freebsd-skq/tools/brssl.h

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2019-01-21 20:23:49 +00:00
/*
* 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.
*/
#ifndef BRSSL_H__
#define BRSSL_H__
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <stdint.h>
#include "bearssl.h"
/*
* malloc() wrapper:
* -- If len is 0, then NULL is returned.
* -- If len is non-zero, and allocation fails, then an error message is
* printed and the process exits with an error code.
*/
void *xmalloc(size_t len);
/*
* free() wrapper, meant to release blocks allocated with xmalloc().
*/
void xfree(void *buf);
/*
* Duplicate a character string into a newly allocated block.
*/
char *xstrdup(const void *src);
/*
* Allocate a new block with the provided length, filled with a copy
* of exactly that many bytes starting at address 'src'.
*/
void *xblobdup(const void *src, size_t len);
/*
* Duplicate a public key, into newly allocated blocks. The returned
* key must be later on released with xfreepkey().
*/
br_x509_pkey *xpkeydup(const br_x509_pkey *pk);
/*
* Release a public key that was allocated with xpkeydup(). If pk is NULL,
* this function does nothing.
*/
void xfreepkey(br_x509_pkey *pk);
/*
* Macros for growable arrays.
*/
/*
* Make a structure type for a vector of 'type'.
*/
#define VECTOR(type) struct { \
type *buf; \
size_t ptr, len; \
}
/*
* Constant initialiser for a vector.
*/
#define VEC_INIT { 0, 0, 0 }
/*
* Clear a vector.
*/
#define VEC_CLEAR(vec) do { \
xfree((vec).buf); \
(vec).buf = NULL; \
(vec).ptr = 0; \
(vec).len = 0; \
} while (0)
/*
* Clear a vector, first calling the provided function on each vector
* element.
*/
#define VEC_CLEAREXT(vec, fun) do { \
size_t vec_tmp; \
for (vec_tmp = 0; vec_tmp < (vec).ptr; vec_tmp ++) { \
(fun)(&(vec).buf[vec_tmp]); \
} \
VEC_CLEAR(vec); \
} while (0)
/*
* Add a value at the end of a vector.
*/
#define VEC_ADD(vec, x) do { \
(vec).buf = vector_expand((vec).buf, sizeof *((vec).buf), \
&(vec).ptr, &(vec).len, 1); \
(vec).buf[(vec).ptr ++] = (x); \
} while (0)
/*
* Add several values at the end of a vector.
*/
#define VEC_ADDMANY(vec, xp, num) do { \
size_t vec_num = (num); \
(vec).buf = vector_expand((vec).buf, sizeof *((vec).buf), \
&(vec).ptr, &(vec).len, vec_num); \
memcpy((vec).buf + (vec).ptr, \
(xp), vec_num * sizeof *((vec).buf)); \
(vec).ptr += vec_num; \
} while (0)
/*
* Access a vector element by index. This is a lvalue, and can be modified.
*/
#define VEC_ELT(vec, idx) ((vec).buf[idx])
/*
* Get current vector length.
*/
#define VEC_LEN(vec) ((vec).ptr)
/*
* Copy all vector elements into a newly allocated block.
*/
#define VEC_TOARRAY(vec) xblobdup((vec).buf, sizeof *((vec).buf) * (vec).ptr)
/*
* Internal function used to handle memory allocations for vectors.
*/
void *vector_expand(void *buf,
size_t esize, size_t *ptr, size_t *len, size_t extra);
/*
* Type for a vector of bytes.
*/
typedef VECTOR(unsigned char) bvector;
/*
* Compare two strings for equality; returned value is 1 if the strings
* are to be considered equal, 0 otherwise. Comparison is case-insensitive
* (ASCII letters only) and skips some characters (all whitespace, defined
* as ASCII codes 0 to 32 inclusive, and also '-', '_', '.', '/', '+' and
* ':').
*/
int eqstr(const char *s1, const char *s2);
/*
* Convert a string to a positive integer (size_t). Returned value is
* (size_t)-1 on error. On error, an explicit error message is printed.
*/
size_t parse_size(const char *s);
/*
* Structure for a known protocol version.
*/
typedef struct {
const char *name;
unsigned version;
const char *comment;
} protocol_version;
/*
* Known protocol versions. Last element has a NULL name.
*/
extern const protocol_version protocol_versions[];
/*
* Parse a version name. If the name is not recognized, then an error
* message is printed, and 0 is returned.
*/
unsigned parse_version(const char *name, size_t len);
/*
* Type for a known hash function.
*/
typedef struct {
const char *name;
const br_hash_class *hclass;
const char *comment;
} hash_function;
/*
* Known hash functions. Last element has a NULL name.
*/
extern const hash_function hash_functions[];
/*
* Parse hash function names. This function expects a comma-separated
* list of names, and returns a bit mask corresponding to the matched
* names. If one of the name does not match, or the list is empty, then
* an error message is printed, and 0 is returned.
*/
unsigned parse_hash_functions(const char *arg);
/*
* Get a curve name (by ID). If the curve ID is not known, this returns
* NULL.
*/
const char *get_curve_name(int id);
/*
* Get a curve name (by ID). The name is written in the provided buffer
* (zero-terminated). If the curve ID is not known, the name is
* "unknown (***)" where "***" is the decimal value of the identifier.
* If the name does not fit in the provided buffer, then dst[0] is set
* to 0 (unless len is 0, in which case nothing is written), and -1 is
* returned. Otherwise, the name is written in dst[] (with a terminating
* 0), and this function returns 0.
*/
int get_curve_name_ext(int id, char *dst, size_t len);
/*
* Type for a known cipher suite.
*/
typedef struct {
const char *name;
uint16_t suite;
unsigned req;
const char *comment;
} cipher_suite;
/*
* Known cipher suites. Last element has a NULL name.
*/
extern const cipher_suite cipher_suites[];
/*
* Flags for cipher suite requirements.
*/
#define REQ_TLS12 0x0001 /* suite needs TLS 1.2 */
#define REQ_SHA1 0x0002 /* suite needs SHA-1 */
#define REQ_SHA256 0x0004 /* suite needs SHA-256 */
#define REQ_SHA384 0x0008 /* suite needs SHA-384 */
#define REQ_AESCBC 0x0010 /* suite needs AES/CBC encryption */
#define REQ_AESGCM 0x0020 /* suite needs AES/GCM encryption */
#define REQ_AESCCM 0x0040 /* suite needs AES/CCM encryption */
#define REQ_CHAPOL 0x0080 /* suite needs ChaCha20+Poly1305 */
#define REQ_3DESCBC 0x0100 /* suite needs 3DES/CBC encryption */
#define REQ_RSAKEYX 0x0200 /* suite uses RSA key exchange */
#define REQ_ECDHE_RSA 0x0400 /* suite uses ECDHE_RSA key exchange */
#define REQ_ECDHE_ECDSA 0x0800 /* suite uses ECDHE_ECDSA key exchange */
#define REQ_ECDH 0x1000 /* suite uses static ECDH key exchange */
/*
* Parse a list of cipher suite names. The names are comma-separated. If
* one of the name is not recognised, or the list is empty, then an
* appropriate error message is printed, and NULL is returned.
* The returned array is allocated with xmalloc() and must be released
* by the caller. That array is terminated with a dummy entry whose 'name'
* field is NULL. The number of entries (not counting the dummy entry)
* is also written into '*num'.
*/
cipher_suite *parse_suites(const char *arg, size_t *num);
/*
* Get the name of a cipher suite. Returned value is NULL if the suite is
* not recognized.
*/
const char *get_suite_name(unsigned suite);
/*
* Get the name of a cipher suite. The name is written in the provided
* buffer; if the suite is not recognised, then the name is
* "unknown (0x****)" where "****" is the hexadecimal value of the suite.
* If the name does not fit in the provided buffer, then dst[0] is set
* to 0 (unless len is 0, in which case nothing is written), and -1 is
* returned. Otherwise, the name is written in dst[] (with a terminating
* 0), and this function returns 0.
*/
int get_suite_name_ext(unsigned suite, char *dst, size_t len);
/*
* Tell whether a cipher suite uses ECDHE key exchange.
*/
int uses_ecdhe(unsigned suite);
/*
* Print out all known names (for protocol versions, cipher suites...).
*/
void list_names(void);
/*
* Print out all known elliptic curve names.
*/
void list_curves(void);
/*
* Get the symbolic name for an elliptic curve (by ID).
*/
const char *ec_curve_name(int curve);
/*
* Get a curve by symbolic name. If the name is not recognized, -1 is
* returned.
*/
int get_curve_by_name(const char *str);
/*
* Get the symbolic name for a hash function name (by ID).
*/
const char *hash_function_name(int id);
/*
* Read a file completely. The returned block is allocated with xmalloc()
* and must be released by the caller.
* If the file cannot be found or read completely, or is empty, then an
* appropriate error message is written, and NULL is returned.
*/
unsigned char *read_file(const char *fname, size_t *len);
/*
* Write a file completely. This returns 0 on success, -1 on error. On
* error, an appropriate error message is printed.
*/
int write_file(const char *fname, const void *data, size_t len);
/*
* This function returns non-zero if the provided buffer "looks like"
* a DER-encoded ASN.1 object (criteria: it has the tag for a SEQUENCE
* with a definite length that matches the total object length).
*/
int looks_like_DER(const unsigned char *buf, size_t len);
/*
* Type for a named blob (the 'name' is a normalised PEM header name).
*/
typedef struct {
char *name;
unsigned char *data;
size_t data_len;
} pem_object;
/*
* Release the contents of a named blob (buffer and name).
*/
void free_pem_object_contents(pem_object *po);
/*
* Decode a buffer as a PEM file, and return all objects. On error, NULL
* is returned and an error message is printed. Absence of any object
* is an error.
*
* The returned array is terminated by a dummy object whose 'name' is
* NULL. The number of objects (not counting the dummy terminator) is
* written in '*num'.
*/
pem_object *decode_pem(const void *src, size_t len, size_t *num);
/*
* Get the certificate(s) from a file. This accepts both a single
* DER-encoded certificate, and a text file that contains
* PEM-encoded certificates (and possibly other objects, which are
* then ignored).
*
* On decoding error, or if the file turns out to contain no certificate
* at all, then an error message is printed and NULL is returned.
*
* The returned array, and all referenced buffers, are allocated with
* xmalloc() and must be released by the caller. The returned array
* ends with a dummy entry whose 'data' field is NULL.
* The number of decoded certificates (not counting the dummy entry)
* is written into '*num'.
*/
br_x509_certificate *read_certificates(const char *fname, size_t *num);
/*
* Release certificates. This releases all certificate data arrays,
* and the whole array as well.
*/
void free_certificates(br_x509_certificate *certs, size_t num);
/*
* Interpret a certificate as a trust anchor. The trust anchor is
* newly allocated with xmalloc() and the caller must release it.
* On decoding error, an error message is printed, and this function
* returns NULL.
*/
br_x509_trust_anchor *certificate_to_trust_anchor(br_x509_certificate *xc);
/*
* Type for a vector of trust anchors.
*/
typedef VECTOR(br_x509_trust_anchor) anchor_list;
/*
* Release contents for a trust anchor (assuming they were dynamically
* allocated with xmalloc()). The structure itself is NOT released.
*/
void free_ta_contents(br_x509_trust_anchor *ta);
/*
* Decode certificates from a file and interpret them as trust anchors.
* The trust anchors are added to the provided list. The number of found
* anchors is returned; on error, 0 is returned (finding no anchor at
* all is considered an error). An appropriate error message is displayed.
*/
size_t read_trust_anchors(anchor_list *dst, const char *fname);
/*
* Get the "signer key type" for the certificate (key type of the
* issuing CA). On error, this prints a message on stderr, and returns 0.
*/
int get_cert_signer_algo(br_x509_certificate *xc);
/*
* Special "no anchor" X.509 validator that wraps around another X.509
* validator and turns "not trusted" error codes into success. This is
* by definition insecure, but convenient for debug purposes.
*/
typedef struct {
const br_x509_class *vtable;
const br_x509_class **inner;
} x509_noanchor_context;
extern const br_x509_class x509_noanchor_vtable;
/*
* Initialise a "no anchor" X.509 validator.
*/
void x509_noanchor_init(x509_noanchor_context *xwc,
const br_x509_class **inner);
/*
* Aggregate type for a private key.
*/
typedef struct {
int key_type; /* BR_KEYTYPE_RSA or BR_KEYTYPE_EC */
union {
br_rsa_private_key rsa;
br_ec_private_key ec;
} key;
} private_key;
/*
* Decode a private key from a file. On error, this prints an error
* message and returns NULL.
*/
private_key *read_private_key(const char *fname);
/*
* Free a private key.
*/
void free_private_key(private_key *sk);
/*
* Get the encoded OID for a given hash function (to use with PKCS#1
* signatures). If the hash function ID is 0 (for MD5+SHA-1), or if
* the ID is not one of the SHA-* functions (SHA-1, SHA-224, SHA-256,
* SHA-384, SHA-512), then this function returns NULL.
*/
const unsigned char *get_hash_oid(int id);
/*
* Get a hash implementation by ID. This returns NULL if the hash
* implementation is not available.
*/
const br_hash_class *get_hash_impl(int id);
/*
* Find the symbolic name and the description for an error. If 'err' is
* recognised then the error symbolic name is returned; if 'comment' is
* not NULL then '*comment' is then set to a descriptive human-readable
* message. If the error code 'err' is not recognised, then '*comment' is
* untouched and this function returns NULL.
*/
const char *find_error_name(int err, const char **comment);
/*
* Find the symbolic name for an algorithm implementation. Provided
* pointer should be a pointer to a vtable or to a function, where
* appropriate. If not recognised, then the string "UNKNOWN" is returned.
*
* If 'long_name' is non-zero, then the returned name recalls the
* algorithm type as well; otherwise, only the core implementation name
* is returned (e.g. the long name could be 'aes_big_cbcenc' while the
* short name is 'big').
*/
const char *get_algo_name(const void *algo, int long_name);
/*
* Run a SSL engine, with a socket connected to the peer, and using
* stdin/stdout to exchange application data. The socket must be a
* non-blocking descriptor.
*
* To help with Win32 compatibility, the socket descriptor is provided
* as an "unsigned long" value.
*
* Returned value:
* 0 SSL connection closed successfully
* x > 0 SSL error "x"
* -1 early socket close
* -2 stdout was closed, or something failed badly
*/
int run_ssl_engine(br_ssl_engine_context *eng,
unsigned long fd, unsigned flags);
#define RUN_ENGINE_VERBOSE 0x0001 /* enable verbose messages */
#define RUN_ENGINE_TRACE 0x0002 /* hex dump of records */
/*
* Do the "client" command. Returned value is 0 on success, -1 on failure.
* Command-line arguments start _after_ the command name.
*/
int do_client(int argc, char *argv[]);
/*
* Do the "server" command. Returned value is 0 on success, -1 on failure.
* Command-line arguments start _after_ the command name.
*/
int do_server(int argc, char *argv[]);
/*
* Do the "verify" command. Returned value is 0 on success, -1 on failure.
* Command-line arguments start _after_ the command name.
*/
int do_verify(int argc, char *argv[]);
/*
* Do the "skey" command. Returned value is 0 on success, -1 on failure.
* Command-line arguments start _after_ the command name.
*/
int do_skey(int argc, char *argv[]);
/*
* Do the "ta" command. Returned value is 0 on success, -1 on failure.
* Command-line arguments start _after_ the command name.
*/
int do_ta(int argc, char *argv[]);
/*
* Do the "chain" command. Returned value is 0 on success, -1 on failure.
* Command-line arguments start _after_ the command name.
*/
int do_chain(int argc, char *argv[]);
/*
* Do the "twrch" command. Returned value is 0 on success, -1 on failure
* (processing or arguments), or a non-zero exit code. Command-line
* arguments start _after_ the command name.
*/
int do_twrch(int argc, char *argv[]);
/*
* Do the "impl" command. Returned value is 0 on success, -1 on failure.
* Command-line arguments start _after_ the command name.
*/
int do_impl(int argc, char *argv[]);
#endif