xref: /freebsd/contrib/bearssl/src/x509/x509_minimal.t0 (revision 42249ef2)

\ Copyright (c) 2016 Thomas Pornin <pornin@bolet.org>
\
\ 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.

preamble {

#include "inner.h"

/*
 * Implementation Notes
 * --------------------
 *
 * The C code pushes the data by chunks; all decoding is done in the
 * T0 code. The cert_length value is set to the certificate length when
 * a new certificate is started; the T0 code picks it up as outer limit,
 * and decoding functions use it to ensure that no attempt is made at
 * reading past it. The T0 code also checks that once the certificate is
 * decoded, there are no trailing bytes.
 *
 * The T0 code sets cert_length to 0 when the certificate is fully
 * decoded.
 *
 * The C code must still perform two checks:
 *
 *  -- If the certificate length is 0, then the T0 code will not be
 *  invoked at all. This invalid condition must thus be reported by the
 *  C code.
 *
 *  -- When reaching the end of certificate, the C code must verify that
 *  the certificate length has been set to 0, thereby signaling that
 *  the T0 code properly decoded a certificate.
 *
 * Processing of a chain works in the following way:
 *
 *  -- The error flag is set to a non-zero value when validation is
 *  finished. The value is either BR_ERR_X509_OK (validation is
 *  successful) or another non-zero error code. When a non-zero error
 *  code is obtained, the remaining bytes in the current certificate and
 *  the subsequent certificates (if any) are completely ignored.
 *
 *  -- Each certificate is decoded in due course, with the following
 *  "interesting points":
 *
 *     -- Start of the TBS: the multihash engine is reset and activated.
 *
 *     -- Start of the issuer DN: the secondary hash engine is started,
 *     to process the encoded issuer DN.
 *
 *     -- End of the issuer DN: the secondary hash engine is stopped. The
 *     resulting hash value is computed and then copied into the
 *     next_dn_hash[] buffer.
 *
 *     -- Start of the subject DN: the secondary hash engine is started,
 *     to process the encoded subject DN.
 *
 *     -- For the EE certificate only: the Common Name, if any, is matched
 *     against the expected server name.
 *
 *     -- End of the subject DN: the secondary hash engine is stopped. The
 *     resulting hash value is computed into the pad. It is then processed:
 *
 *        -- If this is the EE certificate, then the hash is ignored
 *        (except for direct trust processing, see later; the hash is
 *        simply left in current_dn_hash[]).
 *
 *        -- Otherwise, the hashed subject DN is compared with the saved
 *        hash value (in saved_dn_hash[]). They must match.
 *
 *     Either way, the next_dn_hash[] value is then copied into the
 *     saved_dn_hash[] value. Thus, at that point, saved_dn_hash[]
 *     contains the hash of the issuer DN for the current certificate,
 *     and current_dn_hash[] contains the hash of the subject DN for the
 *     current certificate.
 *
 *     -- Public key: it is decoded into the cert_pkey[] buffer. Unknown
 *     key types are reported at that point.
 *
 *        -- If this is the EE certificate, then the key type is compared
 *        with the expected key type (initialization parameter). The public
 *        key data is copied to ee_pkey_data[]. The key and hashed subject
 *        DN are also compared with the "direct trust" keys; if the key
 *        and DN are matched, then validation ends with a success.
 *
 *        -- Otherwise, the saved signature (cert_sig[]) is verified
 *        against the saved TBS hash (tbs_hash[]) and that freshly
 *        decoded public key. Failure here ends validation with an error.
 *
 *     -- Extensions: extension values are processed in due order.
 *
 *        -- Basic Constraints: for all certificates except EE, must be
 *        present, indicate a CA, and have a path legnth compatible with
 *        the chain length so far.
 *
 *        -- Key Usage: for the EE, if present, must allow signatures
 *        or encryption/key exchange, as required for the cipher suite.
 *        For non-EE, if present, must have the "certificate sign" bit.
 *
 *        -- Subject Alt Name: for the EE, dNSName names are matched
 *        against the server name. Ignored for non-EE.
 *
 *        -- Authority Key Identifier, Subject Key Identifier, Issuer
 *        Alt Name, Subject Directory Attributes, CRL Distribution Points
 *        Freshest CRL, Authority Info Access and Subject Info Access
 *        extensions are always ignored: they either contain only
 *        informative data, or they relate to revocation processing, which
 *        we explicitly do not support.
 *
 *        -- All other extensions are ignored if non-critical. If a
 *        critical extension other than the ones above is encountered,
 *        then a failure is reported.
 *
 *     -- End of the TBS: the multihash engine is stopped.
 *
 *     -- Signature algorithm: the signature algorithm on the
 *     certificate is decoded. A failure is reported if that algorithm
 *     is unknown. The hashed TBS corresponding to the signature hash
 *     function is computed and stored in tbs_hash[] (if not supported,
 *     then a failure is reported). The hash OID and length are stored
 *     in cert_sig_hash_oid and cert_sig_hash_len.
 *
 *     -- Signature value: the signature value is copied into the
 *     cert_sig[] array.
 *
 *     -- Certificate end: the hashed issuer DN (saved_dn_hash[]) is
 *     looked up in the trust store (CA trust anchors only); for all
 *     that match, the signature (cert_sig[]) is verified against the
 *     anchor public key (hashed TBS is in tbs_hash[]). If one of these
 *     signatures is valid, then validation ends with a success.
 *
 *  -- If the chain end is reached without obtaining a validation success,
 *  then validation is reported as failed.
 */

#if BR_USE_UNIX_TIME
#include <time.h>
#endif

#if BR_USE_WIN32_TIME
#include <windows.h>
#endif

/*
 * The T0 compiler will produce these prototypes declarations in the
 * header.
 *
void br_x509_minimal_init_main(void *ctx);
void br_x509_minimal_run(void *ctx);
 */

/* see bearssl_x509.h */
void
br_x509_minimal_init(br_x509_minimal_context *ctx,
	const br_hash_class *dn_hash_impl,
	const br_x509_trust_anchor *trust_anchors, size_t trust_anchors_num)
{
	memset(ctx, 0, sizeof *ctx);
	ctx->vtable = &br_x509_minimal_vtable;
	ctx->dn_hash_impl = dn_hash_impl;
	ctx->trust_anchors = trust_anchors;
	ctx->trust_anchors_num = trust_anchors_num;
}

static void
xm_start_chain(const br_x509_class **ctx, const char *server_name)
{
	br_x509_minimal_context *cc;
	size_t u;

	cc = (br_x509_minimal_context *)(void *)ctx;
	for (u = 0; u < cc->num_name_elts; u ++) {
		cc->name_elts[u].status = 0;
		cc->name_elts[u].buf[0] = 0;
	}
	memset(&cc->pkey, 0, sizeof cc->pkey);
	cc->num_certs = 0;
	cc->err = 0;
	cc->cpu.dp = cc->dp_stack;
	cc->cpu.rp = cc->rp_stack;
	br_x509_minimal_init_main(&cc->cpu);
	if (server_name == NULL || *server_name == 0) {
		cc->server_name = NULL;
	} else {
		cc->server_name = server_name;
	}
}

static void
xm_start_cert(const br_x509_class **ctx, uint32_t length)
{
	br_x509_minimal_context *cc;

	cc = (br_x509_minimal_context *)(void *)ctx;
	if (cc->err != 0) {
		return;
	}
	if (length == 0) {
		cc->err = BR_ERR_X509_TRUNCATED;
		return;
	}
	cc->cert_length = length;
}

static void
xm_append(const br_x509_class **ctx, const unsigned char *buf, size_t len)
{
	br_x509_minimal_context *cc;

	cc = (br_x509_minimal_context *)(void *)ctx;
	if (cc->err != 0) {
		return;
	}
	cc->hbuf = buf;
	cc->hlen = len;
	br_x509_minimal_run(&cc->cpu);
}

static void
xm_end_cert(const br_x509_class **ctx)
{
	br_x509_minimal_context *cc;

	cc = (br_x509_minimal_context *)(void *)ctx;
	if (cc->err == 0 && cc->cert_length != 0) {
		cc->err = BR_ERR_X509_TRUNCATED;
	}
	cc->num_certs ++;
}

static unsigned
xm_end_chain(const br_x509_class **ctx)
{
	br_x509_minimal_context *cc;

	cc = (br_x509_minimal_context *)(void *)ctx;
	if (cc->err == 0) {
		if (cc->num_certs == 0) {
			cc->err = BR_ERR_X509_EMPTY_CHAIN;
		} else {
			cc->err = BR_ERR_X509_NOT_TRUSTED;
		}
	} else if (cc->err == BR_ERR_X509_OK) {
		return 0;
	}
	return (unsigned)cc->err;
}

static const br_x509_pkey *
xm_get_pkey(const br_x509_class *const *ctx, unsigned *usages)
{
	br_x509_minimal_context *cc;

	cc = (br_x509_minimal_context *)(void *)ctx;
	if (cc->err == BR_ERR_X509_OK
		|| cc->err == BR_ERR_X509_NOT_TRUSTED)
	{
		if (usages != NULL) {
			*usages = cc->key_usages;
		}
		return &((br_x509_minimal_context *)(void *)ctx)->pkey;
	} else {
		return NULL;
	}
}

/* see bearssl_x509.h */
const br_x509_class br_x509_minimal_vtable = {
	sizeof(br_x509_minimal_context),
	xm_start_chain,
	xm_start_cert,
	xm_append,
	xm_end_cert,
	xm_end_chain,
	xm_get_pkey
};

#define CTX   ((br_x509_minimal_context *)(void *)((unsigned char *)t0ctx - offsetof(br_x509_minimal_context, cpu)))
#define CONTEXT_NAME   br_x509_minimal_context

#define DNHASH_LEN   ((CTX->dn_hash_impl->desc >> BR_HASHDESC_OUT_OFF) & BR_HASHDESC_OUT_MASK)

/*
 * Hash a DN (from a trust anchor) into the provided buffer. This uses the
 * DN hash implementation and context structure from the X.509 engine
 * context.
 */
static void
hash_dn(br_x509_minimal_context *ctx, const void *dn, size_t len,
	unsigned char *out)
{
	ctx->dn_hash_impl->init(&ctx->dn_hash.vtable);
	ctx->dn_hash_impl->update(&ctx->dn_hash.vtable, dn, len);
	ctx->dn_hash_impl->out(&ctx->dn_hash.vtable, out);
}

/*
 * Compare two big integers for equality. The integers use unsigned big-endian
 * encoding; extra leading bytes (of value 0) are allowed.
 */
static int
eqbigint(const unsigned char *b1, size_t len1,
	const unsigned char *b2, size_t len2)
{
	while (len1 > 0 && *b1 == 0) {
		b1 ++;
		len1 --;
	}
	while (len2 > 0 && *b2 == 0) {
		b2 ++;
		len2 --;
	}
	if (len1 != len2) {
		return 0;
	}
	return memcmp(b1, b2, len1) == 0;
}

/*
 * Compare two strings for equality, in a case-insensitive way. This
 * function handles casing only for ASCII letters.
 */
static int
eqnocase(const void *s1, const void *s2, size_t len)
{
	const unsigned char *buf1, *buf2;

	buf1 = s1;
	buf2 = s2;
	while (len -- > 0) {
		int x1, x2;

		x1 = *buf1 ++;
		x2 = *buf2 ++;
		if (x1 >= 'A' && x1 <= 'Z') {
			x1 += 'a' - 'A';
		}
		if (x2 >= 'A' && x2 <= 'Z') {
			x2 += 'a' - 'A';
		}
		if (x1 != x2) {
			return 0;
		}
	}
	return 1;
}

static int verify_signature(br_x509_minimal_context *ctx,
	const br_x509_pkey *pk);

}

postamble {

/*
 * Verify the signature on the certificate with the provided public key.
 * This function checks the public key type with regards to the expected
 * type. Returned value is either 0 on success, or a non-zero error code.
 */
static int
verify_signature(br_x509_minimal_context *ctx, const br_x509_pkey *pk)
{
	int kt;

	kt = ctx->cert_signer_key_type;
	if ((pk->key_type & 0x0F) != kt) {
		return BR_ERR_X509_WRONG_KEY_TYPE;
	}
	switch (kt) {
		unsigned char tmp[64];

	case BR_KEYTYPE_RSA:
		if (ctx->irsa == 0) {
			return BR_ERR_X509_UNSUPPORTED;
		}
		if (!ctx->irsa(ctx->cert_sig, ctx->cert_sig_len,
			&t0_datablock[ctx->cert_sig_hash_oid],
			ctx->cert_sig_hash_len, &pk->key.rsa, tmp))
		{
			return BR_ERR_X509_BAD_SIGNATURE;
		}
		if (memcmp(ctx->tbs_hash, tmp, ctx->cert_sig_hash_len) != 0) {
			return BR_ERR_X509_BAD_SIGNATURE;
		}
		return 0;

	case BR_KEYTYPE_EC:
		if (ctx->iecdsa == 0) {
			return BR_ERR_X509_UNSUPPORTED;
		}
		if (!ctx->iecdsa(ctx->iec, ctx->tbs_hash,
			ctx->cert_sig_hash_len, &pk->key.ec,
			ctx->cert_sig, ctx->cert_sig_len))
		{
			return BR_ERR_X509_BAD_SIGNATURE;
		}
		return 0;

	default:
		return BR_ERR_X509_UNSUPPORTED;
	}
}

}

cc: read8-low ( -- x ) {
	if (CTX->hlen == 0) {
		T0_PUSHi(-1);
	} else {
		unsigned char x = *CTX->hbuf ++;
		if (CTX->do_mhash) {
			br_multihash_update(&CTX->mhash, &x, 1);
		}
		if (CTX->do_dn_hash) {
			CTX->dn_hash_impl->update(&CTX->dn_hash.vtable, &x, 1);
		}
		CTX->hlen --;
		T0_PUSH(x);
	}
}

addr: cert_length
addr: num_certs

cc: read-blob-inner ( addr len -- addr len ) {
	uint32_t len = T0_POP();
	uint32_t addr = T0_POP();
	size_t clen = CTX->hlen;
	if (clen > len) {
		clen = (size_t)len;
	}
	if (addr != 0) {
		memcpy((unsigned char *)CTX + addr, CTX->hbuf, clen);
	}
	if (CTX->do_mhash) {
		br_multihash_update(&CTX->mhash, CTX->hbuf, clen);
	}
	if (CTX->do_dn_hash) {
		CTX->dn_hash_impl->update(
			&CTX->dn_hash.vtable, CTX->hbuf, clen);
	}
	CTX->hbuf += clen;
	CTX->hlen -= clen;
	T0_PUSH(addr + clen);
	T0_PUSH(len - clen);
}

\ Compute the TBS hash, using the provided hash ID. The hash value is
\ written in the tbs_hash[] array, and the hash length is returned. If
\ the requested hash function is not supported, then 0 is returned.
cc: compute-tbs-hash ( id -- hashlen ) {
	int id = T0_POPi();
	size_t len;
	len = br_multihash_out(&CTX->mhash, id, CTX->tbs_hash);
	T0_PUSH(len);
}

\ Push true (-1) if no server name is expected in the EE certificate.
cc: zero-server-name ( -- bool ) {
	T0_PUSHi(-(CTX->server_name == NULL));
}

addr: key_usages
addr: cert_sig
addr: cert_sig_len
addr: cert_signer_key_type
addr: cert_sig_hash_oid
addr: cert_sig_hash_len
addr: tbs_hash
addr: min_rsa_size

\ Start TBS hash computation. The hash functions are reinitialised.
cc: start-tbs-hash ( -- ) {
	br_multihash_init(&CTX->mhash);
	CTX->do_mhash = 1;
}

\ Stop TBS hash computation.
cc: stop-tbs-hash ( -- ) {
	CTX->do_mhash = 0;
}

\ Start DN hash computation.
cc: start-dn-hash ( -- ) {
	CTX->dn_hash_impl->init(&CTX->dn_hash.vtable);
	CTX->do_dn_hash = 1;
}

\ Terminate DN hash computation and write the DN hash into the
\ current_dn_hash buffer.
cc: compute-dn-hash ( -- ) {
	CTX->dn_hash_impl->out(&CTX->dn_hash.vtable, CTX->current_dn_hash);
	CTX->do_dn_hash = 0;
}

\ Get the length of hash values obtained with the DN hasher.
cc: dn-hash-length ( -- len ) {
	T0_PUSH(DNHASH_LEN);
}

\ Copy data between two areas in the context.
cc: blobcopy ( addr-dst addr-src len -- ) {
	size_t len = T0_POP();
	unsigned char *src = (unsigned char *)CTX + T0_POP();
	unsigned char *dst = (unsigned char *)CTX + T0_POP();
	memcpy(dst, src, len);
}

addr: current_dn_hash
addr: next_dn_hash
addr: saved_dn_hash

\ Read a DN, hashing it into current_dn_hash. The DN contents are not
\ inspected (only the outer tag, for SEQUENCE, is checked).
: read-DN ( lim -- lim )
	start-dn-hash
	read-sequence-open skip-close-elt
	compute-dn-hash ;

cc: offset-name-element ( san -- n ) {
	unsigned san = T0_POP();
	size_t u;

	for (u = 0; u < CTX->num_name_elts; u ++) {
		if (CTX->name_elts[u].status == 0) {
			const unsigned char *oid;
			size_t len, off;

			oid = CTX->name_elts[u].oid;
			if (san) {
				if (oid[0] != 0 || oid[1] != 0) {
					continue;
				}
				off = 2;
			} else {
				off = 0;
			}
			len = oid[off];
			if (len != 0 && len == CTX->pad[0]
				&& memcmp(oid + off + 1,
					CTX->pad + 1, len) == 0)
			{
				T0_PUSH(u);
				T0_RET();
			}
		}
	}
	T0_PUSHi(-1);
}

cc: copy-name-element ( bool offbuf -- ) {
	size_t len;
	int32_t off = T0_POPi();
	int ok = T0_POPi();

	if (off >= 0) {
		br_name_element *ne = &CTX->name_elts[off];

		if (ok) {
			len = CTX->pad[0];
			if (len < ne->len) {
				memcpy(ne->buf, CTX->pad + 1, len);
				ne->buf[len] = 0;
				ne->status = 1;
			} else {
				ne->status = -1;
			}
		} else {
			ne->status = -1;
		}
	}
}

cc: copy-name-SAN ( bool tag -- ) {
	unsigned tag = T0_POP();
	unsigned ok = T0_POP();
	size_t u, len;

	len = CTX->pad[0];
	for (u = 0; u < CTX->num_name_elts; u ++) {
		br_name_element *ne;

		ne = &CTX->name_elts[u];
		if (ne->status == 0 && ne->oid[0] == 0 && ne->oid[1] == tag) {
			if (ok && ne->len > len) {
				memcpy(ne->buf, CTX->pad + 1, len);
				ne->buf[len] = 0;
				ne->status = 1;
			} else {
				ne->status = -1;
			}
			break;
		}
	}
}

\ Read a value, decoding string types. If the string type is recognised
\ and the value could be converted to UTF-8 into the pad, then true (-1)
\ is returned; in all other cases, false (0) is returned. Either way, the
\ object is consumed.
: read-string ( lim -- lim bool )
	read-tag case
		\ UTF8String
		12 of check-primitive read-value-UTF8 endof
		\ NumericString
		18 of check-primitive read-value-latin1 endof
		\ PrintableString
		19 of check-primitive read-value-latin1 endof
		\ TeletexString
		20 of check-primitive read-value-latin1 endof
		\ IA5String
		22 of check-primitive read-value-latin1 endof
		\ BMPString
		30 of check-primitive read-value-UTF16 endof
		2drop read-length-skip 0 0
	endcase ;

\ Read a DN for the EE. The normalized DN hash is computed and stored in the
\ current_dn_hash.
\ Name elements are gathered. Also, the Common Name is matched against the
\ intended server name.
\ Returned value is true (-1) if the CN matches the intended server name,
\ false (0) otherwise.
: read-DN-EE ( lim -- lim bool )
	\ Flag will be set to true if there is a CN and it matches the
	\ intended server name.
	0 { eename-matches }

	\ Activate DN hashing.
	start-dn-hash

	\ Parse the DN structure: it is a SEQUENCE of SET of
	\ AttributeTypeAndValue. Each AttributeTypeAndValue is a
	\ SEQUENCE { OBJECT IDENTIFIER, ANY }.
	read-sequence-open
	begin
		dup while

		read-tag 0x11 check-tag-constructed read-length-open-elt
		dup ifnot ERR_X509_BAD_DN fail then
		begin
			dup while

			read-sequence-open

			\ Read the OID. If the OID could not be read (too
			\ long) then the first pad byte will be 0.
			read-OID drop

			\ If it is the Common Name then we'll need to
			\ match it against the intended server name (if
			\ applicable).
			id-at-commonName eqOID { isCN }

			\ Get offset for reception buffer for that element
			\ (or -1).
			0 offset-name-element { offbuf }

			\ Try to read the value as a string.
			read-string

			\ If the value could be decoded as a string,
			\ copy it and/or match it, as appropriate.
			dup isCN and if
				match-server-name if
					-1 >eename-matches
				then
			then
			offbuf copy-name-element

			\ Close the SEQUENCE
			close-elt

		repeat
		close-elt
	repeat
	close-elt

	\ Compute DN hash and deactivate DN hashing.
	compute-dn-hash

	\ Return the CN match flag.
	eename-matches ;

\ Get the validation date and time from the context or system.
cc: get-system-date ( -- days seconds ) {
	if (CTX->days == 0 && CTX->seconds == 0) {
#if BR_USE_UNIX_TIME
		time_t x = time(NULL);

		T0_PUSH((uint32_t)(x / 86400) + 719528);
		T0_PUSH((uint32_t)(x % 86400));
#elif BR_USE_WIN32_TIME
		FILETIME ft;
		uint64_t x;

		GetSystemTimeAsFileTime(&ft);
		x = ((uint64_t)ft.dwHighDateTime << 32)
			+ (uint64_t)ft.dwLowDateTime;
		x = (x / 10000000);
		T0_PUSH((uint32_t)(x / 86400) + 584754);
		T0_PUSH((uint32_t)(x % 86400));
#else
		CTX->err = BR_ERR_X509_TIME_UNKNOWN;
		T0_CO();
#endif
	} else {
		T0_PUSH(CTX->days);
		T0_PUSH(CTX->seconds);
	}
}

\ Compare two dates (days+seconds) together.
: before ( days1 seconds1 days2 seconds2 -- bool )
	{ d1 s1 d2 s2 }
	d1 d2 = if s1 s2 < else d1 d2 < then ;

: after ( days1 seconds1 days2 seconds2 -- bool )
	swap2 before ;

\ Swap the top two elements with the two elements immediately below.
: swap2 ( a b c d -- c d a b )
	3 roll 3 roll ;

\ Match the name in the pad with the expected server name. Returned value
\ is true (-1) on match, false (0) otherwise. If there is no expected
\ server name, then 0 is returned.
\ Match conditions: either an exact match (case insensitive), or a
\ wildcard match, if the found name starts with "*.". We only match a
\ starting wildcard, and only against a complete DN name component.
cc: match-server-name ( -- bool ) {
	size_t n1, n2;

	if (CTX->server_name == NULL) {
		T0_PUSH(0);
		T0_RET();
	}
	n1 = strlen(CTX->server_name);
	n2 = CTX->pad[0];
	if (n1 == n2 && eqnocase(&CTX->pad[1], CTX->server_name, n1)) {
		T0_PUSHi(-1);
		T0_RET();
	}
	if (n2 >= 2 && CTX->pad[1] == '*' && CTX->pad[2] == '.') {
		size_t u;

		u = 0;
		while (u < n1 && CTX->server_name[u] != '.') {
			u ++;
		}
		u ++;
		n1 -= u;
		if ((n2 - 2) == n1
			&& eqnocase(&CTX->pad[3], CTX->server_name + u, n1))
		{
			T0_PUSHi(-1);
			T0_RET();
		}
	}
	T0_PUSH(0);
}

\ Get the address and length for the pkey_data buffer.
: addr-len-pkey_data ( -- addr len )
	CX 0 8191 { offsetof(br_x509_minimal_context, pkey_data) }
	CX 0 8191 { BR_X509_BUFSIZE_KEY } ;

\ Copy the EE public key to the permanent buffer (RSA).
cc: copy-ee-rsa-pkey ( nlen elen -- ) {
	size_t elen = T0_POP();
	size_t nlen = T0_POP();
	memcpy(CTX->ee_pkey_data, CTX->pkey_data, nlen + elen);
	CTX->pkey.key_type = BR_KEYTYPE_RSA;
	CTX->pkey.key.rsa.n = CTX->ee_pkey_data;
	CTX->pkey.key.rsa.nlen = nlen;
	CTX->pkey.key.rsa.e = CTX->ee_pkey_data + nlen;
	CTX->pkey.key.rsa.elen = elen;
}

\ Copy the EE public key to the permanent buffer (EC).
cc: copy-ee-ec-pkey ( curve qlen -- ) {
	size_t qlen = T0_POP();
	uint32_t curve = T0_POP();
	memcpy(CTX->ee_pkey_data, CTX->pkey_data, qlen);
	CTX->pkey.key_type = BR_KEYTYPE_EC;
	CTX->pkey.key.ec.curve = curve;
	CTX->pkey.key.ec.q = CTX->ee_pkey_data;
	CTX->pkey.key.ec.qlen = qlen;
}

\ Check whether the current certificate (EE) is directly trusted.
cc: check-direct-trust ( -- ) {
	size_t u;

	for (u = 0; u < CTX->trust_anchors_num; u ++) {
		const br_x509_trust_anchor *ta;
		unsigned char hashed_DN[64];
		int kt;

		ta = &CTX->trust_anchors[u];
		if (ta->flags & BR_X509_TA_CA) {
			continue;
		}
		hash_dn(CTX, ta->dn.data, ta->dn.len, hashed_DN);
		if (memcmp(hashed_DN, CTX->current_dn_hash, DNHASH_LEN)) {
			continue;
		}
		kt = CTX->pkey.key_type;
		if ((ta->pkey.key_type & 0x0F) != kt) {
			continue;
		}
		switch (kt) {

		case BR_KEYTYPE_RSA:
			if (!eqbigint(CTX->pkey.key.rsa.n,
				CTX->pkey.key.rsa.nlen,
				ta->pkey.key.rsa.n,
				ta->pkey.key.rsa.nlen)
				|| !eqbigint(CTX->pkey.key.rsa.e,
				CTX->pkey.key.rsa.elen,
				ta->pkey.key.rsa.e,
				ta->pkey.key.rsa.elen))
			{
				continue;
			}
			break;

		case BR_KEYTYPE_EC:
			if (CTX->pkey.key.ec.curve != ta->pkey.key.ec.curve
				|| CTX->pkey.key.ec.qlen != ta->pkey.key.ec.qlen
				|| memcmp(CTX->pkey.key.ec.q,
					ta->pkey.key.ec.q,
					ta->pkey.key.ec.qlen) != 0)
			{
				continue;
			}
			break;

		default:
			continue;
		}

		/*
		 * Direct trust match!
		 */
		CTX->err = BR_ERR_X509_OK;
		T0_CO();
	}
}

\ Check the signature on the certificate with regards to all trusted CA.
\ We use the issuer hash (in saved_dn_hash[]) as CA identifier.
cc: check-trust-anchor-CA ( -- ) {
	size_t u;

	for (u = 0; u < CTX->trust_anchors_num; u ++) {
		const br_x509_trust_anchor *ta;
		unsigned char hashed_DN[64];

		ta = &CTX->trust_anchors[u];
		if (!(ta->flags & BR_X509_TA_CA)) {
			continue;
		}
		hash_dn(CTX, ta->dn.data, ta->dn.len, hashed_DN);
		if (memcmp(hashed_DN, CTX->saved_dn_hash, DNHASH_LEN)) {
			continue;
		}
		if (verify_signature(CTX, &ta->pkey) == 0) {
			CTX->err = BR_ERR_X509_OK;
			T0_CO();
		}
	}
}

\ Verify RSA signature. This uses the public key that was just decoded
\ into CTX->pkey_data; the modulus and exponent length are provided as
\ parameters. The resulting hash value is compared with the one in
\ tbs_hash. Returned value is 0 on success, or a non-zero error code.
cc: do-rsa-vrfy ( nlen elen -- err ) {
	size_t elen = T0_POP();
	size_t nlen = T0_POP();
	br_x509_pkey pk;

	pk.key_type = BR_KEYTYPE_RSA;
	pk.key.rsa.n = CTX->pkey_data;
	pk.key.rsa.nlen = nlen;
	pk.key.rsa.e = CTX->pkey_data + nlen;
	pk.key.rsa.elen = elen;
	T0_PUSH(verify_signature(CTX, &pk));
}

\ Verify ECDSA signature. This uses the public key that was just decoded
\ into CTX->pkey_dayta; the curve ID and public point length are provided
\ as parameters. The hash value in tbs_hash is used. Returned value is 0
\ on success, or non-zero error code.
cc: do-ecdsa-vrfy ( curve qlen -- err ) {
	size_t qlen = T0_POP();
	int curve = T0_POP();
	br_x509_pkey pk;

	pk.key_type = BR_KEYTYPE_EC;
	pk.key.ec.curve = curve;
	pk.key.ec.q = CTX->pkey_data;
	pk.key.ec.qlen = qlen;
	T0_PUSH(verify_signature(CTX, &pk));
}

cc: print-bytes ( addr len -- ) {
	extern int printf(const char *fmt, ...);
	size_t len = T0_POP();
	unsigned char *buf = (unsigned char *)CTX + T0_POP();
	size_t u;

	for (u = 0; u < len; u ++) {
		printf("%02X", buf[u]);
	}
}

cc: printOID ( -- ) {
	extern int printf(const char *fmt, ...);
	size_t u, len;

	len = CTX->pad[0];
	if (len == 0) {
		printf("*");
		T0_RET();
	}
	printf("%u.%u", CTX->pad[1] / 40, CTX->pad[1] % 40);
	u = 2;
	while (u <= len) {
		unsigned long ul;

		ul = 0;
		for (;;) {
			int x;

			if (u > len) {
				printf("BAD");
				T0_RET();
			}
			x = CTX->pad[u ++];
			ul = (ul << 7) + (x & 0x7F);
			if (!(x & 0x80)) {
				break;
			}
		}
		printf(".%lu", ul);
	}
}

\ Extensions with specific processing.
OID: basicConstraints      2.5.29.19
OID: keyUsage              2.5.29.15
OID: subjectAltName        2.5.29.17
OID: certificatePolicies   2.5.29.32

\ Policy qualifier "pointer to CPS"
OID: id-qt-cps             1.3.6.1.5.5.7.2.1

\ Extensions which are ignored when encountered, even if critical.
OID: authorityKeyIdentifier        2.5.29.35
OID: subjectKeyIdentifier          2.5.29.14
OID: issuerAltName                 2.5.29.18
OID: subjectDirectoryAttributes    2.5.29.9
OID: crlDistributionPoints         2.5.29.31
OID: freshestCRL                   2.5.29.46
OID: authorityInfoAccess           1.3.6.1.5.5.7.1.1
OID: subjectInfoAccess             1.3.6.1.5.5.7.1.11

\ Process a Basic Constraints extension. This should be called only if
\ the certificate is not the EE. We check that the extension contains
\ the "CA" flag, and that the path length, if specified, is compatible
\ with the current chain length.
: process-basicConstraints ( lim -- lim )
	read-sequence-open
	read-tag-or-end
	dup 0x01 = if
		read-boolean ifnot ERR_X509_NOT_CA fail then
		read-tag-or-end
	else
		ERR_X509_NOT_CA fail
	then
	dup 0x02 = if
		drop check-primitive read-small-int-value
		addr-num_certs get32 1- < if ERR_X509_NOT_CA fail then
		read-tag-or-end
	then
	-1 <> if ERR_X509_UNEXPECTED fail then
	drop
	close-elt
	;

\ Process a Key Usage extension.
\ For the EE certificate:
\   -- if the key usage contains keyEncipherment (2), dataEncipherment (3)
\      or keyAgreement (4), then the "key exchange" usage is allowed;
\   -- if the key usage contains digitalSignature (0) or nonRepudiation (1),
\      then the "signature" usage is allowed.
\ For CA certificates, the extension must contain keyCertSign (5).
: process-keyUsage ( lim ee -- lim )
	{ ee }

	\ Read tag for the BIT STRING and open it.
	read-tag 0x03 check-tag-primitive
	read-length-open-elt
	\ First byte indicates number of ignored bits in the last byte. It
	\ must be between 0 and 7.
	read8 { ign }
	ign 7 > if ERR_X509_UNEXPECTED fail then
	\ Depending on length, we have either 0, 1 or more bytes to read.
	dup case
		0 of ERR_X509_FORBIDDEN_KEY_USAGE fail endof
		1 of read8 ign >> ign << endof
		drop read8 0
	endcase

	\ Check bits.
	ee if
		\ EE: get usages.
		0
		over 0x38 and if 0x10 or then
		swap 0xC0 and if 0x20 or then
		addr-key_usages set8
	else
		\ Not EE: keyCertSign must be set.
		0x04 and ifnot ERR_X509_FORBIDDEN_KEY_USAGE fail then
	then

	\ We don't care about subsequent bytes.
	skip-close-elt ;

\ Process a Certificate Policies extension.
\
\ Since we don't actually support full policies processing, this function
\ only checks that the extension contents can be safely ignored. Indeed,
\ we don't validate against a specific set of policies (in RFC 5280
\ terminology, user-initial-policy-set only contains the special value
\ any-policy). Moreover, we don't support policy constraints (if a
\ critical Policy Constraints extension is encountered, the validation
\ will fail). Therefore, we can safely ignore the contents of this
\ extension, except if it is critical AND one of the policy OID has a
\ qualifier which is distinct from id-qt-cps (because id-qt-cps is
\ specially designated by RFC 5280 has having no mandated action).
\
\ This function is called only if the extension is critical.
: process-certPolicies ( lim -- lim )
	\ Extension value is a SEQUENCE OF PolicyInformation.
	read-sequence-open
	begin dup while
		\ PolicyInformation ::= SEQUENCE {
		\    policyIdentifier  OBJECT IDENTIFIER,
		\    policyQualifiers  SEQUENCE OF PolicyQualifierInfo OPTIONAL
		\ }
		read-sequence-open
		read-OID drop
		dup if
			read-sequence-open
			begin dup while
				\ PolicyQualifierInfo ::= SEQUENCE {
				\    policyQualifierId  OBJECT IDENTIFIER,
				\    qualifier          ANY
				\ }
				read-sequence-open
				read-OID drop id-qt-cps eqOID ifnot
					ERR_X509_CRITICAL_EXTENSION fail
				then
				skip-close-elt
			repeat
			close-elt
		then
		close-elt
	repeat
	close-elt ;

\ Process a Subject Alt Name extension. Returned value is a boolean set
\ to true if the expected server name was matched against a dNSName in
\ the extension.
: process-SAN ( lim -- lim bool )
	0 { m }
	read-sequence-open
	begin dup while
		\ Read the tag. If the tag is context-0, then parse an
		\ 'otherName'. If the tag is context-2, then parse a
		\ dNSName. If the tag is context-1 or context-6,
		\ parse
		read-tag case
			\ OtherName
			0x20 of
				\ OtherName ::= SEQUENCE {
				\     type-id   OBJECT IDENTIFIER,
				\     value     [0] EXPLICIT ANY
				\ }
				check-constructed read-length-open-elt
				read-OID drop
				-1 offset-name-element { offbuf }
				read-tag 0x20 check-tag-constructed
				read-length-open-elt
				read-string offbuf copy-name-element
				close-elt
				close-elt
			endof
			\ rfc822Name (IA5String)
			0x21 of
				check-primitive
				read-value-UTF8 1 copy-name-SAN
			endof
			\ dNSName (IA5String)
			0x22 of
				check-primitive
				read-value-UTF8
				dup if match-server-name m or >m then
				2 copy-name-SAN
			endof
			\ uniformResourceIdentifier (IA5String)
			0x26 of
				check-primitive
				read-value-UTF8 6 copy-name-SAN
			endof
			2drop read-length-skip 0
		endcase

		\ We check only names of type dNSName; they use IA5String,
		\ which is basically ASCII.
		\ read-tag 0x22 = if
		\ 	check-primitive
		\ 	read-small-value drop
		\ 	match-server-name m or >m
		\ else
		\ 	drop read-length-skip
		\ then
	repeat
	close-elt
	m ;

\ Decode a certificate. The "ee" boolean must be true for the EE.
: decode-certificate ( ee -- )
	{ ee }

	\ Obtain the total certificate length.
	addr-cert_length get32

	\ Open the outer SEQUENCE.
	read-sequence-open

	\ TBS
	\ Activate hashing.
	start-tbs-hash
	read-sequence-open

	\ First element may be an explicit version. We accept only
	\ versions 0 to 2 (certificates v1 to v3).
	read-tag dup 0x20 = if
		drop check-constructed read-length-open-elt
		read-tag
		0x02 check-tag-primitive
		read-small-int-value
		2 > if ERR_X509_UNSUPPORTED fail then
		close-elt
		read-tag
	then

	\ Serial number. We just check that the tag is correct.
	0x02 check-tag-primitive
	read-length-skip

	\ Signature algorithm. This structure is redundant with the one
	\ on the outside; we just skip it.
	read-sequence-open skip-close-elt

	\ Issuer name: hashed, then copied into next_dn_hash[].
	read-DN
	addr-next_dn_hash addr-current_dn_hash dn-hash-length blobcopy

	\ Validity dates.
	read-sequence-open
	read-date get-system-date after if ERR_X509_EXPIRED fail then
	read-date get-system-date before if ERR_X509_EXPIRED fail then
	close-elt

	\ Subject name.
	ee if
		\ For the EE, we must check whether the Common Name, if
		\ any, matches the expected server name.
		read-DN-EE { eename }
	else
		\ For a non-EE certificate, the hashed subject DN must match
		\ the saved hashed issuer DN from the previous certificate.
		read-DN
		addr-current_dn_hash addr-saved_dn_hash dn-hash-length eqblob
		ifnot ERR_X509_DN_MISMATCH fail then
	then
	\ Move the hashed issuer DN for this certificate into the
	\ saved_dn_hash[] array.
	addr-saved_dn_hash addr-next_dn_hash dn-hash-length blobcopy

	\ Public Key.
	read-sequence-open
	\ Algorithm Identifier. Right now we are only interested in the
	\ OID, since we only support RSA keys.
	read-sequence-open
	read-OID ifnot ERR_X509_UNSUPPORTED fail then
	{ ; pkey-type }
	choice
		\ RSA public key.
		rsaEncryption eqOID uf
			skip-close-elt
			\ Public key itself: the BIT STRING contains bytes
			\ (no partial byte) and these bytes encode the
			\ actual value.
			read-bits-open
				\ RSA public key is a SEQUENCE of two
				\ INTEGER. We get both INTEGER values into
				\ the pkey_data[] buffer, if they fit.
				read-sequence-open
				addr-len-pkey_data
				read-integer { nlen }
				addr-len-pkey_data swap nlen + swap nlen -
				read-integer { elen }
				close-elt

				\ Check that the public key fits our minimal
				\ size requirements. Note that the integer
				\ decoder already skipped the leading bytes
				\ of value 0, so we are working on the true
				\ modulus length here.
				addr-min_rsa_size get16 128 + nlen > if
					ERR_X509_WEAK_PUBLIC_KEY fail
				then
			close-elt
			KEYTYPE_RSA >pkey-type
		enduf

		\ EC public key.
		id-ecPublicKey eqOID uf
			\ We support only named curves, for which the
			\ "parameters" field in the AlgorithmIdentifier
			\ field should be an OID.
			read-OID ifnot ERR_X509_UNSUPPORTED fail then
			choice
				ansix9p256r1 eqOID uf 23 enduf
				ansix9p384r1 eqOID uf 24 enduf
				ansix9p521r1 eqOID uf 25 enduf
				ERR_X509_UNSUPPORTED fail
			endchoice
			{ curve }
			close-elt
			read-bits-open
			dup { qlen }
			dup addr-len-pkey_data rot < if
				ERR_X509_LIMIT_EXCEEDED fail
			then
			read-blob
			KEYTYPE_EC >pkey-type
		enduf

		\ Not a recognised public key type.
		ERR_X509_UNSUPPORTED fail
	endchoice
	close-elt

	\ Process public key.
	ee if
		\ For the EE certificate, copy the key data to the
		\ relevant buffer.
		pkey-type case
			KEYTYPE_RSA of nlen elen copy-ee-rsa-pkey endof
			KEYTYPE_EC of curve qlen copy-ee-ec-pkey endof
			ERR_X509_UNSUPPORTED fail
		endcase
	else
		\ Verify signature on previous certificate. We invoke
		\ the RSA implementation.
		pkey-type case
			KEYTYPE_RSA of nlen elen do-rsa-vrfy endof
			KEYTYPE_EC of curve qlen do-ecdsa-vrfy endof
			ERR_X509_UNSUPPORTED fail
		endcase
		dup if fail then
		drop
	then

	\ This flag will be set to true if the Basic Constraints extension
	\ is encountered.
	0 { seenBC }

	\ Skip issuerUniqueID and subjectUniqueID, and process extensions
	\ if present. Extensions are an explicit context tag of value 3
	\ around a SEQUENCE OF extensions. Each extension is a SEQUENCE
	\ with an OID, an optional boolean, and a value; the value is
	\ an OCTET STRING.
	read-tag-or-end
	0x21 iftag-skip
	0x22 iftag-skip
	dup 0x23 = if
		drop
		check-constructed read-length-open-elt
		read-sequence-open
		begin dup while
			0 { critical }
			read-sequence-open
			read-OID drop
			read-tag dup 0x01 = if
				read-boolean >critical
				read-tag
			then
			0x04 check-tag-primitive read-length-open-elt
			choice
				\ Extensions with specific processing.
				basicConstraints eqOID uf
					ee if
						skip-remaining
					else
						process-basicConstraints
						-1 >seenBC
					then
				enduf
				keyUsage         eqOID uf
					ee process-keyUsage
				enduf
				subjectAltName   eqOID uf
					ee if
						0 >eename
						process-SAN >eename
					else
						skip-remaining
					then
				enduf

				\ We don't implement full processing of
				\ policies. The call below mostly checks
				\ that the contents of the Certificate
				\ Policies extension can be safely ignored.
				certificatePolicies eqOID uf
					critical if
						process-certPolicies
					else
						skip-remaining
					then
				enduf

				\ Extensions which are always ignored,
				\ even if critical.
				authorityKeyIdentifier     eqOID uf
					skip-remaining
				enduf
				subjectKeyIdentifier       eqOID uf
					skip-remaining
				enduf
				issuerAltName              eqOID uf
					skip-remaining
				enduf
				subjectDirectoryAttributes eqOID uf
					skip-remaining
				enduf
				crlDistributionPoints      eqOID uf
					skip-remaining
				enduf
				freshestCRL                eqOID uf
					skip-remaining
				enduf
				authorityInfoAccess        eqOID uf
					skip-remaining
				enduf
				subjectInfoAccess          eqOID uf
					skip-remaining
				enduf

				\ Unrecognized extensions trigger a failure
				\ if critical; otherwise, they are just
				\ ignored.
				critical if
					ERR_X509_CRITICAL_EXTENSION fail
				then
				skip-remaining
			endchoice
			close-elt
			close-elt
		repeat
		close-elt
		close-elt
	else
		-1 = ifnot ERR_X509_UNEXPECTED fail then
		drop
	then

	close-elt
	\ Terminate hashing.
	stop-tbs-hash

	\ For the EE certificate, verify that the intended server name
	\ was matched.
	ee if
		eename zero-server-name or ifnot
			ERR_X509_BAD_SERVER_NAME fail
		then
	then

	\ If this is the EE certificate, then direct trust may apply.
	\ Note: we do this at this point, not immediately after decoding
	\ the public key, because even in case of direct trust we still
	\ want to check the server name with regards to the SAN extension.
	\ However, we want to check direct trust before trying to decode
	\ the signature algorithm, because it should work even if that
	\ algorithm is not supported.
	ee if check-direct-trust then

	\ Non-EE certificates MUST have a Basic Constraints extension
	\ (that marks them as being CA).
	ee seenBC or ifnot ERR_X509_NOT_CA fail then

	\ signature algorithm
	read-tag check-sequence read-length-open-elt
	\ Read and understand the OID. Right now, we support only
	\ RSA with PKCS#1 v1.5 padding, and hash functions SHA-1,
	\ SHA-224, SHA-256, SHA-384 and SHA-512. We purposely do NOT
	\ support MD5 here.
	\ TODO: add support for RSA/PSS
	read-OID if
		\ Based on the signature OID, we get:
		\ -- the signing key type
		\ -- the hash function numeric identifier
		\ -- the hash function OID
		choice
			sha1WithRSAEncryption   eqOID
				uf 2 KEYTYPE_RSA id-sha1   enduf
			sha224WithRSAEncryption eqOID
				uf 3 KEYTYPE_RSA id-sha224 enduf
			sha256WithRSAEncryption eqOID
				uf 4 KEYTYPE_RSA id-sha256 enduf
			sha384WithRSAEncryption eqOID
				uf 5 KEYTYPE_RSA id-sha384 enduf
			sha512WithRSAEncryption eqOID
				uf 6 KEYTYPE_RSA id-sha512 enduf

			ecdsa-with-SHA1   eqOID
				uf 2 KEYTYPE_EC id-sha1 enduf
			ecdsa-with-SHA224 eqOID
				uf 3 KEYTYPE_EC id-sha224 enduf
			ecdsa-with-SHA256 eqOID
				uf 4 KEYTYPE_EC id-sha256 enduf
			ecdsa-with-SHA384 eqOID
				uf 5 KEYTYPE_EC id-sha384 enduf
			ecdsa-with-SHA512 eqOID
				uf 6 KEYTYPE_EC id-sha512 enduf
			ERR_X509_UNSUPPORTED fail
		endchoice
		addr-cert_sig_hash_oid set16
		addr-cert_signer_key_type set8

		\ Compute the TBS hash into tbs_hash.
		compute-tbs-hash
		dup ifnot ERR_X509_UNSUPPORTED fail then
		addr-cert_sig_hash_len set8
	else
		ERR_X509_UNSUPPORTED fail
	then
	\ We ignore the parameters, whether they are present or not,
	\ because we got all the information from the OID.
	skip-close-elt

	\ signature value
	read-bits-open
	dup CX 0 8191 { BR_X509_BUFSIZE_SIG } > if
		ERR_X509_LIMIT_EXCEEDED fail
	then
	dup addr-cert_sig_len set16
	addr-cert_sig read-blob

	\ Close the outer SEQUENCE.
	close-elt

	\ Close the advertised total certificate length. This checks that
	\ there is no trailing garbage after the certificate.
	close-elt

	\ Flag the certificate as fully processed.
	0 addr-cert_length set32

	\ Check whether the issuer for the current certificate is known
	\ as a trusted CA; in which case, verify the signature.
	check-trust-anchor-CA ;

: main
	\ Unless restricted by a Key Usage extension, all usages are
	\ deemed allowed.
	0x30 addr-key_usages set8
	-1 decode-certificate
	co
	begin
		0 decode-certificate co
	again
	;