asterisk/res/res_pjsip_history.c

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2023-05-25 18:45:57 +00:00
/*
* Asterisk -- An open source telephony toolkit.
*
* Copyright (C) 1999 - 2015, Digium, Inc.
*
* Matt Jordan <mjordan@digium.com>
*
* See http://www.asterisk.org for more information about
* the Asterisk project. Please do not directly contact
* any of the maintainers of this project for assistance;
* the project provides a web site, mailing lists and IRC
* channels for your use.
*
* This program is free software, distributed under the terms of
* the GNU General Public License Version 2. See the LICENSE file
* at the top of the source tree.
*/
/*!
* \file
* \brief PJSIP History
*
* \author Matt Jordan <mjordan@digium.com>
*
*/
/*** MODULEINFO
<depend>pjproject</depend>
<depend>res_pjsip</depend>
<support_level>extended</support_level>
***/
#include "asterisk.h"
#include <pjsip.h>
#include <regex.h>
#include "asterisk/res_pjsip.h"
#include "asterisk/module.h"
#include "asterisk/logger.h"
#include "asterisk/cli.h"
#include "asterisk/netsock2.h"
#include "asterisk/vector.h"
#include "asterisk/lock.h"
#include "asterisk/res_pjproject.h"
#define HISTORY_INITIAL_SIZE 256
/*! \brief Pool factory used by pjlib to allocate memory. */
static pj_caching_pool cachingpool;
/*! \brief Whether or not we are storing history */
static int enabled;
/*! \brief Packet count */
static int packet_number;
/*! \brief An item in the history */
struct pjsip_history_entry {
/*! \brief Packet number */
int number;
/*! \brief Whether or not we transmitted the packet */
int transmitted;
/*! \brief Time the packet was transmitted/received */
struct timeval timestamp;
/*! \brief Source address */
pj_sockaddr src;
/*! \brief Destination address */
pj_sockaddr dst;
/*! \brief Memory pool used to allocate \c msg */
pj_pool_t *pool;
/*! \brief The actual SIP message */
pjsip_msg *msg;
};
/*! \brief Mutex that protects \c vector_history */
AST_MUTEX_DEFINE_STATIC(history_lock);
struct expression_token;
/*! \brief An operator that we understand in an expression */
struct operator {
/*! \brief Our operator's symbol */
const char *symbol;
/*! \brief Precedence of the symbol */
int precedence;
/*! \brief Non-zero if the operator is evaluated right-to-left */
int right_to_left;
/*! \brief Number of operands the operator takes */
int operands;
/*!
* \brief Evaluation function for unary operators
*
* \param op The operator being evaluated
* \param type The type of value contained in \c operand
* \param operand A pointer to the value to evaluate
*
* \retval -1 error
* \retval 0 evaluation is False
* \retval 1 evaluation is True
*/
int (* const evaluate_unary)(struct operator *op, enum aco_option_type type, void *operand);
/*!
* \brief Evaluation function for binary operators
*
* \param op The operator being evaluated
* \param type The type of value contained in \c op_left
* \param op_left A pointer to the value to evaluate (a result or extracted from an entry)
* \param op_right The expression token containing the other value (a result or user-provided)
*
* \retval -1 error
* \retval 0 evaluation is False
* \retval 1 evaluation is True
*/
int (* const evaluate)(struct operator *op, enum aco_option_type type, void *op_left, struct expression_token *op_right);
};
/*! \brief A field that we understand and can perform operations on */
struct allowed_field {
/*! \brief The representation of the field */
const char *symbol;
/*! \brief The type /c get_field returns */
enum aco_option_type return_type;
/*!
* \brief Function that returns the field from a pjsip_history_entry
*
* Note that the function must return a pointer to the location in
* \c pjsip_history_entry - no memory should be allocated as the caller
* will not dispose of any
*/
void *(* const get_field)(struct pjsip_history_entry *entry);
};
/*! \brief The type of token that has been parsed out of an expression */
enum expression_token_type {
/*! The \c expression_token contains a field */
TOKEN_TYPE_FIELD,
/*! The \c expression_token contains an operator */
TOKEN_TYPE_OPERATOR,
/*! The \c expression_token contains a previous result */
TOKEN_TYPE_RESULT
};
/*! \brief A token in the expression or an evaluated part of the expression */
struct expression_token {
/*! \brief The next expression token in the queue */
struct expression_token *next;
/*! \brief The type of value stored in the expression token */
enum expression_token_type token_type;
/*! \brief An operator that evaluates expressions */
struct operator *op;
/*! \brief The result of an evaluated expression */
int result;
/*! \brief The field in the expression */
char field[];
};
/*! \brief Log level for history output */
static int log_level = -1;
/*! \brief The one and only history that we've captured */
static AST_VECTOR(vector_history_t, struct pjsip_history_entry *) vector_history;
/*!
* \brief Operator callback for determining equality
*/
static int evaluate_equal(struct operator *op, enum aco_option_type type, void *op_left, struct expression_token *op_right)
{
switch (type) {
case OPT_BOOL_T:
case OPT_BOOLFLAG_T:
case OPT_INT_T:
case OPT_UINT_T:
{
int right;
if (sscanf(op_right->field, "%30d", &right) != 1) {
ast_log(LOG_WARNING, "Unable to extract field '%s': not an integer\n", op_right->field);
return -1;
}
return (*(int *)op_left) == right;
}
case OPT_DOUBLE_T:
{
double right;
if (sscanf(op_right->field, "%lf", &right) != 1) {
ast_log(LOG_WARNING, "Unable to extract field '%s': not a double\n", op_right->field);
return -1;
}
return (*(double *)op_left) == right;
}
case OPT_CHAR_ARRAY_T:
case OPT_STRINGFIELD_T:
/* In our case, we operate on pj_str_t */
return pj_strcmp2(op_left, op_right->field) == 0;
case OPT_NOOP_T:
/* Used for timeval */
{
struct timeval right = { 0, };
if ((right.tv_sec = ast_string_to_time_t(op_right->field)) == -1) {
ast_log(LOG_WARNING, "Unable to extract field '%s': not a timestamp\n", op_right->field);
return -1;
}
return ast_tvcmp(*(struct timeval *)op_left, right) == 0;
}
case OPT_SOCKADDR_T:
/* In our case, we operate only on pj_sockaddr_t */
{
pj_sockaddr right;
pj_str_t str_right;
pj_cstr(&str_right, op_right->field);
if (pj_sockaddr_parse(pj_AF_UNSPEC(), 0, &str_right, &right) != PJ_SUCCESS) {
ast_log(LOG_WARNING, "Unable to convert field '%s': not an IPv4 or IPv6 address\n", op_right->field);
return -1;
}
return pj_sockaddr_cmp(op_left, &right) == 0;
}
default:
ast_log(LOG_WARNING, "Cannot evaluate field '%s': invalid type for operator '%s'\n",
op_right->field, op->symbol);
}
return -1;
}
/*!
* \brief Operator callback for determining inequality
*/
static int evaluate_not_equal(struct operator *op, enum aco_option_type type, void *op_left, struct expression_token *op_right)
{
return !evaluate_equal(op, type, op_left, op_right);
}
/*!
* \brief Operator callback for determining if one operand is less than another
*/
static int evaluate_less_than(struct operator *op, enum aco_option_type type, void *op_left, struct expression_token *op_right)
{
switch (type) {
case OPT_BOOL_T:
case OPT_BOOLFLAG_T:
case OPT_INT_T:
case OPT_UINT_T:
{
int right;
if (sscanf(op_right->field, "%30d", &right) != 1) {
ast_log(LOG_WARNING, "Unable to extract field '%s': not an integer\n", op_right->field);
return -1;
}
return (*(int *)op_left) < right;
}
case OPT_DOUBLE_T:
{
double right;
if (sscanf(op_right->field, "%lf", &right) != 1) {
ast_log(LOG_WARNING, "Unable to extract field '%s': not a double\n", op_right->field);
return -1;
}
return (*(double *)op_left) < right;
}
case OPT_NOOP_T:
/* Used for timeval */
{
struct timeval right = { 0, };
if ((right.tv_sec = ast_string_to_time_t(op_right->field)) == -1) {
ast_log(LOG_WARNING, "Unable to extract field '%s': not a timestamp\n", op_right->field);
return -1;
}
return ast_tvcmp(*(struct timeval *)op_left, right) == -1;
}
default:
ast_log(LOG_WARNING, "Cannot evaluate field '%s': invalid type for operator '%s'\n",
op_right->field, op->symbol);
}
return -1;
}
/*!
* \brief Operator callback for determining if one operand is greater than another
*/
static int evaluate_greater_than(struct operator *op, enum aco_option_type type, void *op_left, struct expression_token *op_right)
{
switch (type) {
case OPT_BOOL_T:
case OPT_BOOLFLAG_T:
case OPT_INT_T:
case OPT_UINT_T:
{
int right;
if (sscanf(op_right->field, "%30d", &right) != 1) {
ast_log(LOG_WARNING, "Unable to extract field '%s': not an integer\n", op_right->field);
return -1;
}
return (*(int *)op_left) > right;
}
case OPT_DOUBLE_T:
{
double right;
if (sscanf(op_right->field, "%lf", &right) != 1) {
ast_log(LOG_WARNING, "Unable to extract field '%s': not a double\n", op_right->field);
return -1;
}
return (*(double *)op_left) > right;
}
case OPT_NOOP_T:
/* Used for timeval */
{
struct timeval right = { 0, };
if ((right.tv_sec = ast_string_to_time_t(op_right->field)) == -1) {
ast_log(LOG_WARNING, "Unable to extract field '%s': not a timestamp\n", op_right->field);
return -1;
}
return ast_tvcmp(*(struct timeval *)op_left, right) == 1;
}
default:
ast_log(LOG_WARNING, "Cannot evaluate field '%s': invalid type for operator '%s'\n",
op_right->field, op->symbol);
}
return -1;
}
/*!
* \brief Operator callback for determining if one operand is less than or equal to another
*/
static int evaluate_less_than_or_equal(struct operator *op, enum aco_option_type type, void *op_left, struct expression_token *op_right)
{
return !evaluate_greater_than(op, type, op_left, op_right);
}
/*!
* \brief Operator callback for determining if one operand is greater than or equal to another
*/
static int evaluate_greater_than_or_equal(struct operator *op, enum aco_option_type type, void *op_left, struct expression_token *op_right)
{
return !evaluate_less_than(op, type, op_left, op_right);
}
/*!
* \brief Operator callback for determining logical NOT
*/
static int evaluate_not(struct operator *op, enum aco_option_type type, void *operand)
{
switch (type) {
case OPT_BOOL_T:
case OPT_BOOLFLAG_T:
case OPT_INT_T:
case OPT_UINT_T:
return !(*(int *)operand);
default:
ast_log(LOG_WARNING, "Cannot evaluate: invalid operand type for operator '%s'\n", op->symbol);
}
return -1;
}
/*!
* \brief Operator callback for determining logical AND
*/
static int evaluate_and(struct operator *op, enum aco_option_type type, void *op_left, struct expression_token *op_right)
{
switch (type) {
case OPT_BOOL_T:
case OPT_BOOLFLAG_T:
case OPT_INT_T:
case OPT_UINT_T:
return (*(int *)op_left && op_right->result);
default:
ast_log(LOG_WARNING, "Cannot evaluate: invalid operand type for operator '%s'\n", op->symbol);
}
return -1;
}
/*!
* \brief Operator callback for determining logical OR
*/
static int evaluate_or(struct operator *op, enum aco_option_type type, void *op_left, struct expression_token *op_right)
{
switch (type) {
case OPT_BOOL_T:
case OPT_BOOLFLAG_T:
case OPT_INT_T:
case OPT_UINT_T:
return (*(int *)op_left || op_right->result);
default:
ast_log(LOG_WARNING, "Cannot evaluate: invalid operand type for operator '%s'\n", op->symbol);
}
return -1;
}
/*!
* \brief Operator callback for regex 'like'
*/
static int evaluate_like(struct operator *op, enum aco_option_type type, void *op_left, struct expression_token *op_right)
{
switch (type) {
case OPT_CHAR_ARRAY_T:
case OPT_STRINGFIELD_T:
/* In our case, we operate on pj_str_t */
{
int result;
regex_t regexbuf;
char buf[pj_strlen(op_left) + 1];
ast_copy_pj_str(buf, op_left, pj_strlen(op_left));
if (regcomp(&regexbuf, op_right->field, REG_EXTENDED | REG_NOSUB)) {
ast_log(LOG_WARNING, "Failed to compile '%s' into a regular expression\n", op_right->field);
return -1;
}
result = (regexec(&regexbuf, buf, 0, NULL, 0) == 0);
regfree(&regexbuf);
return result;
}
default:
ast_log(LOG_WARNING, "Cannot evaluate: invalid operand type for operator '%s'\n", op->symbol);
}
return -1;
}
/*!
* \brief Operator token for a left parenthesis.
*
* While this is used by the shunting-yard algorithm implementation,
* it should never appear in the resulting RPN queue of expression tokens
*/
static struct operator left_paren = {
.symbol = "(",
.precedence = 15
};
/*!
* \brief Our allowed operations
*/
static struct operator allowed_operators[] = {
{ .symbol = "=", .precedence = 7, .operands = 2, .evaluate = evaluate_equal, },
{ .symbol = "==", .precedence = 7, .operands = 2, .evaluate = evaluate_equal, },
{ .symbol = "!=", .precedence = 7, .operands = 2, .evaluate = evaluate_not_equal, },
{ .symbol = "<", .precedence = 6, .operands = 2, .evaluate = evaluate_less_than, },
{ .symbol = ">", .precedence = 6, .operands = 2, .evaluate = evaluate_greater_than, },
{ .symbol = "<=", .precedence = 6, .operands = 2, .evaluate = evaluate_less_than_or_equal, },
{ .symbol = ">=", .precedence = 6, .operands = 2, .evaluate = evaluate_greater_than_or_equal, },
{ .symbol = "!", .precedence = 2, .operands = 1, .right_to_left = 1, .evaluate_unary = evaluate_not, },
{ .symbol = "&&", .precedence = 11, .operands = 2, .evaluate = evaluate_and, },
{ .symbol = "||", .precedence = 12, .operands = 2, .evaluate = evaluate_or, },
{ .symbol = "like", .precedence = 7, .operands = 2, .evaluate = evaluate_like, },
{ .symbol = "and", .precedence = 11, .operands = 2, .evaluate = evaluate_and, },
{ .symbol = "or", .precedence = 11, .operands = 2, .evaluate = evaluate_or, },
{ .symbol = "not", .precedence = 2, .operands = 1, .right_to_left = 1, .evaluate_unary = evaluate_not, },
};
/*! \brief Callback to retrieve the entry index number */
static void *entry_get_number(struct pjsip_history_entry *entry)
{
return &entry->number;
}
/*! \brief Callback to retrieve the entry's timestamp */
static void *entry_get_timestamp(struct pjsip_history_entry *entry)
{
return &entry->timestamp;
}
/*! \brief Callback to retrieve the entry's destination address */
static void *entry_get_addr(struct pjsip_history_entry *entry)
{
if (entry->transmitted) {
return &entry->dst;
} else {
return &entry->src;
}
}
/*! \brief Callback to retrieve the entry's SIP request method type */
static void *entry_get_sip_msg_request_method(struct pjsip_history_entry *entry)
{
if (entry->msg->type != PJSIP_REQUEST_MSG) {
return NULL;
}
return &entry->msg->line.req.method.name;
}
/*! \brief Callback to retrieve the entry's SIP Call-ID header */
static void *entry_get_sip_msg_call_id(struct pjsip_history_entry *entry)
{
pjsip_cid_hdr *cid_hdr;
cid_hdr = PJSIP_MSG_CID_HDR(entry->msg);
return &cid_hdr->id;
}
/*! \brief The fields we allow */
static struct allowed_field allowed_fields[] = {
{ .symbol = "number", .return_type = OPT_INT_T, .get_field = entry_get_number, },
/* We co-op the NOOP type here for timeval */
{ .symbol = "timestamp", .return_type = OPT_NOOP_T, .get_field = entry_get_timestamp, },
{ .symbol = "addr", .return_type = OPT_SOCKADDR_T, .get_field = entry_get_addr, },
{ .symbol = "sip.msg.request.method", .return_type = OPT_CHAR_ARRAY_T, .get_field = entry_get_sip_msg_request_method, },
{ .symbol = "sip.msg.call-id", .return_type = OPT_CHAR_ARRAY_T, .get_field = entry_get_sip_msg_call_id, },
};
/*! \brief Free an expression token and all others it references */
static struct expression_token *expression_token_free(struct expression_token *token)
{
struct expression_token *it_token;
it_token = token;
while (it_token) {
struct expression_token *prev = it_token;
it_token = it_token->next;
ast_free(prev);
}
return NULL;
}
/*!
* \brief Allocate an expression token
*
* \param token_type The type of token in the expression
* \param value The value/operator/result to pack into the token
*
* \retval NULL on failure
* \retval expression_token on success
*/
static struct expression_token *expression_token_alloc(enum expression_token_type token_type, void *value)
{
struct expression_token *token;
switch (token_type) {
case TOKEN_TYPE_RESULT:
case TOKEN_TYPE_OPERATOR:
token = ast_calloc(1, sizeof(*token));
break;
case TOKEN_TYPE_FIELD:
token = ast_calloc(1, sizeof(*token) + strlen((const char *)value) + 1);
break;
default:
ast_assert(0);
return NULL;
}
if (!token) {
return NULL;
}
token->token_type = token_type;
switch (token_type) {
case TOKEN_TYPE_RESULT:
token->result = *(int *)value;
break;
case TOKEN_TYPE_OPERATOR:
token->op = value;
break;
case TOKEN_TYPE_FIELD:
strcpy(token->field, value); /* safe */
break;
default:
ast_assert(0);
}
return token;
}
/*! \brief Determine if the expression token matches a field in \c allowed_fields */
static struct allowed_field *get_allowed_field(struct expression_token *token)
{
int i;
ast_assert(token->token_type == TOKEN_TYPE_FIELD);
for (i = 0; i < ARRAY_LEN(allowed_fields); i++) {
if (strcasecmp(allowed_fields[i].symbol, token->field)) {
continue;
}
return &allowed_fields[i];
}
return NULL;
}
/*! \brief AO2 destructor for \c pjsip_history_entry */
static void pjsip_history_entry_dtor(void *obj)
{
struct pjsip_history_entry *entry = obj;
if (entry->pool) {
/* This mimics the behavior of pj_pool_safe_release
* which was introduced in pjproject 2.6.
*/
pj_pool_t *temp_pool = entry->pool;
entry->pool = NULL;
pj_pool_release(temp_pool);
}
}
/*!
* \brief Create a \c pjsip_history_entry AO2 object
*
* \param msg The PJSIP message that this history entry wraps
*
* \retval An AO2 \c pjsip_history_entry object on success
* \retval NULL on failure
*/
static struct pjsip_history_entry *pjsip_history_entry_alloc(pjsip_msg *msg)
{
struct pjsip_history_entry *entry;
entry = ao2_alloc_options(sizeof(*entry), pjsip_history_entry_dtor, AO2_ALLOC_OPT_LOCK_NOLOCK);
if (!entry) {
return NULL;
}
entry->number = ast_atomic_fetchadd_int(&packet_number, 1);
entry->timestamp = ast_tvnow();
entry->timestamp.tv_usec = 0;
entry->pool = pj_pool_create(&cachingpool.factory, NULL, PJSIP_POOL_RDATA_LEN,
PJSIP_POOL_RDATA_INC, NULL);
if (!entry->pool) {
ao2_ref(entry, -1);
return NULL;
}
entry->msg = pjsip_msg_clone(entry->pool, msg);
if (!entry->msg) {
ao2_ref(entry, -1);
return NULL;
}
return entry;
}
/*! \brief Format single line history entry */
static void sprint_list_entry(struct pjsip_history_entry *entry, char *line, int len)
{
char addr[64], secs[AST_TIME_T_LEN];
if (entry->transmitted) {
pj_sockaddr_print(&entry->dst, addr, sizeof(addr), 3);
} else {
pj_sockaddr_print(&entry->src, addr, sizeof(addr), 3);
}
ast_time_t_to_string(entry->timestamp.tv_sec, secs, sizeof(secs));
if (entry->msg->type == PJSIP_REQUEST_MSG) {
char uri[128];
pjsip_uri_print(PJSIP_URI_IN_REQ_URI, entry->msg->line.req.uri, uri, sizeof(uri));
snprintf(line, len, "%-5.5d %-10.10s %-5.5s %-24.24s %.*s %s SIP/2.0",
entry->number,
secs,
entry->transmitted ? "* ==>" : "* <==",
addr,
(int)pj_strlen(&entry->msg->line.req.method.name),
pj_strbuf(&entry->msg->line.req.method.name),
uri);
} else {
snprintf(line, len, "%-5.5d %-10.10s %-5.5s %-24.24s SIP/2.0 %u %.*s",
entry->number,
secs,
entry->transmitted ? "* ==>" : "* <==",
addr,
entry->msg->line.status.code,
(int)pj_strlen(&entry->msg->line.status.reason),
pj_strbuf(&entry->msg->line.status.reason));
}
}
/*! \brief PJSIP callback when a SIP message is transmitted */
static pj_status_t history_on_tx_msg(pjsip_tx_data *tdata)
{
struct pjsip_history_entry *entry;
if (!enabled) {
return PJ_SUCCESS;
}
entry = pjsip_history_entry_alloc(tdata->msg);
if (!entry) {
return PJ_SUCCESS;
}
entry->transmitted = 1;
pj_sockaddr_cp(&entry->src, &tdata->tp_info.transport->local_addr);
pj_sockaddr_cp(&entry->dst, &tdata->tp_info.dst_addr);
ast_mutex_lock(&history_lock);
if (AST_VECTOR_APPEND(&vector_history, entry)) {
ao2_ref(entry, -1);
entry = NULL;
}
ast_mutex_unlock(&history_lock);
if (log_level != -1 && entry) {
char line[256];
sprint_list_entry(entry, line, sizeof(line));
ast_log_dynamic_level(log_level, "%s\n", line);
}
return PJ_SUCCESS;
}
/*! \brief PJSIP callback when a SIP message is received */
static pj_bool_t history_on_rx_msg(pjsip_rx_data *rdata)
{
struct pjsip_history_entry *entry;
if (!enabled) {
return PJ_FALSE;
}
if (!rdata->msg_info.msg) {
return PJ_FALSE;
}
entry = pjsip_history_entry_alloc(rdata->msg_info.msg);
if (!entry) {
return PJ_FALSE;
}
if (rdata->tp_info.transport->addr_len) {
pj_sockaddr_cp(&entry->dst, &rdata->tp_info.transport->local_addr);
}
if (rdata->pkt_info.src_addr_len) {
pj_sockaddr_cp(&entry->src, &rdata->pkt_info.src_addr);
}
ast_mutex_lock(&history_lock);
if (AST_VECTOR_APPEND(&vector_history, entry)) {
ao2_ref(entry, -1);
entry = NULL;
}
ast_mutex_unlock(&history_lock);
if (log_level != -1 && entry) {
char line[256];
sprint_list_entry(entry, line, sizeof(line));
ast_log_dynamic_level(log_level, "%s\n", line);
}
return PJ_FALSE;
}
/*! \brief Vector callback that releases the reference for the entry in a history vector */
static void clear_history_entry_cb(struct pjsip_history_entry *entry)
{
ao2_ref(entry, -1);
}
/*!
* \brief Remove all entries from \c vector_history
*
* This must be called from a registered PJSIP thread
*/
static int clear_history_entries(void *obj)
{
ast_mutex_lock(&history_lock);
AST_VECTOR_RESET(&vector_history, clear_history_entry_cb);
packet_number = 0;
ast_mutex_unlock(&history_lock);
return 0;
}
/*!
* \brief Build a reverse polish notation expression queue
*
* This function is an implementation of the Shunting-Yard Algorithm. It takes
* a user provided infix-notation expression and converts it into a reverse
* polish notation expression, which is a queue of tokens that can be easily
* parsed.
*
* \param a The CLI arguments provided by the User, containing the infix expression
*
* \retval NULL error
* \retval expression_token A 'queue' of expression tokens in RPN
*/
static struct expression_token *build_expression_queue(struct ast_cli_args *a)
{
AST_VECTOR(, struct operator *) operators; /* A stack of saved operators */
struct expression_token *output = NULL; /* The output queue */
struct expression_token *head = NULL; /* Pointer to the head of /c output */
int i;
#define APPEND_TO_OUTPUT(output, token) do { \
if ((output)) { \
(output)->next = (token); \
(output) = (token); \
} else { \
(output) = (token); \
head = (output); \
} \
} while (0)
if (AST_VECTOR_INIT(&operators, 8)) {
return NULL;
}
for (i = 4; i < a->argc; i++) {
struct expression_token *out_token;
char *token = ast_strdupa(a->argv[i]);
int j;
/* Strip off and append any left parentheses */
if (token[0] == '(') {
AST_VECTOR_APPEND(&operators, &left_paren);
if (!token[1]) {
continue;
}
token = &token[1];
}
/* Handle the case where the token is an operator */
for (j = 0; j < ARRAY_LEN(allowed_operators); j++) {
int k;
if (strcasecmp(token, allowed_operators[j].symbol)) {
continue;
}
for (k = AST_VECTOR_SIZE(&operators) - 1; k >= 0; k--) {
struct operator *top = AST_VECTOR_GET(&operators, k);
/* Remove and push queued up operators, if they are of
* less precedence than this operator
*/
if ((allowed_operators[j].right_to_left && allowed_operators[j].precedence >= top->precedence)
|| (!allowed_operators[j].right_to_left && allowed_operators[j].precedence > top->precedence)) {
if (!(out_token = expression_token_alloc(TOKEN_TYPE_OPERATOR, top))) {
goto error;
}
APPEND_TO_OUTPUT(output, out_token);
AST_VECTOR_REMOVE(&operators, k, 1);
}
}
AST_VECTOR_APPEND(&operators, &allowed_operators[j]);
token = NULL;
break;
}
/* Token was an operator; continue to next token */
if (!token) {
continue;
}
/* Handle a right parentheses either by itself or as part of the token.
* If part of the token, push the token onto the output queue first
*/
if (token[0] == ')' || token[strlen(token) - 1] == ')') {
if (token[strlen(token) - 1] == ')') {
token[strlen(token) - 1] = '\0';
if (!(out_token = expression_token_alloc(TOKEN_TYPE_FIELD, token))) {
goto error;
}
APPEND_TO_OUTPUT(output, out_token);
token = NULL;
}
for (j = AST_VECTOR_SIZE(&operators) - 1; j >= 0; j--) {
struct operator *top = AST_VECTOR_GET(&operators, j);
AST_VECTOR_REMOVE(&operators, j, 1);
if (top == &left_paren) {
break;
}
if (!(out_token = expression_token_alloc(TOKEN_TYPE_OPERATOR, top))) {
goto error;
}
APPEND_TO_OUTPUT(output, out_token);
}
}
/* Just a plain token, push to the output queue */
if (token) {
if (!(out_token = expression_token_alloc(TOKEN_TYPE_FIELD, token))) {
goto error;
}
APPEND_TO_OUTPUT(output, out_token);
}
}
/* Remove any non-applied operators that remain, applying them
* to the output queue
*/
for (i = AST_VECTOR_SIZE(&operators) - 1; i >= 0; i--) {
struct operator *top = AST_VECTOR_GET(&operators, i);
struct expression_token *out_token;
AST_VECTOR_REMOVE(&operators, i, 1);
if (top == &left_paren) {
ast_log(LOG_WARNING, "Unbalanced '(' parentheses in expression!\n");
continue;
}
if (!(out_token = expression_token_alloc(TOKEN_TYPE_OPERATOR, top))) {
goto error;
}
APPEND_TO_OUTPUT(output, out_token);
}
AST_VECTOR_FREE(&operators);
return head;
error:
AST_VECTOR_FREE(&operators);
expression_token_free(output);
return NULL;
}
/*!
* \brief Evaluate a single entry in this history using a RPN expression
*
* \param entry The entry in the history to evaluate
* \param queue The RPN expression
*
* \retval 0 The expression evaluated FALSE on \c entry
* \retval 1 The expression evaluated TRUE on \c entry
* \retval -1 The expression errored
*/
static int evaluate_history_entry(struct pjsip_history_entry *entry, struct expression_token *queue)
{
AST_VECTOR(, struct expression_token *) stack; /* Our stack of results and operands */
struct expression_token *it_queue;
struct expression_token *final;
int result;
int i;
if (AST_VECTOR_INIT(&stack, 16)) {
return -1;
}
for (it_queue = queue; it_queue; it_queue = it_queue->next) {
struct expression_token *op_one;
struct expression_token *op_two = NULL;
struct expression_token *result;
int res = 0;
/* If this is not an operator, push it to the stack */
if (!it_queue->op) {
if (AST_VECTOR_APPEND(&stack, it_queue)) {
goto error;
}
continue;
}
if (AST_VECTOR_SIZE(&stack) < it_queue->op->operands) {
ast_log(LOG_WARNING, "Unable to evaluate expression operator '%s': not enough operands\n",
it_queue->op->symbol);
goto error;
}
if (it_queue->op->operands == 1) {
/* Unary operators currently consist only of 'not', which can only act
* upon an evaluated condition result.
*/
ast_assert(it_queue->op->evaluate_unary != NULL);
op_one = AST_VECTOR_REMOVE(&stack, AST_VECTOR_SIZE(&stack) - 1, 1);
if (op_one->token_type != TOKEN_TYPE_RESULT) {
ast_log(LOG_WARNING, "Unable to evaluate '%s': operand is not the result of an operation\n",
it_queue->op->symbol);
goto error;
}
res = it_queue->op->evaluate_unary(it_queue->op, OPT_INT_T, &op_one->result) == 0 ? 0 : 1;
} else if (it_queue->op->operands == 2) {
struct allowed_field *field;
enum aco_option_type type;
void *value;
ast_assert(it_queue->op->evaluate != NULL);
op_one = AST_VECTOR_REMOVE(&stack, AST_VECTOR_SIZE(&stack) - 1, 1);
op_two = AST_VECTOR_REMOVE(&stack, AST_VECTOR_SIZE(&stack) - 1, 1);
/* If operand two is a field, then it must be a field we recognize. */
if (op_two->token_type == TOKEN_TYPE_FIELD) {
field = get_allowed_field(op_two);
if (!field) {
ast_log(LOG_WARNING, "Unknown or unrecognized field: %s\n", op_two->field);
goto error;
}
type = field->return_type;
value = field->get_field(entry);
} else if (op_two->token_type == TOKEN_TYPE_RESULT) {
type = OPT_INT_T;
value = &op_two->result;
} else {
ast_log(LOG_WARNING, "Attempting to evaluate an operator: %s\n", op_two->op->symbol);
goto error;
}
if (value) {
res = it_queue->op->evaluate(it_queue->op, type, value, op_one) == 0 ? 0 : 1;
} else {
res = 0;
}
} else {
ast_log(LOG_WARNING, "Operator '%s' has an invalid number of operands\n", it_queue->op->symbol);
ast_assert(0);
goto error;
}
/* Results are temporary; clean used ones up */
if (op_one && op_one->token_type == TOKEN_TYPE_RESULT) {
ast_free(op_one);
}
if (op_two && op_two->token_type == TOKEN_TYPE_RESULT) {
ast_free(op_two);
}
/* Push the result onto the stack */
result = expression_token_alloc(TOKEN_TYPE_RESULT, &res);
if (!result) {
goto error;
}
if (AST_VECTOR_APPEND(&stack, result)) {
expression_token_free(result);
goto error;
}
}
/*
* When the evaluation is complete, we must have:
* - A single result remaining on the stack
* - An actual result
*/
if (AST_VECTOR_SIZE(&stack) != 1) {
ast_log(LOG_WARNING, "Expression was unbalanced: %zu results remained after evaluation\n",
AST_VECTOR_SIZE(&stack));
goto error;
}
final = AST_VECTOR_GET(&stack, 0);
if (final->token_type != TOKEN_TYPE_RESULT) {
ast_log(LOG_WARNING, "Expression did not create a usable result\n");
goto error;
}
result = final->result;
ast_free(final);
AST_VECTOR_FREE(&stack);
return result;
error:
/* Clean out any remaining result expression tokens */
for (i = 0; i < AST_VECTOR_SIZE(&stack); i++) {
struct expression_token *failed_token = AST_VECTOR_GET(&stack, i);
if (failed_token->token_type == TOKEN_TYPE_RESULT) {
ast_free(failed_token);
}
}
AST_VECTOR_FREE(&stack);
return -1;
}
/*!
* \brief Create a filtered history based on a user provided expression
*
* \param a The CLI arguments containing the expression
*
* \retval NULL on error
* \retval A vector containing the filtered history on success
*/
static struct vector_history_t *filter_history(struct ast_cli_args *a)
{
struct vector_history_t *output;
struct expression_token *queue;
int i;
output = ast_malloc(sizeof(*output));
if (!output) {
return NULL;
}
if (AST_VECTOR_INIT(output, HISTORY_INITIAL_SIZE / 2)) {
ast_free(output);
return NULL;
}
queue = build_expression_queue(a);
if (!queue) {
AST_VECTOR_PTR_FREE(output);
return NULL;
}
ast_mutex_lock(&history_lock);
for (i = 0; i < AST_VECTOR_SIZE(&vector_history); i++) {
struct pjsip_history_entry *entry = AST_VECTOR_GET(&vector_history, i);
int res;
res = evaluate_history_entry(entry, queue);
if (res == -1) {
/* Error in expression evaluation; bail */
ast_mutex_unlock(&history_lock);
AST_VECTOR_RESET(output, clear_history_entry_cb);
AST_VECTOR_FREE(output);
ast_free(output);
expression_token_free(queue);
return NULL;
} else if (!res) {
continue;
} else {
ao2_bump(entry);
if (AST_VECTOR_APPEND(output, entry)) {
ao2_cleanup(entry);
}
}
}
ast_mutex_unlock(&history_lock);
expression_token_free(queue);
return output;
}
/*! \brief Print a detailed view of a single entry in the history to the CLI */
static void display_single_entry(struct ast_cli_args *a, struct pjsip_history_entry *entry)
{
char addr[64], secs[AST_TIME_T_LEN];
char *buf;
buf = ast_calloc(1, PJSIP_MAX_PKT_LEN * sizeof(char));
if (!buf) {
return;
}
if (pjsip_msg_print(entry->msg, buf, PJSIP_MAX_PKT_LEN) == -1) {
ast_log(LOG_WARNING, "Unable to print SIP message %d: packet too large!\n", entry->number);
ast_free(buf);
return;
}
if (entry->transmitted) {
pj_sockaddr_print(&entry->dst, addr, sizeof(addr), 3);
} else {
pj_sockaddr_print(&entry->src, addr, sizeof(addr), 3);
}
ast_time_t_to_string(entry->timestamp.tv_sec, secs, sizeof(secs));
ast_cli(a->fd, "<--- History Entry %d %s %s at %-10.10s --->\n",
entry->number,
entry->transmitted ? "Sent to" : "Received from",
addr,
secs);
ast_cli(a->fd, "%s\n", buf);
ast_free(buf);
}
/*! \brief Print a list of the entries to the CLI */
static void display_entry_list(struct ast_cli_args *a, struct vector_history_t *vec)
{
int i;
ast_cli(a->fd, "%-5.5s %-10.10s %-30.30s %-35.35s\n",
"No.",
"Timestamp",
"(Dir) Address",
"SIP Message");
ast_cli(a->fd, "===== ========== ============================== ===================================\n");
for (i = 0; i < AST_VECTOR_SIZE(vec); i++) {
struct pjsip_history_entry *entry;
char line[256];
entry = AST_VECTOR_GET(vec, i);
sprint_list_entry(entry, line, sizeof(line));
ast_cli(a->fd, "%s\n", line);
}
}
/*! \brief Cleanup routine for a history vector, serviced on a registered PJSIP thread */
static int safe_vector_cleanup(void *obj)
{
struct vector_history_t *vec = obj;
AST_VECTOR_RESET(vec, clear_history_entry_cb);
AST_VECTOR_FREE(vec);
ast_free(vec);
return 0;
}
static char *pjsip_show_history(struct ast_cli_entry *e, int cmd, struct ast_cli_args *a)
{
struct vector_history_t *vec = &vector_history;
struct pjsip_history_entry *entry = NULL;
if (cmd == CLI_INIT) {
e->command = "pjsip show history";
e->usage =
"Usage: pjsip show history [entry <num>|where [...]]\n"
" Displays the currently collected history or an\n"
" entry within the history.\n\n"
" * Running the command with no options will display\n"
" the entire history.\n"
" * Providing 'entry <num>' will display the full\n"
" detail of a particular entry in this history.\n"
" * Providing 'where ...' will allow for filtering\n"
" the history. The history can be filtered using\n"
" any of the following fields:\n"
" - number: The history entry number\n"
" - timestamp: The time associated with the history entry\n"
" - addr: The source/destination address of the SIP message\n"
" - sip.msg.request.method: The request method type\n"
" - sip.msg.call-id: The Call-ID header of the SIP message\n"
"\n"
" When filtering, standard Boolean operators can be used,\n"
" as well as 'like' for regexs.\n"
"\n"
" Example:\n"
" 'pjsip show history where number > 5 and (addr = \"192.168.0.3:5060\" or addr = \"192.168.0.5:5060\")'\n";
return NULL;
} else if (cmd == CLI_GENERATE) {
return NULL;
}
if (a->argc > 3) {
if (!strcasecmp(a->argv[3], "entry") && a->argc == 5) {
int num;
if (sscanf(a->argv[4], "%30d", &num) != 1) {
ast_cli(a->fd, "'%s' is not a valid entry number\n", a->argv[4]);
return CLI_FAILURE;
}
/* Get the entry at the provided position */
ast_mutex_lock(&history_lock);
if (num >= AST_VECTOR_SIZE(&vector_history) || num < 0) {
ast_cli(a->fd, "Entry '%d' does not exist\n", num);
ast_mutex_unlock(&history_lock);
return CLI_FAILURE;
}
entry = ao2_bump(AST_VECTOR_GET(&vector_history, num));
ast_mutex_unlock(&history_lock);
} else if (!strcasecmp(a->argv[3], "where")) {
vec = filter_history(a);
if (!vec) {
return CLI_FAILURE;
}
} else {
return CLI_SHOWUSAGE;
}
}
if (AST_VECTOR_SIZE(vec) == 1) {
if (vec == &vector_history) {
ast_mutex_lock(&history_lock);
}
entry = ao2_bump(AST_VECTOR_GET(vec, 0));
if (vec == &vector_history) {
ast_mutex_unlock(&history_lock);
}
}
if (entry) {
display_single_entry(a, entry);
} else {
if (vec == &vector_history) {
ast_mutex_lock(&history_lock);
}
display_entry_list(a, vec);
if (vec == &vector_history) {
ast_mutex_unlock(&history_lock);
}
}
if (vec != &vector_history) {
ast_sip_push_task(NULL, safe_vector_cleanup, vec);
}
ao2_cleanup(entry);
return CLI_SUCCESS;
}
static char *pjsip_set_history(struct ast_cli_entry *e, int cmd, struct ast_cli_args *a)
{
const char *what;
if (cmd == CLI_INIT) {
e->command = "pjsip set history {on|off|clear}";
e->usage =
"Usage: pjsip set history {on|off|clear}\n"
" Enables/disables/clears the PJSIP history.\n\n"
" Enabling the history will start recording transmitted/received\n"
" packets. Disabling the history will stop recording, but keep\n"
" the already received packets. Clearing the history will wipe\n"
" the received packets from memory.\n\n"
" As the PJSIP history is maintained in memory, and includes\n"
" all received/transmitted requests and responses, it should\n"
" only be enabled for debugging purposes, and cleared when done.\n";
return NULL;
} else if (cmd == CLI_GENERATE) {
return NULL;
}
what = a->argv[e->args - 1]; /* Guaranteed to exist */
if (a->argc == e->args) {
if (!strcasecmp(what, "on")) {
enabled = 1;
ast_cli(a->fd, "PJSIP History enabled\n");
return CLI_SUCCESS;
} else if (!strcasecmp(what, "off")) {
enabled = 0;
ast_cli(a->fd, "PJSIP History disabled\n");
return CLI_SUCCESS;
} else if (!strcasecmp(what, "clear")) {
ast_sip_push_task(NULL, clear_history_entries, NULL);
ast_cli(a->fd, "PJSIP History cleared\n");
return CLI_SUCCESS;
}
}
return CLI_SHOWUSAGE;
}
static pjsip_module logging_module = {
.name = { "History Module", 14 },
.priority = 0,
.on_rx_request = history_on_rx_msg,
.on_rx_response = history_on_rx_msg,
.on_tx_request = history_on_tx_msg,
.on_tx_response = history_on_tx_msg,
};
static struct ast_cli_entry cli_pjsip[] = {
AST_CLI_DEFINE(pjsip_set_history, "Enable/Disable PJSIP History"),
AST_CLI_DEFINE(pjsip_show_history, "Display PJSIP History"),
};
static int load_module(void)
{
log_level = ast_logger_register_level("PJSIP_HISTORY");
if (log_level < 0) {
ast_log(LOG_WARNING, "Unable to register history log level\n");
}
ast_pjproject_caching_pool_init(&cachingpool, &pj_pool_factory_default_policy, 0);
AST_VECTOR_INIT(&vector_history, HISTORY_INITIAL_SIZE);
ast_sip_register_service(&logging_module);
ast_cli_register_multiple(cli_pjsip, ARRAY_LEN(cli_pjsip));
return AST_MODULE_LOAD_SUCCESS;
}
static int unload_module(void)
{
ast_cli_unregister_multiple(cli_pjsip, ARRAY_LEN(cli_pjsip));
ast_sip_unregister_service(&logging_module);
ast_sip_push_task_wait_servant(NULL, clear_history_entries, NULL);
AST_VECTOR_FREE(&vector_history);
ast_pjproject_caching_pool_destroy(&cachingpool);
if (log_level != -1) {
ast_logger_unregister_level("PJSIP_HISTORY");
}
return 0;
}
AST_MODULE_INFO(ASTERISK_GPL_KEY, AST_MODFLAG_LOAD_ORDER, "PJSIP History",
.support_level = AST_MODULE_SUPPORT_EXTENDED,
.load = load_module,
.unload = unload_module,
.load_pri = AST_MODPRI_APP_DEPEND,
.requires = "res_pjsip",
);