Contributors: 19
Author Tokens Token Proportion Commits Commit Proportion
David Howells 2980 77.24% 20 45.45%
Eric Snowberg 237 6.14% 2 4.55%
Vitaly Chikunov 154 3.99% 2 4.55%
Stefan Berger 105 2.72% 3 6.82%
Tianjia Zhang 80 2.07% 1 2.27%
Lukas Wunner 60 1.56% 1 2.27%
Maciej S. Szmigiero 53 1.37% 1 2.27%
Eric Biggers 49 1.27% 3 6.82%
Dimitri John Ledkov 42 1.09% 1 2.27%
Tadeusz Struk 38 0.98% 1 2.27%
Chun-Yi Lee 19 0.49% 1 2.27%
Andrzej Zaborowski 14 0.36% 1 2.27%
Mimi Zohar 12 0.31% 1 2.27%
Saulo Alessandre 5 0.13% 1 2.27%
Dmitry Kasatkin 3 0.08% 1 2.27%
Thomas Gleixner 2 0.05% 1 2.27%
Sudip Mukherjee 2 0.05% 1 2.27%
Masahiro Yamada 2 0.05% 1 2.27%
Randy Dunlap 1 0.03% 1 2.27%
Total 3858 44


// SPDX-License-Identifier: GPL-2.0-or-later
/* X.509 certificate parser
 *
 * Copyright (C) 2012 Red Hat, Inc. All Rights Reserved.
 * Written by David Howells (dhowells@redhat.com)
 */

#define pr_fmt(fmt) "X.509: "fmt
#include <linux/kernel.h>
#include <linux/export.h>
#include <linux/slab.h>
#include <linux/err.h>
#include <linux/oid_registry.h>
#include <crypto/public_key.h>
#include "x509_parser.h"
#include "x509.asn1.h"
#include "x509_akid.asn1.h"

struct x509_parse_context {
	struct x509_certificate	*cert;		/* Certificate being constructed */
	unsigned long	data;			/* Start of data */
	const void	*key;			/* Key data */
	size_t		key_size;		/* Size of key data */
	const void	*params;		/* Key parameters */
	size_t		params_size;		/* Size of key parameters */
	enum OID	key_algo;		/* Algorithm used by the cert's key */
	enum OID	last_oid;		/* Last OID encountered */
	enum OID	sig_algo;		/* Algorithm used to sign the cert */
	u8		o_size;			/* Size of organizationName (O) */
	u8		cn_size;		/* Size of commonName (CN) */
	u8		email_size;		/* Size of emailAddress */
	u16		o_offset;		/* Offset of organizationName (O) */
	u16		cn_offset;		/* Offset of commonName (CN) */
	u16		email_offset;		/* Offset of emailAddress */
	unsigned	raw_akid_size;
	const void	*raw_akid;		/* Raw authorityKeyId in ASN.1 */
	const void	*akid_raw_issuer;	/* Raw directoryName in authorityKeyId */
	unsigned	akid_raw_issuer_size;
};

/*
 * Free an X.509 certificate
 */
void x509_free_certificate(struct x509_certificate *cert)
{
	if (cert) {
		public_key_free(cert->pub);
		public_key_signature_free(cert->sig);
		kfree(cert->issuer);
		kfree(cert->subject);
		kfree(cert->id);
		kfree(cert->skid);
		kfree(cert);
	}
}
EXPORT_SYMBOL_GPL(x509_free_certificate);

/*
 * Parse an X.509 certificate
 */
struct x509_certificate *x509_cert_parse(const void *data, size_t datalen)
{
	struct x509_certificate *cert __free(x509_free_certificate);
	struct x509_parse_context *ctx __free(kfree) = NULL;
	struct asymmetric_key_id *kid;
	long ret;

	cert = kzalloc(sizeof(struct x509_certificate), GFP_KERNEL);
	if (!cert)
		return ERR_PTR(-ENOMEM);
	cert->pub = kzalloc(sizeof(struct public_key), GFP_KERNEL);
	if (!cert->pub)
		return ERR_PTR(-ENOMEM);
	cert->sig = kzalloc(sizeof(struct public_key_signature), GFP_KERNEL);
	if (!cert->sig)
		return ERR_PTR(-ENOMEM);
	ctx = kzalloc(sizeof(struct x509_parse_context), GFP_KERNEL);
	if (!ctx)
		return ERR_PTR(-ENOMEM);

	ctx->cert = cert;
	ctx->data = (unsigned long)data;

	/* Attempt to decode the certificate */
	ret = asn1_ber_decoder(&x509_decoder, ctx, data, datalen);
	if (ret < 0)
		return ERR_PTR(ret);

	/* Decode the AuthorityKeyIdentifier */
	if (ctx->raw_akid) {
		pr_devel("AKID: %u %*phN\n",
			 ctx->raw_akid_size, ctx->raw_akid_size, ctx->raw_akid);
		ret = asn1_ber_decoder(&x509_akid_decoder, ctx,
				       ctx->raw_akid, ctx->raw_akid_size);
		if (ret < 0) {
			pr_warn("Couldn't decode AuthKeyIdentifier\n");
			return ERR_PTR(ret);
		}
	}

	cert->pub->key = kmemdup(ctx->key, ctx->key_size, GFP_KERNEL);
	if (!cert->pub->key)
		return ERR_PTR(-ENOMEM);

	cert->pub->keylen = ctx->key_size;

	cert->pub->params = kmemdup(ctx->params, ctx->params_size, GFP_KERNEL);
	if (!cert->pub->params)
		return ERR_PTR(-ENOMEM);

	cert->pub->paramlen = ctx->params_size;
	cert->pub->algo = ctx->key_algo;

	/* Grab the signature bits */
	ret = x509_get_sig_params(cert);
	if (ret < 0)
		return ERR_PTR(ret);

	/* Generate cert issuer + serial number key ID */
	kid = asymmetric_key_generate_id(cert->raw_serial,
					 cert->raw_serial_size,
					 cert->raw_issuer,
					 cert->raw_issuer_size);
	if (IS_ERR(kid))
		return ERR_CAST(kid);
	cert->id = kid;

	/* Detect self-signed certificates */
	ret = x509_check_for_self_signed(cert);
	if (ret < 0)
		return ERR_PTR(ret);

	return_ptr(cert);
}
EXPORT_SYMBOL_GPL(x509_cert_parse);

/*
 * Note an OID when we find one for later processing when we know how
 * to interpret it.
 */
int x509_note_OID(void *context, size_t hdrlen,
	     unsigned char tag,
	     const void *value, size_t vlen)
{
	struct x509_parse_context *ctx = context;

	ctx->last_oid = look_up_OID(value, vlen);
	if (ctx->last_oid == OID__NR) {
		char buffer[50];
		sprint_oid(value, vlen, buffer, sizeof(buffer));
		pr_debug("Unknown OID: [%lu] %s\n",
			 (unsigned long)value - ctx->data, buffer);
	}
	return 0;
}

/*
 * Save the position of the TBS data so that we can check the signature over it
 * later.
 */
int x509_note_tbs_certificate(void *context, size_t hdrlen,
			      unsigned char tag,
			      const void *value, size_t vlen)
{
	struct x509_parse_context *ctx = context;

	pr_debug("x509_note_tbs_certificate(,%zu,%02x,%ld,%zu)!\n",
		 hdrlen, tag, (unsigned long)value - ctx->data, vlen);

	ctx->cert->tbs = value - hdrlen;
	ctx->cert->tbs_size = vlen + hdrlen;
	return 0;
}

/*
 * Record the algorithm that was used to sign this certificate.
 */
int x509_note_sig_algo(void *context, size_t hdrlen, unsigned char tag,
		       const void *value, size_t vlen)
{
	struct x509_parse_context *ctx = context;

	pr_debug("PubKey Algo: %u\n", ctx->last_oid);

	switch (ctx->last_oid) {
	default:
		return -ENOPKG; /* Unsupported combination */

	case OID_sha1WithRSAEncryption:
		ctx->cert->sig->hash_algo = "sha1";
		goto rsa_pkcs1;

	case OID_sha256WithRSAEncryption:
		ctx->cert->sig->hash_algo = "sha256";
		goto rsa_pkcs1;

	case OID_sha384WithRSAEncryption:
		ctx->cert->sig->hash_algo = "sha384";
		goto rsa_pkcs1;

	case OID_sha512WithRSAEncryption:
		ctx->cert->sig->hash_algo = "sha512";
		goto rsa_pkcs1;

	case OID_sha224WithRSAEncryption:
		ctx->cert->sig->hash_algo = "sha224";
		goto rsa_pkcs1;

	case OID_id_ecdsa_with_sha1:
		ctx->cert->sig->hash_algo = "sha1";
		goto ecdsa;

	case OID_id_rsassa_pkcs1_v1_5_with_sha3_256:
		ctx->cert->sig->hash_algo = "sha3-256";
		goto rsa_pkcs1;

	case OID_id_rsassa_pkcs1_v1_5_with_sha3_384:
		ctx->cert->sig->hash_algo = "sha3-384";
		goto rsa_pkcs1;

	case OID_id_rsassa_pkcs1_v1_5_with_sha3_512:
		ctx->cert->sig->hash_algo = "sha3-512";
		goto rsa_pkcs1;

	case OID_id_ecdsa_with_sha224:
		ctx->cert->sig->hash_algo = "sha224";
		goto ecdsa;

	case OID_id_ecdsa_with_sha256:
		ctx->cert->sig->hash_algo = "sha256";
		goto ecdsa;

	case OID_id_ecdsa_with_sha384:
		ctx->cert->sig->hash_algo = "sha384";
		goto ecdsa;

	case OID_id_ecdsa_with_sha512:
		ctx->cert->sig->hash_algo = "sha512";
		goto ecdsa;

	case OID_id_ecdsa_with_sha3_256:
		ctx->cert->sig->hash_algo = "sha3-256";
		goto ecdsa;

	case OID_id_ecdsa_with_sha3_384:
		ctx->cert->sig->hash_algo = "sha3-384";
		goto ecdsa;

	case OID_id_ecdsa_with_sha3_512:
		ctx->cert->sig->hash_algo = "sha3-512";
		goto ecdsa;

	case OID_gost2012Signature256:
		ctx->cert->sig->hash_algo = "streebog256";
		goto ecrdsa;

	case OID_gost2012Signature512:
		ctx->cert->sig->hash_algo = "streebog512";
		goto ecrdsa;

	case OID_SM2_with_SM3:
		ctx->cert->sig->hash_algo = "sm3";
		goto sm2;
	}

rsa_pkcs1:
	ctx->cert->sig->pkey_algo = "rsa";
	ctx->cert->sig->encoding = "pkcs1";
	ctx->sig_algo = ctx->last_oid;
	return 0;
ecrdsa:
	ctx->cert->sig->pkey_algo = "ecrdsa";
	ctx->cert->sig->encoding = "raw";
	ctx->sig_algo = ctx->last_oid;
	return 0;
sm2:
	ctx->cert->sig->pkey_algo = "sm2";
	ctx->cert->sig->encoding = "raw";
	ctx->sig_algo = ctx->last_oid;
	return 0;
ecdsa:
	ctx->cert->sig->pkey_algo = "ecdsa";
	ctx->cert->sig->encoding = "x962";
	ctx->sig_algo = ctx->last_oid;
	return 0;
}

/*
 * Note the whereabouts and type of the signature.
 */
int x509_note_signature(void *context, size_t hdrlen,
			unsigned char tag,
			const void *value, size_t vlen)
{
	struct x509_parse_context *ctx = context;

	pr_debug("Signature: alg=%u, size=%zu\n", ctx->last_oid, vlen);

	/*
	 * In X.509 certificates, the signature's algorithm is stored in two
	 * places: inside the TBSCertificate (the data that is signed), and
	 * alongside the signature.  These *must* match.
	 */
	if (ctx->last_oid != ctx->sig_algo) {
		pr_warn("signatureAlgorithm (%u) differs from tbsCertificate.signature (%u)\n",
			ctx->last_oid, ctx->sig_algo);
		return -EINVAL;
	}

	if (strcmp(ctx->cert->sig->pkey_algo, "rsa") == 0 ||
	    strcmp(ctx->cert->sig->pkey_algo, "ecrdsa") == 0 ||
	    strcmp(ctx->cert->sig->pkey_algo, "sm2") == 0 ||
	    strcmp(ctx->cert->sig->pkey_algo, "ecdsa") == 0) {
		/* Discard the BIT STRING metadata */
		if (vlen < 1 || *(const u8 *)value != 0)
			return -EBADMSG;

		value++;
		vlen--;
	}

	ctx->cert->raw_sig = value;
	ctx->cert->raw_sig_size = vlen;
	return 0;
}

/*
 * Note the certificate serial number
 */
int x509_note_serial(void *context, size_t hdrlen,
		     unsigned char tag,
		     const void *value, size_t vlen)
{
	struct x509_parse_context *ctx = context;
	ctx->cert->raw_serial = value;
	ctx->cert->raw_serial_size = vlen;
	return 0;
}

/*
 * Note some of the name segments from which we'll fabricate a name.
 */
int x509_extract_name_segment(void *context, size_t hdrlen,
			      unsigned char tag,
			      const void *value, size_t vlen)
{
	struct x509_parse_context *ctx = context;

	switch (ctx->last_oid) {
	case OID_commonName:
		ctx->cn_size = vlen;
		ctx->cn_offset = (unsigned long)value - ctx->data;
		break;
	case OID_organizationName:
		ctx->o_size = vlen;
		ctx->o_offset = (unsigned long)value - ctx->data;
		break;
	case OID_email_address:
		ctx->email_size = vlen;
		ctx->email_offset = (unsigned long)value - ctx->data;
		break;
	default:
		break;
	}

	return 0;
}

/*
 * Fabricate and save the issuer and subject names
 */
static int x509_fabricate_name(struct x509_parse_context *ctx, size_t hdrlen,
			       unsigned char tag,
			       char **_name, size_t vlen)
{
	const void *name, *data = (const void *)ctx->data;
	size_t namesize;
	char *buffer;

	if (*_name)
		return -EINVAL;

	/* Empty name string if no material */
	if (!ctx->cn_size && !ctx->o_size && !ctx->email_size) {
		buffer = kmalloc(1, GFP_KERNEL);
		if (!buffer)
			return -ENOMEM;
		buffer[0] = 0;
		goto done;
	}

	if (ctx->cn_size && ctx->o_size) {
		/* Consider combining O and CN, but use only the CN if it is
		 * prefixed by the O, or a significant portion thereof.
		 */
		namesize = ctx->cn_size;
		name = data + ctx->cn_offset;
		if (ctx->cn_size >= ctx->o_size &&
		    memcmp(data + ctx->cn_offset, data + ctx->o_offset,
			   ctx->o_size) == 0)
			goto single_component;
		if (ctx->cn_size >= 7 &&
		    ctx->o_size >= 7 &&
		    memcmp(data + ctx->cn_offset, data + ctx->o_offset, 7) == 0)
			goto single_component;

		buffer = kmalloc(ctx->o_size + 2 + ctx->cn_size + 1,
				 GFP_KERNEL);
		if (!buffer)
			return -ENOMEM;

		memcpy(buffer,
		       data + ctx->o_offset, ctx->o_size);
		buffer[ctx->o_size + 0] = ':';
		buffer[ctx->o_size + 1] = ' ';
		memcpy(buffer + ctx->o_size + 2,
		       data + ctx->cn_offset, ctx->cn_size);
		buffer[ctx->o_size + 2 + ctx->cn_size] = 0;
		goto done;

	} else if (ctx->cn_size) {
		namesize = ctx->cn_size;
		name = data + ctx->cn_offset;
	} else if (ctx->o_size) {
		namesize = ctx->o_size;
		name = data + ctx->o_offset;
	} else {
		namesize = ctx->email_size;
		name = data + ctx->email_offset;
	}

single_component:
	buffer = kmalloc(namesize + 1, GFP_KERNEL);
	if (!buffer)
		return -ENOMEM;
	memcpy(buffer, name, namesize);
	buffer[namesize] = 0;

done:
	*_name = buffer;
	ctx->cn_size = 0;
	ctx->o_size = 0;
	ctx->email_size = 0;
	return 0;
}

int x509_note_issuer(void *context, size_t hdrlen,
		     unsigned char tag,
		     const void *value, size_t vlen)
{
	struct x509_parse_context *ctx = context;
	struct asymmetric_key_id *kid;

	ctx->cert->raw_issuer = value;
	ctx->cert->raw_issuer_size = vlen;

	if (!ctx->cert->sig->auth_ids[2]) {
		kid = asymmetric_key_generate_id(value, vlen, "", 0);
		if (IS_ERR(kid))
			return PTR_ERR(kid);
		ctx->cert->sig->auth_ids[2] = kid;
	}

	return x509_fabricate_name(ctx, hdrlen, tag, &ctx->cert->issuer, vlen);
}

int x509_note_subject(void *context, size_t hdrlen,
		      unsigned char tag,
		      const void *value, size_t vlen)
{
	struct x509_parse_context *ctx = context;
	ctx->cert->raw_subject = value;
	ctx->cert->raw_subject_size = vlen;
	return x509_fabricate_name(ctx, hdrlen, tag, &ctx->cert->subject, vlen);
}

/*
 * Extract the parameters for the public key
 */
int x509_note_params(void *context, size_t hdrlen,
		     unsigned char tag,
		     const void *value, size_t vlen)
{
	struct x509_parse_context *ctx = context;

	/*
	 * AlgorithmIdentifier is used three times in the x509, we should skip
	 * first and ignore third, using second one which is after subject and
	 * before subjectPublicKey.
	 */
	if (!ctx->cert->raw_subject || ctx->key)
		return 0;
	ctx->params = value - hdrlen;
	ctx->params_size = vlen + hdrlen;
	return 0;
}

/*
 * Extract the data for the public key algorithm
 */
int x509_extract_key_data(void *context, size_t hdrlen,
			  unsigned char tag,
			  const void *value, size_t vlen)
{
	struct x509_parse_context *ctx = context;
	enum OID oid;

	ctx->key_algo = ctx->last_oid;
	switch (ctx->last_oid) {
	case OID_rsaEncryption:
		ctx->cert->pub->pkey_algo = "rsa";
		break;
	case OID_gost2012PKey256:
	case OID_gost2012PKey512:
		ctx->cert->pub->pkey_algo = "ecrdsa";
		break;
	case OID_sm2:
		ctx->cert->pub->pkey_algo = "sm2";
		break;
	case OID_id_ecPublicKey:
		if (parse_OID(ctx->params, ctx->params_size, &oid) != 0)
			return -EBADMSG;

		switch (oid) {
		case OID_sm2:
			ctx->cert->pub->pkey_algo = "sm2";
			break;
		case OID_id_prime192v1:
			ctx->cert->pub->pkey_algo = "ecdsa-nist-p192";
			break;
		case OID_id_prime256v1:
			ctx->cert->pub->pkey_algo = "ecdsa-nist-p256";
			break;
		case OID_id_ansip384r1:
			ctx->cert->pub->pkey_algo = "ecdsa-nist-p384";
			break;
		case OID_id_ansip521r1:
			ctx->cert->pub->pkey_algo = "ecdsa-nist-p521";
			break;
		default:
			return -ENOPKG;
		}
		break;
	default:
		return -ENOPKG;
	}

	/* Discard the BIT STRING metadata */
	if (vlen < 1 || *(const u8 *)value != 0)
		return -EBADMSG;
	ctx->key = value + 1;
	ctx->key_size = vlen - 1;
	return 0;
}

/* The keyIdentifier in AuthorityKeyIdentifier SEQUENCE is tag(CONT,PRIM,0) */
#define SEQ_TAG_KEYID (ASN1_CONT << 6)

/*
 * Process certificate extensions that are used to qualify the certificate.
 */
int x509_process_extension(void *context, size_t hdrlen,
			   unsigned char tag,
			   const void *value, size_t vlen)
{
	struct x509_parse_context *ctx = context;
	struct asymmetric_key_id *kid;
	const unsigned char *v = value;

	pr_debug("Extension: %u\n", ctx->last_oid);

	if (ctx->last_oid == OID_subjectKeyIdentifier) {
		/* Get hold of the key fingerprint */
		if (ctx->cert->skid || vlen < 3)
			return -EBADMSG;
		if (v[0] != ASN1_OTS || v[1] != vlen - 2)
			return -EBADMSG;
		v += 2;
		vlen -= 2;

		ctx->cert->raw_skid_size = vlen;
		ctx->cert->raw_skid = v;
		kid = asymmetric_key_generate_id(v, vlen, "", 0);
		if (IS_ERR(kid))
			return PTR_ERR(kid);
		ctx->cert->skid = kid;
		pr_debug("subjkeyid %*phN\n", kid->len, kid->data);
		return 0;
	}

	if (ctx->last_oid == OID_keyUsage) {
		/*
		 * Get hold of the keyUsage bit string
		 * v[1] is the encoding size
		 *       (Expect either 0x02 or 0x03, making it 1 or 2 bytes)
		 * v[2] is the number of unused bits in the bit string
		 *       (If >= 3 keyCertSign is missing when v[1] = 0x02)
		 * v[3] and possibly v[4] contain the bit string
		 *
		 * From RFC 5280 4.2.1.3:
		 *   0x04 is where keyCertSign lands in this bit string
		 *   0x80 is where digitalSignature lands in this bit string
		 */
		if (v[0] != ASN1_BTS)
			return -EBADMSG;
		if (vlen < 4)
			return -EBADMSG;
		if (v[2] >= 8)
			return -EBADMSG;
		if (v[3] & 0x80)
			ctx->cert->pub->key_eflags |= 1 << KEY_EFLAG_DIGITALSIG;
		if (v[1] == 0x02 && v[2] <= 2 && (v[3] & 0x04))
			ctx->cert->pub->key_eflags |= 1 << KEY_EFLAG_KEYCERTSIGN;
		else if (vlen > 4 && v[1] == 0x03 && (v[3] & 0x04))
			ctx->cert->pub->key_eflags |= 1 << KEY_EFLAG_KEYCERTSIGN;
		return 0;
	}

	if (ctx->last_oid == OID_authorityKeyIdentifier) {
		/* Get hold of the CA key fingerprint */
		ctx->raw_akid = v;
		ctx->raw_akid_size = vlen;
		return 0;
	}

	if (ctx->last_oid == OID_basicConstraints) {
		/*
		 * Get hold of the basicConstraints
		 * v[1] is the encoding size
		 *	(Expect 0x2 or greater, making it 1 or more bytes)
		 * v[2] is the encoding type
		 *	(Expect an ASN1_BOOL for the CA)
		 * v[3] is the contents of the ASN1_BOOL
		 *      (Expect 1 if the CA is TRUE)
		 * vlen should match the entire extension size
		 */
		if (v[0] != (ASN1_CONS_BIT | ASN1_SEQ))
			return -EBADMSG;
		if (vlen < 2)
			return -EBADMSG;
		if (v[1] != vlen - 2)
			return -EBADMSG;
		if (vlen >= 4 && v[1] != 0 && v[2] == ASN1_BOOL && v[3] == 1)
			ctx->cert->pub->key_eflags |= 1 << KEY_EFLAG_CA;
		return 0;
	}

	return 0;
}

/**
 * x509_decode_time - Decode an X.509 time ASN.1 object
 * @_t: The time to fill in
 * @hdrlen: The length of the object header
 * @tag: The object tag
 * @value: The object value
 * @vlen: The size of the object value
 *
 * Decode an ASN.1 universal time or generalised time field into a struct the
 * kernel can handle and check it for validity.  The time is decoded thus:
 *
 *	[RFC5280 §4.1.2.5]
 *	CAs conforming to this profile MUST always encode certificate validity
 *	dates through the year 2049 as UTCTime; certificate validity dates in
 *	2050 or later MUST be encoded as GeneralizedTime.  Conforming
 *	applications MUST be able to process validity dates that are encoded in
 *	either UTCTime or GeneralizedTime.
 */
int x509_decode_time(time64_t *_t,  size_t hdrlen,
		     unsigned char tag,
		     const unsigned char *value, size_t vlen)
{
	static const unsigned char month_lengths[] = { 31, 28, 31, 30, 31, 30,
						       31, 31, 30, 31, 30, 31 };
	const unsigned char *p = value;
	unsigned year, mon, day, hour, min, sec, mon_len;

#define dec2bin(X) ({ unsigned char x = (X) - '0'; if (x > 9) goto invalid_time; x; })
#define DD2bin(P) ({ unsigned x = dec2bin(P[0]) * 10 + dec2bin(P[1]); P += 2; x; })

	if (tag == ASN1_UNITIM) {
		/* UTCTime: YYMMDDHHMMSSZ */
		if (vlen != 13)
			goto unsupported_time;
		year = DD2bin(p);
		if (year >= 50)
			year += 1900;
		else
			year += 2000;
	} else if (tag == ASN1_GENTIM) {
		/* GenTime: YYYYMMDDHHMMSSZ */
		if (vlen != 15)
			goto unsupported_time;
		year = DD2bin(p) * 100 + DD2bin(p);
		if (year >= 1950 && year <= 2049)
			goto invalid_time;
	} else {
		goto unsupported_time;
	}

	mon  = DD2bin(p);
	day = DD2bin(p);
	hour = DD2bin(p);
	min  = DD2bin(p);
	sec  = DD2bin(p);

	if (*p != 'Z')
		goto unsupported_time;

	if (year < 1970 ||
	    mon < 1 || mon > 12)
		goto invalid_time;

	mon_len = month_lengths[mon - 1];
	if (mon == 2) {
		if (year % 4 == 0) {
			mon_len = 29;
			if (year % 100 == 0) {
				mon_len = 28;
				if (year % 400 == 0)
					mon_len = 29;
			}
		}
	}

	if (day < 1 || day > mon_len ||
	    hour > 24 || /* ISO 8601 permits 24:00:00 as midnight tomorrow */
	    min > 59 ||
	    sec > 60) /* ISO 8601 permits leap seconds [X.680 46.3] */
		goto invalid_time;

	*_t = mktime64(year, mon, day, hour, min, sec);
	return 0;

unsupported_time:
	pr_debug("Got unsupported time [tag %02x]: '%*phN'\n",
		 tag, (int)vlen, value);
	return -EBADMSG;
invalid_time:
	pr_debug("Got invalid time [tag %02x]: '%*phN'\n",
		 tag, (int)vlen, value);
	return -EBADMSG;
}
EXPORT_SYMBOL_GPL(x509_decode_time);

int x509_note_not_before(void *context, size_t hdrlen,
			 unsigned char tag,
			 const void *value, size_t vlen)
{
	struct x509_parse_context *ctx = context;
	return x509_decode_time(&ctx->cert->valid_from, hdrlen, tag, value, vlen);
}

int x509_note_not_after(void *context, size_t hdrlen,
			unsigned char tag,
			const void *value, size_t vlen)
{
	struct x509_parse_context *ctx = context;
	return x509_decode_time(&ctx->cert->valid_to, hdrlen, tag, value, vlen);
}

/*
 * Note a key identifier-based AuthorityKeyIdentifier
 */
int x509_akid_note_kid(void *context, size_t hdrlen,
		       unsigned char tag,
		       const void *value, size_t vlen)
{
	struct x509_parse_context *ctx = context;
	struct asymmetric_key_id *kid;

	pr_debug("AKID: keyid: %*phN\n", (int)vlen, value);

	if (ctx->cert->sig->auth_ids[1])
		return 0;

	kid = asymmetric_key_generate_id(value, vlen, "", 0);
	if (IS_ERR(kid))
		return PTR_ERR(kid);
	pr_debug("authkeyid %*phN\n", kid->len, kid->data);
	ctx->cert->sig->auth_ids[1] = kid;
	return 0;
}

/*
 * Note a directoryName in an AuthorityKeyIdentifier
 */
int x509_akid_note_name(void *context, size_t hdrlen,
			unsigned char tag,
			const void *value, size_t vlen)
{
	struct x509_parse_context *ctx = context;

	pr_debug("AKID: name: %*phN\n", (int)vlen, value);

	ctx->akid_raw_issuer = value;
	ctx->akid_raw_issuer_size = vlen;
	return 0;
}

/*
 * Note a serial number in an AuthorityKeyIdentifier
 */
int x509_akid_note_serial(void *context, size_t hdrlen,
			  unsigned char tag,
			  const void *value, size_t vlen)
{
	struct x509_parse_context *ctx = context;
	struct asymmetric_key_id *kid;

	pr_debug("AKID: serial: %*phN\n", (int)vlen, value);

	if (!ctx->akid_raw_issuer || ctx->cert->sig->auth_ids[0])
		return 0;

	kid = asymmetric_key_generate_id(value,
					 vlen,
					 ctx->akid_raw_issuer,
					 ctx->akid_raw_issuer_size);
	if (IS_ERR(kid))
		return PTR_ERR(kid);

	pr_debug("authkeyid %*phN\n", kid->len, kid->data);
	ctx->cert->sig->auth_ids[0] = kid;
	return 0;
}