openssl/demos/tunala/tunala.h
Richard Levitte cf1b7d9664 Make all configuration macros available for application by making
sure they are available in opensslconf.h, by giving them names starting
with "OPENSSL_" to avoid conflicts with other packages and by making
sure e_os2.h will cover all platform-specific cases together with
opensslconf.h.

I've checked fairly well that nothing breaks with this (apart from
external software that will adapt if they have used something like
NO_KRB5), but I can't guarantee it completely, so a review of this
change would be a good thing.
2001-02-19 16:06:34 +00:00

162 lines
6.7 KiB
C

/* Tunala ("Tunneler with a New Zealand accent")
*
* Written by Geoff Thorpe, but endorsed/supported by noone. Please use this is
* if it's useful or informative to you, but it's only here as a scratchpad for
* ideas about how you might (or might not) program with OpenSSL. If you deploy
* this is in a mission-critical environment, and have not read, understood,
* audited, and modified this code to your satisfaction, and the result is that
* all hell breaks loose and you are looking for a new employer, then it proves
* nothing except perhaps that Darwinism is alive and well. Let's just say, *I*
* don't use this in a mission-critical environment, so it would be stupid for
* anyone to assume that it is solid and/or tested enough when even its author
* doesn't place that much trust in it. You have been warned.
*
* With thanks to Cryptographic Appliances, Inc.
*/
#ifndef _TUNALA_H
#define _TUNALA_H
#ifndef NO_SYSTEM_H
#include <string.h>
#include <unistd.h>
#include <fcntl.h>
#include <netdb.h>
#include <signal.h>
#include <sys/socket.h>
#include <netinet/in.h>
#endif /* !defined(NO_SYSTEM_H) */
#ifndef NO_OPENSSL
#include <openssl/err.h>
#include <openssl/engine.h>
#include <openssl/ssl.h>
#endif /* !defined(NO_OPENSSL) */
#ifndef OPENSSL_NO_BUFFER
/* This is the generic "buffer" type that is used when feeding the
* state-machine. It's basically a FIFO with respect to the "adddata" &
* "takedata" type functions that operate on it. */
#define MAX_DATA_SIZE 16384
typedef struct _buffer_t {
unsigned char data[MAX_DATA_SIZE];
unsigned int used;
/* Statistical values - counts the total number of bytes read in and
* read out (respectively) since "buffer_init()" */
unsigned long total_in, total_out;
} buffer_t;
/* Initialise a buffer structure before use */
void buffer_init(buffer_t *buf);
/* Cleanup a buffer structure - presently not needed, but if buffer_t is
* converted to using dynamic allocation, this would be required - so should be
* called to protect against an explosion of memory leaks later if the change is
* made. */
void buffer_close(buffer_t *buf);
/* Basic functions to manipulate buffers */
unsigned int buffer_used(buffer_t *buf); /* How much data in the buffer */
unsigned int buffer_unused(buffer_t *buf); /* How much space in the buffer */
int buffer_full(buffer_t *buf); /* Boolean, is it full? */
int buffer_notfull(buffer_t *buf); /* Boolean, is it not full? */
int buffer_empty(buffer_t *buf); /* Boolean, is it empty? */
int buffer_notempty(buffer_t *buf); /* Boolean, is it not empty? */
unsigned long buffer_total_in(buffer_t *buf); /* Total bytes written to buffer */
unsigned long buffer_total_out(buffer_t *buf); /* Total bytes read from buffer */
#if 0 /* Currently used only within buffer.c - better to expose only
* higher-level functions anyway */
/* Add data to the tail of the buffer, returns the amount that was actually
* added (so, you need to check if return value is less than size) */
unsigned int buffer_adddata(buffer_t *buf, const unsigned char *ptr,
unsigned int size);
/* Take data from the front of the buffer (and scroll the rest forward). If
* "ptr" is NULL, this just removes data off the front of the buffer. Return
* value is the amount actually removed (can be less than size if the buffer has
* too little data). */
unsigned int buffer_takedata(buffer_t *buf, unsigned char *ptr,
unsigned int size);
/* Flushes as much data as possible out of the "from" buffer into the "to"
* buffer. Return value is the amount moved. The amount moved can be restricted
* to a maximum by specifying "cap" - setting it to -1 means no limit. */
unsigned int buffer_tobuffer(buffer_t *to, buffer_t *from, int cap);
#endif
#ifndef NO_IP
/* Read or write between a file-descriptor and a buffer */
int buffer_from_fd(buffer_t *buf, int fd);
int buffer_to_fd(buffer_t *buf, int fd);
#endif /* !defined(NO_IP) */
#ifndef NO_OPENSSL
/* Read or write between an SSL or BIO and a buffer */
void buffer_from_SSL(buffer_t *buf, SSL *ssl);
void buffer_to_SSL(buffer_t *buf, SSL *ssl);
void buffer_from_BIO(buffer_t *buf, BIO *bio);
void buffer_to_BIO(buffer_t *buf, BIO *bio);
/* Callbacks */
void cb_ssl_info(SSL *s, int where, int ret);
void cb_ssl_info_set_output(FILE *fp); /* Called if output should be sent too */
int cb_ssl_verify(int ok, X509_STORE_CTX *ctx);
void cb_ssl_verify_set_output(FILE *fp);
void cb_ssl_verify_set_depth(unsigned int verify_depth);
void cb_ssl_verify_set_level(unsigned int level);
#endif /* !defined(NO_OPENSSL) */
#endif /* !defined(OPENSSL_NO_BUFFER) */
#ifndef NO_TUNALA
#ifdef OPENSSL_NO_BUFFER
#error "TUNALA section of tunala.h requires BUFFER support"
#endif
typedef struct _state_machine_t {
SSL *ssl;
BIO *bio_intossl;
BIO *bio_fromssl;
buffer_t clean_in, clean_out;
buffer_t dirty_in, dirty_out;
} state_machine_t;
typedef enum {
SM_CLEAN_IN, SM_CLEAN_OUT,
SM_DIRTY_IN, SM_DIRTY_OUT
} sm_buffer_t;
void state_machine_init(state_machine_t *machine);
void state_machine_close(state_machine_t *machine);
buffer_t *state_machine_get_buffer(state_machine_t *machine, sm_buffer_t type);
SSL *state_machine_get_SSL(state_machine_t *machine);
int state_machine_set_SSL(state_machine_t *machine, SSL *ssl, int is_server);
/* Performs the data-IO loop and returns zero if the machine should close */
int state_machine_churn(state_machine_t *machine);
/* Is used to handle closing conditions - namely when one side of the tunnel has
* closed but the other should finish flushing. */
int state_machine_close_clean(state_machine_t *machine);
int state_machine_close_dirty(state_machine_t *machine);
#endif /* !defined(NO_TUNALA) */
#ifndef NO_IP
/* Initialise anything related to the networking. This includes blocking pesky
* SIGPIPE signals. */
int ip_initialise(void);
/* ip is the 4-byte ip address (eg. 127.0.0.1 is {0x7F,0x00,0x00,0x01}), port is
* the port to listen on (host byte order), and the return value is the
* file-descriptor or -1 on error. */
int ip_create_listener_split(const unsigned char *ip, unsigned short port);
/* Same semantics as above. */
int ip_create_connection_split(const unsigned char *ip, unsigned short port);
/* Converts a string into the ip/port before calling the above */
int ip_create_listener(const char *address);
int ip_create_connection(const char *address);
/* Just does a string conversion on its own. NB: If accept_all_ip is non-zero,
* then the address string could be just a port. Ie. it's suitable for a
* listening address but not a connecting address. */
int ip_parse_address(const char *address, unsigned char **parsed_ip,
unsigned short *port, int accept_all_ip);
/* Accepts an incoming connection through the listener. Assumes selects and
* what-not have deemed it an appropriate thing to do. */
int ip_accept_connection(int listen_fd);
#endif /* !defined(NO_IP) */
#endif /* !defined(_TUNALA_H) */