putty/sshdssg.c

/*
 * DSS key generation.
 */

#include "misc.h"
#include "ssh.h"

int dsa_generate(struct dss_key *key, int bits, progfn_t pfn,
		 void *pfnparam)
{
    Bignum qm1, power, g, h, tmp;
    unsigned pfirst, qfirst;
    int progress;

    /*
     * Set up the phase limits for the progress report. We do this
     * by passing minus the phase number.
     *
     * For prime generation: our initial filter finds things
     * coprime to everything below 2^16. Computing the product of
     * (p-1)/p for all prime p below 2^16 gives about 20.33; so
     * among B-bit integers, one in every 20.33 will get through
     * the initial filter to be a candidate prime.
     *
     * Meanwhile, we are searching for primes in the region of 2^B;
     * since pi(x) ~ x/log(x), when x is in the region of 2^B, the
     * prime density will be d/dx pi(x) ~ 1/log(B), i.e. about
     * 1/0.6931B. So the chance of any given candidate being prime
     * is 20.33/0.6931B, which is roughly 29.34 divided by B.
     *
     * So now we have this probability P, we're looking at an
     * exponential distribution with parameter P: we will manage in
     * one attempt with probability P, in two with probability
     * P(1-P), in three with probability P(1-P)^2, etc. The
     * probability that we have still not managed to find a prime
     * after N attempts is (1-P)^N.
     * 
     * We therefore inform the progress indicator of the number B
     * (29.34/B), so that it knows how much to increment by each
     * time. We do this in 16-bit fixed point, so 29.34 becomes
     * 0x1D.57C4.
     */
    pfn(pfnparam, PROGFN_PHASE_EXTENT, 1, 0x2800);
    pfn(pfnparam, PROGFN_EXP_PHASE, 1, -0x1D57C4 / 160);
    pfn(pfnparam, PROGFN_PHASE_EXTENT, 2, 0x40 * bits);
    pfn(pfnparam, PROGFN_EXP_PHASE, 2, -0x1D57C4 / bits);

    /*
     * In phase three we are finding an order-q element of the
     * multiplicative group of p, by finding an element whose order
     * is _divisible_ by q and raising it to the power of (p-1)/q.
     * _Most_ elements will have order divisible by q, since for a
     * start phi(p) of them will be primitive roots. So
     * realistically we don't need to set this much below 1 (64K).
     * Still, we'll set it to 1/2 (32K) to be on the safe side.
     */
    pfn(pfnparam, PROGFN_PHASE_EXTENT, 3, 0x2000);
    pfn(pfnparam, PROGFN_EXP_PHASE, 3, -32768);

    /*
     * In phase four we are finding an element x between 1 and q-1
     * (exclusive), by inventing 160 random bits and hoping they
     * come out to a plausible number; so assuming q is uniformly
     * distributed between 2^159 and 2^160, the chance of any given
     * attempt succeeding is somewhere between 0.5 and 1. Lacking
     * the energy to arrange to be able to specify this probability
     * _after_ generating q, we'll just set it to 0.75.
     */
    pfn(pfnparam, PROGFN_PHASE_EXTENT, 4, 0x2000);
    pfn(pfnparam, PROGFN_EXP_PHASE, 4, -49152);

    pfn(pfnparam, PROGFN_READY, 0, 0);

    invent_firstbits(&pfirst, &qfirst);
    /*
     * Generate q: a prime of length 160.
     */
    key->q = primegen(160, 2, 2, NULL, 1, pfn, pfnparam, qfirst);
    /*
     * Now generate p: a prime of length `bits', such that p-1 is
     * divisible by q.
     */
    key->p = primegen(bits-160, 2, 2, key->q, 2, pfn, pfnparam, pfirst);

    /*
     * Next we need g. Raise 2 to the power (p-1)/q modulo p, and
     * if that comes out to one then try 3, then 4 and so on. As
     * soon as we hit a non-unit (and non-zero!) one, that'll do
     * for g.
     */
    power = bigdiv(key->p, key->q);    /* this is floor(p/q) == (p-1)/q */
    h = bignum_from_long(1);
    progress = 0;
    while (1) {
	pfn(pfnparam, PROGFN_PROGRESS, 3, ++progress);
	g = modpow(h, power, key->p);
	if (bignum_cmp(g, One) > 0)
	    break;		       /* got one */
	tmp = h;
	h = bignum_add_long(h, 1);
	freebn(tmp);
    }
    key->g = g;
    freebn(h);

    /*
     * Now we're nearly done. All we need now is our private key x,
     * which should be a number between 1 and q-1 exclusive, and
     * our public key y = g^x mod p.
     */
    qm1 = copybn(key->q);
    decbn(qm1);
    progress = 0;
    while (1) {
	int i, v, byte, bitsleft;
	Bignum x;

	pfn(pfnparam, PROGFN_PROGRESS, 4, ++progress);
	x = bn_power_2(159);
	byte = 0;
	bitsleft = 0;

	for (i = 0; i < 160; i++) {
	    if (bitsleft <= 0)
		bitsleft = 8, byte = random_byte();
	    v = byte & 1;
	    byte >>= 1;
	    bitsleft--;
	    bignum_set_bit(x, i, v);
	}

	if (bignum_cmp(x, One) <= 0 || bignum_cmp(x, qm1) >= 0) {
	    freebn(x);
	    continue;
	} else {
	    key->x = x;
	    break;
	}
    }
    freebn(qm1);

    key->y = modpow(key->g, key->x, key->p);

    return 1;
}
Arrgh, there's always one. Actually check in the extra file :-) [originally from svn r1286] 2001-09-23 01:00:53 +04:00			`/*`
			`* DSS key generation.`
			`*/`

			`#include "misc.h"`
			`#include "ssh.h"`

			`int dsa_generate(struct dss_key *key, int bits, progfn_t pfn,`
			`void *pfnparam)`
			`{`
			`Bignum qm1, power, g, h, tmp;`
Generate keys more carefully, so that when the user asks for an n-bit key they always get an n-bit number instead of n-1. The latter was perfectly harmless but kept confusing users. [originally from svn r9421] 2012-03-04 04:24:49 +04:00			`unsigned pfirst, qfirst;`
Arrgh, there's always one. Actually check in the extra file :-) [originally from svn r1286] 2001-09-23 01:00:53 +04:00			`int progress;`

			`/*`
			`* Set up the phase limits for the progress report. We do this`
			`* by passing minus the phase number.`
			`*`
			`* For prime generation: our initial filter finds things`
			`* coprime to everything below 2^16. Computing the product of`
			`* (p-1)/p for all prime p below 2^16 gives about 20.33; so`
			`* among B-bit integers, one in every 20.33 will get through`
			`* the initial filter to be a candidate prime.`
			`*`
			`* Meanwhile, we are searching for primes in the region of 2^B;`
			`* since pi(x) ~ x/log(x), when x is in the region of 2^B, the`
			`* prime density will be d/dx pi(x) ~ 1/log(B), i.e. about`
			`* 1/0.6931B. So the chance of any given candidate being prime`
			`* is 20.33/0.6931B, which is roughly 29.34 divided by B.`
			`*`
			`* So now we have this probability P, we're looking at an`
			`* exponential distribution with parameter P: we will manage in`
			`* one attempt with probability P, in two with probability`
			`* P(1-P), in three with probability P(1-P)^2, etc. The`
			`* probability that we have still not managed to find a prime`
			`* after N attempts is (1-P)^N.`
			`*`
			`* We therefore inform the progress indicator of the number B`
			`* (29.34/B), so that it knows how much to increment by each`
			`* time. We do this in 16-bit fixed point, so 29.34 becomes`
			`* 0x1D.57C4.`
			`*/`
			`pfn(pfnparam, PROGFN_PHASE_EXTENT, 1, 0x2800);`
			`pfn(pfnparam, PROGFN_EXP_PHASE, 1, -0x1D57C4 / 160);`
			`pfn(pfnparam, PROGFN_PHASE_EXTENT, 2, 0x40 * bits);`
			`pfn(pfnparam, PROGFN_EXP_PHASE, 2, -0x1D57C4 / bits);`

			`/*`
			`* In phase three we are finding an order-q element of the`
			`* multiplicative group of p, by finding an element whose order`
			`* is _divisible_ by q and raising it to the power of (p-1)/q.`
			`* _Most_ elements will have order divisible by q, since for a`
			`* start phi(p) of them will be primitive roots. So`
			`* realistically we don't need to set this much below 1 (64K).`
			`* Still, we'll set it to 1/2 (32K) to be on the safe side.`
			`*/`
			`pfn(pfnparam, PROGFN_PHASE_EXTENT, 3, 0x2000);`
			`pfn(pfnparam, PROGFN_EXP_PHASE, 3, -32768);`

			`/*`
			`* In phase four we are finding an element x between 1 and q-1`
			`* (exclusive), by inventing 160 random bits and hoping they`
			`* come out to a plausible number; so assuming q is uniformly`
			`* distributed between 2^159 and 2^160, the chance of any given`
			`* attempt succeeding is somewhere between 0.5 and 1. Lacking`
			`* the energy to arrange to be able to specify this probability`
			`* _after_ generating q, we'll just set it to 0.75.`
			`*/`
			`pfn(pfnparam, PROGFN_PHASE_EXTENT, 4, 0x2000);`
			`pfn(pfnparam, PROGFN_EXP_PHASE, 4, -49152);`

			`pfn(pfnparam, PROGFN_READY, 0, 0);`

Generate keys more carefully, so that when the user asks for an n-bit key they always get an n-bit number instead of n-1. The latter was perfectly harmless but kept confusing users. [originally from svn r9421] 2012-03-04 04:24:49 +04:00			`invent_firstbits(&pfirst, &qfirst);`
Arrgh, there's always one. Actually check in the extra file :-) [originally from svn r1286] 2001-09-23 01:00:53 +04:00			`/*`
			`* Generate q: a prime of length 160.`
			`*/`
Generate keys more carefully, so that when the user asks for an n-bit key they always get an n-bit number instead of n-1. The latter was perfectly harmless but kept confusing users. [originally from svn r9421] 2012-03-04 04:24:49 +04:00			`key->q = primegen(160, 2, 2, NULL, 1, pfn, pfnparam, qfirst);`
Arrgh, there's always one. Actually check in the extra file :-) [originally from svn r1286] 2001-09-23 01:00:53 +04:00			`/*`
			* Now generate p: a prime of length `bits', such that p-1 is
			`* divisible by q.`
			`*/`
Generate keys more carefully, so that when the user asks for an n-bit key they always get an n-bit number instead of n-1. The latter was perfectly harmless but kept confusing users. [originally from svn r9421] 2012-03-04 04:24:49 +04:00			`key->p = primegen(bits-160, 2, 2, key->q, 2, pfn, pfnparam, pfirst);`
Arrgh, there's always one. Actually check in the extra file :-) [originally from svn r1286] 2001-09-23 01:00:53 +04:00
			`/*`
			`* Next we need g. Raise 2 to the power (p-1)/q modulo p, and`
			`* if that comes out to one then try 3, then 4 and so on. As`
			`* soon as we hit a non-unit (and non-zero!) one, that'll do`
			`* for g.`
			`*/`
			`power = bigdiv(key->p, key->q); /* this is floor(p/q) == (p-1)/q */`
			`h = bignum_from_long(1);`
			`progress = 0;`
			`while (1) {`
			`pfn(pfnparam, PROGFN_PROGRESS, 3, ++progress);`
			`g = modpow(h, power, key->p);`
			`if (bignum_cmp(g, One) > 0)`
			`break; /* got one */`
			`tmp = h;`
			`h = bignum_add_long(h, 1);`
			`freebn(tmp);`
			`}`
			`key->g = g;`
			`freebn(h);`

			`/*`
			`* Now we're nearly done. All we need now is our private key x,`
			`* which should be a number between 1 and q-1 exclusive, and`
			`* our public key y = g^x mod p.`
			`*/`
			`qm1 = copybn(key->q);`
			`decbn(qm1);`
			`progress = 0;`
			`while (1) {`
			`int i, v, byte, bitsleft;`
			`Bignum x;`

			`pfn(pfnparam, PROGFN_PROGRESS, 4, ++progress);`
			`x = bn_power_2(159);`
			`byte = 0;`
			`bitsleft = 0;`

			`for (i = 0; i < 160; i++) {`
			`if (bitsleft <= 0)`
			`bitsleft = 8, byte = random_byte();`
			`v = byte & 1;`
			`byte >>= 1;`
			`bitsleft--;`
			`bignum_set_bit(x, i, v);`
			`}`

			`if (bignum_cmp(x, One) <= 0 \|\| bignum_cmp(x, qm1) >= 0) {`
			`freebn(x);`
			`continue;`
			`} else {`
			`key->x = x;`
			`break;`
			`}`
			`}`
			`freebn(qm1);`

			`key->y = modpow(key->g, key->x, key->p);`

			`return 1;`
			`}`