зеркало из https://github.com/github/putty.git
477 строки
13 KiB
C
477 строки
13 KiB
C
/*
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* Digital Signature Standard implementation for PuTTY.
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*/
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#include <stdio.h>
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#include <stdlib.h>
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#include <assert.h>
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#include "ssh.h"
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#include "mpint.h"
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#include "misc.h"
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static void dss_freekey(ssh_key *key); /* forward reference */
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static ssh_key *dss_new_pub(const ssh_keyalg *self, ptrlen data)
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{
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BinarySource src[1];
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struct dss_key *dss;
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BinarySource_BARE_INIT(src, data.ptr, data.len);
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if (!ptrlen_eq_string(get_string(src), "ssh-dss"))
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return NULL;
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dss = snew(struct dss_key);
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dss->sshk.vt = &ssh_dss;
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dss->p = get_mp_ssh2(src);
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dss->q = get_mp_ssh2(src);
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dss->g = get_mp_ssh2(src);
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dss->y = get_mp_ssh2(src);
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dss->x = NULL;
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if (get_err(src) ||
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mp_eq_integer(dss->p, 0) || mp_eq_integer(dss->q, 0)) {
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/* Invalid key. */
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dss_freekey(&dss->sshk);
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return NULL;
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}
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return &dss->sshk;
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}
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static void dss_freekey(ssh_key *key)
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{
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struct dss_key *dss = container_of(key, struct dss_key, sshk);
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if (dss->p)
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mp_free(dss->p);
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if (dss->q)
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mp_free(dss->q);
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if (dss->g)
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mp_free(dss->g);
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if (dss->y)
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mp_free(dss->y);
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if (dss->x)
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mp_free(dss->x);
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sfree(dss);
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}
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static void append_hex_to_strbuf(strbuf *sb, mp_int *x)
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{
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if (sb->len > 0)
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put_byte(sb, ',');
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put_data(sb, "0x", 2);
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char *hex = mp_get_hex(x);
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size_t hexlen = strlen(hex);
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put_data(sb, hex, hexlen);
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smemclr(hex, hexlen);
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sfree(hex);
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}
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static char *dss_cache_str(ssh_key *key)
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{
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struct dss_key *dss = container_of(key, struct dss_key, sshk);
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strbuf *sb = strbuf_new();
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if (!dss->p)
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return NULL;
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append_hex_to_strbuf(sb, dss->p);
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append_hex_to_strbuf(sb, dss->q);
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append_hex_to_strbuf(sb, dss->g);
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append_hex_to_strbuf(sb, dss->y);
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return strbuf_to_str(sb);
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}
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static bool dss_verify(ssh_key *key, ptrlen sig, ptrlen data)
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{
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struct dss_key *dss = container_of(key, struct dss_key, sshk);
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BinarySource src[1];
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unsigned char hash[20];
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bool toret;
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if (!dss->p)
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return false;
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BinarySource_BARE_INIT(src, sig.ptr, sig.len);
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/*
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* Commercial SSH (2.0.13) and OpenSSH disagree over the format
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* of a DSA signature. OpenSSH is in line with RFC 4253:
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* it uses a string "ssh-dss", followed by a 40-byte string
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* containing two 160-bit integers end-to-end. Commercial SSH
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* can't be bothered with the header bit, and considers a DSA
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* signature blob to be _just_ the 40-byte string containing
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* the two 160-bit integers. We tell them apart by measuring
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* the length: length 40 means the commercial-SSH bug, anything
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* else is assumed to be RFC-compliant.
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*/
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if (sig.len != 40) { /* bug not present; read admin fields */
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ptrlen type = get_string(src);
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sig = get_string(src);
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if (get_err(src) || !ptrlen_eq_string(type, "ssh-dss") ||
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sig.len != 40)
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return false;
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}
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/* Now we're sitting on a 40-byte string for sure. */
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mp_int *r = mp_from_bytes_be(make_ptrlen(sig.ptr, 20));
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mp_int *s = mp_from_bytes_be(make_ptrlen((const char *)sig.ptr + 20, 20));
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if (!r || !s) {
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if (r)
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mp_free(r);
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if (s)
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mp_free(s);
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return false;
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}
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if (mp_eq_integer(s, 0)) {
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mp_free(r);
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mp_free(s);
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return false;
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}
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/*
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* Step 1. w <- s^-1 mod q.
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*/
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mp_int *w = mp_invert(s, dss->q);
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if (!w) {
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mp_free(r);
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mp_free(s);
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return false;
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}
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/*
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* Step 2. u1 <- SHA(message) * w mod q.
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*/
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SHA_Simple(data.ptr, data.len, hash);
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mp_int *sha = mp_from_bytes_be(make_ptrlen(hash, 20));
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mp_int *u1 = mp_modmul(sha, w, dss->q);
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/*
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* Step 3. u2 <- r * w mod q.
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*/
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mp_int *u2 = mp_modmul(r, w, dss->q);
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/*
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* Step 4. v <- (g^u1 * y^u2 mod p) mod q.
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*/
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mp_int *gu1p = mp_modpow(dss->g, u1, dss->p);
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mp_int *yu2p = mp_modpow(dss->y, u2, dss->p);
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mp_int *gu1yu2p = mp_modmul(gu1p, yu2p, dss->p);
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mp_int *v = mp_mod(gu1yu2p, dss->q);
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/*
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* Step 5. v should now be equal to r.
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*/
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toret = mp_cmp_eq(v, r);
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mp_free(w);
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mp_free(sha);
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mp_free(u1);
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mp_free(u2);
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mp_free(gu1p);
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mp_free(yu2p);
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mp_free(gu1yu2p);
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mp_free(v);
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mp_free(r);
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mp_free(s);
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return toret;
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}
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static void dss_public_blob(ssh_key *key, BinarySink *bs)
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{
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struct dss_key *dss = container_of(key, struct dss_key, sshk);
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put_stringz(bs, "ssh-dss");
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put_mp_ssh2(bs, dss->p);
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put_mp_ssh2(bs, dss->q);
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put_mp_ssh2(bs, dss->g);
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put_mp_ssh2(bs, dss->y);
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}
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static void dss_private_blob(ssh_key *key, BinarySink *bs)
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{
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struct dss_key *dss = container_of(key, struct dss_key, sshk);
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put_mp_ssh2(bs, dss->x);
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}
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static ssh_key *dss_new_priv(const ssh_keyalg *self, ptrlen pub, ptrlen priv)
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{
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BinarySource src[1];
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ssh_key *sshk;
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struct dss_key *dss;
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ptrlen hash;
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SHA_State s;
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unsigned char digest[20];
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mp_int *ytest;
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sshk = dss_new_pub(self, pub);
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if (!sshk)
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return NULL;
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dss = container_of(sshk, struct dss_key, sshk);
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BinarySource_BARE_INIT(src, priv.ptr, priv.len);
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dss->x = get_mp_ssh2(src);
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if (get_err(src)) {
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dss_freekey(&dss->sshk);
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return NULL;
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}
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/*
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* Check the obsolete hash in the old DSS key format.
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*/
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hash = get_string(src);
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if (hash.len == 20) {
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SHA_Init(&s);
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put_mp_ssh2(&s, dss->p);
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put_mp_ssh2(&s, dss->q);
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put_mp_ssh2(&s, dss->g);
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SHA_Final(&s, digest);
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if (!smemeq(hash.ptr, digest, 20)) {
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dss_freekey(&dss->sshk);
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return NULL;
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}
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}
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/*
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* Now ensure g^x mod p really is y.
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*/
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ytest = mp_modpow(dss->g, dss->x, dss->p);
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if (!mp_cmp_eq(ytest, dss->y)) {
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mp_free(ytest);
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dss_freekey(&dss->sshk);
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return NULL;
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}
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mp_free(ytest);
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return &dss->sshk;
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}
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static ssh_key *dss_new_priv_openssh(const ssh_keyalg *self,
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BinarySource *src)
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{
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struct dss_key *dss;
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dss = snew(struct dss_key);
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dss->sshk.vt = &ssh_dss;
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dss->p = get_mp_ssh2(src);
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dss->q = get_mp_ssh2(src);
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dss->g = get_mp_ssh2(src);
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dss->y = get_mp_ssh2(src);
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dss->x = get_mp_ssh2(src);
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if (get_err(src) ||
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mp_eq_integer(dss->q, 0) || mp_eq_integer(dss->p, 0)) {
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/* Invalid key. */
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dss_freekey(&dss->sshk);
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return NULL;
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}
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return &dss->sshk;
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}
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static void dss_openssh_blob(ssh_key *key, BinarySink *bs)
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{
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struct dss_key *dss = container_of(key, struct dss_key, sshk);
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put_mp_ssh2(bs, dss->p);
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put_mp_ssh2(bs, dss->q);
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put_mp_ssh2(bs, dss->g);
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put_mp_ssh2(bs, dss->y);
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put_mp_ssh2(bs, dss->x);
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}
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static int dss_pubkey_bits(const ssh_keyalg *self, ptrlen pub)
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{
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ssh_key *sshk;
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struct dss_key *dss;
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int ret;
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sshk = dss_new_pub(self, pub);
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if (!sshk)
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return -1;
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dss = container_of(sshk, struct dss_key, sshk);
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ret = mp_get_nbits(dss->p);
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dss_freekey(&dss->sshk);
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return ret;
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}
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mp_int *dss_gen_k(const char *id_string, mp_int *modulus,
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mp_int *private_key,
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unsigned char *digest, int digest_len)
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{
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/*
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* The basic DSS signing algorithm is:
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*
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* - invent a random k between 1 and q-1 (exclusive).
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* - Compute r = (g^k mod p) mod q.
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* - Compute s = k^-1 * (hash + x*r) mod q.
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*
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* This has the dangerous properties that:
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*
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* - if an attacker in possession of the public key _and_ the
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* signature (for example, the host you just authenticated
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* to) can guess your k, he can reverse the computation of s
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* and work out x = r^-1 * (s*k - hash) mod q. That is, he
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* can deduce the private half of your key, and masquerade
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* as you for as long as the key is still valid.
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*
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* - since r is a function purely of k and the public key, if
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* the attacker only has a _range of possibilities_ for k
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* it's easy for him to work through them all and check each
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* one against r; he'll never be unsure of whether he's got
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* the right one.
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*
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* - if you ever sign two different hashes with the same k, it
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* will be immediately obvious because the two signatures
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* will have the same r, and moreover an attacker in
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* possession of both signatures (and the public key of
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* course) can compute k = (hash1-hash2) * (s1-s2)^-1 mod q,
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* and from there deduce x as before.
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*
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* - the Bleichenbacher attack on DSA makes use of methods of
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* generating k which are significantly non-uniformly
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* distributed; in particular, generating a 160-bit random
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* number and reducing it mod q is right out.
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*
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* For this reason we must be pretty careful about how we
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* generate our k. Since this code runs on Windows, with no
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* particularly good system entropy sources, we can't trust our
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* RNG itself to produce properly unpredictable data. Hence, we
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* use a totally different scheme instead.
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*
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* What we do is to take a SHA-512 (_big_) hash of the private
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* key x, and then feed this into another SHA-512 hash that
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* also includes the message hash being signed. That is:
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*
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* proto_k = SHA512 ( SHA512(x) || SHA160(message) )
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*
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* This number is 512 bits long, so reducing it mod q won't be
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* noticeably non-uniform. So
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*
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* k = proto_k mod q
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*
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* This has the interesting property that it's _deterministic_:
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* signing the same hash twice with the same key yields the
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* same signature.
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*
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* Despite this determinism, it's still not predictable to an
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* attacker, because in order to repeat the SHA-512
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* construction that created it, the attacker would have to
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* know the private key value x - and by assumption he doesn't,
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* because if he knew that he wouldn't be attacking k!
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*
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* (This trick doesn't, _per se_, protect against reuse of k.
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* Reuse of k is left to chance; all it does is prevent
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* _excessively high_ chances of reuse of k due to entropy
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* problems.)
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*
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* Thanks to Colin Plumb for the general idea of using x to
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* ensure k is hard to guess, and to the Cambridge University
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* Computer Security Group for helping to argue out all the
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* fine details.
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*/
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SHA512_State ss;
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unsigned char digest512[64];
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/*
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* Hash some identifying text plus x.
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*/
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SHA512_Init(&ss);
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put_asciz(&ss, id_string);
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put_mp_ssh2(&ss, private_key);
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SHA512_Final(&ss, digest512);
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/*
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* Now hash that digest plus the message hash.
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*/
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SHA512_Init(&ss);
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put_data(&ss, digest512, sizeof(digest512));
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put_data(&ss, digest, digest_len);
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SHA512_Final(&ss, digest512);
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/*
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* Now convert the result into a bignum, and coerce it to the
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* range [2,q), which we do by reducing it mod q-2 and adding 2.
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*/
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mp_int *modminus2 = mp_copy(modulus);
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mp_sub_integer_into(modminus2, modminus2, 2);
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mp_int *proto_k = mp_from_bytes_be(make_ptrlen(digest512, 64));
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mp_int *k = mp_mod(proto_k, modminus2);
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mp_free(proto_k);
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mp_free(modminus2);
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mp_add_integer_into(k, k, 2);
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smemclr(&ss, sizeof(ss));
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smemclr(digest512, sizeof(digest512));
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return k;
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}
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static void dss_sign(ssh_key *key, ptrlen data, unsigned flags, BinarySink *bs)
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{
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struct dss_key *dss = container_of(key, struct dss_key, sshk);
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unsigned char digest[20];
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int i;
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SHA_Simple(data.ptr, data.len, digest);
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mp_int *k = dss_gen_k("DSA deterministic k generator", dss->q, dss->x,
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digest, sizeof(digest));
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mp_int *kinv = mp_invert(k, dss->q); /* k^-1 mod q */
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/*
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* Now we have k, so just go ahead and compute the signature.
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*/
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mp_int *gkp = mp_modpow(dss->g, k, dss->p); /* g^k mod p */
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mp_int *r = mp_mod(gkp, dss->q); /* r = (g^k mod p) mod q */
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mp_free(gkp);
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mp_int *hash = mp_from_bytes_be(make_ptrlen(digest, 20));
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mp_int *hxr = mp_mul(dss->x, r);
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mp_add_into(hxr, hxr, hash); /* hash + x*r */
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mp_int *s = mp_modmul(kinv, hxr, dss->q); /* s = k^-1 * (hash+x*r) mod q */
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mp_free(hxr);
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mp_free(kinv);
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mp_free(k);
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mp_free(hash);
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put_stringz(bs, "ssh-dss");
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put_uint32(bs, 40);
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for (i = 0; i < 20; i++)
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put_byte(bs, mp_get_byte(r, 19 - i));
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for (i = 0; i < 20; i++)
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put_byte(bs, mp_get_byte(s, 19 - i));
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mp_free(r);
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mp_free(s);
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}
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const ssh_keyalg ssh_dss = {
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dss_new_pub,
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dss_new_priv,
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dss_new_priv_openssh,
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dss_freekey,
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dss_sign,
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dss_verify,
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dss_public_blob,
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dss_private_blob,
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dss_openssh_blob,
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dss_cache_str,
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dss_pubkey_bits,
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"ssh-dss",
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"dss",
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NULL,
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0, /* no supported flags */
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};
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