacc(uint32_t *d, const uint32_t *a, const uint32_t *b); /* * Compute x/y mod m, result in x. Values x and y must be between 0 and * m-1, and have the same announced bit length as m. Modulus m must be * odd. The "m0i" parameter is equal to -1/m mod 2^31. The array 't' * must point to a temporary area that can hold at least three integers * of the size of m. * * m may not overlap x and y. x and y may overlap each other (this can * be useful to test whether a value is invertible modulo m). t must be * disjoint from all other arrays. * * Returned value is 1 on success, 0 otherwise. Success is attained if * y is invertible modulo m. */ uint32_t br_i31_moddiv(uint32_t *x, const uint32_t *y, const uint32_t *m, uint32_t m0i, uint32_t *t); /* ==================================================================== */ /* * FIXME: document "i15" functions. */ static inline void br_i15_zero(uint16_t *x, uint16_t bit_len) { *x ++ = bit_len; memset(x, 0, ((bit_len + 15) >> 4) * sizeof *x); } uint32_t br_i15_iszero(const uint16_t *x); uint16_t br_i15_ninv15(uint16_t x); uint32_t br_i15_add(uint16_t *a, const uint16_t *b, uint32_t ctl); uint32_t br_i15_sub(uint16_t *a, const uint16_t *b, uint32_t ctl); void br_i15_muladd_small(uint16_t *x, uint16_t z, const uint16_t *m); void br_i15_montymul(uint16_t *d, const uint16_t *x, const uint16_t *y, const uint16_t *m, uint16_t m0i); void br_i15_to_monty(uint16_t *x, const uint16_t *m); void br_i15_modpow(uint16_t *x, const unsigned char *e, size_t elen, const uint16_t *m, uint16_t m0i, uint16_t *t1, uint16_t *t2); uint32_t br_i15_modpow_opt(uint16_t *x, const unsigned char *e, size_t elen, const uint16_t *m, uint16_t m0i, uint16_t *tmp, size_t twlen); void br_i15_encode(void *dst, size_t len, const uint16_t *x); uint32_t br_i15_decode_mod(uint16_t *x, const void *src, size_t len, const uint16_t *m); void br_i15_rshift(uint16_t *x, int count); uint32_t br_i15_bit_length(uint16_t *x, size_t xlen); void br_i15_decode(uint16_t *x, const void *src, size_t len); void br_i15_from_monty(uint16_t *x, const uint16_t *m, uint16_t m0i); void br_i15_decode_reduce(uint16_t *x, const void *src, size_t len, const uint16_t *m); void br_i15_reduce(uint16_t *x, const uint16_t *a, const uint16_t *m); void br_i15_mulacc(uint16_t *d, const uint16_t *a, const uint16_t *b); uint32_t br_i15_moddiv(uint16_t *x, const uint16_t *y, const uint16_t *m, uint16_t m0i, uint16_t *t); /* * Variant of br_i31_modpow_opt() that internally uses 64x64->128 * multiplications. It expects the same parameters as br_i31_modpow_opt(), * except that the temporaries should be 64-bit integers, not 32-bit * integers. */ uint32_t br_i62_modpow_opt(uint32_t *x31, const unsigned char *e, size_t elen, const uint32_t *m31, uint32_t m0i31, uint64_t *tmp, size_t twlen); /* * Type for a function with the same API as br_i31_modpow_opt() (some * implementations of this type may have stricter alignment requirements * on the temporaries). */ typedef uint32_t (*br_i31_modpow_opt_type)(uint32_t *x, const unsigned char *e, size_t elen, const uint32_t *m, uint32_t m0i, uint32_t *tmp, size_t twlen); /* * Wrapper for br_i62_modpow_opt() that uses the same type as * br_i31_modpow_opt(); however, it requires its 'tmp' argument to the * 64-bit aligned. */ uint32_t br_i62_modpow_opt_as_i31(uint32_t *x, const unsigned char *e, size_t elen, const uint32_t *m, uint32_t m0i, uint32_t *tmp, size_t twlen); /* ==================================================================== */ static inline size_t br_digest_size(const br_hash_class *digest_class) { return (size_t)(digest_class->desc >> BR_HASHDESC_OUT_OFF) & BR_HASHDESC_OUT_MASK; } /* * Get the output size (in bytes) of a hash function. */ size_t br_digest_size_by_ID(int digest_id); /* * Get the OID (encoded OBJECT IDENTIFIER value, without tag and length) * for a hash function. If digest_id is not a supported digest identifier * (in particular if it is equal to 0, i.e. br_md5sha1_ID), then NULL is * returned and *len is set to 0. */ const unsigned char *br_digest_OID(int digest_id, size_t *len); /* ==================================================================== */ /* * DES support functions. */ /* * Apply DES Initial Permutation. */ void br_des_do_IP(uint32_t *xl, uint32_t *xr); /* * Apply DES Final Permutation (inverse of IP). */ void br_des_do_invIP(uint32_t *xl, uint32_t *xr); /* * Key schedule unit: for a DES key (8 bytes), compute 16 subkeys. Each * subkey is two 28-bit words represented as two 32-bit words; the PC-2 * bit extration is NOT applied. */ void br_des_keysched_unit(uint32_t *skey, const void *key); /* * Reversal of 16 DES sub-keys (for decryption). */ void br_des_rev_skey(uint32_t *skey); /* * DES/3DES key schedule for 'des_tab' (encryption direction). Returned * value is the number of rounds. */ unsigned br_des_tab_keysched(uint32_t *skey, const void *key, size_t key_len); /* * DES/3DES key schedule for 'des_ct' (encryption direction). Returned * value is the number of rounds. */ unsigned br_des_ct_keysched(uint32_t *skey, const void *key, size_t key_len); /* * DES/3DES subkey decompression (from the compressed bitsliced subkeys). */ void br_des_ct_skey_expand(uint32_t *sk_exp, unsigned num_rounds, const uint32_t *skey); /* * DES/3DES block encryption/decryption ('des_tab'). */ void br_des_tab_process_block(unsigned num_rounds, const uint32_t *skey, void *block); /* * DES/3DES block encryption/decryption ('des_ct'). */ void br_des_ct_process_block(unsigned num_rounds, const uint32_t *skey, void *block); /* ==================================================================== */ /* * AES support functions. */ /* * The AES S-box (256-byte table). */ extern const unsigned char br_aes_S[]; /* * AES key schedule. skey[] is filled with n+1 128-bit subkeys, where n * is the number of rounds (10 to 14, depending on key size). The number * of rounds is returned. If the key size is invalid (not 16, 24 or 32), * then 0 is returned. * * This implementation uses a 256-byte table and is NOT constant-time. */ unsigned br_aes_keysched(uint32_t *skey, const void *key, size_t key_len); /* * AES key schedule for decryption ('aes_big' implementation). */ unsigned br_aes_big_keysched_inv(uint32_t *skey, const void *key, size_t key_len); /* * AES block encryption with the 'aes_big' implementation (fast, but * not constant-time). This function encrypts a single block "in place". */ void br_aes_big_encrypt(unsigned num_rounds, const uint32_t *skey, void *data); /* * AES block decryption with the 'aes_big' implementation (fast, but * not constant-time). This function decrypts a single block "in place". */ void br_aes_big_decrypt(unsigned num_rounds, const uint32_t *skey, void *data); /* * AES block encryption with the 'aes_small' implementation (small, but * slow and not constant-time). This function encrypts a single block * "in place". */ void br_aes_small_encrypt(unsigned num_rounds, const uint32_t *skey, void *data); /* * AES block decryption with the 'aes_small' implementation (small, but * slow and not constant-time). This function decrypts a single block * "in place". */ void br_aes_small_decrypt(unsigned num_rounds, const uint32_t *skey, void *data); /* * The constant-time implementation is "bitsliced": the 128-bit state is * split over eight 32-bit words q* in the following way: * * -- Input block consists in 16 bytes: * a00 a10 a20 a30 a01 a11 a21 a31 a02 a12 a22 a32 a03 a13 a23 a33 * In the terminology of FIPS 197, this is a 4x4 matrix which is read * column by column. * * -- Each byte is split into eight bits which are distributed over the * eight words, at the same rank. Thus, for a byte x at rank k, bit 0 * (least significant) of x will be at rank k in q0 (if that bit is b, * then it contributes "b << k" to the value of q0), bit 1 of x will be * at rank k in q1, and so on. * * -- Ranks given to bits are in "row order" and are either all even, or * all odd. Two independent AES states are thus interleaved, one using * the even ranks, the other the odd ranks. Row order means: * a00 a01 a02 a03 a10 a11 a12 a13 a20 a21 a22 a23 a30 a31 a32 a33 * * Converting input bytes from two AES blocks to bitslice representation * is done in the following way: * -- Decode first block into the four words q0 q2 q4 q6, in that order, * using little-endian convention. * -- Decode second block into the four words q1 q3 q5 q7, in that order, * using little-endian convention. * -- Call br_aes_ct_ortho(). * * Converting back to bytes is done by using the reverse operations. Note * that br_aes_ct_ortho() is its own inverse. */ /* * Perform bytewise orthogonalization of eight 32-bit words. Bytes * of q0..q7 are spread over all words: for a byte x that occurs * at rank i in q[j] (byte x uses bits 8*i to 8*i+7 in q[j]), the bit * of rank k in x (0 <= k <= 7) goes to q[k] at rank 8*i+j. * * This operation is an involution. */ void br_aes_ct_ortho(uint32_t *q); /* * The AES S-box, as a bitsliced constant-time version. The input array * consists in eight 32-bit words; 32 S-box instances are computed in * parallel. Bits 0 to 7 of each S-box input (bit 0 is least significant) * are spread over the words 0 to 7, at the same rank. */ void br_aes_ct_bitslice_Sbox(uint32_t *q); /* * Like br_aes_bitslice_Sbox(), but for the inverse S-box. */ void br_aes_ct_bitslice_invSbox(uint32_t *q); /* * Compute AES encryption on bitsliced data. Since input is stored on * eight 32-bit words, two block encryptions are actually performed * in parallel. */ void br_aes_ct_bitslice_encrypt(unsigned num_rounds, const uint32_t *skey, uint32_t *q); /* * Compute AES decryption on bitsliced data. Since input is stored on * eight 32-bit words, two block decryptions are actually performed * in parallel. */ void br_aes_ct_bitslice_decrypt(unsigned num_rounds, const uint32_t *skey, uint32_t *q); /* * AES key schedule, constant-time version. skey[] is filled with n+1 * 128-bit subkeys, where n is the number of rounds (10 to 14, depending * on key size). The number of rounds is returned. If the key size is * invalid (not 16, 24 or 32), then 0 is returned. */ unsigned br_aes_ct_keysched(uint32_t *comp_skey, const void *key, size_t key_len); /* * Expand AES subkeys as produced by br_aes_ct_keysched(), into * a larger array suitable for br_aes_ct_bitslice_encrypt() and * br_aes_ct_bitslice_decrypt(). */ void br_aes_ct_skey_expand(uint32_t *skey, unsigned num_rounds, const uint32_t *comp_skey); /* * For the ct64 implementation, the same bitslicing technique is used, * but four instances are interleaved. First instance uses bits 0, 4, * 8, 12,... of each word; second instance uses bits 1, 5, 9, 13,... * and so on. */ /* * Perform bytewise orthogonalization of eight 64-bit words. Bytes * of q0..q7 are spread over all words: for a byte x that occurs * at rank i in q[j] (byte x uses bits 8*i to 8*i+7 in q[j]), the bit * of rank k in x (0 <= k <= 7) goes to q[k] at rank 8*i+j. * * This operation is an involution. */ void br_aes_ct64_ortho(uint64_t *q); /* * Interleave bytes for an AES input block. If input bytes are * denoted 0123456789ABCDEF, and have been decoded with little-endian * convention (w[0] contains 0123, with '3' being most significant; * w[1] contains 4567, and so on), then output word q0 will be * set to 08192A3B (again little-endian convention) and q1 will * be set to 4C5D6E7F. */ void br_aes_ct64_interleave_in(uint64_t *q0, uint64_t *q1, const uint32_t *w); /* * Perform the opposite of br_aes_ct64_interleave_in(). */ void br_aes_ct64_interleave_out(uint32_t *w, uint64_t q0, uint64_t q1); /* * The AES S-box, as a bitsliced constant-time version. The input array * consists in eight 64-bit words; 64 S-box instances are computed in * parallel. Bits 0 to 7 of each S-box input (bit 0 is least significant) * are spread over the words 0 to 7, at the same rank. */ void br_aes_ct64_bitslice_Sbox(uint64_t *q); /* * Like br_aes_bitslice_Sbox(), but for the inverse S-box. */ void br_aes_ct64_bitslice_invSbox(uint64_t *q); /* * Compute AES encryption on bitsliced data. Since input is stored on * eight 64-bit words, four block encryptions are actually performed * in parallel. */ void br_aes_ct64_bitslice_encrypt(unsigned num_rounds, const uint64_t *skey, uint64_t *q); /* * Compute AES decryption on bitsliced data. Since input is stored on * eight 64-bit words, four block decryptions are actually performed * in parallel. */ void br_aes_ct64_bitslice_decrypt(unsigned num_rounds, const uint64_t *skey, uint64_t *q); /* * AES key schedule, constant-time version. skey[] is filled with n+1 * 128-bit subkeys, where n is the number of rounds (10 to 14, depending * on key size). The number of rounds is returned. If the key size is * invalid (not 16, 24 or 32), then 0 is returned. */ unsigned br_aes_ct64_keysched(uint64_t *comp_skey, const void *key, size_t key_len); /* * Expand AES subkeys as produced by br_aes_ct64_keysched(), into * a larger array suitable for br_aes_ct64_bitslice_encrypt() and * br_aes_ct64_bitslice_decrypt(). */ void br_aes_ct64_skey_expand(uint64_t *skey, unsigned num_rounds, const uint64_t *comp_skey); /* * Test support for AES-NI opcodes. */ int br_aes_x86ni_supported(void); /* * AES key schedule, using x86 AES-NI instructions. This yields the * subkeys in the encryption direction. Number of rounds is returned. * Key size MUST be 16, 24 or 32 bytes; otherwise, 0 is returned. */ unsigned br_aes_x86ni_keysched_enc(unsigned char *skni, const void *key, size_t len); /* * AES key schedule, using x86 AES-NI instructions. This yields the * subkeys in the decryption direction. Number of rounds is returned. * Key size MUST be 16, 24 or 32 bytes; otherwise, 0 is returned. */ unsigned br_aes_x86ni_keysched_dec(unsigned char *skni, const void *key, size_t len); /* * Test support for AES POWER8 opcodes. */ int br_aes_pwr8_supported(void); /* * AES key schedule, using POWER8 instructions. This yields the * subkeys in the encryption direction. Number of rounds is returned. * Key size MUST be 16, 24 or 32 bytes; otherwise, 0 is returned. */ unsigned br_aes_pwr8_keysched(unsigned char *skni, const void *key, size_t len); /* ==================================================================== */ /* * RSA. */ /* * Apply proper PKCS#1 v1.5 padding (for signatures). 'hash_oid' is * the encoded hash function OID, or NULL. */ uint32_t br_rsa_pkcs1_sig_pad(const unsigned char *hash_oid, const unsigned char *hash, size_t hash_len, uint32_t n_bitlen, unsigned char *x); /* * Check PKCS#1 v1.5 padding (for signatures). 'hash_oid' is the encoded * hash function OID, or NULL. The provided 'sig' value is _after_ the * modular exponentiation, i.e. it should be the padded hash. On * success, the hashed message is extracted. */ uint32_t br_rsa_pkcs1_sig_unpad(const unsigned char *sig, size_t sig_len, const unsigned char *hash_oid, size_t hash_len, unsigned char *hash_out); /* * Apply OAEP padding. Returned value is the actual padded string length, * or zero on error. */ size_t br_rsa_oaep_pad(const br_prng_class **rnd, const br_hash_class *dig, const void *label, size_t label_len, const br_rsa_public_key *pk, void *dst, size_t dst_nax_len, const void *src, size_t src_len); /* * Unravel and check OAEP padding. If the padding is correct, then 1 is * returned, '*len' is adjusted to the length of the message, and the * data is moved to the start of the 'data' buffer. If the padding is * incorrect, then 0 is returned and '*len' is untouched. Either way, * the complete buffer contents are altered. */ uint32_t br_rsa_oaep_unpad(const br_hash_class *dig, const void *label, size_t label_len, void *data, size_t *len); /* * Compute MGF1 for a given seed, and XOR the output into the provided * buffer. */ void br_mgf1_xor(void *data, size_t len, const br_hash_class *dig, const void *seed, size_t seed_len); /* * Inner function for RSA key generation; used by the "i31" and "i62" * implementations. */ uint32_t br_rsa_i31_keygen_inner(const br_prng_class **rng, br_rsa_private_key *sk, void *kbuf_priv, br_rsa_public_key *pk, void *kbuf_pub, unsigned size, uint32_t pubexp, br_i31_modpow_opt_type mp31); /* ==================================================================== */ /* * Elliptic curves. */ /* * Type for generic EC parameters: curve order (unsigned big-endian * encoding) and encoded conventional generator. */ typedef struct { int curve; const unsigned char *order; size_t order_len; const unsigned char *generator; size_t generator_len; } br_ec_curve_def; extern const br_ec_curve_def br_secp256r1; extern const br_ec_curve_def br_secp384r1; extern const br_ec_curve_def br_secp521r1; /* * For Curve25519, the advertised "order" really is 2^255-1, since the * point multipliction function really works over arbitrary 255-bit * scalars. This value is only meant as a hint for ECDH key generation; * only ECDSA uses the exact curve order, and ECDSA is not used with * that specific curve. */ extern const br_ec_curve_def br_curve25519; /* * Decode some bytes as an i31 integer, with truncation (corresponding * to the 'bits2int' operation in RFC 6979). The target ENCODED bit * length is provided as last parameter. The resulting value will have * this declared bit length, and consists the big-endian unsigned decoding * of exactly that many bits in the source (capped at the source length). */ void br_ecdsa_i31_bits2int(uint32_t *x, const void *src, size_t len, uint32_t ebitlen); /* * Decode some bytes as an i15 integer, with truncation (corresponding * to the 'bits2int' operation in RFC 6979). The target ENCODED bit * length is provided as last parameter. The resulting value will have * this declared bit length, and consists the big-endian unsigned decoding * of exactly that many bits in the source (capped at the source length). */ void br_ecdsa_i15_bits2int(uint16_t *x, const void *src, size_t len, uint32_t ebitlen); /* ==================================================================== */ /* * ASN.1 support functions. */ /* * A br_asn1_uint structure contains encoding information about an * INTEGER nonnegative value: pointer to the integer contents (unsigned * big-endian representation), length of the integer contents, * and length of the encoded value. The data shall have minimal length: * - If the integer value is zero, then 'len' must be zero. * - If the integer value is not zero, then data[0] must be non-zero. * * Under these conditions, 'asn1len' is necessarily equal to either len * or len+1. */ typedef struct { const unsigned char *data; size_t len; size_t asn1len; } br_asn1_uint; /* * Given an encoded integer (unsigned big-endian, with possible leading * bytes of value 0), returned the "prepared INTEGER" structure. */ br_asn1_uint br_asn1_uint_prepare(const void *xdata, size_t xlen); /* * Encode an ASN.1 length. The length of the encoded length is returned. * If 'dest' is NULL, then no encoding is performed, but the length of * the encoded length is still computed and returned. */ size_t br_asn1_encode_length(void *dest, size_t len); /* * Convenient macro for computing lengths of lengths. */ #define len_of_len(len) br_asn1_encode_length(NULL, len) /* * Encode a (prepared) ASN.1 INTEGER. The encoded length is returned. * If 'dest' is NULL, then no encoding is performed, but the length of * the encoded integer is still computed and returned. */ size_t br_asn1_encode_uint(void *dest, br_asn1_uint pp); /* * Get the OID that identifies an elliptic curve. Returned value is * the DER-encoded OID, with the length (always one byte) but without * the tag. Thus, the first byte of the returned buffer contains the * number of subsequent bytes in the value. If the curve is not * recognised, NULL is returned. */ const unsigned char *br_get_curve_OID(int curve); /* * Inner function for EC private key encoding. This is equivalent to * the API function br_encode_ec_raw_der(), except for an extra * parameter: if 'include_curve_oid' is zero, then the curve OID is * _not_ included in the output blob (this is for PKCS#8 support). */ size_t br_encode_ec_raw_der_inner(void *dest, const br_ec_private_key *sk, const br_ec_public_key *pk, int include_curve_oid); /* ==================================================================== */ /* * SSL/TLS support functions. */ /* * Record types. */ #define BR_SSL_CHANGE_CIPHER_SPEC 20 #define BR_SSL_ALERT 21 #define BR_SSL_HANDSHAKE 22 #define BR_SSL_APPLICATION_DATA 23 /* * Handshake message types. */ #define BR_SSL_HELLO_REQUEST 0 #define BR_SSL_CLIENT_HELLO 1 #define BR_SSL_SERVER_HELLO 2 #define BR_SSL_CERTIFICATE 11 #define BR_SSL_SERVER_KEY_EXCHANGE 12 #define BR_SSL_CERTIFICATE_REQUEST 13 #define BR_SSL_SERVER_HELLO_DONE 14 #define BR_SSL_CERTIFICATE_VERIFY 15 #define BR_SSL_CLIENT_KEY_EXCHANGE 16 #define BR_SSL_FINISHED 20 /* * Alert levels. */ #define BR_LEVEL_WARNING 1 #define BR_LEVEL_FATAL 2 /* * Low-level I/O state. */ #define BR_IO_FAILED 0 #define BR_IO_IN 1 #define BR_IO_OUT 2 #define BR_IO_INOUT 3 /* * Mark a SSL engine as failed. The provided error code is recorded if * the engine was not already marked as failed. If 'err' is 0, then the * engine is marked as closed (without error). */ void br_ssl_engine_fail(br_ssl_engine_context *cc, int err); /* * Test whether the engine is closed (normally or as a failure). */ static inline int br_ssl_engine_closed(const br_ssl_engine_context *cc) { return cc->iomode == BR_IO_FAILED; } /* * Configure a new maximum fragment length. If possible, the maximum * length for outgoing records is immediately adjusted (if there are * not already too many buffered bytes for that). */ void br_ssl_engine_new_max_frag_len( br_ssl_engine_context *rc, unsigned max_frag_len); /* * Test whether the current incoming record has been fully received * or not. This functions returns 0 only if a complete record header * has been received, but some of the (possibly encrypted) payload * has not yet been obtained. */ int br_ssl_engine_recvrec_finished(const br_ssl_engine_context *rc); /* * Flush the current record (if not empty). This is meant to be called * from the handshake processor only. */ void br_ssl_engine_flush_record(br_ssl_engine_context *cc); /* * Test whether there is some accumulated payload to send. */ static inline int br_ssl_engine_has_pld_to_send(const br_ssl_engine_context *rc) { return rc->oxa != rc->oxb && rc->oxa != rc->oxc; } /* * Initialize RNG in engine. Returned value is 1 on success, 0 on error. * This function will try to use the OS-provided RNG, if available. If * there is no OS-provided RNG, or if it failed, and no entropy was * injected by the caller, then a failure will be reported. On error, * the context error code is set. */ int br_ssl_engine_init_rand(br_ssl_engine_context *cc); /* * Reset the handshake-related parts of the engine. */ void br_ssl_engine_hs_reset(br_ssl_engine_context *cc, void (*hsinit)(void *), void (*hsrun)(void *)); /* * Get the PRF to use for this context, for the provided PRF hash * function ID. */ br_tls_prf_impl br_ssl_engine_get_PRF(br_ssl_engine_context *cc, int prf_id); /* * Consume the provided pre-master secret and compute the corresponding * master secret. The 'prf_id' is the ID of the hash function to use * with the TLS 1.2 PRF (ignored if the version is TLS 1.0 or 1.1). */ void br_ssl_engine_compute_master(br_ssl_engine_context *cc, int prf_id, const void *pms, size_t len); /* * Switch to CBC decryption for incoming records. * cc the engine context * is_client non-zero for a client, zero for a server * prf_id id of hash function for PRF (ignored if not TLS 1.2+) * mac_id id of hash function for HMAC * bc_impl block cipher implementation (CBC decryption) * cipher_key_len block cipher key length (in bytes) */ void br_ssl_engine_switch_cbc_in(br_ssl_engine_context *cc, int is_client, int prf_id, int mac_id, const br_block_cbcdec_class *bc_impl, size_t cipher_key_len); /* * Switch to CBC encryption for outgoing records. * cc the engine context * is_client non-zero for a client, zero for a server * prf_id id of hash function for PRF (ignored if not TLS 1.2+) * mac_id id of hash function for HMAC * bc_impl block cipher implementation (CBC encryption) * cipher_key_len block cipher key length (in bytes) */ void br_ssl_engine_switch_cbc_out(br_ssl_engine_context *cc, int is_client, int prf_id, int mac_id, const br_block_cbcenc_class *bc_impl, size_t cipher_key_len); /* * Switch to GCM decryption for incoming records. * cc the engine context * is_client non-zero for a client, zero for a server * prf_id id of hash function for PRF * bc_impl block cipher implementation (CTR) * cipher_key_len block cipher key length (in bytes) */ void br_ssl_engine_switch_gcm_in(br_ssl_engine_context *cc, int is_client, int prf_id, const br_block_ctr_class *bc_impl, size_t cipher_key_len); /* * Switch to GCM encryption for outgoing records. * cc the engine context * is_client non-zero for a client, zero for a server * prf_id id of hash function for PRF * bc_impl block cipher implementation (CTR) * cipher_key_len block cipher key length (in bytes) */ void br_ssl_engine_switch_gcm_out(br_ssl_engine_context *cc, int is_client, int prf_id, const br_block_ctr_class *bc_impl, size_t cipher_key_len); /* * Switch to ChaCha20+Poly1305 decryption for incoming records. * cc the engine context * is_client non-zero for a client, zero for a server * prf_id id of hash function for PRF */ void br_ssl_engine_switch_chapol_in(br_ssl_engine_context *cc, int is_client, int prf_id); /* * Switch to ChaCha20+Poly1305 encryption for outgoing records. * cc the engine context * is_client non-zero for a client, zero for a server * prf_id id of hash function for PRF */ void br_ssl_engine_switch_chapol_out(br_ssl_engine_context *cc, int is_client, int prf_id); /* * Switch to CCM decryption for incoming records. * cc the engine context * is_client non-zero for a client, zero for a server * prf_id id of hash function for PRF * bc_impl block cipher implementation (CTR+CBC) * cipher_key_len block cipher key length (in bytes) * tag_len tag length (in bytes) */ void br_ssl_engine_switch_ccm_in(br_ssl_engine_context *cc, int is_client, int prf_id, const br_block_ctrcbc_class *bc_impl, size_t cipher_key_len, size_t tag_len); /* * Switch to GCM encryption for outgoing records. * cc the engine context * is_client non-zero for a client, zero for a server * prf_id id of hash function for PRF * bc_impl block cipher implementation (CTR+CBC) * cipher_key_len block cipher key length (in bytes) * tag_len tag length (in bytes) */ void br_ssl_engine_switch_ccm_out(br_ssl_engine_context *cc, int is_client, int prf_id, const br_block_ctrcbc_class *bc_impl, size_t cipher_key_len, size_t tag_len); /* * Calls to T0-generated code. */ void br_ssl_hs_client_init_main(void *ctx); void br_ssl_hs_client_run(void *ctx); void br_ssl_hs_server_init_main(void *ctx); void br_ssl_hs_server_run(void *ctx); /* * Get the hash function to use for signatures, given a bit mask of * supported hash functions. This implements a strict choice order * (namely SHA-256, SHA-384, SHA-512, SHA-224, SHA-1). If the mask * does not document support of any of these hash functions, then this * functions returns 0. */ int br_ssl_choose_hash(unsigned bf); /* ==================================================================== */ /* * PowerPC / POWER assembly stuff. The special BR_POWER_ASM_MACROS macro * must be defined before including this file; this is done by source * files that use some inline assembly for PowerPC / POWER machines. */ #if BR_POWER_ASM_MACROS #define lxvw4x(xt, ra, rb) lxvw4x_(xt, ra, rb) #define stxvw4x(xt, ra, rb) stxvw4x_(xt, ra, rb) #define bdnz(foo) bdnz_(foo) #define bdz(foo) bdz_(foo) #define beq(foo) beq_(foo) #define li(rx, value) li_(rx, value) #define addi(rx, ra, imm) addi_(rx, ra, imm) #define cmpldi(rx, imm) cmpldi_(rx, imm) #define mtctr(rx) mtctr_(rx) #define vspltb(vrt, vrb, uim) vspltb_(vrt, vrb, uim) #define vspltw(vrt, vrb, uim) vspltw_(vrt, vrb, uim) #define vspltisb(vrt, imm) vspltisb_(vrt, imm) #define vspltisw(vrt, imm) vspltisw_(vrt, imm) #define vrlw(vrt, vra, vrb) vrlw_(vrt, vra, vrb) #define vsbox(vrt, vra) vsbox_(vrt, vra) #define vxor(vrt, vra, vrb) vxor_(vrt, vra, vrb) #define vand(vrt, vra, vrb) vand_(vrt, vra, vrb) #define vsro(vrt, vra, vrb) vsro_(vrt, vra, vrb) #define vsl(vrt, vra, vrb) vsl_(vrt, vra, vrb) #define vsldoi(vt, va, vb, sh) vsldoi_(vt, va, vb, sh) #define vsr(vrt, vra, vrb) vsr_(vrt, vra, vrb) #define vaddcuw(vrt, vra, vrb) vaddcuw_(vrt, vra, vrb) #define vadduwm(vrt, vra, vrb) vadduwm_(vrt, vra, vrb) #define vsububm(vrt, vra, vrb) vsububm_(vrt, vra, vrb) #define vsubuwm(vrt, vra, vrb) vsubuwm_(vrt, vra, vrb) #define vsrw(vrt, vra, vrb) vsrw_(vrt, vra, vrb) #define vcipher(vt, va, vb) vcipher_(vt, va, vb) #define vcipherlast(vt, va, vb) vcipherlast_(vt, va, vb) #define vncipher(vt, va, vb) vncipher_(vt, va, vb) #define vncipherlast(vt, va, vb) vncipherlast_(vt, va, vb) #define vperm(vt, va, vb, vc) vperm_(vt, va, vb, vc) #define vpmsumd(vt, va, vb) vpmsumd_(vt, va, vb) #define xxpermdi(vt, va, vb, d) xxpermdi_(vt, va, vb, d) #define lxvw4x_(xt, ra, rb) "\tlxvw4x\t" #xt "," #ra "," #rb "\n" #define stxvw4x_(xt, ra, rb) "\tstxvw4x\t" #xt "," #ra "," #rb "\n" #define label(foo) #foo "%=:\n" #define bdnz_(foo) "\tbdnz\t" #foo "%=\n" #define bdz_(foo) "\tbdz\t" #foo "%=\n" #define beq_(foo) "\tbeq\t" #foo "%=\n" #define li_(rx, value) "\tli\t" #rx "," #value "\n" #define addi_(rx, ra, imm) "\taddi\t" #rx "," #ra "," #imm "\n" #define cmpldi_(rx, imm) "\tcmpldi\t" #rx "," #imm "\n" #define mtctr_(rx) "\tmtctr\t" #rx "\n" #define vspltb_(vrt, vrb, uim) "\tvspltb\t" #vrt "," #vrb "," #uim "\n" #define vspltw_(vrt, vrb, uim) "\tvspltw\t" #vrt "," #vrb "," #uim "\n" #define vspltisb_(vrt, imm) "\tvspltisb\t" #vrt "," #imm "\n" #define vspltisw_(vrt, imm) "\tvspltisw\t" #vrt "," #imm "\n" #define vrlw_(vrt, vra, vrb) "\tvrlw\t" #vrt "," #vra "," #vrb "\n" #define vsbox_(vrt, vra) "\tvsbox\t" #vrt "," #vra "\n" #define vxor_(vrt, vra, vrb) "\tvxor\t" #vrt "," #vra "," #vrb "\n" #define vand_(vrt, vra, vrb) "\tvand\t" #vrt "," #vra "," #vrb "\n" #define vsro_(vrt, vra, vrb) "\tvsro\t" #vrt "," #vra "," #vrb "\n" #define vsl_(vrt, vra, vrb) "\tvsl\t" #vrt "," #vra "," #vrb "\n" #define vsldoi_(vt, va, vb, sh) "\tvsldoi\t" #vt "," #va "," #vb "," #sh "\n" #define vsr_(vrt, vra, vrb) "\tvsr\t" #vrt "," #vra "," #vrb "\n" #define vaddcuw_(vrt, vra, vrb) "\tvaddcuw\t" #vrt "," #vra "," #vrb "\n" #define vadduwm_(vrt, vra, vrb) "\tvadduwm\t" #vrt "," #vra "," #vrb "\n" #define vsububm_(vrt, vra, vrb) "\tvsububm\t" #vrt "," #vra "," #vrb "\n" #define vsubuwm_(vrt, vra, vrb) "\tvsubuwm\t" #vrt "," #vra "," #vrb "\n" #define vsrw_(vrt, vra, vrb) "\tvsrw\t" #vrt "," #vra "," #vrb "\n" #define vcipher_(vt, va, vb) "\tvcipher\t" #vt "," #va "," #vb "\n" #define vcipherlast_(vt, va, vb) "\tvcipherlast\t" #vt "," #va "," #vb "\n" #define vncipher_(vt, va, vb) "\tvncipher\t" #vt "," #va "," #vb "\n" #define vncipherlast_(vt, va, vb) "\tvncipherlast\t" #vt "," #va "," #vb "\n" #define vperm_(vt, va, vb, vc) "\tvperm\t" #vt "," #va "," #vb "," #vc "\n" #define vpmsumd_(vt, va, vb) "\tvpmsumd\t" #vt "," #va "," #vb "\n" #define xxpermdi_(vt, va, vb, d) "\txxpermdi\t" #vt "," #va "," #vb "," #d "\n" #endif /* ==================================================================== */ /* * Special "activate intrinsics" code, needed for some compiler versions. * This is defined at the end of this file, so that it won't impact any * of the inline functions defined previously; and it is controlled by * a specific macro defined in the caller code. * * Calling code conventions: * * - Caller must define BR_ENABLE_INTRINSICS before including "inner.h". * - Functions that use intrinsics must be enclosed in an "enabled" * region (between BR_TARGETS_X86_UP and BR_TARGETS_X86_DOWN). * - Functions that use intrinsics must be tagged with the appropriate * BR_TARGET(). */ #if BR_ENABLE_INTRINSICS && (BR_GCC_4_4 || BR_CLANG_3_7 || BR_MSC_2005) /* * x86 intrinsics (both 32-bit and 64-bit). */ #if BR_i386 || BR_amd64 /* * On GCC before version 5.0, we need to use the pragma to enable the * target options globally, because the 'target' function attribute * appears to be unreliable. Before 4.6 we must also avoid the * push_options / pop_options mechanism, because it tends to trigger * some internal compiler errors. */ #if BR_GCC && !BR_GCC_5_0 #if BR_GCC_4_6 #define BR_TARGETS_X86_UP \ _Pragma("GCC push_options") \ _Pragma("GCC target(\"sse2,ssse3,sse4.1,aes,pclmul,rdrnd\")") #define BR_TARGETS_X86_DOWN \ _Pragma("GCC pop_options") #else #define BR_TARGETS_X86_UP \ _Pragma("GCC target(\"sse2,ssse3,sse4.1,aes,pclmul\")") #endif #define BR_TARGETS_X86_DOWN #pragma GCC diagnostic ignored "-Wpsabi" #endif #if BR_CLANG && !BR_CLANG_3_8 #undef __SSE2__ #undef __SSE3__ #undef __SSSE3__ #undef __SSE4_1__ #undef __AES__ #undef __PCLMUL__ #undef __RDRND__ #define __SSE2__ 1 #define __SSE3__ 1 #define __SSSE3__ 1 #define __SSE4_1__ 1 #define __AES__ 1 #define __PCLMUL__ 1 #define __RDRND__ 1 #endif #ifndef BR_TARGETS_X86_UP #define BR_TARGETS_X86_UP #endif #ifndef BR_TARGETS_X86_DOWN #define BR_TARGETS_X86_DOWN #endif #if BR_GCC || BR_CLANG BR_TARGETS_X86_UP #include #include #define br_bswap32 __builtin_bswap32 BR_TARGETS_X86_DOWN #endif #if BR_MSC #include #include #include #define br_bswap32 _byteswap_ulong #endif static inline int br_cpuid(uint32_t mask_eax, uint32_t mask_ebx, uint32_t mask_ecx, uint32_t mask_edx) { #if BR_GCC || BR_CLANG unsigned eax, ebx, ecx, edx; if (__get_cpuid(1, &eax, &ebx, &ecx, &edx)) { if ((eax & mask_eax) == mask_eax && (ebx & mask_ebx) == mask_ebx && (ecx & mask_ecx) == mask_ecx && (edx & mask_edx) == mask_edx) { return 1; } } #elif BR_MSC int info[4]; __cpuid(info, 1); if (((uint32_t)info[0] & mask_eax) == mask_eax && ((uint32_t)info[1] & mask_ebx) == mask_ebx && ((uint32_t)info[2] & mask_ecx) == mask_ecx && ((uint32_t)info[3] & mask_edx) == mask_edx) { return 1; } #endif return 0; } #endif #endif /* ==================================================================== */ #endif