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putty
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putty/sshpubk.c

1624 строки
43 KiB
C
Исходник Ответственный История

/*
* Generic SSH public-key handling operations. In particular,
* reading of SSH public-key files, and also the generic `sign'
* operation for SSH-2 (which checks the type of the key and
* dispatches to the appropriate key-type specific function).
*/
#include <stdio.h>
#include <stdlib.h>
#include <assert.h>
#include "putty.h"
#include "ssh.h"
#include "misc.h"
#define rsa_signature "SSH PRIVATE KEY FILE FORMAT 1.1\n"
#define BASE64_TOINT(x) ( (x)-'A'<26 ? (x)-'A'+0 :\
(x)-'a'<26 ? (x)-'a'+26 :\
(x)-'0'<10 ? (x)-'0'+52 :\
(x)=='+' ? 62 : \
(x)=='/' ? 63 : 0 )
static int key_type_fp(FILE *fp);
static int rsa_ssh1_load_main(FILE * fp, struct RSAKey *key, int pub_only,
char **commentptr, const char *passphrase,
const char **error)
{
strbuf *buf;
int ciphertype;
int ret = 0;
struct MD5Context md5c;
ptrlen comment;
BinarySource src[1];
*error = NULL;
/* Slurp the whole file (minus the header) into a buffer. */
buf = strbuf_new();
{
int ch;
while ((ch = fgetc(fp)) != EOF)
put_byte(buf, ch);
}
fclose(fp);
BinarySource_BARE_INIT(src, buf->u, buf->len);
*error = "file format error";
/*
* A zero byte. (The signature includes a terminating NUL, which
* we haven't gone past yet because we read it using fgets which
* stopped after the \n.)
*/
if (get_byte(src) != 0)
goto end;
/* One byte giving encryption type, and one reserved uint32. */
ciphertype = get_byte(src);
if (ciphertype != 0 && ciphertype != SSH_CIPHER_3DES)
goto end;
if (get_uint32(src) != 0)
goto end; /* reserved field nonzero, panic! */
/* Now the serious stuff. An ordinary SSH-1 public key. */
get_rsa_ssh1_pub(src, key, RSA_SSH1_MODULUS_FIRST);
/* Next, the comment field. */
comment = get_string(src);
if (commentptr)
*commentptr = mkstr(comment);
if (key)
key->comment = mkstr(comment);
if (pub_only) {
ret = 1;
goto end;
}
if (!key) {
ret = ciphertype != 0;
*error = NULL;
goto end;
}
/*
* Decrypt remainder of buffer.
*/
if (ciphertype) {
unsigned char keybuf[16];
size_t enclen = buf->len - src->pos;
if (enclen & 7)
goto end;
MD5Init(&md5c);
put_data(&md5c, passphrase, strlen(passphrase));
MD5Final(keybuf, &md5c);
des3_decrypt_pubkey(keybuf, buf->u + src->pos, enclen);
smemclr(keybuf, sizeof(keybuf)); /* burn the evidence */
}
/*
* We are now in the secret part of the key. The first four
* bytes should be of the form a, b, a, b.
*/
{
int b0a = get_byte(src);
int b1a = get_byte(src);
int b0b = get_byte(src);
int b1b = get_byte(src);
if (b0a != b0b || b1a != b1b) {
*error = "wrong passphrase";
ret = -1;
goto end;
}
}
/*
* After that, we have one further bignum which is our
* decryption exponent, and then the three auxiliary values
* (iqmp, q, p).
*/
get_rsa_ssh1_priv(src, key);
key->iqmp = get_mp_ssh1(src);
key->q = get_mp_ssh1(src);
key->p = get_mp_ssh1(src);
if (!rsa_verify(key)) {
*error = "rsa_verify failed";
freersakey(key);
ret = 0;
} else
ret = 1;
end:
strbuf_free(buf);
return ret;
}
int rsa_ssh1_loadkey(const Filename *filename, struct RSAKey *key,
const char *passphrase, const char **errorstr)
{
FILE *fp;
char buf[64];
int ret = 0;
const char *error = NULL;
fp = f_open(filename, "rb", FALSE);
if (!fp) {
error = "can't open file";
goto end;
}
/*
* Read the first line of the file and see if it's a v1 private
* key file.
*/
if (fgets(buf, sizeof(buf), fp) && !strcmp(buf, rsa_signature)) {
/*
* This routine will take care of calling fclose() for us.
*/
ret = rsa_ssh1_load_main(fp, key, FALSE, NULL, passphrase, &error);
fp = NULL;
goto end;
}
/*
* Otherwise, we have nothing. Return empty-handed.
*/
error = "not an SSH-1 RSA file";
end:
if (fp)
fclose(fp);
if ((ret != 1) && errorstr)
*errorstr = error;
return ret;
}
/*
* See whether an RSA key is encrypted. Return its comment field as
* well.
*/
int rsa_ssh1_encrypted(const Filename *filename, char **comment)
{
FILE *fp;
char buf[64];
fp = f_open(filename, "rb", FALSE);
if (!fp)
return 0; /* doesn't even exist */
/*
* Read the first line of the file and see if it's a v1 private
* key file.
*/
if (fgets(buf, sizeof(buf), fp) && !strcmp(buf, rsa_signature)) {
const char *dummy;
/*
* This routine will take care of calling fclose() for us.
*/
return rsa_ssh1_load_main(fp, NULL, FALSE, comment, NULL, &dummy);
}
fclose(fp);
return 0; /* wasn't the right kind of file */
}
/*
* Read the public part of an SSH-1 RSA key from a file (public or
* private), and generate its public blob in exponent-first order.
*/
int rsa_ssh1_loadpub(const Filename *filename, BinarySink *bs,
char **commentptr, const char **errorstr)
{
FILE *fp;
char buf[64];
struct RSAKey key;
int ret;
const char *error = NULL;
/* Default return if we fail. */
ret = FALSE;
fp = f_open(filename, "rb", FALSE);
if (!fp) {
error = "can't open file";
goto end;
}
/*
* Read the first line of the file and see if it's a v1 private
* key file.
*/
if (fgets(buf, sizeof(buf), fp) && !strcmp(buf, rsa_signature)) {
memset(&key, 0, sizeof(key));
if (rsa_ssh1_load_main(fp, &key, TRUE, commentptr, NULL, &error)) {
rsa_ssh1_public_blob(bs, &key, RSA_SSH1_EXPONENT_FIRST);
freersakey(&key);
ret = TRUE;
}
fp = NULL; /* rsa_ssh1_load_main unconditionally closes fp */
} else {
/*
* Try interpreting the file as an SSH-1 public key.
*/
char *line, *p, *bitsp, *expp, *modp, *commentp;
rewind(fp);
line = chomp(fgetline(fp));
p = line;
bitsp = p;
p += strspn(p, "0123456789");
if (*p != ' ')
goto not_public_either;
*p++ = '\0';
expp = p;
p += strspn(p, "0123456789");
if (*p != ' ')
goto not_public_either;
*p++ = '\0';
modp = p;
p += strspn(p, "0123456789");
if (*p) {
if (*p != ' ')
goto not_public_either;
*p++ = '\0';
commentp = p;
} else {
commentp = NULL;
}
memset(&key, 0, sizeof(key));
key.exponent = bignum_from_decimal(expp);
key.modulus = bignum_from_decimal(modp);
if (atoi(bitsp) != bignum_bitcount(key.modulus)) {
freebn(key.exponent);
freebn(key.modulus);
sfree(line);
error = "key bit count does not match in SSH-1 public key file";
goto end;
}
if (commentptr)
*commentptr = commentp ? dupstr(commentp) : NULL;
rsa_ssh1_public_blob(bs, &key, RSA_SSH1_EXPONENT_FIRST);
freersakey(&key);
sfree(line);
fclose(fp);
return TRUE;
not_public_either:
sfree(line);
error = "not an SSH-1 RSA file";
}
end:
if (fp)
fclose(fp);
if ((ret != 1) && errorstr)
*errorstr = error;
return ret;
}
/*
* Save an RSA key file. Return nonzero on success.
*/
int rsa_ssh1_savekey(const Filename *filename, struct RSAKey *key,
char *passphrase)
{
strbuf *buf = strbuf_new();
int estart;
FILE *fp;
/*
* The public part of the key.
*/
put_data(buf, rsa_signature, sizeof(rsa_signature));
put_byte(buf, passphrase ? SSH_CIPHER_3DES : 0); /* encryption type */
put_uint32(buf, 0); /* reserved */
rsa_ssh1_public_blob(BinarySink_UPCAST(buf), key,
RSA_SSH1_MODULUS_FIRST);
put_stringz(buf, NULLTOEMPTY(key->comment));
/*
* The encrypted portion starts here.
*/
estart = buf->len;
/*
* Two bytes, then the same two bytes repeated.
*/
{
unsigned char b0 = random_byte();
unsigned char b1 = random_byte();
put_byte(buf, b0);
put_byte(buf, b1);
put_byte(buf, b0);
put_byte(buf, b1);
}
/*
* Four more bignums: the decryption exponent, then iqmp, then
* q, then p.
*/
put_mp_ssh1(buf, key->private_exponent);
put_mp_ssh1(buf, key->iqmp);
put_mp_ssh1(buf, key->q);
put_mp_ssh1(buf, key->p);
/*
* Now write zeros until the encrypted portion is a multiple of
* 8 bytes.
*/
put_padding(buf, (estart - buf->len) & 7, 0);
/*
* Now encrypt the encrypted portion.
*/
if (passphrase) {
struct MD5Context md5c;
unsigned char keybuf[16];
MD5Init(&md5c);
put_data(&md5c, passphrase, strlen(passphrase));
MD5Final(keybuf, &md5c);
des3_encrypt_pubkey(keybuf, buf->u + estart, buf->len - estart);
smemclr(keybuf, sizeof(keybuf)); /* burn the evidence */
}
/*
* Done. Write the result to the file.
*/
fp = f_open(filename, "wb", TRUE);
if (fp) {
int ret = (fwrite(buf->u, 1, buf->len, fp) == (size_t) (buf->len));
if (fclose(fp))
ret = 0;
return ret;
} else
return 0;
}
/* ----------------------------------------------------------------------
* SSH-2 private key load/store functions.
*/
/*
* PuTTY's own format for SSH-2 keys is as follows:
*
* The file is text. Lines are terminated by CRLF, although CR-only
* and LF-only are tolerated on input.
*
* The first line says "PuTTY-User-Key-File-2: " plus the name of the
* algorithm ("ssh-dss", "ssh-rsa" etc).
*
* The next line says "Encryption: " plus an encryption type.
* Currently the only supported encryption types are "aes256-cbc"
* and "none".
*
* The next line says "Comment: " plus the comment string.
*
* Next there is a line saying "Public-Lines: " plus a number N.
* The following N lines contain a base64 encoding of the public
* part of the key. This is encoded as the standard SSH-2 public key
* blob (with no initial length): so for RSA, for example, it will
* read
*
* string "ssh-rsa"
* mpint exponent
* mpint modulus
*
* Next, there is a line saying "Private-Lines: " plus a number N,
* and then N lines containing the (potentially encrypted) private
* part of the key. For the key type "ssh-rsa", this will be
* composed of
*
* mpint private_exponent
* mpint p (the larger of the two primes)
* mpint q (the smaller prime)
* mpint iqmp (the inverse of q modulo p)
* data padding (to reach a multiple of the cipher block size)
*
* And for "ssh-dss", it will be composed of
*
* mpint x (the private key parameter)
* [ string hash 20-byte hash of mpints p || q || g only in old format ]
*
* Finally, there is a line saying "Private-MAC: " plus a hex
* representation of a HMAC-SHA-1 of:
*
* string name of algorithm ("ssh-dss", "ssh-rsa")
* string encryption type
* string comment
* string public-blob
* string private-plaintext (the plaintext version of the
* private part, including the final
* padding)
*
* The key to the MAC is itself a SHA-1 hash of:
*
* data "putty-private-key-file-mac-key"
* data passphrase
*
* (An empty passphrase is used for unencrypted keys.)
*
* If the key is encrypted, the encryption key is derived from the
* passphrase by means of a succession of SHA-1 hashes. Each hash
* is the hash of:
*
* uint32 sequence-number
* data passphrase
*
* where the sequence-number increases from zero. As many of these
* hashes are used as necessary.
*
* For backwards compatibility with snapshots between 0.51 and
* 0.52, we also support the older key file format, which begins
* with "PuTTY-User-Key-File-1" (version number differs). In this
* format the Private-MAC: field only covers the private-plaintext
* field and nothing else (and without the 4-byte string length on
* the front too). Moreover, the Private-MAC: field can be replaced
* with a Private-Hash: field which is a plain SHA-1 hash instead of
* an HMAC (this was generated for unencrypted keys).
*/
static int read_header(FILE * fp, char *header)
{
int len = 39;
int c;
while (1) {
c = fgetc(fp);
if (c == '\n' || c == '\r' || c == EOF)
return 0; /* failure */
if (c == ':') {
c = fgetc(fp);
if (c != ' ')
return 0;
*header = '\0';
return 1; /* success! */
}
if (len == 0)
return 0; /* failure */
*header++ = c;
len--;
}
return 0; /* failure */
}
static char *read_body(FILE * fp)
{
char *text;
int len;
int size;
int c;
size = 128;
text = snewn(size, char);
len = 0;
text[len] = '\0';
while (1) {
c = fgetc(fp);
if (c == '\r' || c == '\n' || c == EOF) {
if (c != EOF) {
c = fgetc(fp);
if (c != '\r' && c != '\n')
ungetc(c, fp);
}
return text;
}
if (len + 1 >= size) {
size += 128;
text = sresize(text, size, char);
}
text[len++] = c;
text[len] = '\0';
}
}
static int read_blob(FILE *fp, int nlines, BinarySink *bs)
{
unsigned char *blob;
char *line;
int linelen;
int i, j, k;
/* We expect at most 64 base64 characters, ie 48 real bytes, per line. */
blob = snewn(48 * nlines, unsigned char);
for (i = 0; i < nlines; i++) {
line = read_body(fp);
if (!line) {
sfree(blob);
return FALSE;
}
linelen = strlen(line);
if (linelen % 4 != 0 || linelen > 64) {
sfree(blob);
sfree(line);
return FALSE;
}
for (j = 0; j < linelen; j += 4) {
unsigned char decoded[3];
k = base64_decode_atom(line + j, decoded);
if (!k) {
sfree(line);
sfree(blob);
return FALSE;
}
put_data(bs, decoded, k);
}
sfree(line);
}
return TRUE;
}
/*
* Magic error return value for when the passphrase is wrong.
*/
struct ssh2_userkey ssh2_wrong_passphrase = { NULL, NULL };
const ssh_keyalg *find_pubkey_alg_len(ptrlen name)
{
if (ptrlen_eq_string(name, "ssh-rsa"))
return &ssh_rsa;
else if (ptrlen_eq_string(name, "ssh-dss"))
return &ssh_dss;
else if (ptrlen_eq_string(name, "ecdsa-sha2-nistp256"))
return &ssh_ecdsa_nistp256;
else if (ptrlen_eq_string(name, "ecdsa-sha2-nistp384"))
return &ssh_ecdsa_nistp384;
else if (ptrlen_eq_string(name, "ecdsa-sha2-nistp521"))
return &ssh_ecdsa_nistp521;
else if (ptrlen_eq_string(name, "ssh-ed25519"))
return &ssh_ecdsa_ed25519;
else
return NULL;
}
const ssh_keyalg *find_pubkey_alg(const char *name)
{
return find_pubkey_alg_len(ptrlen_from_asciz(name));
}
struct ssh2_userkey *ssh2_load_userkey(const Filename *filename,
const char *passphrase,
const char **errorstr)
{
FILE *fp;
char header[40], *b, *encryption, *comment, *mac;
const ssh_keyalg *alg;
struct ssh2_userkey *ret;
int cipher, cipherblk;
strbuf *public_blob, *private_blob;
int i, is_mac, old_fmt;
int passlen = passphrase ? strlen(passphrase) : 0;
const char *error = NULL;
ret = NULL; /* return NULL for most errors */
encryption = comment = mac = NULL;
public_blob = private_blob = NULL;
fp = f_open(filename, "rb", FALSE);
if (!fp) {
error = "can't open file";
goto error;
}
/* Read the first header line which contains the key type. */
if (!read_header(fp, header)) {
error = "no header line found in key file";
goto error;
}
if (0 == strcmp(header, "PuTTY-User-Key-File-2")) {
old_fmt = 0;
} else if (0 == strcmp(header, "PuTTY-User-Key-File-1")) {
/* this is an old key file; warn and then continue */
old_keyfile_warning();
old_fmt = 1;
} else if (0 == strncmp(header, "PuTTY-User-Key-File-", 20)) {
/* this is a key file FROM THE FUTURE; refuse it, but with a
* more specific error message than the generic one below */
error = "PuTTY key format too new";
goto error;
} else {
error = "not a PuTTY SSH-2 private key";
goto error;
}
error = "file format error";
if ((b = read_body(fp)) == NULL)
goto error;
/* Select key algorithm structure. */
alg = find_pubkey_alg(b);
if (!alg) {
sfree(b);
goto error;
}
sfree(b);
/* Read the Encryption header line. */
if (!read_header(fp, header) || 0 != strcmp(header, "Encryption"))
goto error;
if ((encryption = read_body(fp)) == NULL)
goto error;
if (!strcmp(encryption, "aes256-cbc")) {
cipher = 1;
cipherblk = 16;
} else if (!strcmp(encryption, "none")) {
cipher = 0;
cipherblk = 1;
} else {
goto error;
}
/* Read the Comment header line. */
if (!read_header(fp, header) || 0 != strcmp(header, "Comment"))
goto error;
if ((comment = read_body(fp)) == NULL)
goto error;
/* Read the Public-Lines header line and the public blob. */
if (!read_header(fp, header) || 0 != strcmp(header, "Public-Lines"))
goto error;
if ((b = read_body(fp)) == NULL)
goto error;
i = atoi(b);
sfree(b);
public_blob = strbuf_new();
if (!read_blob(fp, i, BinarySink_UPCAST(public_blob)))
goto error;
/* Read the Private-Lines header line and the Private blob. */
if (!read_header(fp, header) || 0 != strcmp(header, "Private-Lines"))
goto error;
if ((b = read_body(fp)) == NULL)
goto error;
i = atoi(b);
sfree(b);
private_blob = strbuf_new();
if (!read_blob(fp, i, BinarySink_UPCAST(private_blob)))
goto error;
/* Read the Private-MAC or Private-Hash header line. */
if (!read_header(fp, header))
goto error;
if (0 == strcmp(header, "Private-MAC")) {
if ((mac = read_body(fp)) == NULL)
goto error;
is_mac = 1;
} else if (0 == strcmp(header, "Private-Hash") && old_fmt) {
if ((mac = read_body(fp)) == NULL)
goto error;
is_mac = 0;
} else
goto error;
fclose(fp);
fp = NULL;
/*
* Decrypt the private blob.
*/
if (cipher) {
unsigned char key[40];
SHA_State s;
if (!passphrase)
goto error;
if (private_blob->len % cipherblk)
goto error;
SHA_Init(&s);
put_uint32(&s, 0);
put_data(&s, passphrase, passlen);
SHA_Final(&s, key + 0);
SHA_Init(&s);
put_uint32(&s, 1);
put_data(&s, passphrase, passlen);
SHA_Final(&s, key + 20);
aes256_decrypt_pubkey(key, private_blob->u, private_blob->len);
}
/*
* Verify the MAC.
*/
{
char realmac[41];
unsigned char binary[20];
strbuf *macdata;
int free_macdata;
if (old_fmt) {
/* MAC (or hash) only covers the private blob. */
macdata = private_blob;
free_macdata = FALSE;
} else {
macdata = strbuf_new();
put_stringz(macdata, alg->ssh_id);
put_stringz(macdata, encryption);
put_stringz(macdata, comment);
put_string(macdata, public_blob->s,
public_blob->len);
put_string(macdata, private_blob->s,
private_blob->len);
free_macdata = TRUE;
}
if (is_mac) {
SHA_State s;
unsigned char mackey[20];
char header[] = "putty-private-key-file-mac-key";
SHA_Init(&s);
put_data(&s, header, sizeof(header)-1);
if (cipher && passphrase)
put_data(&s, passphrase, passlen);
SHA_Final(&s, mackey);
hmac_sha1_simple(mackey, 20, macdata->s,
macdata->len, binary);
smemclr(mackey, sizeof(mackey));
smemclr(&s, sizeof(s));
} else {
SHA_Simple(macdata->s, macdata->len, binary);
}
if (free_macdata)
strbuf_free(macdata);
for (i = 0; i < 20; i++)
sprintf(realmac + 2 * i, "%02x", binary[i]);
if (strcmp(mac, realmac)) {
/* An incorrect MAC is an unconditional Error if the key is
* unencrypted. Otherwise, it means Wrong Passphrase. */
if (cipher) {
error = "wrong passphrase";
ret = SSH2_WRONG_PASSPHRASE;
} else {
error = "MAC failed";
ret = NULL;
}
goto error;
}
}
sfree(mac);
mac = NULL;
/*
* Create and return the key.
*/
ret = snew(struct ssh2_userkey);
ret->comment = comment;
ret->key = ssh_key_new_priv(
alg, ptrlen_from_strbuf(public_blob),
ptrlen_from_strbuf(private_blob));
if (!ret->key) {
sfree(ret);
ret = NULL;
error = "createkey failed";
goto error;
}
strbuf_free(public_blob);
strbuf_free(private_blob);
sfree(encryption);
if (errorstr)
*errorstr = NULL;
return ret;
/*
* Error processing.
*/
error:
if (fp)
fclose(fp);
if (comment)
sfree(comment);
if (encryption)
sfree(encryption);
if (mac)
sfree(mac);
if (public_blob)
strbuf_free(public_blob);
if (private_blob)
strbuf_free(private_blob);
if (errorstr)
*errorstr = error;
return ret;
}
int rfc4716_loadpub(FILE *fp, char **algorithm,
BinarySink *bs,
char **commentptr, const char **errorstr)
{
const char *error;
char *line, *colon, *value;
char *comment = NULL;
unsigned char *pubblob = NULL;
int pubbloblen, pubblobsize;
char base64in[4];
unsigned char base64out[3];
int base64bytes;
int alglen;
line = chomp(fgetline(fp));
if (!line || 0 != strcmp(line, "---- BEGIN SSH2 PUBLIC KEY ----")) {
error = "invalid begin line in SSH-2 public key file";
goto error;
}
sfree(line); line = NULL;
while (1) {
line = chomp(fgetline(fp));
if (!line) {
error = "truncated SSH-2 public key file";
goto error;
}
colon = strstr(line, ": ");
if (!colon)
break;
*colon = '\0';
value = colon + 2;
if (!strcmp(line, "Comment")) {
char *p, *q;
/* Remove containing double quotes, if present */
p = value;
if (*p == '"' && p[strlen(p)-1] == '"') {
p[strlen(p)-1] = '\0';
p++;
}
/* Remove \-escaping, not in RFC4716 but seen in the wild
* in practice. */
for (q = line; *p; p++) {
if (*p == '\\' && p[1])
p++;
*q++ = *p;
}
*q = '\0';
sfree(comment); /* *just* in case of multiple Comment headers */
comment = dupstr(line);
} else if (!strcmp(line, "Subject") ||
!strncmp(line, "x-", 2)) {
/* Headers we recognise and ignore. Do nothing. */
} else {
error = "unrecognised header in SSH-2 public key file";
goto error;
}
sfree(line); line = NULL;
}
/*
* Now line contains the initial line of base64 data. Loop round
* while it still does contain base64.
*/
pubblobsize = 4096;
pubblob = snewn(pubblobsize, unsigned char);
pubbloblen = 0;
base64bytes = 0;
while (line && line[0] != '-') {
char *p;
for (p = line; *p; p++) {
base64in[base64bytes++] = *p;
if (base64bytes == 4) {
int n = base64_decode_atom(base64in, base64out);
if (pubbloblen + n > pubblobsize) {
pubblobsize = (pubbloblen + n) * 5 / 4 + 1024;
pubblob = sresize(pubblob, pubblobsize, unsigned char);
}
memcpy(pubblob + pubbloblen, base64out, n);
pubbloblen += n;
base64bytes = 0;
}
}
sfree(line); line = NULL;
line = chomp(fgetline(fp));
}
/*
* Finally, check the END line makes sense.
*/
if (!line || 0 != strcmp(line, "---- END SSH2 PUBLIC KEY ----")) {
error = "invalid end line in SSH-2 public key file";
goto error;
}
sfree(line); line = NULL;
/*
* OK, we now have a public blob and optionally a comment. We must
* return the key algorithm string too, so look for that at the
* start of the public blob.
*/
if (pubbloblen < 4) {
error = "not enough data in SSH-2 public key file";
goto error;
}
alglen = toint(GET_32BIT(pubblob));
if (alglen < 0 || alglen > pubbloblen-4) {
error = "invalid algorithm prefix in SSH-2 public key file";
goto error;
}
if (algorithm)
*algorithm = dupprintf("%.*s", alglen, pubblob+4);
if (commentptr)
*commentptr = comment;
else
sfree(comment);
put_data(bs, pubblob, pubbloblen);
sfree(pubblob);
return TRUE;
error:
sfree(line);
sfree(comment);
sfree(pubblob);
if (errorstr)
*errorstr = error;
return FALSE;
}
int openssh_loadpub(FILE *fp, char **algorithm,
BinarySink *bs,
char **commentptr, const char **errorstr)
{
const char *error;
char *line, *base64;
char *comment = NULL;
unsigned char *pubblob = NULL;
int pubbloblen, pubblobsize;
int alglen;
line = chomp(fgetline(fp));
base64 = strchr(line, ' ');
if (!base64) {
error = "no key blob in OpenSSH public key file";
goto error;
}
*base64++ = '\0';
comment = strchr(base64, ' ');
if (comment) {
*comment++ = '\0';
comment = dupstr(comment);
}
pubblobsize = strlen(base64) / 4 * 3;
pubblob = snewn(pubblobsize, unsigned char);
pubbloblen = 0;
while (!memchr(base64, '\0', 4)) {
assert(pubbloblen + 3 <= pubblobsize);
pubbloblen += base64_decode_atom(base64, pubblob + pubbloblen);
base64 += 4;
}
if (*base64) {
error = "invalid length for base64 data in OpenSSH public key file";
goto error;
}
/*
* Sanity check: the first word on the line should be the key
* algorithm, and should match the encoded string at the start of
* the public blob.
*/
alglen = strlen(line);
if (pubbloblen < alglen + 4 ||
GET_32BIT(pubblob) != alglen ||
0 != memcmp(pubblob + 4, line, alglen)) {
error = "key algorithms do not match in OpenSSH public key file";
goto error;
}
/*
* Done.
*/
if (algorithm)
*algorithm = dupstr(line);
if (commentptr)
*commentptr = comment;
else
sfree(comment);
sfree(line);
put_data(bs, pubblob, pubbloblen);
sfree(pubblob);
return TRUE;
error:
sfree(line);
sfree(comment);
sfree(pubblob);
if (errorstr)
*errorstr = error;
return FALSE;
}
int ssh2_userkey_loadpub(const Filename *filename, char **algorithm,
BinarySink *bs,
char **commentptr, const char **errorstr)
{
FILE *fp;
char header[40], *b;
const ssh_keyalg *alg;
int type, i;
const char *error = NULL;
char *comment = NULL;
fp = f_open(filename, "rb", FALSE);
if (!fp) {
error = "can't open file";
goto error;
}
/* Initially, check if this is a public-only key file. Sometimes
* we'll be asked to read a public blob from one of those. */
type = key_type_fp(fp);
if (type == SSH_KEYTYPE_SSH2_PUBLIC_RFC4716) {
int ret = rfc4716_loadpub(fp, algorithm, bs, commentptr, errorstr);
fclose(fp);
return ret;
} else if (type == SSH_KEYTYPE_SSH2_PUBLIC_OPENSSH) {
int ret = openssh_loadpub(fp, algorithm, bs, commentptr, errorstr);
fclose(fp);
return ret;
} else if (type != SSH_KEYTYPE_SSH2) {
error = "not a PuTTY SSH-2 private key";
goto error;
}
/* Read the first header line which contains the key type. */
if (!read_header(fp, header)
|| (0 != strcmp(header, "PuTTY-User-Key-File-2") &&
0 != strcmp(header, "PuTTY-User-Key-File-1"))) {
if (0 == strncmp(header, "PuTTY-User-Key-File-", 20))
error = "PuTTY key format too new";
else
error = "not a PuTTY SSH-2 private key";
goto error;
}
error = "file format error";
if ((b = read_body(fp)) == NULL)
goto error;
/* Select key algorithm structure. */
alg = find_pubkey_alg(b);
sfree(b);
if (!alg) {
goto error;
}
/* Read the Encryption header line. */
if (!read_header(fp, header) || 0 != strcmp(header, "Encryption"))
goto error;
if ((b = read_body(fp)) == NULL)
goto error;
sfree(b); /* we don't care */
/* Read the Comment header line. */
if (!read_header(fp, header) || 0 != strcmp(header, "Comment"))
goto error;
if ((comment = read_body(fp)) == NULL)
goto error;
if (commentptr)
*commentptr = comment;
else
sfree(comment);
/* Read the Public-Lines header line and the public blob. */
if (!read_header(fp, header) || 0 != strcmp(header, "Public-Lines"))
goto error;
if ((b = read_body(fp)) == NULL)
goto error;
i = atoi(b);
sfree(b);
if (!read_blob(fp, i, bs))
goto error;
fclose(fp);
if (algorithm)
*algorithm = dupstr(alg->ssh_id);
return TRUE;
/*
* Error processing.
*/
error:
if (fp)
fclose(fp);
if (errorstr)
*errorstr = error;
if (comment && commentptr) {
sfree(comment);
*commentptr = NULL;
}
return FALSE;
}
int ssh2_userkey_encrypted(const Filename *filename, char **commentptr)
{
FILE *fp;
char header[40], *b, *comment;
int ret;
if (commentptr)
*commentptr = NULL;
fp = f_open(filename, "rb", FALSE);
if (!fp)
return 0;
if (!read_header(fp, header)
|| (0 != strcmp(header, "PuTTY-User-Key-File-2") &&
0 != strcmp(header, "PuTTY-User-Key-File-1"))) {
fclose(fp);
return 0;
}
if ((b = read_body(fp)) == NULL) {
fclose(fp);
return 0;
}
sfree(b); /* we don't care about key type here */
/* Read the Encryption header line. */
if (!read_header(fp, header) || 0 != strcmp(header, "Encryption")) {
fclose(fp);
return 0;
}
if ((b = read_body(fp)) == NULL) {
fclose(fp);
return 0;
}
/* Read the Comment header line. */
if (!read_header(fp, header) || 0 != strcmp(header, "Comment")) {
fclose(fp);
sfree(b);
return 1;
}
if ((comment = read_body(fp)) == NULL) {
fclose(fp);
sfree(b);
return 1;
}
if (commentptr)
*commentptr = comment;
else
sfree(comment);
fclose(fp);
if (!strcmp(b, "aes256-cbc"))
ret = 1;
else
ret = 0;
sfree(b);
return ret;
}
int base64_lines(int datalen)
{
/* When encoding, we use 64 chars/line, which equals 48 real chars. */
return (datalen + 47) / 48;
}
void base64_encode(FILE *fp, const unsigned char *data, int datalen, int cpl)
{
int linelen = 0;
char out[4];
int n, i;
while (datalen > 0) {
n = (datalen < 3 ? datalen : 3);
base64_encode_atom(data, n, out);
data += n;
datalen -= n;
for (i = 0; i < 4; i++) {
if (linelen >= cpl) {
linelen = 0;
fputc('\n', fp);
}
fputc(out[i], fp);
linelen++;
}
}
fputc('\n', fp);
}
int ssh2_save_userkey(const Filename *filename, struct ssh2_userkey *key,
char *passphrase)
{
FILE *fp;
strbuf *pub_blob, *priv_blob;
unsigned char *priv_blob_encrypted;
int priv_encrypted_len;
int passlen;
int cipherblk;
int i;
const char *cipherstr;
unsigned char priv_mac[20];
/*
* Fetch the key component blobs.
*/
pub_blob = strbuf_new();
ssh_key_public_blob(key->key, BinarySink_UPCAST(pub_blob));
priv_blob = strbuf_new();
ssh_key_private_blob(key->key, BinarySink_UPCAST(priv_blob));
/*
* Determine encryption details, and encrypt the private blob.
*/
if (passphrase) {
cipherstr = "aes256-cbc";
cipherblk = 16;
} else {
cipherstr = "none";
cipherblk = 1;
}
priv_encrypted_len = priv_blob->len + cipherblk - 1;
priv_encrypted_len -= priv_encrypted_len % cipherblk;
priv_blob_encrypted = snewn(priv_encrypted_len, unsigned char);
memset(priv_blob_encrypted, 0, priv_encrypted_len);
memcpy(priv_blob_encrypted, priv_blob->u, priv_blob->len);
/* Create padding based on the SHA hash of the unpadded blob. This prevents
* too easy a known-plaintext attack on the last block. */
SHA_Simple(priv_blob->u, priv_blob->len, priv_mac);
assert(priv_encrypted_len - priv_blob->len < 20);
memcpy(priv_blob_encrypted + priv_blob->len, priv_mac,
priv_encrypted_len - priv_blob->len);
/* Now create the MAC. */
{
strbuf *macdata;
SHA_State s;
unsigned char mackey[20];
char header[] = "putty-private-key-file-mac-key";
macdata = strbuf_new();
put_stringz(macdata, ssh_key_ssh_id(key->key));
put_stringz(macdata, cipherstr);
put_stringz(macdata, key->comment);
put_string(macdata, pub_blob->s, pub_blob->len);
put_string(macdata, priv_blob_encrypted, priv_encrypted_len);
SHA_Init(&s);
put_data(&s, header, sizeof(header)-1);
if (passphrase)
put_data(&s, passphrase, strlen(passphrase));
SHA_Final(&s, mackey);
hmac_sha1_simple(mackey, 20, macdata->s,
macdata->len, priv_mac);
strbuf_free(macdata);
smemclr(mackey, sizeof(mackey));
smemclr(&s, sizeof(s));
}
if (passphrase) {
unsigned char key[40];
SHA_State s;
passlen = strlen(passphrase);
SHA_Init(&s);
put_uint32(&s, 0);
put_data(&s, passphrase, passlen);
SHA_Final(&s, key + 0);
SHA_Init(&s);
put_uint32(&s, 1);
put_data(&s, passphrase, passlen);
SHA_Final(&s, key + 20);
aes256_encrypt_pubkey(key, priv_blob_encrypted,
priv_encrypted_len);
smemclr(key, sizeof(key));
smemclr(&s, sizeof(s));
}
fp = f_open(filename, "w", TRUE);
if (!fp) {
strbuf_free(pub_blob);
strbuf_free(priv_blob);
smemclr(priv_blob_encrypted, priv_encrypted_len);
sfree(priv_blob_encrypted);
return 0;
}
fprintf(fp, "PuTTY-User-Key-File-2: %s\n", ssh_key_ssh_id(key->key));
fprintf(fp, "Encryption: %s\n", cipherstr);
fprintf(fp, "Comment: %s\n", key->comment);
fprintf(fp, "Public-Lines: %d\n", base64_lines(pub_blob->len));
base64_encode(fp, pub_blob->u, pub_blob->len, 64);
fprintf(fp, "Private-Lines: %d\n", base64_lines(priv_encrypted_len));
base64_encode(fp, priv_blob_encrypted, priv_encrypted_len, 64);
fprintf(fp, "Private-MAC: ");
for (i = 0; i < 20; i++)
fprintf(fp, "%02x", priv_mac[i]);
fprintf(fp, "\n");
fclose(fp);
strbuf_free(pub_blob);
strbuf_free(priv_blob);
smemclr(priv_blob_encrypted, priv_encrypted_len);
sfree(priv_blob_encrypted);
return 1;
}
/* ----------------------------------------------------------------------
* Output public keys.
*/
char *ssh1_pubkey_str(struct RSAKey *key)
{
char *buffer;
char *dec1, *dec2;
dec1 = bignum_decimal(key->exponent);
dec2 = bignum_decimal(key->modulus);
buffer = dupprintf("%d %s %s%s%s", bignum_bitcount(key->modulus),
dec1, dec2,
key->comment ? " " : "",
key->comment ? key->comment : "");
sfree(dec1);
sfree(dec2);
return buffer;
}
void ssh1_write_pubkey(FILE *fp, struct RSAKey *key)
{
char *buffer = ssh1_pubkey_str(key);
fprintf(fp, "%s\n", buffer);
sfree(buffer);
}
static char *ssh2_pubkey_openssh_str_internal(const char *comment,
const void *v_pub_blob,
int pub_len)
{
const unsigned char *ssh2blob = (const unsigned char *)v_pub_blob;
ptrlen alg;
char *buffer, *p;
int i;
{
BinarySource src[1];
BinarySource_BARE_INIT(src, ssh2blob, pub_len);
alg = get_string(src);
if (get_err(src)) {
const char *replacement_str = "INVALID-ALGORITHM";
alg.ptr = replacement_str;
alg.len = strlen(replacement_str);
}
}
buffer = snewn(alg.len +
4 * ((pub_len+2) / 3) +
(comment ? strlen(comment) : 0) + 3, char);
p = buffer + sprintf(buffer, "%.*s ", PTRLEN_PRINTF(alg));
i = 0;
while (i < pub_len) {
int n = (pub_len - i < 3 ? pub_len - i : 3);
base64_encode_atom(ssh2blob + i, n, p);
i += n;
p += 4;
}
if (comment) {
*p++ = ' ';
strcpy(p, comment);
} else
*p++ = '\0';
return buffer;
}
char *ssh2_pubkey_openssh_str(struct ssh2_userkey *key)
{
strbuf *blob;
char *ret;
blob = strbuf_new();
ssh_key_public_blob(key->key, BinarySink_UPCAST(blob));
ret = ssh2_pubkey_openssh_str_internal(
key->comment, blob->s, blob->len);
strbuf_free(blob);
return ret;
}
void ssh2_write_pubkey(FILE *fp, const char *comment,
const void *v_pub_blob, int pub_len,
int keytype)
{
unsigned char *pub_blob = (unsigned char *)v_pub_blob;
if (keytype == SSH_KEYTYPE_SSH2_PUBLIC_RFC4716) {
const char *p;
int i, column;
fprintf(fp, "---- BEGIN SSH2 PUBLIC KEY ----\n");
if (comment) {
fprintf(fp, "Comment: \"");
for (p = comment; *p; p++) {
if (*p == '\\' || *p == '\"')
fputc('\\', fp);
fputc(*p, fp);
}
fprintf(fp, "\"\n");
}
i = 0;
column = 0;
while (i < pub_len) {
char buf[5];
int n = (pub_len - i < 3 ? pub_len - i : 3);
base64_encode_atom(pub_blob + i, n, buf);
i += n;
buf[4] = '\0';
fputs(buf, fp);
if (++column >= 16) {
fputc('\n', fp);
column = 0;
}
}
if (column > 0)
fputc('\n', fp);
fprintf(fp, "---- END SSH2 PUBLIC KEY ----\n");
} else if (keytype == SSH_KEYTYPE_SSH2_PUBLIC_OPENSSH) {
char *buffer = ssh2_pubkey_openssh_str_internal(comment,
v_pub_blob, pub_len);
fprintf(fp, "%s\n", buffer);
sfree(buffer);
} else {
assert(0 && "Bad key type in ssh2_write_pubkey");
}
}
/* ----------------------------------------------------------------------
* Utility functions to compute SSH-2 fingerprints in a uniform way.
*/
char *ssh2_fingerprint_blob(const void *blob, int bloblen)
{
unsigned char digest[16];
char fingerprint_str[16*3];
ptrlen algname;
const ssh_keyalg *alg;
int i;
BinarySource src[1];
/*
* The fingerprint hash itself is always just the MD5 of the blob.
*/
MD5Simple(blob, bloblen, digest);
for (i = 0; i < 16; i++)
sprintf(fingerprint_str + i*3, "%02x%s", digest[i], i==15 ? "" : ":");
/*
* Identify the key algorithm, if possible.
*/
BinarySource_BARE_INIT(src, blob, bloblen);
algname = get_string(src);
if (!get_err(src)) {
alg = find_pubkey_alg_len(algname);
if (alg) {
int bits = ssh_key_public_bits(alg, make_ptrlen(blob, bloblen));
return dupprintf("%.*s %d %s", PTRLEN_PRINTF(algname),
bits, fingerprint_str);
} else {
return dupprintf("%.*s %s", PTRLEN_PRINTF(algname),
fingerprint_str);
}
} else {
/*
* No algorithm available (which means a seriously confused
* key blob, but there we go). Return only the hash.
*/
return dupstr(fingerprint_str);
}
}
char *ssh2_fingerprint(ssh_key *data)
{
strbuf *blob = strbuf_new();
ssh_key_public_blob(data, BinarySink_UPCAST(blob));
char *ret = ssh2_fingerprint_blob(blob->s, blob->len);
strbuf_free(blob);
return ret;
}
/* ----------------------------------------------------------------------
* Determine the type of a private key file.
*/
static int key_type_fp(FILE *fp)
{
char buf[1024];
const char public_std_sig[] = "---- BEGIN SSH2 PUBLIC KEY";
const char putty2_sig[] = "PuTTY-User-Key-File-";
const char sshcom_sig[] = "---- BEGIN SSH2 ENCRYPTED PRIVAT";
const char openssh_new_sig[] = "-----BEGIN OPENSSH PRIVATE KEY";
const char openssh_sig[] = "-----BEGIN ";
int i;
char *p;
i = fread(buf, 1, sizeof(buf)-1, fp);
rewind(fp);
if (i < 0)
return SSH_KEYTYPE_UNOPENABLE;
if (i < 32)
return SSH_KEYTYPE_UNKNOWN;
assert(i > 0 && i < sizeof(buf));
buf[i] = '\0';
if (!memcmp(buf, rsa_signature, sizeof(rsa_signature)-1))
return SSH_KEYTYPE_SSH1;
if (!memcmp(buf, public_std_sig, sizeof(public_std_sig)-1))
return SSH_KEYTYPE_SSH2_PUBLIC_RFC4716;
if (!memcmp(buf, putty2_sig, sizeof(putty2_sig)-1))
return SSH_KEYTYPE_SSH2;
if (!memcmp(buf, openssh_new_sig, sizeof(openssh_new_sig)-1))
return SSH_KEYTYPE_OPENSSH_NEW;
if (!memcmp(buf, openssh_sig, sizeof(openssh_sig)-1))
return SSH_KEYTYPE_OPENSSH_PEM;
if (!memcmp(buf, sshcom_sig, sizeof(sshcom_sig)-1))
return SSH_KEYTYPE_SSHCOM;
if ((p = buf + strspn(buf, "0123456789"), *p == ' ') &&
(p = p+1 + strspn(p+1, "0123456789"), *p == ' ') &&
(p = p+1 + strspn(p+1, "0123456789"), *p == ' ' || *p == '\n' || !*p))
return SSH_KEYTYPE_SSH1_PUBLIC;
if ((p = buf + strcspn(buf, " "),
find_pubkey_alg_len(make_ptrlen(buf, p-buf))) &&
(p = p+1 + strspn(p+1, "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghij"
"klmnopqrstuvwxyz+/="),
*p == ' ' || *p == '\n' || !*p))
return SSH_KEYTYPE_SSH2_PUBLIC_OPENSSH;
return SSH_KEYTYPE_UNKNOWN; /* unrecognised or EOF */
}
int key_type(const Filename *filename)
{
FILE *fp;
int ret;
fp = f_open(filename, "r", FALSE);
if (!fp)
return SSH_KEYTYPE_UNOPENABLE;
ret = key_type_fp(fp);
fclose(fp);
return ret;
}
/*
* Convert the type word to a string, for `wrong type' error
* messages.
*/
const char *key_type_to_str(int type)
{
switch (type) {
case SSH_KEYTYPE_UNOPENABLE: return "unable to open file"; break;
case SSH_KEYTYPE_UNKNOWN: return "not a recognised key file format"; break;
case SSH_KEYTYPE_SSH1_PUBLIC: return "SSH-1 public key"; break;
case SSH_KEYTYPE_SSH2_PUBLIC_RFC4716: return "SSH-2 public key (RFC 4716 format)"; break;
case SSH_KEYTYPE_SSH2_PUBLIC_OPENSSH: return "SSH-2 public key (OpenSSH format)"; break;
case SSH_KEYTYPE_SSH1: return "SSH-1 private key"; break;
case SSH_KEYTYPE_SSH2: return "PuTTY SSH-2 private key"; break;
case SSH_KEYTYPE_OPENSSH_PEM: return "OpenSSH SSH-2 private key (old PEM format)"; break;
case SSH_KEYTYPE_OPENSSH_NEW: return "OpenSSH SSH-2 private key (new format)"; break;
case SSH_KEYTYPE_SSHCOM: return "ssh.com SSH-2 private key"; break;
/*
* This function is called with a key type derived from
* looking at an actual key file, so the output-only type
* OPENSSH_AUTO should never get here, and is much an INTERNAL
* ERROR as a code we don't even understand.
*/
case SSH_KEYTYPE_OPENSSH_AUTO: return "INTERNAL ERROR (OPENSSH_AUTO)"; break;
default: return "INTERNAL ERROR"; break;
}
}
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