A library for setting up Secure Socket Layer (SSL) connections and verifying remote hosts using certificates. Contains only the source files for mbed platform implementation of the library.
Dependents: HTTPClient-SSL HTTPClient-SSL HTTPClient-SSL HTTPClient-SSL
cyassl/ctaocrypt/tfm.h
- Committer:
- Vanger
- Date:
- 2015-01-19
- Revision:
- 0:b86d15c6ba29
File content as of revision 0:b86d15c6ba29:
/* tfm.h * * Copyright (C) 2006-2014 wolfSSL Inc. * * This file is part of CyaSSL. * * CyaSSL 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 2 of the License, or * (at your option) any later version. * * CyaSSL 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 02110-1301, USA */ /* * Based on public domain TomsFastMath 0.10 by Tom St Denis, tomstdenis@iahu.ca, * http://math.libtomcrypt.com */ /** * Edited by Moisés Guimarães (moises.guimaraes@phoebus.com.br) * to fit CyaSSL's needs. */ #ifndef CTAO_CRYPT_TFM_H #define CTAO_CRYPT_TFM_H #include <cyassl/ctaocrypt/types.h> #ifndef CHAR_BIT #include <limits.h> #endif #ifdef __cplusplus extern "C" { #endif #ifndef MIN #define MIN(x,y) ((x)<(y)?(x):(y)) #endif #ifndef MAX #define MAX(x,y) ((x)>(y)?(x):(y)) #endif #ifndef NO_64BIT /* autodetect x86-64 and make sure we are using 64-bit digits with x86-64 asm */ #if defined(__x86_64__) #if defined(TFM_X86) || defined(TFM_SSE2) || defined(TFM_ARM) #error x86-64 detected, x86-32/SSE2/ARM optimizations are not valid! #endif #if !defined(TFM_X86_64) && !defined(TFM_NO_ASM) #define TFM_X86_64 #endif #endif #if defined(TFM_X86_64) #if !defined(FP_64BIT) #define FP_64BIT #endif #endif /* use 64-bit digit even if not using asm on x86_64 */ #if defined(__x86_64__) && !defined(FP_64BIT) #define FP_64BIT #endif /* if intel compiler doesn't provide 128 bit type don't turn on 64bit */ #if defined(FP_64BIT) && defined(__INTEL_COMPILER) && !defined(HAVE___UINT128_T) #undef FP_64BIT #undef TFM_X86_64 #endif #endif /* NO_64BIT */ /* try to detect x86-32 */ #if defined(__i386__) && !defined(TFM_SSE2) #if defined(TFM_X86_64) || defined(TFM_ARM) #error x86-32 detected, x86-64/ARM optimizations are not valid! #endif #if !defined(TFM_X86) && !defined(TFM_NO_ASM) #define TFM_X86 #endif #endif /* make sure we're 32-bit for x86-32/sse/arm/ppc32 */ #if (defined(TFM_X86) || defined(TFM_SSE2) || defined(TFM_ARM) || defined(TFM_PPC32)) && defined(FP_64BIT) #warning x86-32, SSE2 and ARM, PPC32 optimizations require 32-bit digits (undefining) #undef FP_64BIT #endif /* multi asms? */ #ifdef TFM_X86 #define TFM_ASM #endif #ifdef TFM_X86_64 #ifdef TFM_ASM #error TFM_ASM already defined! #endif #define TFM_ASM #endif #ifdef TFM_SSE2 #ifdef TFM_ASM #error TFM_ASM already defined! #endif #define TFM_ASM #endif #ifdef TFM_ARM #ifdef TFM_ASM #error TFM_ASM already defined! #endif #define TFM_ASM #endif #ifdef TFM_PPC32 #ifdef TFM_ASM #error TFM_ASM already defined! #endif #define TFM_ASM #endif #ifdef TFM_PPC64 #ifdef TFM_ASM #error TFM_ASM already defined! #endif #define TFM_ASM #endif #ifdef TFM_AVR32 #ifdef TFM_ASM #error TFM_ASM already defined! #endif #define TFM_ASM #endif /* we want no asm? */ #ifdef TFM_NO_ASM #undef TFM_X86 #undef TFM_X86_64 #undef TFM_SSE2 #undef TFM_ARM #undef TFM_PPC32 #undef TFM_PPC64 #undef TFM_AVR32 #undef TFM_ASM #endif /* ECC helpers */ #ifdef TFM_ECC192 #ifdef FP_64BIT #define TFM_MUL3 #define TFM_SQR3 #else #define TFM_MUL6 #define TFM_SQR6 #endif #endif #ifdef TFM_ECC224 #ifdef FP_64BIT #define TFM_MUL4 #define TFM_SQR4 #else #define TFM_MUL7 #define TFM_SQR7 #endif #endif #ifdef TFM_ECC256 #ifdef FP_64BIT #define TFM_MUL4 #define TFM_SQR4 #else #define TFM_MUL8 #define TFM_SQR8 #endif #endif #ifdef TFM_ECC384 #ifdef FP_64BIT #define TFM_MUL6 #define TFM_SQR6 #else #define TFM_MUL12 #define TFM_SQR12 #endif #endif #ifdef TFM_ECC521 #ifdef FP_64BIT #define TFM_MUL9 #define TFM_SQR9 #else #define TFM_MUL17 #define TFM_SQR17 #endif #endif /* some default configurations. */ #if defined(FP_64BIT) /* for GCC only on supported platforms */ typedef unsigned long long fp_digit; /* 64bit, 128 uses mode(TI) below */ typedef unsigned long fp_word __attribute__ ((mode(TI))); #else #if defined(_MSC_VER) || defined(__BORLANDC__) typedef unsigned __int64 ulong64; #else typedef unsigned long long ulong64; #endif #ifndef NO_64BIT typedef unsigned int fp_digit; typedef ulong64 fp_word; #define FP_32BIT #else /* some procs like coldfire prefer not to place multiply into 64bit type even though it exists */ typedef unsigned short fp_digit; typedef unsigned int fp_word; #endif #endif /* # of digits this is */ #define DIGIT_BIT (int)((CHAR_BIT) * sizeof(fp_digit)) /* Max size of any number in bits. Basically the largest size you will be * multiplying should be half [or smaller] of FP_MAX_SIZE-four_digit * * It defaults to 4096-bits [allowing multiplications upto 2048x2048 bits ] */ #ifndef FP_MAX_BITS #define FP_MAX_BITS 4096 #endif #define FP_MAX_SIZE (FP_MAX_BITS+(8*DIGIT_BIT)) /* will this lib work? */ #if (CHAR_BIT & 7) #error CHAR_BIT must be a multiple of eight. #endif #if FP_MAX_BITS % CHAR_BIT #error FP_MAX_BITS must be a multiple of CHAR_BIT #endif #define FP_MASK (fp_digit)(-1) #define FP_SIZE (FP_MAX_SIZE/DIGIT_BIT) /* signs */ #define FP_ZPOS 0 #define FP_NEG 1 /* return codes */ #define FP_OKAY 0 #define FP_VAL 1 #define FP_MEM 2 /* equalities */ #define FP_LT -1 /* less than */ #define FP_EQ 0 /* equal to */ #define FP_GT 1 /* greater than */ /* replies */ #define FP_YES 1 /* yes response */ #define FP_NO 0 /* no response */ /* a FP type */ typedef struct { fp_digit dp[FP_SIZE]; int used, sign; } fp_int; /* externally define this symbol to ignore the default settings, useful for changing the build from the make process */ #ifndef TFM_ALREADY_SET /* do we want the large set of small multiplications ? Enable these if you are going to be doing a lot of small (<= 16 digit) multiplications say in ECC Or if you're on a 64-bit machine doing RSA as a 1024-bit integer == 16 digits ;-) */ /* need to refactor the function */ /*#define TFM_SMALL_SET */ /* do we want huge code Enable these if you are doing 20, 24, 28, 32, 48, 64 digit multiplications (useful for RSA) Less important on 64-bit machines as 32 digits == 2048 bits */ #if 0 #define TFM_MUL3 #define TFM_MUL4 #define TFM_MUL6 #define TFM_MUL7 #define TFM_MUL8 #define TFM_MUL9 #define TFM_MUL12 #define TFM_MUL17 #endif #ifdef TFM_HUGE_SET #define TFM_MUL20 #define TFM_MUL24 #define TFM_MUL28 #define TFM_MUL32 #if (FP_MAX_BITS >= 6144) && defined(FP_64BIT) #define TFM_MUL48 #endif #if (FP_MAX_BITS >= 8192) && defined(FP_64BIT) #define TFM_MUL64 #endif #endif #if 0 #define TFM_SQR3 #define TFM_SQR4 #define TFM_SQR6 #define TFM_SQR7 #define TFM_SQR8 #define TFM_SQR9 #define TFM_SQR12 #define TFM_SQR17 #endif #ifdef TFM_HUGE_SET #define TFM_SQR20 #define TFM_SQR24 #define TFM_SQR28 #define TFM_SQR32 #define TFM_SQR48 #define TFM_SQR64 #endif /* do we want some overflow checks Not required if you make sure your numbers are within range (e.g. by default a modulus for fp_exptmod() can only be upto 2048 bits long) */ /* #define TFM_CHECK */ /* Is the target a P4 Prescott */ /* #define TFM_PRESCOTT */ /* Do we want timing resistant fp_exptmod() ? * This makes it slower but also timing invariant with respect to the exponent */ /* #define TFM_TIMING_RESISTANT */ #endif /* TFM_ALREADY_SET */ /* functions */ /* returns a TFM ident string useful for debugging... */ /*const char *fp_ident(void);*/ /* initialize [or zero] an fp int */ #define fp_init(a) (void)XMEMSET((a), 0, sizeof(fp_int)) #define fp_zero(a) fp_init(a) /* zero/even/odd ? */ #define fp_iszero(a) (((a)->used == 0) ? FP_YES : FP_NO) #define fp_iseven(a) (((a)->used >= 0 && (((a)->dp[0] & 1) == 0)) ? FP_YES : FP_NO) #define fp_isodd(a) (((a)->used > 0 && (((a)->dp[0] & 1) == 1)) ? FP_YES : FP_NO) /* set to a small digit */ void fp_set(fp_int *a, fp_digit b); /* copy from a to b */ #define fp_copy(a, b) (void)(((a) != (b)) ? ((void)XMEMCPY((b), (a), sizeof(fp_int))) : (void)0) #define fp_init_copy(a, b) fp_copy(b, a) /* clamp digits */ #define fp_clamp(a) { while ((a)->used && (a)->dp[(a)->used-1] == 0) --((a)->used); (a)->sign = (a)->used ? (a)->sign : FP_ZPOS; } /* negate and absolute */ #define fp_neg(a, b) { fp_copy(a, b); (b)->sign ^= 1; fp_clamp(b); } #define fp_abs(a, b) { fp_copy(a, b); (b)->sign = 0; } /* right shift x digits */ void fp_rshd(fp_int *a, int x); /* right shift x bits */ void fp_rshb(fp_int *a, int x); /* left shift x digits */ void fp_lshd(fp_int *a, int x); /* signed comparison */ int fp_cmp(fp_int *a, fp_int *b); /* unsigned comparison */ int fp_cmp_mag(fp_int *a, fp_int *b); /* power of 2 operations */ void fp_div_2d(fp_int *a, int b, fp_int *c, fp_int *d); void fp_mod_2d(fp_int *a, int b, fp_int *c); void fp_mul_2d(fp_int *a, int b, fp_int *c); void fp_2expt (fp_int *a, int b); void fp_mul_2(fp_int *a, fp_int *c); void fp_div_2(fp_int *a, fp_int *c); /* Counts the number of lsbs which are zero before the first zero bit */ int fp_cnt_lsb(fp_int *a); /* c = a + b */ void fp_add(fp_int *a, fp_int *b, fp_int *c); /* c = a - b */ void fp_sub(fp_int *a, fp_int *b, fp_int *c); /* c = a * b */ void fp_mul(fp_int *a, fp_int *b, fp_int *c); /* b = a*a */ void fp_sqr(fp_int *a, fp_int *b); /* a/b => cb + d == a */ int fp_div(fp_int *a, fp_int *b, fp_int *c, fp_int *d); /* c = a mod b, 0 <= c < b */ int fp_mod(fp_int *a, fp_int *b, fp_int *c); /* compare against a single digit */ int fp_cmp_d(fp_int *a, fp_digit b); /* c = a + b */ void fp_add_d(fp_int *a, fp_digit b, fp_int *c); /* c = a - b */ void fp_sub_d(fp_int *a, fp_digit b, fp_int *c); /* c = a * b */ void fp_mul_d(fp_int *a, fp_digit b, fp_int *c); /* a/b => cb + d == a */ /*int fp_div_d(fp_int *a, fp_digit b, fp_int *c, fp_digit *d);*/ /* c = a mod b, 0 <= c < b */ /*int fp_mod_d(fp_int *a, fp_digit b, fp_digit *c);*/ /* ---> number theory <--- */ /* d = a + b (mod c) */ /*int fp_addmod(fp_int *a, fp_int *b, fp_int *c, fp_int *d);*/ /* d = a - b (mod c) */ /*int fp_submod(fp_int *a, fp_int *b, fp_int *c, fp_int *d);*/ /* d = a * b (mod c) */ int fp_mulmod(fp_int *a, fp_int *b, fp_int *c, fp_int *d); /* c = a * a (mod b) */ int fp_sqrmod(fp_int *a, fp_int *b, fp_int *c); /* c = 1/a (mod b) */ int fp_invmod(fp_int *a, fp_int *b, fp_int *c); /* c = (a, b) */ /*void fp_gcd(fp_int *a, fp_int *b, fp_int *c);*/ /* c = [a, b] */ /*void fp_lcm(fp_int *a, fp_int *b, fp_int *c);*/ /* setups the montgomery reduction */ int fp_montgomery_setup(fp_int *a, fp_digit *mp); /* computes a = B**n mod b without division or multiplication useful for * normalizing numbers in a Montgomery system. */ void fp_montgomery_calc_normalization(fp_int *a, fp_int *b); /* computes x/R == x (mod N) via Montgomery Reduction */ void fp_montgomery_reduce(fp_int *a, fp_int *m, fp_digit mp); /* d = a**b (mod c) */ int fp_exptmod(fp_int *a, fp_int *b, fp_int *c, fp_int *d); /* primality stuff */ /* perform a Miller-Rabin test of a to the base b and store result in "result" */ /*void fp_prime_miller_rabin (fp_int * a, fp_int * b, int *result);*/ /* 256 trial divisions + 8 Miller-Rabins, returns FP_YES if probable prime */ /*int fp_isprime(fp_int *a);*/ /* Primality generation flags */ /*#define TFM_PRIME_BBS 0x0001 */ /* BBS style prime */ /*#define TFM_PRIME_SAFE 0x0002 */ /* Safe prime (p-1)/2 == prime */ /*#define TFM_PRIME_2MSB_OFF 0x0004 */ /* force 2nd MSB to 0 */ /*#define TFM_PRIME_2MSB_ON 0x0008 */ /* force 2nd MSB to 1 */ /* callback for fp_prime_random, should fill dst with random bytes and return how many read [upto len] */ /*typedef int tfm_prime_callback(unsigned char *dst, int len, void *dat);*/ /*#define fp_prime_random(a, t, size, bbs, cb, dat) fp_prime_random_ex(a, t, ((size) * 8) + 1, (bbs==1)?TFM_PRIME_BBS:0, cb, dat)*/ /*int fp_prime_random_ex(fp_int *a, int t, int size, int flags, tfm_prime_callback cb, void *dat);*/ /* radix conersions */ int fp_count_bits(fp_int *a); int fp_leading_bit(fp_int *a); int fp_unsigned_bin_size(fp_int *a); void fp_read_unsigned_bin(fp_int *a, unsigned char *b, int c); void fp_to_unsigned_bin(fp_int *a, unsigned char *b); /*int fp_signed_bin_size(fp_int *a);*/ /*void fp_read_signed_bin(fp_int *a, unsigned char *b, int c);*/ /*void fp_to_signed_bin(fp_int *a, unsigned char *b);*/ /*int fp_read_radix(fp_int *a, char *str, int radix);*/ /*int fp_toradix(fp_int *a, char *str, int radix);*/ /*int fp_toradix_n(fp_int * a, char *str, int radix, int maxlen);*/ /* VARIOUS LOW LEVEL STUFFS */ void s_fp_add(fp_int *a, fp_int *b, fp_int *c); void s_fp_sub(fp_int *a, fp_int *b, fp_int *c); void fp_reverse(unsigned char *s, int len); void fp_mul_comba(fp_int *a, fp_int *b, fp_int *c); #ifdef TFM_SMALL_SET void fp_mul_comba_small(fp_int *a, fp_int *b, fp_int *c); #endif #ifdef TFM_MUL3 void fp_mul_comba3(fp_int *a, fp_int *b, fp_int *c); #endif #ifdef TFM_MUL4 void fp_mul_comba4(fp_int *a, fp_int *b, fp_int *c); #endif #ifdef TFM_MUL6 void fp_mul_comba6(fp_int *a, fp_int *b, fp_int *c); #endif #ifdef TFM_MUL7 void fp_mul_comba7(fp_int *a, fp_int *b, fp_int *c); #endif #ifdef TFM_MUL8 void fp_mul_comba8(fp_int *a, fp_int *b, fp_int *c); #endif #ifdef TFM_MUL9 void fp_mul_comba9(fp_int *a, fp_int *b, fp_int *c); #endif #ifdef TFM_MUL12 void fp_mul_comba12(fp_int *a, fp_int *b, fp_int *c); #endif #ifdef TFM_MUL17 void fp_mul_comba17(fp_int *a, fp_int *b, fp_int *c); #endif #ifdef TFM_MUL20 void fp_mul_comba20(fp_int *a, fp_int *b, fp_int *c); #endif #ifdef TFM_MUL24 void fp_mul_comba24(fp_int *a, fp_int *b, fp_int *c); #endif #ifdef TFM_MUL28 void fp_mul_comba28(fp_int *a, fp_int *b, fp_int *c); #endif #ifdef TFM_MUL32 void fp_mul_comba32(fp_int *a, fp_int *b, fp_int *c); #endif #ifdef TFM_MUL48 void fp_mul_comba48(fp_int *a, fp_int *b, fp_int *c); #endif #ifdef TFM_MUL64 void fp_mul_comba64(fp_int *a, fp_int *b, fp_int *c); #endif void fp_sqr_comba(fp_int *a, fp_int *b); #ifdef TFM_SMALL_SET void fp_sqr_comba_small(fp_int *a, fp_int *b); #endif #ifdef TFM_SQR3 void fp_sqr_comba3(fp_int *a, fp_int *b); #endif #ifdef TFM_SQR4 void fp_sqr_comba4(fp_int *a, fp_int *b); #endif #ifdef TFM_SQR6 void fp_sqr_comba6(fp_int *a, fp_int *b); #endif #ifdef TFM_SQR7 void fp_sqr_comba7(fp_int *a, fp_int *b); #endif #ifdef TFM_SQR8 void fp_sqr_comba8(fp_int *a, fp_int *b); #endif #ifdef TFM_SQR9 void fp_sqr_comba9(fp_int *a, fp_int *b); #endif #ifdef TFM_SQR12 void fp_sqr_comba12(fp_int *a, fp_int *b); #endif #ifdef TFM_SQR17 void fp_sqr_comba17(fp_int *a, fp_int *b); #endif #ifdef TFM_SQR20 void fp_sqr_comba20(fp_int *a, fp_int *b); #endif #ifdef TFM_SQR24 void fp_sqr_comba24(fp_int *a, fp_int *b); #endif #ifdef TFM_SQR28 void fp_sqr_comba28(fp_int *a, fp_int *b); #endif #ifdef TFM_SQR32 void fp_sqr_comba32(fp_int *a, fp_int *b); #endif #ifdef TFM_SQR48 void fp_sqr_comba48(fp_int *a, fp_int *b); #endif #ifdef TFM_SQR64 void fp_sqr_comba64(fp_int *a, fp_int *b); #endif /*extern const char *fp_s_rmap;*/ /** * Used by CyaSSL */ /* Types */ typedef fp_digit mp_digit; typedef fp_word mp_word; typedef fp_int mp_int; /* Constants */ #define MP_LT FP_LT /* less than */ #define MP_EQ FP_EQ /* equal to */ #define MP_GT FP_GT /* greater than */ #define MP_VAL FP_VAL /* invalid */ #define MP_OKAY FP_OKAY /* ok result */ #define MP_NO FP_NO /* yes/no result */ #define MP_YES FP_YES /* yes/no result */ /* Prototypes */ #define mp_zero(a) fp_zero(a) #define mp_iseven(a) fp_iseven(a) int mp_init (mp_int * a); void mp_clear (mp_int * a); int mp_init_multi(mp_int* a, mp_int* b, mp_int* c, mp_int* d, mp_int* e, mp_int* f); int mp_add (mp_int * a, mp_int * b, mp_int * c); int mp_sub (mp_int * a, mp_int * b, mp_int * c); int mp_add_d (mp_int * a, mp_digit b, mp_int * c); int mp_mul (mp_int * a, mp_int * b, mp_int * c); int mp_mulmod (mp_int * a, mp_int * b, mp_int * c, mp_int * d); int mp_mod(mp_int *a, mp_int *b, mp_int *c); int mp_invmod(mp_int *a, mp_int *b, mp_int *c); int mp_exptmod (mp_int * g, mp_int * x, mp_int * p, mp_int * y); int mp_cmp(mp_int *a, mp_int *b); int mp_cmp_d(mp_int *a, mp_digit b); int mp_unsigned_bin_size(mp_int * a); int mp_read_unsigned_bin (mp_int * a, const unsigned char *b, int c); int mp_to_unsigned_bin (mp_int * a, unsigned char *b); int mp_sub_d(fp_int *a, fp_digit b, fp_int *c); int mp_copy(fp_int* a, fp_int* b); int mp_isodd(mp_int* a); int mp_iszero(mp_int* a); int mp_count_bits(mp_int *a); int mp_leading_bit(mp_int *a); int mp_set_int(fp_int *a, fp_digit b); void mp_rshb(mp_int *a, int x); #ifdef HAVE_ECC int mp_read_radix(mp_int* a, const char* str, int radix); int mp_set(fp_int *a, fp_digit b); int mp_sqr(fp_int *a, fp_int *b); int mp_montgomery_reduce(fp_int *a, fp_int *m, fp_digit mp); int mp_montgomery_setup(fp_int *a, fp_digit *rho); int mp_div_2(fp_int * a, fp_int * b); int mp_init_copy(fp_int * a, fp_int * b); #endif #if defined(HAVE_ECC) || defined(CYASSL_KEY_GEN) int mp_sqrmod(mp_int* a, mp_int* b, mp_int* c); int mp_montgomery_calc_normalization(mp_int *a, mp_int *b); #endif #ifdef CYASSL_KEY_GEN int mp_gcd(fp_int *a, fp_int *b, fp_int *c); int mp_lcm(fp_int *a, fp_int *b, fp_int *c); int mp_prime_is_prime(mp_int* a, int t, int* result); #endif /* CYASSL_KEY_GEN */ int mp_cnt_lsb(fp_int *a); int mp_div_2d(fp_int *a, int b, fp_int *c, fp_int *d); int mp_mod_d(fp_int* a, fp_digit b, fp_digit* c); CYASSL_API word32 CheckRunTimeFastMath(void); /* If user uses RSA, DH, DSA, or ECC math lib directly then fast math FP_SIZE must match, return 1 if a match otherwise 0 */ #define CheckFastMathSettings() (FP_SIZE == CheckRunTimeFastMath()) #ifdef __cplusplus } #endif #endif /* CTAO_CRYPT_TFM_H */