/* Name: imath.c Purpose: Arbitrary precision integer arithmetic routines. Author: M. J. Fromberger Copyright (C) 2002-2007 Michael J. Fromberger, All Rights Reserved. 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. */ #include "imath.h" #if DEBUG #include #endif #include #include #include #include #if DEBUG #define STATIC /* public */ #else #define STATIC static #endif const mp_result MP_OK = 0; /* no error, all is well */ const mp_result MP_FALSE = 0; /* boolean false */ const mp_result MP_TRUE = -1; /* boolean true */ const mp_result MP_MEMORY = -2; /* out of memory */ const mp_result MP_RANGE = -3; /* argument out of range */ const mp_result MP_UNDEF = -4; /* result undefined */ const mp_result MP_TRUNC = -5; /* output truncated */ const mp_result MP_BADARG = -6; /* invalid null argument */ const mp_result MP_MINERR = -6; const mp_sign MP_NEG = 1; /* value is strictly negative */ const mp_sign MP_ZPOS = 0; /* value is non-negative */ STATIC const char *s_unknown_err = "unknown result code"; STATIC const char *s_error_msg[] = { "error code 0", "boolean true", "out of memory", "argument out of range", "result undefined", "output truncated", "invalid argument", NULL }; /* Argument checking macros Use CHECK() where a return value is required; NRCHECK() elsewhere */ #define CHECK(TEST) assert(TEST) #define NRCHECK(TEST) assert(TEST) /* The ith entry of this table gives the value of log_i(2). An integer value n requires ceil(log_i(n)) digits to be represented in base i. Since it is easy to compute lg(n), by counting bits, we can compute log_i(n) = lg(n) * log_i(2). The use of this table eliminates a dependency upon linkage against the standard math libraries. If MP_MAX_RADIX is increased, this table should be expanded too. */ STATIC const double s_log2[] = { 0.000000000, 0.000000000, 1.000000000, 0.630929754, /* (D)(D) 2 3 */ 0.500000000, 0.430676558, 0.386852807, 0.356207187, /* 4 5 6 7 */ 0.333333333, 0.315464877, 0.301029996, 0.289064826, /* 8 9 10 11 */ 0.278942946, 0.270238154, 0.262649535, 0.255958025, /* 12 13 14 15 */ 0.250000000, 0.244650542, 0.239812467, 0.235408913, /* 16 17 18 19 */ 0.231378213, 0.227670249, 0.224243824, 0.221064729, /* 20 21 22 23 */ 0.218104292, 0.215338279, 0.212746054, 0.210309918, /* 24 25 26 27 */ 0.208014598, 0.205846832, 0.203795047, 0.201849087, /* 28 29 30 31 */ 0.200000000, 0.198239863, 0.196561632, 0.194959022, /* 32 33 34 35 */ 0.193426404, /* 36 */ }; /* Return the number of digits needed to represent a static value */ #define MP_VALUE_DIGITS(V) \ ((sizeof(V)+(sizeof(mp_digit)-1))/sizeof(mp_digit)) /* Round precision P to nearest word boundary */ #define ROUND_PREC(P) ((mp_size)(2*(((P)+1)/2))) /* Set array P of S digits to zero */ #define ZERO(P, S) \ do{ \ mp_size i__ = (S) * sizeof(mp_digit); \ mp_digit *p__ = (P); \ memset(p__, 0, i__); \ } while(0) /* Copy S digits from array P to array Q */ #define COPY(P, Q, S) \ do{ \ mp_size i__ = (S) * sizeof(mp_digit); \ mp_digit *p__ = (P), *q__ = (Q); \ memcpy(q__, p__, i__); \ } while(0) /* Reverse N elements of type T in array A */ #define REV(T, A, N) \ do{ \ T *u_ = (A), *v_ = u_ + (N) - 1; \ while (u_ < v_) { \ T xch = *u_; \ *u_++ = *v_; \ *v_-- = xch; \ } \ } while(0) #define CLAMP(Z) \ do{ \ mp_int z_ = (Z); \ mp_size uz_ = MP_USED(z_); \ mp_digit *dz_ = MP_DIGITS(z_) + uz_ -1; \ while (uz_ > 1 && (*dz_-- == 0)) \ --uz_; \ MP_USED(z_) = uz_; \ } while(0) /* Select min/max. Do not provide expressions for which multiple evaluation would be problematic, e.g. x++ */ #define MIN(A, B) ((B)<(A)?(B):(A)) #define MAX(A, B) ((B)>(A)?(B):(A)) /* Exchange lvalues A and B of type T, e.g. SWAP(int, x, y) where x and y are variables of type int. */ #define SWAP(T, A, B) \ do{ \ T t_ = (A); \ A = (B); \ B = t_; \ } while(0) /* Used to set up and access simple temp stacks within functions. */ #define DECLARE_TEMP(N) \ mpz_t temp[(N)]; \ int last__ = 0 #define CLEANUP_TEMP() \ CLEANUP: \ while (--last__ >= 0) \ mp_int_clear(TEMP(last__)) #define TEMP(K) (temp + (K)) #define LAST_TEMP() TEMP(last__) #define SETUP(E) \ do{ \ if ((res = (E)) != MP_OK) \ goto CLEANUP; \ ++(last__); \ } while(0) /* Compare value to zero. */ #define CMPZ(Z) \ (((Z)->used==1&&(Z)->digits[0]==0)?0:((Z)->sign==MP_NEG)?-1:1) /* Multiply X by Y into Z, ignoring signs. Requires that Z have enough storage preallocated to hold the result. */ #define UMUL(X, Y, Z) \ do{ \ mp_size ua_ = MP_USED(X), ub_ = MP_USED(Y); \ mp_size o_ = ua_ + ub_; \ ZERO(MP_DIGITS(Z), o_); \ (void) s_kmul(MP_DIGITS(X), MP_DIGITS(Y), MP_DIGITS(Z), ua_, ub_); \ MP_USED(Z) = o_; \ CLAMP(Z); \ } while(0) /* Square X into Z. Requires that Z have enough storage to hold the result. */ #define USQR(X, Z) \ do{ \ mp_size ua_ = MP_USED(X), o_ = ua_ + ua_; \ ZERO(MP_DIGITS(Z), o_); \ (void) s_ksqr(MP_DIGITS(X), MP_DIGITS(Z), ua_); \ MP_USED(Z) = o_; \ CLAMP(Z); \ } while(0) #define UPPER_HALF(W) ((mp_word)((W) >> MP_DIGIT_BIT)) #define LOWER_HALF(W) ((mp_digit)(W)) #define HIGH_BIT_SET(W) ((W) >> (MP_WORD_BIT - 1)) #define ADD_WILL_OVERFLOW(W, V) ((MP_WORD_MAX - (V)) < (W)) /* Default number of digits allocated to a new mp_int */ #if IMATH_TEST mp_size default_precision = MP_DEFAULT_PREC; #else STATIC const mp_size default_precision = MP_DEFAULT_PREC; #endif /* Minimum number of digits to invoke recursive multiply */ #if IMATH_TEST mp_size multiply_threshold = MP_MULT_THRESH; #else STATIC const mp_size multiply_threshold = MP_MULT_THRESH; #endif /* Allocate a buffer of (at least) num digits, or return NULL if that couldn't be done. */ STATIC mp_digit *s_alloc(mp_size num); /* Release a buffer of digits allocated by s_alloc(). */ STATIC void s_free(void *ptr); /* Insure that z has at least min digits allocated, resizing if necessary. Returns true if successful, false if out of memory. */ STATIC int s_pad(mp_int z, mp_size min); /* Fill in a "fake" mp_int on the stack with a given value */ STATIC void s_fake(mp_int z, mp_small value, mp_digit vbuf[]); STATIC void s_ufake(mp_int z, mp_usmall value, mp_digit vbuf[]); /* Compare two runs of digits of given length, returns <0, 0, >0 */ STATIC int s_cdig(mp_digit *da, mp_digit *db, mp_size len); /* Pack the unsigned digits of v into array t */ STATIC int s_uvpack(mp_usmall v, mp_digit t[]); /* Compare magnitudes of a and b, returns <0, 0, >0 */ STATIC int s_ucmp(mp_int a, mp_int b); /* Compare magnitudes of a and v, returns <0, 0, >0 */ STATIC int s_vcmp(mp_int a, mp_small v); STATIC int s_uvcmp(mp_int a, mp_usmall uv); /* Unsigned magnitude addition; assumes dc is big enough. Carry out is returned (no memory allocated). */ STATIC mp_digit s_uadd(mp_digit *da, mp_digit *db, mp_digit *dc, mp_size size_a, mp_size size_b); /* Unsigned magnitude subtraction. Assumes dc is big enough. */ STATIC void s_usub(mp_digit *da, mp_digit *db, mp_digit *dc, mp_size size_a, mp_size size_b); /* Unsigned recursive multiplication. Assumes dc is big enough. */ STATIC int s_kmul(mp_digit *da, mp_digit *db, mp_digit *dc, mp_size size_a, mp_size size_b); /* Unsigned magnitude multiplication. Assumes dc is big enough. */ STATIC void s_umul(mp_digit *da, mp_digit *db, mp_digit *dc, mp_size size_a, mp_size size_b); /* Unsigned recursive squaring. Assumes dc is big enough. */ STATIC int s_ksqr(mp_digit *da, mp_digit *dc, mp_size size_a); /* Unsigned magnitude squaring. Assumes dc is big enough. */ STATIC void s_usqr(mp_digit *da, mp_digit *dc, mp_size size_a); /* Single digit addition. Assumes a is big enough. */ STATIC void s_dadd(mp_int a, mp_digit b); /* Single digit multiplication. Assumes a is big enough. */ STATIC void s_dmul(mp_int a, mp_digit b); /* Single digit multiplication on buffers; assumes dc is big enough. */ STATIC void s_dbmul(mp_digit *da, mp_digit b, mp_digit *dc, mp_size size_a); /* Single digit division. Replaces a with the quotient, returns the remainder. */ STATIC mp_digit s_ddiv(mp_int a, mp_digit b); /* Quick division by a power of 2, replaces z (no allocation) */ STATIC void s_qdiv(mp_int z, mp_size p2); /* Quick remainder by a power of 2, replaces z (no allocation) */ STATIC void s_qmod(mp_int z, mp_size p2); /* Quick multiplication by a power of 2, replaces z. Allocates if necessary; returns false in case this fails. */ STATIC int s_qmul(mp_int z, mp_size p2); /* Quick subtraction from a power of 2, replaces z. Allocates if necessary; returns false in case this fails. */ STATIC int s_qsub(mp_int z, mp_size p2); /* Return maximum k such that 2^k divides z. */ STATIC int s_dp2k(mp_int z); /* Return k >= 0 such that z = 2^k, or -1 if there is no such k. */ STATIC int s_isp2(mp_int z); /* Set z to 2^k. May allocate; returns false in case this fails. */ STATIC int s_2expt(mp_int z, mp_small k); /* Normalize a and b for division, returns normalization constant */ STATIC int s_norm(mp_int a, mp_int b); /* Compute constant mu for Barrett reduction, given modulus m, result replaces z, m is untouched. */ STATIC mp_result s_brmu(mp_int z, mp_int m); /* Reduce a modulo m, using Barrett's algorithm. */ STATIC int s_reduce(mp_int x, mp_int m, mp_int mu, mp_int q1, mp_int q2); /* Modular exponentiation, using Barrett reduction */ STATIC mp_result s_embar(mp_int a, mp_int b, mp_int m, mp_int mu, mp_int c); /* Unsigned magnitude division. Assumes |a| > |b|. Allocates temporaries; overwrites a with quotient, b with remainder. */ STATIC mp_result s_udiv_knuth(mp_int a, mp_int b); /* Compute the number of digits in radix r required to represent the given value. Does not account for sign flags, terminators, etc. */ STATIC int s_outlen(mp_int z, mp_size r); /* Guess how many digits of precision will be needed to represent a radix r value of the specified number of digits. Returns a value guaranteed to be no smaller than the actual number required. */ STATIC mp_size s_inlen(int len, mp_size r); /* Convert a character to a digit value in radix r, or -1 if out of range */ STATIC int s_ch2val(char c, int r); /* Convert a digit value to a character */ STATIC char s_val2ch(int v, int caps); /* Take 2's complement of a buffer in place */ STATIC void s_2comp(unsigned char *buf, int len); /* Convert a value to binary, ignoring sign. On input, *limpos is the bound on how many bytes should be written to buf; on output, *limpos is set to the number of bytes actually written. */ STATIC mp_result s_tobin(mp_int z, unsigned char *buf, int *limpos, int pad); #if DEBUG /* Dump a representation of the mp_int to standard output */ void s_print(char *tag, mp_int z); void s_print_buf(char *tag, mp_digit *buf, mp_size num); #endif mp_result mp_int_init(mp_int z) { if (z == NULL) return MP_BADARG; z->single = 0; z->digits = &(z->single); z->alloc = 1; z->used = 1; z->sign = MP_ZPOS; return MP_OK; } mp_int mp_int_alloc(void) { mp_int out = malloc(sizeof(mpz_t)); if (out != NULL) mp_int_init(out); return out; } mp_result mp_int_init_size(mp_int z, mp_size prec) { CHECK(z != NULL); if (prec == 0) prec = default_precision; else if (prec == 1) return mp_int_init(z); else prec = (mp_size) ROUND_PREC(prec); if ((MP_DIGITS(z) = s_alloc(prec)) == NULL) return MP_MEMORY; z->digits[0] = 0; MP_USED(z) = 1; MP_ALLOC(z) = prec; MP_SIGN(z) = MP_ZPOS; return MP_OK; } mp_result mp_int_init_copy(mp_int z, mp_int old) { mp_result res; mp_size uold; CHECK(z != NULL && old != NULL); uold = MP_USED(old); if (uold == 1) { mp_int_init(z); } else { mp_size target = MAX(uold, default_precision); if ((res = mp_int_init_size(z, target)) != MP_OK) return res; } MP_USED(z) = uold; MP_SIGN(z) = MP_SIGN(old); COPY(MP_DIGITS(old), MP_DIGITS(z), uold); return MP_OK; } mp_result mp_int_init_value(mp_int z, mp_small value) { mpz_t vtmp; mp_digit vbuf[MP_VALUE_DIGITS(value)]; s_fake(&vtmp, value, vbuf); return mp_int_init_copy(z, &vtmp); } mp_result mp_int_init_uvalue(mp_int z, mp_usmall uvalue) { mpz_t vtmp; mp_digit vbuf[MP_VALUE_DIGITS(uvalue)]; s_ufake(&vtmp, uvalue, vbuf); return mp_int_init_copy(z, &vtmp); } mp_result mp_int_set_value(mp_int z, mp_small value) { mpz_t vtmp; mp_digit vbuf[MP_VALUE_DIGITS(value)]; s_fake(&vtmp, value, vbuf); return mp_int_copy(&vtmp, z); } mp_result mp_int_set_uvalue(mp_int z, mp_usmall uvalue) { mpz_t vtmp; mp_digit vbuf[MP_VALUE_DIGITS(uvalue)]; s_ufake(&vtmp, uvalue, vbuf); return mp_int_copy(&vtmp, z); } void mp_int_clear(mp_int z) { if (z == NULL) return; if (MP_DIGITS(z) != NULL) { if (MP_DIGITS(z) != &(z->single)) s_free(MP_DIGITS(z)); MP_DIGITS(z) = NULL; } } void mp_int_free(mp_int z) { NRCHECK(z != NULL); mp_int_clear(z); free(z); /* note: NOT s_free() */ } mp_result mp_int_copy(mp_int a, mp_int c) { CHECK(a != NULL && c != NULL); if (a != c) { mp_size ua = MP_USED(a); mp_digit *da, *dc; if (!s_pad(c, ua)) return MP_MEMORY; da = MP_DIGITS(a); dc = MP_DIGITS(c); COPY(da, dc, ua); MP_USED(c) = ua; MP_SIGN(c) = MP_SIGN(a); } return MP_OK; } void mp_int_swap(mp_int a, mp_int c) { if (a != c) { mpz_t tmp = *a; *a = *c; *c = tmp; if (MP_DIGITS(a) == &(c->single)) MP_DIGITS(a) = &(a->single); if (MP_DIGITS(c) == &(a->single)) MP_DIGITS(c) = &(c->single); } } void mp_int_zero(mp_int z) { NRCHECK(z != NULL); z->digits[0] = 0; MP_USED(z) = 1; MP_SIGN(z) = MP_ZPOS; } mp_result mp_int_abs(mp_int a, mp_int c) { mp_result res; CHECK(a != NULL && c != NULL); if ((res = mp_int_copy(a, c)) != MP_OK) return res; MP_SIGN(c) = MP_ZPOS; return MP_OK; } mp_result mp_int_neg(mp_int a, mp_int c) { mp_result res; CHECK(a != NULL && c != NULL); if ((res = mp_int_copy(a, c)) != MP_OK) return res; if (CMPZ(c) != 0) MP_SIGN(c) = 1 - MP_SIGN(a); return MP_OK; } mp_result mp_int_add(mp_int a, mp_int b, mp_int c) { mp_size ua, ub, uc, max; CHECK(a != NULL && b != NULL && c != NULL); ua = MP_USED(a); ub = MP_USED(b); uc = MP_USED(c); max = MAX(ua, ub); if (MP_SIGN(a) == MP_SIGN(b)) { /* Same sign -- add magnitudes, preserve sign of addends */ mp_digit carry; if (!s_pad(c, max)) return MP_MEMORY; carry = s_uadd(MP_DIGITS(a), MP_DIGITS(b), MP_DIGITS(c), ua, ub); uc = max; if (carry) { if (!s_pad(c, max + 1)) return MP_MEMORY; c->digits[max] = carry; ++uc; } MP_USED(c) = uc; MP_SIGN(c) = MP_SIGN(a); } else { /* Different signs -- subtract magnitudes, preserve sign of greater */ mp_int x, y; int cmp = s_ucmp(a, b); /* magnitude comparision, sign ignored */ /* Set x to max(a, b), y to min(a, b) to simplify later code. A special case yields zero for equal magnitudes. */ if (cmp == 0) { mp_int_zero(c); return MP_OK; } else if (cmp < 0) { x = b; y = a; } else { x = a; y = b; } if (!s_pad(c, MP_USED(x))) return MP_MEMORY; /* Subtract smaller from larger */ s_usub(MP_DIGITS(x), MP_DIGITS(y), MP_DIGITS(c), MP_USED(x), MP_USED(y)); MP_USED(c) = MP_USED(x); CLAMP(c); /* Give result the sign of the larger */ MP_SIGN(c) = MP_SIGN(x); } return MP_OK; } mp_result mp_int_add_value(mp_int a, mp_small value, mp_int c) { mpz_t vtmp; mp_digit vbuf[MP_VALUE_DIGITS(value)]; s_fake(&vtmp, value, vbuf); return mp_int_add(a, &vtmp, c); } mp_result mp_int_sub(mp_int a, mp_int b, mp_int c) { mp_size ua, ub, uc, max; CHECK(a != NULL && b != NULL && c != NULL); ua = MP_USED(a); ub = MP_USED(b); uc = MP_USED(c); max = MAX(ua, ub); if (MP_SIGN(a) != MP_SIGN(b)) { /* Different signs -- add magnitudes and keep sign of a */ mp_digit carry; if (!s_pad(c, max)) return MP_MEMORY; carry = s_uadd(MP_DIGITS(a), MP_DIGITS(b), MP_DIGITS(c), ua, ub); uc = max; if (carry) { if (!s_pad(c, max + 1)) return MP_MEMORY; c->digits[max] = carry; ++uc; } MP_USED(c) = uc; MP_SIGN(c) = MP_SIGN(a); } else { /* Same signs -- subtract magnitudes */ mp_int x, y; mp_sign osign; int cmp = s_ucmp(a, b); if (!s_pad(c, max)) return MP_MEMORY; if (cmp >= 0) { x = a; y = b; osign = MP_ZPOS; } else { x = b; y = a; osign = MP_NEG; } if (MP_SIGN(a) == MP_NEG && cmp != 0) osign = 1 - osign; s_usub(MP_DIGITS(x), MP_DIGITS(y), MP_DIGITS(c), MP_USED(x), MP_USED(y)); MP_USED(c) = MP_USED(x); CLAMP(c); MP_SIGN(c) = osign; } return MP_OK; } mp_result mp_int_sub_value(mp_int a, mp_small value, mp_int c) { mpz_t vtmp; mp_digit vbuf[MP_VALUE_DIGITS(value)]; s_fake(&vtmp, value, vbuf); return mp_int_sub(a, &vtmp, c); } mp_result mp_int_mul(mp_int a, mp_int b, mp_int c) { mp_digit *out; mp_size osize, ua, ub, p = 0; mp_sign osign; CHECK(a != NULL && b != NULL && c != NULL); /* If either input is zero, we can shortcut multiplication */ if (mp_int_compare_zero(a) == 0 || mp_int_compare_zero(b) == 0) { mp_int_zero(c); return MP_OK; } /* Output is positive if inputs have same sign, otherwise negative */ osign = (MP_SIGN(a) == MP_SIGN(b)) ? MP_ZPOS : MP_NEG; /* If the output is not identical to any of the inputs, we'll write the results directly; otherwise, allocate a temporary space. */ ua = MP_USED(a); ub = MP_USED(b); osize = MAX(ua, ub); osize = 4 * ((osize + 1) / 2); if (c == a || c == b) { p = ROUND_PREC(osize); p = MAX(p, default_precision); if ((out = s_alloc(p)) == NULL) return MP_MEMORY; } else { if (!s_pad(c, osize)) return MP_MEMORY; out = MP_DIGITS(c); } ZERO(out, osize); if (!s_kmul(MP_DIGITS(a), MP_DIGITS(b), out, ua, ub)) return MP_MEMORY; /* If we allocated a new buffer, get rid of whatever memory c was already using, and fix up its fields to reflect that. */ if (out != MP_DIGITS(c)) { if ((void *) MP_DIGITS(c) != (void *) c) s_free(MP_DIGITS(c)); MP_DIGITS(c) = out; MP_ALLOC(c) = p; } MP_USED(c) = osize; /* might not be true, but we'll fix it ... */ CLAMP(c); /* ... right here */ MP_SIGN(c) = osign; return MP_OK; } mp_result mp_int_mul_value(mp_int a, mp_small value, mp_int c) { mpz_t vtmp; mp_digit vbuf[MP_VALUE_DIGITS(value)]; s_fake(&vtmp, value, vbuf); return mp_int_mul(a, &vtmp, c); } mp_result mp_int_mul_pow2(mp_int a, mp_small p2, mp_int c) { mp_result res; CHECK(a != NULL && c != NULL && p2 >= 0); if ((res = mp_int_copy(a, c)) != MP_OK) return res; if (s_qmul(c, (mp_size) p2)) return MP_OK; else return MP_MEMORY; } mp_result mp_int_sqr(mp_int a, mp_int c) { mp_digit *out; mp_size osize, p = 0; CHECK(a != NULL && c != NULL); /* Get a temporary buffer big enough to hold the result */ osize = (mp_size) 4 * ((MP_USED(a) + 1) / 2); if (a == c) { p = ROUND_PREC(osize); p = MAX(p, default_precision); if ((out = s_alloc(p)) == NULL) return MP_MEMORY; } else { if (!s_pad(c, osize)) return MP_MEMORY; out = MP_DIGITS(c); } ZERO(out, osize); s_ksqr(MP_DIGITS(a), out, MP_USED(a)); /* Get rid of whatever memory c was already using, and fix up its fields to reflect the new digit array it's using */ if (out != MP_DIGITS(c)) { if ((void *) MP_DIGITS(c) != (void *) c) s_free(MP_DIGITS(c)); MP_DIGITS(c) = out; MP_ALLOC(c) = p; } MP_USED(c) = osize; /* might not be true, but we'll fix it ... */ CLAMP(c); /* ... right here */ MP_SIGN(c) = MP_ZPOS; return MP_OK; } mp_result mp_int_div(mp_int a, mp_int b, mp_int q, mp_int r) { int cmp, lg; mp_result res = MP_OK; mp_int qout, rout; mp_sign sa = MP_SIGN(a), sb = MP_SIGN(b); DECLARE_TEMP(2); CHECK(a != NULL && b != NULL && q != r); if (CMPZ(b) == 0) return MP_UNDEF; else if ((cmp = s_ucmp(a, b)) < 0) { /* If |a| < |b|, no division is required: q = 0, r = a */ if (r && (res = mp_int_copy(a, r)) != MP_OK) return res; if (q) mp_int_zero(q); return MP_OK; } else if (cmp == 0) { /* If |a| = |b|, no division is required: q = 1 or -1, r = 0 */ if (r) mp_int_zero(r); if (q) { mp_int_zero(q); q->digits[0] = 1; if (sa != sb) MP_SIGN(q) = MP_NEG; } return MP_OK; } /* When |a| > |b|, real division is required. We need someplace to store quotient and remainder, but q and r are allowed to be NULL or to overlap with the inputs. */ if ((lg = s_isp2(b)) < 0) { if (q && b != q) { if ((res = mp_int_copy(a, q)) != MP_OK) goto CLEANUP; else qout = q; } else { qout = LAST_TEMP(); SETUP(mp_int_init_copy(LAST_TEMP(), a)); } if (r && a != r) { if ((res = mp_int_copy(b, r)) != MP_OK) goto CLEANUP; else rout = r; } else { rout = LAST_TEMP(); SETUP(mp_int_init_copy(LAST_TEMP(), b)); } if ((res = s_udiv_knuth(qout, rout)) != MP_OK) goto CLEANUP; } else { if (q && (res = mp_int_copy(a, q)) != MP_OK) goto CLEANUP; if (r && (res = mp_int_copy(a, r)) != MP_OK) goto CLEANUP; if (q) s_qdiv(q, (mp_size) lg); qout = q; if (r) s_qmod(r, (mp_size) lg); rout = r; } /* Recompute signs for output */ if (rout) { MP_SIGN(rout) = sa; if (CMPZ(rout) == 0) MP_SIGN(rout) = MP_ZPOS; } if (qout) { MP_SIGN(qout) = (sa == sb) ? MP_ZPOS : MP_NEG; if (CMPZ(qout) == 0) MP_SIGN(qout) = MP_ZPOS; } if (q && (res = mp_int_copy(qout, q)) != MP_OK) goto CLEANUP; if (r && (res = mp_int_copy(rout, r)) != MP_OK) goto CLEANUP; CLEANUP_TEMP(); return res; } mp_result mp_int_mod(mp_int a, mp_int m, mp_int c) { mp_result res; mpz_t tmp; mp_int out; if (m == c) { mp_int_init(&tmp); out = &tmp; } else { out = c; } if ((res = mp_int_div(a, m, NULL, out)) != MP_OK) goto CLEANUP; if (CMPZ(out) < 0) res = mp_int_add(out, m, c); else res = mp_int_copy(out, c); CLEANUP: if (out != c) mp_int_clear(&tmp); return res; } mp_result mp_int_div_value(mp_int a, mp_small value, mp_int q, mp_small *r) { mpz_t vtmp, rtmp; mp_digit vbuf[MP_VALUE_DIGITS(value)]; mp_result res; mp_int_init(&rtmp); s_fake(&vtmp, value, vbuf); if ((res = mp_int_div(a, &vtmp, q, &rtmp)) != MP_OK) goto CLEANUP; if (r) (void) mp_int_to_int(&rtmp, r); /* can't fail */ CLEANUP: mp_int_clear(&rtmp); return res; } mp_result mp_int_div_pow2(mp_int a, mp_small p2, mp_int q, mp_int r) { mp_result res = MP_OK; CHECK(a != NULL && p2 >= 0 && q != r); if (q != NULL && (res = mp_int_copy(a, q)) == MP_OK) s_qdiv(q, (mp_size) p2); if (res == MP_OK && r != NULL && (res = mp_int_copy(a, r)) == MP_OK) s_qmod(r, (mp_size) p2); return res; } mp_result mp_int_expt(mp_int a, mp_small b, mp_int c) { mpz_t t; mp_result res; unsigned int v = labs(b); CHECK(c != NULL); if (b < 0) return MP_RANGE; if ((res = mp_int_init_copy(&t, a)) != MP_OK) return res; (void) mp_int_set_value(c, 1); while (v != 0) { if (v & 1) { if ((res = mp_int_mul(c, &t, c)) != MP_OK) goto CLEANUP; } v >>= 1; if (v == 0) break; if ((res = mp_int_sqr(&t, &t)) != MP_OK) goto CLEANUP; } CLEANUP: mp_int_clear(&t); return res; } mp_result mp_int_expt_value(mp_small a, mp_small b, mp_int c) { mpz_t t; mp_result res; unsigned int v = labs(b); CHECK(c != NULL); if (b < 0) return MP_RANGE; if ((res = mp_int_init_value(&t, a)) != MP_OK) return res; (void) mp_int_set_value(c, 1); while (v != 0) { if (v & 1) { if ((res = mp_int_mul(c, &t, c)) != MP_OK) goto CLEANUP; } v >>= 1; if (v == 0) break; if ((res = mp_int_sqr(&t, &t)) != MP_OK) goto CLEANUP; } CLEANUP: mp_int_clear(&t); return res; } mp_result mp_int_expt_full(mp_int a, mp_int b, mp_int c) { mpz_t t; mp_result res; unsigned ix, jx; CHECK(a != NULL && b != NULL && c != NULL); if (MP_SIGN(b) == MP_NEG) return MP_RANGE; if ((res = mp_int_init_copy(&t, a)) != MP_OK) return res; (void) mp_int_set_value(c, 1); for (ix = 0; ix < MP_USED(b); ++ix) { mp_digit d = b->digits[ix]; for (jx = 0; jx < MP_DIGIT_BIT; ++jx) { if (d & 1) { if ((res = mp_int_mul(c, &t, c)) != MP_OK) goto CLEANUP; } d >>= 1; if (d == 0 && ix + 1 == MP_USED(b)) break; if ((res = mp_int_sqr(&t, &t)) != MP_OK) goto CLEANUP; } } CLEANUP: mp_int_clear(&t); return res; } int mp_int_compare(mp_int a, mp_int b) { mp_sign sa; CHECK(a != NULL && b != NULL); sa = MP_SIGN(a); if (sa == MP_SIGN(b)) { int cmp = s_ucmp(a, b); /* If they're both zero or positive, the normal comparison applies; if both negative, the sense is reversed. */ if (sa == MP_ZPOS) return cmp; else return -cmp; } else { if (sa == MP_ZPOS) return 1; else return -1; } } int mp_int_compare_unsigned(mp_int a, mp_int b) { NRCHECK(a != NULL && b != NULL); return s_ucmp(a, b); } int mp_int_compare_zero(mp_int z) { NRCHECK(z != NULL); if (MP_USED(z) == 1 && z->digits[0] == 0) return 0; else if (MP_SIGN(z) == MP_ZPOS) return 1; else return -1; } int mp_int_compare_value(mp_int z, mp_small value) { mp_sign vsign = (value < 0) ? MP_NEG : MP_ZPOS; int cmp; CHECK(z != NULL); if (vsign == MP_SIGN(z)) { cmp = s_vcmp(z, value); return (vsign == MP_ZPOS) ? cmp : -cmp; } else { return (value < 0) ? 1 : -1; } } int mp_int_compare_uvalue(mp_int z, mp_usmall uv) { CHECK(z != NULL); if (MP_SIGN(z) == MP_NEG) return -1; else return s_uvcmp(z, uv); } mp_result mp_int_exptmod(mp_int a, mp_int b, mp_int m, mp_int c) { mp_result res; mp_size um; mp_int s; DECLARE_TEMP(3); CHECK(a != NULL && b != NULL && c != NULL && m != NULL); /* Zero moduli and negative exponents are not considered. */ if (CMPZ(m) == 0) return MP_UNDEF; if (CMPZ(b) < 0) return MP_RANGE; um = MP_USED(m); SETUP(mp_int_init_size(TEMP(0), 2 * um)); SETUP(mp_int_init_size(TEMP(1), 2 * um)); if (c == b || c == m) { SETUP(mp_int_init_size(TEMP(2), 2 * um)); s = TEMP(2); } else { s = c; } if ((res = mp_int_mod(a, m, TEMP(0))) != MP_OK) goto CLEANUP; if ((res = s_brmu(TEMP(1), m)) != MP_OK) goto CLEANUP; if ((res = s_embar(TEMP(0), b, m, TEMP(1), s)) != MP_OK) goto CLEANUP; res = mp_int_copy(s, c); CLEANUP_TEMP(); return res; } mp_result mp_int_exptmod_evalue(mp_int a, mp_small value, mp_int m, mp_int c) { mpz_t vtmp; mp_digit vbuf[MP_VALUE_DIGITS(value)]; s_fake(&vtmp, value, vbuf); return mp_int_exptmod(a, &vtmp, m, c); } mp_result mp_int_exptmod_bvalue(mp_small value, mp_int b, mp_int m, mp_int c) { mpz_t vtmp; mp_digit vbuf[MP_VALUE_DIGITS(value)]; s_fake(&vtmp, value, vbuf); return mp_int_exptmod(&vtmp, b, m, c); } mp_result mp_int_exptmod_known(mp_int a, mp_int b, mp_int m, mp_int mu, mp_int c) { mp_result res; mp_size um; mp_int s; DECLARE_TEMP(2); CHECK(a && b && m && c); /* Zero moduli and negative exponents are not considered. */ if (CMPZ(m) == 0) return MP_UNDEF; if (CMPZ(b) < 0) return MP_RANGE; um = MP_USED(m); SETUP(mp_int_init_size(TEMP(0), 2 * um)); if (c == b || c == m) { SETUP(mp_int_init_size(TEMP(1), 2 * um)); s = TEMP(1); } else { s = c; } if ((res = mp_int_mod(a, m, TEMP(0))) != MP_OK) goto CLEANUP; if ((res = s_embar(TEMP(0), b, m, mu, s)) != MP_OK) goto CLEANUP; res = mp_int_copy(s, c); CLEANUP_TEMP(); return res; } mp_result mp_int_redux_const(mp_int m, mp_int c) { CHECK(m != NULL && c != NULL && m != c); return s_brmu(c, m); } mp_result mp_int_invmod(mp_int a, mp_int m, mp_int c) { mp_result res; mp_sign sa; DECLARE_TEMP(2); CHECK(a != NULL && m != NULL && c != NULL); if (CMPZ(a) == 0 || CMPZ(m) <= 0) return MP_RANGE; sa = MP_SIGN(a); /* need this for the result later */ for (last__ = 0; last__ < 2; ++last__) mp_int_init(LAST_TEMP()); if ((res = mp_int_egcd(a, m, TEMP(0), TEMP(1), NULL)) != MP_OK) goto CLEANUP; if (mp_int_compare_value(TEMP(0), 1) != 0) { res = MP_UNDEF; goto CLEANUP; } /* It is first necessary to constrain the value to the proper range */ if ((res = mp_int_mod(TEMP(1), m, TEMP(1))) != MP_OK) goto CLEANUP; /* Now, if 'a' was originally negative, the value we have is actually the magnitude of the negative representative; to get the positive value we have to subtract from the modulus. Otherwise, the value is okay as it stands. */ if (sa == MP_NEG) res = mp_int_sub(m, TEMP(1), c); else res = mp_int_copy(TEMP(1), c); CLEANUP_TEMP(); return res; } /* Binary GCD algorithm due to Josef Stein, 1961 */ mp_result mp_int_gcd(mp_int a, mp_int b, mp_int c) { int ca, cb, k = 0; mpz_t u, v, t; mp_result res; CHECK(a != NULL && b != NULL && c != NULL); ca = CMPZ(a); cb = CMPZ(b); if (ca == 0 && cb == 0) return MP_UNDEF; else if (ca == 0) return mp_int_abs(b, c); else if (cb == 0) return mp_int_abs(a, c); mp_int_init(&t); if ((res = mp_int_init_copy(&u, a)) != MP_OK) goto U; if ((res = mp_int_init_copy(&v, b)) != MP_OK) goto V; MP_SIGN(&u) = MP_ZPOS; MP_SIGN(&v) = MP_ZPOS; { /* Divide out common factors of 2 from u and v */ int div2_u = s_dp2k(&u), div2_v = s_dp2k(&v); k = MIN(div2_u, div2_v); s_qdiv(&u, (mp_size) k); s_qdiv(&v, (mp_size) k); } if (mp_int_is_odd(&u)) { if ((res = mp_int_neg(&v, &t)) != MP_OK) goto CLEANUP; } else { if ((res = mp_int_copy(&u, &t)) != MP_OK) goto CLEANUP; } for (;;) { s_qdiv(&t, s_dp2k(&t)); if (CMPZ(&t) > 0) { if ((res = mp_int_copy(&t, &u)) != MP_OK) goto CLEANUP; } else { if ((res = mp_int_neg(&t, &v)) != MP_OK) goto CLEANUP; } if ((res = mp_int_sub(&u, &v, &t)) != MP_OK) goto CLEANUP; if (CMPZ(&t) == 0) break; } if ((res = mp_int_abs(&u, c)) != MP_OK) goto CLEANUP; if (!s_qmul(c, (mp_size) k)) res = MP_MEMORY; CLEANUP: mp_int_clear(&v); V: mp_int_clear(&u); U: mp_int_clear(&t); return res; } /* This is the binary GCD algorithm again, but this time we keep track of the elementary matrix operations as we go, so we can get values x and y satisfying c = ax + by. */ mp_result mp_int_egcd(mp_int a, mp_int b, mp_int c, mp_int x, mp_int y) { int k, ca, cb; mp_result res; DECLARE_TEMP(8); CHECK(a != NULL && b != NULL && c != NULL && (x != NULL || y != NULL)); ca = CMPZ(a); cb = CMPZ(b); if (ca == 0 && cb == 0) return MP_UNDEF; else if (ca == 0) { if ((res = mp_int_abs(b, c)) != MP_OK) return res; mp_int_zero(x); (void) mp_int_set_value(y, 1); return MP_OK; } else if (cb == 0) { if ((res = mp_int_abs(a, c)) != MP_OK) return res; (void) mp_int_set_value(x, 1); mp_int_zero(y); return MP_OK; } /* Initialize temporaries: A:0, B:1, C:2, D:3, u:4, v:5, ou:6, ov:7 */ for (last__ = 0; last__ < 4; ++last__) mp_int_init(LAST_TEMP()); TEMP(0)->digits[0] = 1; TEMP(3)->digits[0] = 1; SETUP(mp_int_init_copy(TEMP(4), a)); SETUP(mp_int_init_copy(TEMP(5), b)); /* We will work with absolute values here */ MP_SIGN(TEMP(4)) = MP_ZPOS; MP_SIGN(TEMP(5)) = MP_ZPOS; { /* Divide out common factors of 2 from u and v */ int div2_u = s_dp2k(TEMP(4)), div2_v = s_dp2k(TEMP(5)); k = MIN(div2_u, div2_v); s_qdiv(TEMP(4), k); s_qdiv(TEMP(5), k); } SETUP(mp_int_init_copy(TEMP(6), TEMP(4))); SETUP(mp_int_init_copy(TEMP(7), TEMP(5))); for (;;) { while (mp_int_is_even(TEMP(4))) { s_qdiv(TEMP(4), 1); if (mp_int_is_odd(TEMP(0)) || mp_int_is_odd(TEMP(1))) { if ((res = mp_int_add(TEMP(0), TEMP(7), TEMP(0))) != MP_OK) goto CLEANUP; if ((res = mp_int_sub(TEMP(1), TEMP(6), TEMP(1))) != MP_OK) goto CLEANUP; } s_qdiv(TEMP(0), 1); s_qdiv(TEMP(1), 1); } while (mp_int_is_even(TEMP(5))) { s_qdiv(TEMP(5), 1); if (mp_int_is_odd(TEMP(2)) || mp_int_is_odd(TEMP(3))) { if ((res = mp_int_add(TEMP(2), TEMP(7), TEMP(2))) != MP_OK) goto CLEANUP; if ((res = mp_int_sub(TEMP(3), TEMP(6), TEMP(3))) != MP_OK) goto CLEANUP; } s_qdiv(TEMP(2), 1); s_qdiv(TEMP(3), 1); } if (mp_int_compare(TEMP(4), TEMP(5)) >= 0) { if ((res = mp_int_sub(TEMP(4), TEMP(5), TEMP(4))) != MP_OK) goto CLEANUP; if ((res = mp_int_sub(TEMP(0), TEMP(2), TEMP(0))) != MP_OK) goto CLEANUP; if ((res = mp_int_sub(TEMP(1), TEMP(3), TEMP(1))) != MP_OK) goto CLEANUP; } else { if ((res = mp_int_sub(TEMP(5), TEMP(4), TEMP(5))) != MP_OK) goto CLEANUP; if ((res = mp_int_sub(TEMP(2), TEMP(0), TEMP(2))) != MP_OK) goto CLEANUP; if ((res = mp_int_sub(TEMP(3), TEMP(1), TEMP(3))) != MP_OK) goto CLEANUP; } if (CMPZ(TEMP(4)) == 0) { if (x && (res = mp_int_copy(TEMP(2), x)) != MP_OK) goto CLEANUP; if (y && (res = mp_int_copy(TEMP(3), y)) != MP_OK) goto CLEANUP; if (c) { if (!s_qmul(TEMP(5), k)) { res = MP_MEMORY; goto CLEANUP; } res = mp_int_copy(TEMP(5), c); } break; } } CLEANUP_TEMP(); return res; } mp_result mp_int_lcm(mp_int a, mp_int b, mp_int c) { mpz_t lcm; mp_result res; CHECK(a != NULL && b != NULL && c != NULL); /* Since a * b = gcd(a, b) * lcm(a, b), we can compute lcm(a, b) = (a / gcd(a, b)) * b. This formulation insures everything works even if the input variables share space. */ if ((res = mp_int_init(&lcm)) != MP_OK) return res; if ((res = mp_int_gcd(a, b, &lcm)) != MP_OK) goto CLEANUP; if ((res = mp_int_div(a, &lcm, &lcm, NULL)) != MP_OK) goto CLEANUP; if ((res = mp_int_mul(&lcm, b, &lcm)) != MP_OK) goto CLEANUP; res = mp_int_copy(&lcm, c); CLEANUP: mp_int_clear(&lcm); return res; } int mp_int_divisible_value(mp_int a, mp_small v) { mp_small rem = 0; if (mp_int_div_value(a, v, NULL, &rem) != MP_OK) return 0; return rem == 0; } int mp_int_is_pow2(mp_int z) { CHECK(z != NULL); return s_isp2(z); } /* Implementation of Newton's root finding method, based loosely on a patch contributed by Hal Finkel modified by M. J. Fromberger. */ mp_result mp_int_root(mp_int a, mp_small b, mp_int c) { mp_result res = MP_OK; int flips = 0; DECLARE_TEMP(5); CHECK(a != NULL && c != NULL && b > 0); if (b == 1) { return mp_int_copy(a, c); } if (MP_SIGN(a) == MP_NEG) { if (b % 2 == 0) return MP_UNDEF; /* root does not exist for negative a with even b */ else flips = 1; } SETUP(mp_int_init_copy(LAST_TEMP(), a)); SETUP(mp_int_init_copy(LAST_TEMP(), a)); SETUP(mp_int_init(LAST_TEMP())); SETUP(mp_int_init(LAST_TEMP())); SETUP(mp_int_init(LAST_TEMP())); (void) mp_int_abs(TEMP(0), TEMP(0)); (void) mp_int_abs(TEMP(1), TEMP(1)); for (;;) { if ((res = mp_int_expt(TEMP(1), b, TEMP(2))) != MP_OK) goto CLEANUP; if (mp_int_compare_unsigned(TEMP(2), TEMP(0)) <= 0) break; if ((res = mp_int_sub(TEMP(2), TEMP(0), TEMP(2))) != MP_OK) goto CLEANUP; if ((res = mp_int_expt(TEMP(1), b - 1, TEMP(3))) != MP_OK) goto CLEANUP; if ((res = mp_int_mul_value(TEMP(3), b, TEMP(3))) != MP_OK) goto CLEANUP; if ((res = mp_int_div(TEMP(2), TEMP(3), TEMP(4), NULL)) != MP_OK) goto CLEANUP; if ((res = mp_int_sub(TEMP(1), TEMP(4), TEMP(4))) != MP_OK) goto CLEANUP; if (mp_int_compare_unsigned(TEMP(1), TEMP(4)) == 0) { if ((res = mp_int_sub_value(TEMP(4), 1, TEMP(4))) != MP_OK) goto CLEANUP; } if ((res = mp_int_copy(TEMP(4), TEMP(1))) != MP_OK) goto CLEANUP; } if ((res = mp_int_copy(TEMP(1), c)) != MP_OK) goto CLEANUP; /* If the original value of a was negative, flip the output sign. */ if (flips) (void) mp_int_neg(c, c); /* cannot fail */ CLEANUP_TEMP(); return res; } mp_result mp_int_to_int(mp_int z, mp_small *out) { mp_usmall uv = 0; mp_size uz; mp_digit *dz; mp_sign sz; CHECK(z != NULL); /* Make sure the value is representable as a small integer */ sz = MP_SIGN(z); if ((sz == MP_ZPOS && mp_int_compare_value(z, MP_SMALL_MAX) > 0) || mp_int_compare_value(z, MP_SMALL_MIN) < 0) return MP_RANGE; uz = MP_USED(z); dz = MP_DIGITS(z) + uz - 1; while (uz > 0) { uv <<= MP_DIGIT_BIT/2; uv = (uv << (MP_DIGIT_BIT/2)) | *dz--; --uz; } if (out) *out = (mp_small)((sz == MP_NEG) ? -uv : uv); return MP_OK; } mp_result mp_int_to_uint(mp_int z, mp_usmall *out) { mp_usmall uv = 0; mp_size uz; mp_digit *dz; mp_sign sz; CHECK(z != NULL); /* Make sure the value is representable as an unsigned small integer */ sz = MP_SIGN(z); if (sz == MP_NEG || mp_int_compare_uvalue(z, MP_USMALL_MAX) > 0) return MP_RANGE; uz = MP_USED(z); dz = MP_DIGITS(z) + uz - 1; while (uz > 0) { uv <<= MP_DIGIT_BIT/2; uv = (uv << (MP_DIGIT_BIT/2)) | *dz--; --uz; } if (out) *out = uv; return MP_OK; } mp_result mp_int_to_string(mp_int z, mp_size radix, char *str, int limit) { mp_result res; int cmp = 0; CHECK(z != NULL && str != NULL && limit >= 2); if (radix < MP_MIN_RADIX || radix > MP_MAX_RADIX) return MP_RANGE; if (CMPZ(z) == 0) { *str++ = s_val2ch(0, 1); } else { mpz_t tmp; char *h, *t; if ((res = mp_int_init_copy(&tmp, z)) != MP_OK) return res; if (MP_SIGN(z) == MP_NEG) { *str++ = '-'; --limit; } h = str; /* Generate digits in reverse order until finished or limit reached */ for (/* */; limit > 0; --limit) { mp_digit d; if ((cmp = CMPZ(&tmp)) == 0) break; d = s_ddiv(&tmp, (mp_digit)radix); *str++ = s_val2ch(d, 1); } t = str - 1; /* Put digits back in correct output order */ while (h < t) { char tc = *h; *h++ = *t; *t-- = tc; } mp_int_clear(&tmp); } *str = '\0'; if (cmp == 0) return MP_OK; else return MP_TRUNC; } mp_result mp_int_string_len(mp_int z, mp_size radix) { int len; CHECK(z != NULL); if (radix < MP_MIN_RADIX || radix > MP_MAX_RADIX) return MP_RANGE; len = s_outlen(z, radix) + 1; /* for terminator */ /* Allow for sign marker on negatives */ if (MP_SIGN(z) == MP_NEG) len += 1; return len; } /* Read zero-terminated string into z */ mp_result mp_int_read_string(mp_int z, mp_size radix, const char *str) { return mp_int_read_cstring(z, radix, str, NULL); } mp_result mp_int_read_cstring(mp_int z, mp_size radix, const char *str, char **end) { int ch; CHECK(z != NULL && str != NULL); if (radix < MP_MIN_RADIX || radix > MP_MAX_RADIX) return MP_RANGE; /* Skip leading whitespace */ while (isspace((int)*str)) ++str; /* Handle leading sign tag (+/-, positive default) */ switch (*str) { case '-': MP_SIGN(z) = MP_NEG; ++str; break; case '+': ++str; /* fallthrough */ default: MP_SIGN(z) = MP_ZPOS; break; } /* Skip leading zeroes */ while ((ch = s_ch2val(*str, radix)) == 0) ++str; /* Make sure there is enough space for the value */ if (!s_pad(z, s_inlen(strlen(str), radix))) return MP_MEMORY; MP_USED(z) = 1; z->digits[0] = 0; while (*str != '\0' && ((ch = s_ch2val(*str, radix)) >= 0)) { s_dmul(z, (mp_digit)radix); s_dadd(z, (mp_digit)ch); ++str; } CLAMP(z); /* Override sign for zero, even if negative specified. */ if (CMPZ(z) == 0) MP_SIGN(z) = MP_ZPOS; if (end != NULL) *end = (char *)str; /* Return a truncation error if the string has unprocessed characters remaining, so the caller can tell if the whole string was done */ if (*str != '\0') return MP_TRUNC; else return MP_OK; } mp_result mp_int_count_bits(mp_int z) { mp_size nbits = 0, uz; mp_digit d; CHECK(z != NULL); uz = MP_USED(z); if (uz == 1 && z->digits[0] == 0) return 1; --uz; nbits = uz * MP_DIGIT_BIT; d = z->digits[uz]; while (d != 0) { d >>= 1; ++nbits; } return nbits; } mp_result mp_int_to_binary(mp_int z, unsigned char *buf, int limit) { static const int PAD_FOR_2C = 1; mp_result res; int limpos = limit; CHECK(z != NULL && buf != NULL); res = s_tobin(z, buf, &limpos, PAD_FOR_2C); if (MP_SIGN(z) == MP_NEG) s_2comp(buf, limpos); return res; } mp_result mp_int_read_binary(mp_int z, unsigned char *buf, int len) { mp_size need, i; unsigned char *tmp; mp_digit *dz; CHECK(z != NULL && buf != NULL && len > 0); /* Figure out how many digits are needed to represent this value */ need = ((len * CHAR_BIT) + (MP_DIGIT_BIT - 1)) / MP_DIGIT_BIT; if (!s_pad(z, need)) return MP_MEMORY; mp_int_zero(z); /* If the high-order bit is set, take the 2's complement before reading the value (it will be restored afterward) */ if (buf[0] >> (CHAR_BIT - 1)) { MP_SIGN(z) = MP_NEG; s_2comp(buf, len); } dz = MP_DIGITS(z); for (tmp = buf, i = len; i > 0; --i, ++tmp) { s_qmul(z, (mp_size) CHAR_BIT); *dz |= *tmp; } /* Restore 2's complement if we took it before */ if (MP_SIGN(z) == MP_NEG) s_2comp(buf, len); return MP_OK; } mp_result mp_int_binary_len(mp_int z) { mp_result res = mp_int_count_bits(z); int bytes = mp_int_unsigned_len(z); if (res <= 0) return res; bytes = (res + (CHAR_BIT - 1)) / CHAR_BIT; /* If the highest-order bit falls exactly on a byte boundary, we need to pad with an extra byte so that the sign will be read correctly when reading it back in. */ if (bytes * CHAR_BIT == res) ++bytes; return bytes; } mp_result mp_int_to_unsigned(mp_int z, unsigned char *buf, int limit) { static const int NO_PADDING = 0; CHECK(z != NULL && buf != NULL); return s_tobin(z, buf, &limit, NO_PADDING); } mp_result mp_int_read_unsigned(mp_int z, unsigned char *buf, int len) { mp_size need, i; unsigned char *tmp; CHECK(z != NULL && buf != NULL && len > 0); /* Figure out how many digits are needed to represent this value */ need = ((len * CHAR_BIT) + (MP_DIGIT_BIT - 1)) / MP_DIGIT_BIT; if (!s_pad(z, need)) return MP_MEMORY; mp_int_zero(z); for (tmp = buf, i = len; i > 0; --i, ++tmp) { (void) s_qmul(z, CHAR_BIT); *MP_DIGITS(z) |= *tmp; } return MP_OK; } mp_result mp_int_unsigned_len(mp_int z) { mp_result res = mp_int_count_bits(z); int bytes; if (res <= 0) return res; bytes = (res + (CHAR_BIT - 1)) / CHAR_BIT; return bytes; } const char *mp_error_string(mp_result res) { int ix; if (res > 0) return s_unknown_err; res = -res; for (ix = 0; ix < res && s_error_msg[ix] != NULL; ++ix) ; if (s_error_msg[ix] != NULL) return s_error_msg[ix]; else return s_unknown_err; } /*------------------------------------------------------------------------*/ /* Private functions for internal use. These make assumptions. */ STATIC mp_digit *s_alloc(mp_size num) { mp_digit *out = malloc(num * sizeof(mp_digit)); assert(out != NULL); /* for debugging */ #if DEBUG > 1 { mp_digit v = (mp_digit) 0xdeadbeef; int ix; for (ix = 0; ix < num; ++ix) out[ix] = v; } #endif return out; } STATIC mp_digit *s_realloc(mp_digit *old, mp_size osize, mp_size nsize) { #if DEBUG > 1 mp_digit *new = s_alloc(nsize); int ix; for (ix = 0; ix < nsize; ++ix) new[ix] = (mp_digit) 0xdeadbeef; memcpy(new, old, osize * sizeof(mp_digit)); #else mp_digit *new = realloc(old, nsize * sizeof(mp_digit)); assert(new != NULL); /* for debugging */ #endif return new; } STATIC void s_free(void *ptr) { free(ptr); } STATIC int s_pad(mp_int z, mp_size min) { if (MP_ALLOC(z) < min) { mp_size nsize = ROUND_PREC(min); mp_digit *tmp; if ((void *)z->digits == (void *)z) { if ((tmp = s_alloc(nsize)) == NULL) return 0; COPY(MP_DIGITS(z), tmp, MP_USED(z)); } else if ((tmp = s_realloc(MP_DIGITS(z), MP_ALLOC(z), nsize)) == NULL) return 0; MP_DIGITS(z) = tmp; MP_ALLOC(z) = nsize; } return 1; } /* Note: This will not work correctly when value == MP_SMALL_MIN */ STATIC void s_fake(mp_int z, mp_small value, mp_digit vbuf[]) { mp_usmall uv = (mp_usmall) (value < 0) ? -value : value; s_ufake(z, uv, vbuf); if (value < 0) z->sign = MP_NEG; } STATIC void s_ufake(mp_int z, mp_usmall value, mp_digit vbuf[]) { mp_size ndig = (mp_size) s_uvpack(value, vbuf); z->used = ndig; z->alloc = MP_VALUE_DIGITS(value); z->sign = MP_ZPOS; z->digits = vbuf; } STATIC int s_cdig(mp_digit *da, mp_digit *db, mp_size len) { mp_digit *dat = da + len - 1, *dbt = db + len - 1; for (/* */; len != 0; --len, --dat, --dbt) { if (*dat > *dbt) return 1; else if (*dat < *dbt) return -1; } return 0; } STATIC int s_uvpack(mp_usmall uv, mp_digit t[]) { int ndig = 0; if (uv == 0) t[ndig++] = 0; else { while (uv != 0) { t[ndig++] = (mp_digit) uv; uv >>= MP_DIGIT_BIT/2; uv >>= MP_DIGIT_BIT/2; } } return ndig; } STATIC int s_ucmp(mp_int a, mp_int b) { mp_size ua = MP_USED(a), ub = MP_USED(b); if (ua > ub) return 1; else if (ub > ua) return -1; else return s_cdig(MP_DIGITS(a), MP_DIGITS(b), ua); } STATIC int s_vcmp(mp_int a, mp_small v) { mp_usmall uv = (v < 0) ? -(mp_usmall) v : (mp_usmall) v; return s_uvcmp(a, uv); } STATIC int s_uvcmp(mp_int a, mp_usmall uv) { mpz_t vtmp; mp_digit vdig[MP_VALUE_DIGITS(uv)]; s_ufake(&vtmp, uv, vdig); return s_ucmp(a, &vtmp); } STATIC mp_digit s_uadd(mp_digit *da, mp_digit *db, mp_digit *dc, mp_size size_a, mp_size size_b) { mp_size pos; mp_word w = 0; /* Insure that da is the longer of the two to simplify later code */ if (size_b > size_a) { SWAP(mp_digit *, da, db); SWAP(mp_size, size_a, size_b); } /* Add corresponding digits until the shorter number runs out */ for (pos = 0; pos < size_b; ++pos, ++da, ++db, ++dc) { w = w + (mp_word) *da + (mp_word) *db; *dc = LOWER_HALF(w); w = UPPER_HALF(w); } /* Propagate carries as far as necessary */ for (/* */; pos < size_a; ++pos, ++da, ++dc) { w = w + *da; *dc = LOWER_HALF(w); w = UPPER_HALF(w); } /* Return carry out */ return (mp_digit)w; } STATIC void s_usub(mp_digit *da, mp_digit *db, mp_digit *dc, mp_size size_a, mp_size size_b) { mp_size pos; mp_word w = 0; /* We assume that |a| >= |b| so this should definitely hold */ assert(size_a >= size_b); /* Subtract corresponding digits and propagate borrow */ for (pos = 0; pos < size_b; ++pos, ++da, ++db, ++dc) { w = ((mp_word)MP_DIGIT_MAX + 1 + /* MP_RADIX */ (mp_word)*da) - w - (mp_word)*db; *dc = LOWER_HALF(w); w = (UPPER_HALF(w) == 0); } /* Finish the subtraction for remaining upper digits of da */ for (/* */; pos < size_a; ++pos, ++da, ++dc) { w = ((mp_word)MP_DIGIT_MAX + 1 + /* MP_RADIX */ (mp_word)*da) - w; *dc = LOWER_HALF(w); w = (UPPER_HALF(w) == 0); } /* If there is a borrow out at the end, it violates the precondition */ assert(w == 0); } STATIC int s_kmul(mp_digit *da, mp_digit *db, mp_digit *dc, mp_size size_a, mp_size size_b) { mp_size bot_size; /* Make sure b is the smaller of the two input values */ if (size_b > size_a) { SWAP(mp_digit *, da, db); SWAP(mp_size, size_a, size_b); } /* Insure that the bottom is the larger half in an odd-length split; the code below relies on this being true. */ bot_size = (size_a + 1) / 2; /* If the values are big enough to bother with recursion, use the Karatsuba algorithm to compute the product; otherwise use the normal multiplication algorithm */ if (multiply_threshold && size_a >= multiply_threshold && size_b > bot_size) { mp_digit *t1, *t2, *t3, carry; mp_digit *a_top = da + bot_size; mp_digit *b_top = db + bot_size; mp_size at_size = size_a - bot_size; mp_size bt_size = size_b - bot_size; mp_size buf_size = 2 * bot_size; /* Do a single allocation for all three temporary buffers needed; each buffer must be big enough to hold the product of two bottom halves, and one buffer needs space for the completed product; twice the space is plenty. */ if ((t1 = s_alloc(4 * buf_size)) == NULL) return 0; t2 = t1 + buf_size; t3 = t2 + buf_size; ZERO(t1, 4 * buf_size); /* t1 and t2 are initially used as temporaries to compute the inner product (a1 + a0)(b1 + b0) = a1b1 + a1b0 + a0b1 + a0b0 */ carry = s_uadd(da, a_top, t1, bot_size, at_size); /* t1 = a1 + a0 */ t1[bot_size] = carry; carry = s_uadd(db, b_top, t2, bot_size, bt_size); /* t2 = b1 + b0 */ t2[bot_size] = carry; (void) s_kmul(t1, t2, t3, bot_size + 1, bot_size + 1); /* t3 = t1 * t2 */ /* Now we'll get t1 = a0b0 and t2 = a1b1, and subtract them out so that we're left with only the pieces we want: t3 = a1b0 + a0b1 */ ZERO(t1, buf_size); ZERO(t2, buf_size); (void) s_kmul(da, db, t1, bot_size, bot_size); /* t1 = a0 * b0 */ (void) s_kmul(a_top, b_top, t2, at_size, bt_size); /* t2 = a1 * b1 */ /* Subtract out t1 and t2 to get the inner product */ s_usub(t3, t1, t3, buf_size + 2, buf_size); s_usub(t3, t2, t3, buf_size + 2, buf_size); /* Assemble the output value */ COPY(t1, dc, buf_size); carry = s_uadd(t3, dc + bot_size, dc + bot_size, buf_size + 1, buf_size); assert(carry == 0); carry = s_uadd(t2, dc + 2*bot_size, dc + 2*bot_size, buf_size, buf_size); assert(carry == 0); s_free(t1); /* note t2 and t3 are just internal pointers to t1 */ } else { s_umul(da, db, dc, size_a, size_b); } return 1; } STATIC void s_umul(mp_digit *da, mp_digit *db, mp_digit *dc, mp_size size_a, mp_size size_b) { mp_size a, b; mp_word w; for (a = 0; a < size_a; ++a, ++dc, ++da) { mp_digit *dct = dc; mp_digit *dbt = db; if (*da == 0) continue; w = 0; for (b = 0; b < size_b; ++b, ++dbt, ++dct) { w = (mp_word)*da * (mp_word)*dbt + w + (mp_word)*dct; *dct = LOWER_HALF(w); w = UPPER_HALF(w); } *dct = (mp_digit)w; } } STATIC int s_ksqr(mp_digit *da, mp_digit *dc, mp_size size_a) { if (multiply_threshold && size_a > multiply_threshold) { mp_size bot_size = (size_a + 1) / 2; mp_digit *a_top = da + bot_size; mp_digit *t1, *t2, *t3, carry; mp_size at_size = size_a - bot_size; mp_size buf_size = 2 * bot_size; if ((t1 = s_alloc(4 * buf_size)) == NULL) return 0; t2 = t1 + buf_size; t3 = t2 + buf_size; ZERO(t1, 4 * buf_size); (void) s_ksqr(da, t1, bot_size); /* t1 = a0 ^ 2 */ (void) s_ksqr(a_top, t2, at_size); /* t2 = a1 ^ 2 */ (void) s_kmul(da, a_top, t3, bot_size, at_size); /* t3 = a0 * a1 */ /* Quick multiply t3 by 2, shifting left (can't overflow) */ { int i, top = bot_size + at_size; mp_word w, save = 0; for (i = 0; i < top; ++i) { w = t3[i]; w = (w << 1) | save; t3[i] = LOWER_HALF(w); save = UPPER_HALF(w); } t3[i] = LOWER_HALF(save); } /* Assemble the output value */ COPY(t1, dc, 2 * bot_size); carry = s_uadd(t3, dc + bot_size, dc + bot_size, buf_size + 1, buf_size); assert(carry == 0); carry = s_uadd(t2, dc + 2*bot_size, dc + 2*bot_size, buf_size, buf_size); assert(carry == 0); s_free(t1); /* note that t2 and t2 are internal pointers only */ } else { s_usqr(da, dc, size_a); } return 1; } STATIC void s_usqr(mp_digit *da, mp_digit *dc, mp_size size_a) { mp_size i, j; mp_word w; for (i = 0; i < size_a; ++i, dc += 2, ++da) { mp_digit *dct = dc, *dat = da; if (*da == 0) continue; /* Take care of the first digit, no rollover */ w = (mp_word)*dat * (mp_word)*dat + (mp_word)*dct; *dct = LOWER_HALF(w); w = UPPER_HALF(w); ++dat; ++dct; for (j = i + 1; j < size_a; ++j, ++dat, ++dct) { mp_word t = (mp_word)*da * (mp_word)*dat; mp_word u = w + (mp_word)*dct, ov = 0; /* Check if doubling t will overflow a word */ if (HIGH_BIT_SET(t)) ov = 1; w = t + t; /* Check if adding u to w will overflow a word */ if (ADD_WILL_OVERFLOW(w, u)) ov = 1; w += u; *dct = LOWER_HALF(w); w = UPPER_HALF(w); if (ov) { w += MP_DIGIT_MAX; /* MP_RADIX */ ++w; } } w = w + *dct; *dct = (mp_digit)w; while ((w = UPPER_HALF(w)) != 0) { ++dct; w = w + *dct; *dct = LOWER_HALF(w); } assert(w == 0); } } STATIC void s_dadd(mp_int a, mp_digit b) { mp_word w = 0; mp_digit *da = MP_DIGITS(a); mp_size ua = MP_USED(a); w = (mp_word)*da + b; *da++ = LOWER_HALF(w); w = UPPER_HALF(w); for (ua -= 1; ua > 0; --ua, ++da) { w = (mp_word)*da + w; *da = LOWER_HALF(w); w = UPPER_HALF(w); } if (w) { *da = (mp_digit)w; MP_USED(a) += 1; } } STATIC void s_dmul(mp_int a, mp_digit b) { mp_word w = 0; mp_digit *da = MP_DIGITS(a); mp_size ua = MP_USED(a); while (ua > 0) { w = (mp_word)*da * b + w; *da++ = LOWER_HALF(w); w = UPPER_HALF(w); --ua; } if (w) { *da = (mp_digit)w; MP_USED(a) += 1; } } STATIC void s_dbmul(mp_digit *da, mp_digit b, mp_digit *dc, mp_size size_a) { mp_word w = 0; while (size_a > 0) { w = (mp_word)*da++ * (mp_word)b + w; *dc++ = LOWER_HALF(w); w = UPPER_HALF(w); --size_a; } if (w) *dc = LOWER_HALF(w); } STATIC mp_digit s_ddiv(mp_int a, mp_digit b) { mp_word w = 0, qdigit; mp_size ua = MP_USED(a); mp_digit *da = MP_DIGITS(a) + ua - 1; for (/* */; ua > 0; --ua, --da) { w = (w << MP_DIGIT_BIT) | *da; if (w >= b) { qdigit = w / b; w = w % b; } else { qdigit = 0; } *da = (mp_digit)qdigit; } CLAMP(a); return (mp_digit)w; } STATIC void s_qdiv(mp_int z, mp_size p2) { mp_size ndig = p2 / MP_DIGIT_BIT, nbits = p2 % MP_DIGIT_BIT; mp_size uz = MP_USED(z); if (ndig) { mp_size mark; mp_digit *to, *from; if (ndig >= uz) { mp_int_zero(z); return; } to = MP_DIGITS(z); from = to + ndig; for (mark = ndig; mark < uz; ++mark) *to++ = *from++; MP_USED(z) = uz - ndig; } if (nbits) { mp_digit d = 0, *dz, save; mp_size up = MP_DIGIT_BIT - nbits; uz = MP_USED(z); dz = MP_DIGITS(z) + uz - 1; for (/* */; uz > 0; --uz, --dz) { save = *dz; *dz = (*dz >> nbits) | (d << up); d = save; } CLAMP(z); } if (MP_USED(z) == 1 && z->digits[0] == 0) MP_SIGN(z) = MP_ZPOS; } STATIC void s_qmod(mp_int z, mp_size p2) { mp_size start = p2 / MP_DIGIT_BIT + 1, rest = p2 % MP_DIGIT_BIT; mp_size uz = MP_USED(z); mp_digit mask = (1u << rest) - 1; if (start <= uz) { MP_USED(z) = start; z->digits[start - 1] &= mask; CLAMP(z); } } STATIC int s_qmul(mp_int z, mp_size p2) { mp_size uz, need, rest, extra, i; mp_digit *from, *to, d; if (p2 == 0) return 1; uz = MP_USED(z); need = p2 / MP_DIGIT_BIT; rest = p2 % MP_DIGIT_BIT; /* Figure out if we need an extra digit at the top end; this occurs if the topmost `rest' bits of the high-order digit of z are not zero, meaning they will be shifted off the end if not preserved */ extra = 0; if (rest != 0) { mp_digit *dz = MP_DIGITS(z) + uz - 1; if ((*dz >> (MP_DIGIT_BIT - rest)) != 0) extra = 1; } if (!s_pad(z, uz + need + extra)) return 0; /* If we need to shift by whole digits, do that in one pass, then to back and shift by partial digits. */ if (need > 0) { from = MP_DIGITS(z) + uz - 1; to = from + need; for (i = 0; i < uz; ++i) *to-- = *from--; ZERO(MP_DIGITS(z), need); uz += need; } if (rest) { d = 0; for (i = need, from = MP_DIGITS(z) + need; i < uz; ++i, ++from) { mp_digit save = *from; *from = (*from << rest) | (d >> (MP_DIGIT_BIT - rest)); d = save; } d >>= (MP_DIGIT_BIT - rest); if (d != 0) { *from = d; uz += extra; } } MP_USED(z) = uz; CLAMP(z); return 1; } /* Compute z = 2^p2 - |z|; requires that 2^p2 >= |z| The sign of the result is always zero/positive. */ STATIC int s_qsub(mp_int z, mp_size p2) { mp_digit hi = (1 << (p2 % MP_DIGIT_BIT)), *zp; mp_size tdig = (p2 / MP_DIGIT_BIT), pos; mp_word w = 0; if (!s_pad(z, tdig + 1)) return 0; for (pos = 0, zp = MP_DIGITS(z); pos < tdig; ++pos, ++zp) { w = ((mp_word) MP_DIGIT_MAX + 1) - w - (mp_word)*zp; *zp = LOWER_HALF(w); w = UPPER_HALF(w) ? 0 : 1; } w = ((mp_word) MP_DIGIT_MAX + 1 + hi) - w - (mp_word)*zp; *zp = LOWER_HALF(w); assert(UPPER_HALF(w) != 0); /* no borrow out should be possible */ MP_SIGN(z) = MP_ZPOS; CLAMP(z); return 1; } STATIC int s_dp2k(mp_int z) { int k = 0; mp_digit *dp = MP_DIGITS(z), d; if (MP_USED(z) == 1 && *dp == 0) return 1; while (*dp == 0) { k += MP_DIGIT_BIT; ++dp; } d = *dp; while ((d & 1) == 0) { d >>= 1; ++k; } return k; } STATIC int s_isp2(mp_int z) { mp_size uz = MP_USED(z), k = 0; mp_digit *dz = MP_DIGITS(z), d; while (uz > 1) { if (*dz++ != 0) return -1; k += MP_DIGIT_BIT; --uz; } d = *dz; while (d > 1) { if (d & 1) return -1; ++k; d >>= 1; } return (int) k; } STATIC int s_2expt(mp_int z, mp_small k) { mp_size ndig, rest; mp_digit *dz; ndig = (k + MP_DIGIT_BIT) / MP_DIGIT_BIT; rest = k % MP_DIGIT_BIT; if (!s_pad(z, ndig)) return 0; dz = MP_DIGITS(z); ZERO(dz, ndig); *(dz + ndig - 1) = (1 << rest); MP_USED(z) = ndig; return 1; } STATIC int s_norm(mp_int a, mp_int b) { mp_digit d = b->digits[MP_USED(b) - 1]; int k = 0; while (d < (1u << (mp_digit)(MP_DIGIT_BIT - 1))) { /* d < (MP_RADIX / 2) */ d <<= 1; ++k; } /* These multiplications can't fail */ if (k != 0) { (void) s_qmul(a, (mp_size) k); (void) s_qmul(b, (mp_size) k); } return k; } STATIC mp_result s_brmu(mp_int z, mp_int m) { mp_size um = MP_USED(m) * 2; if (!s_pad(z, um)) return MP_MEMORY; s_2expt(z, MP_DIGIT_BIT * um); return mp_int_div(z, m, z, NULL); } STATIC int s_reduce(mp_int x, mp_int m, mp_int mu, mp_int q1, mp_int q2) { mp_size um = MP_USED(m), umb_p1, umb_m1; umb_p1 = (um + 1) * MP_DIGIT_BIT; umb_m1 = (um - 1) * MP_DIGIT_BIT; if (mp_int_copy(x, q1) != MP_OK) return 0; /* Compute q2 = floor((floor(x / b^(k-1)) * mu) / b^(k+1)) */ s_qdiv(q1, umb_m1); UMUL(q1, mu, q2); s_qdiv(q2, umb_p1); /* Set x = x mod b^(k+1) */ s_qmod(x, umb_p1); /* Now, q is a guess for the quotient a / m. Compute x - q * m mod b^(k+1), replacing x. This may be off by a factor of 2m, but no more than that. */ UMUL(q2, m, q1); s_qmod(q1, umb_p1); (void) mp_int_sub(x, q1, x); /* can't fail */ /* The result may be < 0; if it is, add b^(k+1) to pin it in the proper range. */ if ((CMPZ(x) < 0) && !s_qsub(x, umb_p1)) return 0; /* If x > m, we need to back it off until it is in range. This will be required at most twice. */ if (mp_int_compare(x, m) >= 0) { (void) mp_int_sub(x, m, x); if (mp_int_compare(x, m) >= 0) (void) mp_int_sub(x, m, x); } /* At this point, x has been properly reduced. */ return 1; } /* Perform modular exponentiation using Barrett's method, where mu is the reduction constant for m. Assumes a < m, b > 0. */ STATIC mp_result s_embar(mp_int a, mp_int b, mp_int m, mp_int mu, mp_int c) { mp_digit *db, *dbt, umu, d; mp_result res; DECLARE_TEMP(3); umu = MP_USED(mu); db = MP_DIGITS(b); dbt = db + MP_USED(b) - 1; while (last__ < 3) { SETUP(mp_int_init_size(LAST_TEMP(), 4 * umu)); ZERO(MP_DIGITS(TEMP(last__ - 1)), MP_ALLOC(TEMP(last__ - 1))); } (void) mp_int_set_value(c, 1); /* Take care of low-order digits */ while (db < dbt) { int i; for (d = *db, i = MP_DIGIT_BIT; i > 0; --i, d >>= 1) { if (d & 1) { /* The use of a second temporary avoids allocation */ UMUL(c, a, TEMP(0)); if (!s_reduce(TEMP(0), m, mu, TEMP(1), TEMP(2))) { res = MP_MEMORY; goto CLEANUP; } mp_int_copy(TEMP(0), c); } USQR(a, TEMP(0)); assert(MP_SIGN(TEMP(0)) == MP_ZPOS); if (!s_reduce(TEMP(0), m, mu, TEMP(1), TEMP(2))) { res = MP_MEMORY; goto CLEANUP; } assert(MP_SIGN(TEMP(0)) == MP_ZPOS); mp_int_copy(TEMP(0), a); } ++db; } /* Take care of highest-order digit */ d = *dbt; for (;;) { if (d & 1) { UMUL(c, a, TEMP(0)); if (!s_reduce(TEMP(0), m, mu, TEMP(1), TEMP(2))) { res = MP_MEMORY; goto CLEANUP; } mp_int_copy(TEMP(0), c); } d >>= 1; if (!d) break; USQR(a, TEMP(0)); if (!s_reduce(TEMP(0), m, mu, TEMP(1), TEMP(2))) { res = MP_MEMORY; goto CLEANUP; } (void) mp_int_copy(TEMP(0), a); } CLEANUP_TEMP(); return res; } /* Division of nonnegative integers This function implements division algorithm for unsigned multi-precision integers. The algorithm is based on Algorithm D from Knuth's "The Art of Computer Programming", 3rd ed. 1998, pg 272-273. We diverge from Knuth's algorithm in that we do not perform the subtraction from the remainder until we have determined that we have the correct quotient digit. This makes our algorithm less efficient that Knuth because we might have to perform multiple multiplication and comparison steps before the subtraction. The advantage is that it is easy to implement and ensure correctness without worrying about underflow from the subtraction. inputs: u a n+m digit integer in base b (b is 2^MP_DIGIT_BIT) v a n digit integer in base b (b is 2^MP_DIGIT_BIT) n >= 1 m >= 0 outputs: u / v stored in u u % v stored in v */ STATIC mp_result s_udiv_knuth(mp_int u, mp_int v) { mpz_t q, r, t; mp_result res = MP_OK; int k,j; mp_size m,n; /* Force signs to positive */ MP_SIGN(u) = MP_ZPOS; MP_SIGN(v) = MP_ZPOS; /* Use simple division algorithm when v is only one digit long */ if (MP_USED(v) == 1) { mp_digit d, rem; d = v->digits[0]; rem = s_ddiv(u, d); mp_int_set_value(v, rem); return MP_OK; } /* Algorithm D The n and m variables are defined as used by Knuth. u is an n digit number with digits u_{n-1}..u_0. v is an n+m digit number with digits from v_{m+n-1}..v_0. We require that n > 1 and m >= 0 */ n = MP_USED(v); m = MP_USED(u) - n; assert(n > 1); assert(m >= 0); /* D1: Normalize. The normalization step provides the necessary condition for Theorem B, which states that the quotient estimate for q_j, call it qhat qhat = u_{j+n}u_{j+n-1} / v_{n-1} is bounded by qhat - 2 <= q_j <= qhat. That is, qhat is always greater than the actual quotient digit q, and it is never more than two larger than the actual quotient digit. */ k = s_norm(u, v); /* Extend size of u by one if needed. The algorithm begins with a value of u that has one more digit of input. The normalization step sets u_{m+n}..u_0 = 2^k * u_{m+n-1}..u_0. If the multiplication did not increase the number of digits of u, we need to add a leading zero here. */ if (k == 0 || MP_USED(u) != m + n + 1) { if (!s_pad(u, m+n+1)) return MP_MEMORY; u->digits[m+n] = 0; u->used = m+n+1; } /* Add a leading 0 to v. The multiplication in step D4 multiplies qhat * 0v_{n-1}..v_0. We need to add the leading zero to v here to ensure that the multiplication will produce the full n+1 digit result. */ if (!s_pad(v, n+1)) return MP_MEMORY; v->digits[n] = 0; /* Initialize temporary variables q and t. q allocates space for m+1 digits to store the quotient digits t allocates space for n+1 digits to hold the result of q_j*v */ if ((res = mp_int_init_size(&q, m + 1)) != MP_OK) return res; if ((res = mp_int_init_size(&t, n + 1)) != MP_OK) goto CLEANUP; /* D2: Initialize j */ j = m; r.digits = MP_DIGITS(u) + j; /* The contents of r are shared with u */ r.used = n + 1; r.sign = MP_ZPOS; r.alloc = MP_ALLOC(u); ZERO(t.digits, t.alloc); /* Calculate the m+1 digits of the quotient result */ for (; j >= 0; j--) { /* D3: Calculate q' */ /* r->digits is aligned to position j of the number u */ mp_word pfx, qhat; pfx = r.digits[n]; pfx <<= MP_DIGIT_BIT / 2; pfx <<= MP_DIGIT_BIT / 2; pfx |= r.digits[n-1]; /* pfx = u_{j+n}{j+n-1} */ qhat = pfx / v->digits[n-1]; /* Check to see if qhat > b, and decrease qhat if so. Theorem B guarantess that qhat is at most 2 larger than the actual value, so it is possible that qhat is greater than the maximum value that will fit in a digit */ if (qhat > MP_DIGIT_MAX) qhat = MP_DIGIT_MAX; /* D4,D5,D6: Multiply qhat * v and test for a correct value of q We proceed a bit different than the way described by Knuth. This way is simpler but less efficent. Instead of doing the multiply and subtract then checking for underflow, we first do the multiply of qhat * v and see if it is larger than the current remainder r. If it is larger, we decrease qhat by one and try again. We may need to decrease qhat one more time before we get a value that is smaller than r. This way is less efficent than Knuth becuase we do more multiplies, but we do not need to worry about underflow this way. */ /* t = qhat * v */ s_dbmul(MP_DIGITS(v), (mp_digit) qhat, t.digits, n+1); t.used = n + 1; CLAMP(&t); /* Clamp r for the comparison. Comparisons do not like leading zeros. */ CLAMP(&r); if (s_ucmp(&t, &r) > 0) { /* would the remainder be negative? */ qhat -= 1; /* try a smaller q */ s_dbmul(MP_DIGITS(v), (mp_digit) qhat, t.digits, n+1); t.used = n + 1; CLAMP(&t); if (s_ucmp(&t, &r) > 0) { /* would the remainder be negative? */ assert(qhat > 0); qhat -= 1; /* try a smaller q */ s_dbmul(MP_DIGITS(v), (mp_digit) qhat, t.digits, n+1); t.used = n + 1; CLAMP(&t); } assert(s_ucmp(&t, &r) <= 0 && "The mathematics failed us."); } /* Unclamp r. The D algorithm expects r = u_{j+n}..u_j to always be n+1 digits long. */ r.used = n + 1; /* D4: Multiply and subtract Note: The multiply was completed above so we only need to subtract here. */ s_usub(r.digits, t.digits, r.digits, r.used, t.used); /* D5: Test remainder Note: Not needed because we always check that qhat is the correct value before performing the subtract. Value cast to mp_digit to prevent warning, qhat has been clamped to MP_DIGIT_MAX */ q.digits[j] = (mp_digit)qhat; /* D6: Add back Note: Not needed because we always check that qhat is the correct value before performing the subtract. */ /* D7: Loop on j */ r.digits--; ZERO(t.digits, t.alloc); } /* Get rid of leading zeros in q */ q.used = m + 1; CLAMP(&q); /* Denormalize the remainder */ CLAMP(u); /* use u here because the r.digits pointer is off-by-one */ if (k != 0) s_qdiv(u, k); mp_int_copy(u, v); /* ok: 0 <= r < v */ mp_int_copy(&q, u); /* ok: q <= u */ mp_int_clear(&t); CLEANUP: mp_int_clear(&q); return res; } STATIC int s_outlen(mp_int z, mp_size r) { mp_result bits; double raw; assert(r >= MP_MIN_RADIX && r <= MP_MAX_RADIX); bits = mp_int_count_bits(z); raw = (double)bits * s_log2[r]; return (int)(raw + 0.999999); } STATIC mp_size s_inlen(int len, mp_size r) { double raw = (double)len / s_log2[r]; mp_size bits = (mp_size)(raw + 0.5); return (mp_size)((bits + (MP_DIGIT_BIT - 1)) / MP_DIGIT_BIT) + 1; } STATIC int s_ch2val(char c, int r) { int out; if (isdigit((unsigned char) c)) out = c - '0'; else if (r > 10 && isalpha((unsigned char) c)) out = toupper(c) - 'A' + 10; else return -1; return (out >= r) ? -1 : out; } STATIC char s_val2ch(int v, int caps) { assert(v >= 0); if (v < 10) return v + '0'; else { char out = (v - 10) + 'a'; if (caps) return toupper(out); else return out; } } STATIC void s_2comp(unsigned char *buf, int len) { int i; unsigned short s = 1; for (i = len - 1; i >= 0; --i) { unsigned char c = ~buf[i]; s = c + s; c = s & UCHAR_MAX; s >>= CHAR_BIT; buf[i] = c; } /* last carry out is ignored */ } STATIC mp_result s_tobin(mp_int z, unsigned char *buf, int *limpos, int pad) { mp_size uz; mp_digit *dz; int pos = 0, limit = *limpos; uz = MP_USED(z); dz = MP_DIGITS(z); while (uz > 0 && pos < limit) { mp_digit d = *dz++; int i; for (i = sizeof(mp_digit); i > 0 && pos < limit; --i) { buf[pos++] = (unsigned char)d; d >>= CHAR_BIT; /* Don't write leading zeroes */ if (d == 0 && uz == 1) i = 0; /* exit loop without signaling truncation */ } /* Detect truncation (loop exited with pos >= limit) */ if (i > 0) break; --uz; } if (pad != 0 && (buf[pos - 1] >> (CHAR_BIT - 1))) { if (pos < limit) buf[pos++] = 0; else uz = 1; } /* Digits are in reverse order, fix that */ REV(unsigned char, buf, pos); /* Return the number of bytes actually written */ *limpos = pos; return (uz == 0) ? MP_OK : MP_TRUNC; } #if DEBUG void s_print(char *tag, mp_int z) { int i; fprintf(stderr, "%s: %c ", tag, (MP_SIGN(z) == MP_NEG) ? '-' : '+'); for (i = MP_USED(z) - 1; i >= 0; --i) fprintf(stderr, "%0*X", (int)(MP_DIGIT_BIT / 4), z->digits[i]); fputc('\n', stderr); } void s_print_buf(char *tag, mp_digit *buf, mp_size num) { int i; fprintf(stderr, "%s: ", tag); for (i = num - 1; i >= 0; --i) fprintf(stderr, "%0*X", (int)(MP_DIGIT_BIT / 4), buf[i]); fputc('\n', stderr); } #endif /* Here there be dragons */