/*
* Apache example module. Provide demonstrations of how modules do things.
*
*/
#include "mod_ptt.h"
extern int numboards;
extern boardheader_t *bcache;
/*--------------------------------------------------------------------------*/
/* */
/* Data declarations. */
/* */
/* Here are the static cells and structure declarations private to our */
/* module. */
/* */
/*--------------------------------------------------------------------------*/
/*
* Sample configuration record. Used for both per-directory and per-server
* configuration data.
*
* It's perfectly reasonable to have two different structures for the two
* different environments. The same command handlers will be called for
* both, though, so the handlers need to be able to tell them apart. One
* possibility is for both structures to start with an int which is zero for
* one and 1 for the other.
*
* Note that while the per-directory and per-server configuration records are
* available to most of the module handlers, they should be treated as
* READ-ONLY by all except the command and merge handlers. Sometimes handlers
* are handed a record that applies to the current location by implication or
* inheritance, and modifying it will change the rules for other locations.
*/
typedef struct excfg {
int cmode; /* Environment to which record applies (directory,
* server, or combination).
*/
#define CONFIG_MODE_SERVER 1
#define CONFIG_MODE_DIRECTORY 2
#define CONFIG_MODE_COMBO 3 /* Shouldn't ever happen. */
int local; /* Boolean: "Example" directive declared here? */
int congenital; /* Boolean: did we inherit an "Example"? */
char *trace; /* Pointer to trace string. */
char *loc; /* Location to which this record applies. */
} excfg;
/*
* Let's set up a module-local static cell to point to the accreting callback
* trace. As each API callback is made to us, we'll tack on the particulars
* to whatever we've already recorded. To avoid massive memory bloat as
* directories are walked again and again, we record the routine/environment
* the first time (non-request context only), and ignore subsequent calls for
* the same routine/environment.
*/
static const char *trace = NULL;
static table *static_calls_made = NULL;
/*
* To avoid leaking memory from pools other than the per-request one, we
* allocate a module-private pool, and then use a sub-pool of that which gets
* freed each time we modify the trace. That way previous layers of trace
* data don't get lost.
*/
static pool *ptt_pool = NULL;
static pool *ptt_subpool = NULL;
/*
* Declare ourselves so the configuration routines can find and know us.
* We'll fill it in at the end of the module.
*/
module MODULE_VAR_EXPORT ptt_module;
/*--------------------------------------------------------------------------*/
/* */
/* The following pseudo-prototype declarations illustrate the parameters */
/* passed to command handlers for the different types of directive */
/* syntax. If an argument was specified in the directive definition */
/* (look for "command_rec" below), it's available to the command handler */
/* via the (void *) info field in the cmd_parms argument passed to the */
/* handler (cmd->info for the examples below). */
/* */
/*--------------------------------------------------------------------------*/
/*
* Command handler for a NO_ARGS directive.
*
* static const char *handle_NO_ARGS(cmd_parms *cmd, void *mconfig);
*/
/*
* Command handler for a RAW_ARGS directive. The "args" argument is the text
* of the commandline following the directive itself.
*
* static const char *handle_RAW_ARGS(cmd_parms *cmd, void *mconfig,
* const char *args);
*/
/*
* Command handler for a FLAG directive. The single parameter is passed in
* "bool", which is either zero or not for Off or On respectively.
*
* static const char *handle_FLAG(cmd_parms *cmd, void *mconfig, int bool);
*/
/*
* Command handler for a TAKE1 directive. The single parameter is passed in
* "word1".
*
* static const char *handle_TAKE1(cmd_parms *cmd, void *mconfig,
* char *word1);
*/
/*
* Command handler for a TAKE2 directive. TAKE2 commands must always have
* exactly two arguments.
*
* static const char *handle_TAKE2(cmd_parms *cmd, void *mconfig,
* char *word1, char *word2);
*/
/*
* Command handler for a TAKE3 directive. Like TAKE2, these must have exactly
* three arguments, or the parser complains and doesn't bother calling us.
*
* static const char *handle_TAKE3(cmd_parms *cmd, void *mconfig,
* char *word1, char *word2, char *word3);
*/
/*
* Command handler for a TAKE12 directive. These can take either one or two
* arguments.
* - word2 is a NULL pointer if no second argument was specified.
*
* static const char *handle_TAKE12(cmd_parms *cmd, void *mconfig,
* char *word1, char *word2);
*/
/*
* Command handler for a TAKE123 directive. A TAKE123 directive can be given,
* as might be expected, one, two, or three arguments.
* - word2 is a NULL pointer if no second argument was specified.
* - word3 is a NULL pointer if no third argument was specified.
*
* static const char *handle_TAKE123(cmd_parms *cmd, void *mconfig,
* char *word1, char *word2, char *word3);
*/
/*
* Command handler for a TAKE13 directive. Either one or three arguments are
* permitted - no two-parameters-only syntax is allowed.
* - word2 and word3 are NULL pointers if only one argument was specified.
*
* static const char *handle_TAKE13(cmd_parms *cmd, void *mconfig,
* char *word1, char *word2, char *word3);
*/
/*
* Command handler for a TAKE23 directive. At least two and as many as three
* arguments must be specified.
* - word3 is a NULL pointer if no third argument was specified.
*
* static const char *handle_TAKE23(cmd_parms *cmd, void *mconfig,
* char *word1, char *word2, char *word3);
*/
/*
* Command handler for a ITERATE directive.
* - Handler is called once for each of n arguments given to the directive.
* - word1 points to each argument in turn.
*
* static const char *handle_ITERATE(cmd_parms *cmd, void *mconfig,
* char *word1);
*/
/*
* Command handler for a ITERATE2 directive.
* - Handler is called once for each of the second and subsequent arguments
* given to the directive.
* - word1 is the same for each call for a particular directive instance (the
* first argument).
* - word2 points to each of the second and subsequent arguments in turn.
*
* static const char *handle_ITERATE2(cmd_parms *cmd, void *mconfig,
* char *word1, char *word2);
*/
/*--------------------------------------------------------------------------*/
/* */
/* These routines are strictly internal to this module, and support its */
/* operation. They are not referenced by any external portion of the */
/* server. */
/* */
/*--------------------------------------------------------------------------*/
/*
* Locate our directory configuration record for the current request.
*/
static excfg *our_dconfig(request_rec *r)
{
return (excfg *) ap_get_module_config(r->per_dir_config, &ptt_module);
}
#if 0
/*
* Locate our server configuration record for the specified server.
*/
static excfg *our_sconfig(server_rec *s)
{
return (excfg *) ap_get_module_config(s->module_config, &ptt_module);
}
/*
* Likewise for our configuration record for the specified request.
*/
static excfg *our_rconfig(request_rec *r)
{
return (excfg *) ap_get_module_config(r->request_config, &ptt_module);
}
#endif
/*
* This routine sets up some module-wide cells if they haven't been already.
*/
static void setup_module_cells()
{
/*
* If we haven't already allocated our module-private pool, do so now.
*/
if (ptt_pool == NULL) {
ptt_pool = ap_make_sub_pool(NULL);
};
/*
* Likewise for the table of routine/environment pairs we visit outside of
* request context.
*/
if (static_calls_made == NULL) {
static_calls_made = ap_make_table(ptt_pool, 16);
};
}
/*
* This routine is used to add a trace of a callback to the list. We're
* passed the server record (if available), the request record (if available),
* a pointer to our private configuration record (if available) for the
* environment to which the callback is supposed to apply, and some text. We
* turn this into a textual representation and add it to the tail of the list.
* The list can be displayed by the example_handler() routine.
*
* If the call occurs within a request context (i.e., we're passed a request
* record), we put the trace into the request pool and attach it to the
* request via the notes mechanism. Otherwise, the trace gets added
* to the static (non-request-specific) list.
*
* Note that the r->notes table is only for storing strings; if you need to
* maintain per-request data of any other type, you need to use another
* mechanism.
*/
#define TRACE_NOTE "ptt-trace"
static void trace_add(server_rec *s, request_rec *r, excfg *mconfig,
const char *note)
{
const char *sofar;
char *addon;
char *where;
pool *p;
const char *trace_copy;
/*
* Make sure our pools and tables are set up - we need 'em.
*/
setup_module_cells();
/*
* Now, if we're in request-context, we use the request pool.
*/
if (r != NULL) {
p = r->pool;
if ((trace_copy = ap_table_get(r->notes, TRACE_NOTE)) == NULL) {
trace_copy = "";
}
}
else {
/*
* We're not in request context, so the trace gets attached to our
* module-wide pool. We do the create/destroy every time we're called
* in non-request context; this avoids leaking memory in some of
* the subsequent calls that allocate memory only once (such as the
* key formation below).
*
* Make a new sub-pool and copy any existing trace to it. Point the
* trace cell at the copied value.
*/
p = ap_make_sub_pool(ptt_pool);
if (trace != NULL) {
trace = ap_pstrdup(p, trace);
}
/*
* Now, if we have a sub-pool from before, nuke it and replace with
* the one we just allocated.
*/
if (ptt_subpool != NULL) {
ap_destroy_pool(ptt_subpool);
}
ptt_subpool = p;
trace_copy = trace;
}
/*
* If we weren't passed a configuration record, we can't figure out to
* what location this call applies. This only happens for co-routines
* that don't operate in a particular directory or server context. If we
* got a valid record, extract the location (directory or server) to which
* it applies.
*/
where = (mconfig != NULL) ? mconfig->loc : "nowhere";
where = (where != NULL) ? where : "";
/*
* Now, if we're not in request context, see if we've been called with
* this particular combination before. The table is allocated in the
* module's private pool, which doesn't get destroyed.
*/
if (r == NULL) {
char *key;
key = ap_pstrcat(p, note, ":", where, NULL);
if (ap_table_get(static_calls_made, key) != NULL) {
/*
* Been here, done this.
*/
return;
}
else {
/*
* First time for this combination of routine and environment -
* log it so we don't do it again.
*/
ap_table_set(static_calls_made, key, "been here");
}
}
addon = ap_pstrcat(p, " <LI>\n", " <DL>\n", " <DT><SAMP>",
note, "</SAMP>\n", " </DT>\n", " <DD><SAMP>[",
where, "]</SAMP>\n", " </DD>\n", " </DL>\n",
" </LI>\n", NULL);
sofar = (trace_copy == NULL) ? "" : trace_copy;
trace_copy = ap_pstrcat(p, sofar, addon, NULL);
if (r != NULL) {
ap_table_set(r->notes, TRACE_NOTE, trace_copy);
}
else {
trace = trace_copy;
}
/*
* You *could* change the following if you wanted to see the calling
* sequence reported in the server's error_log, but beware - almost all of
* these co-routines are called for every single request, and the impact
* on the size (and readability) of the error_log is considerable.
*/
#define EXAMPLE_LOG_EACH 0
#if EXAMPLE_LOG_EACH
if (s != NULL) {
ap_log_error(APLOG_MARK, APLOG_DEBUG, s, "mod_ptt: %s", note);
}
#endif
}
/*--------------------------------------------------------------------------*/
/* We prototyped the various syntax for command handlers (routines that */
/* are called when the configuration parser detects a directive declared */
/* by our module) earlier. Now we actually declare a "real" routine that */
/* will be invoked by the parser when our "real" directive is */
/* encountered. */
/* */
/* If a command handler encounters a problem processing the directive, it */
/* signals this fact by returning a non-NULL pointer to a string */
/* describing the problem. */
/* */
/* The magic return value DECLINE_CMD is used to deal with directives */
/* that might be declared by multiple modules. If the command handler */
/* returns NULL, the directive was processed; if it returns DECLINE_CMD, */
/* the next module (if any) that declares the directive is given a chance */
/* at it. If it returns any other value, it's treated as the text of an */
/* error message. */
/*--------------------------------------------------------------------------*/
/*
* Command handler for the NO_ARGS "Example" directive. All we do is mark the
* call in the trace log, and flag the applicability of the directive to the
* current location in that location's configuration record.
*/
static const char *cmd_ptt(cmd_parms *cmd, void *mconfig)
{
excfg *cfg = (excfg *) mconfig;
/*
* "Example Wuz Here"
*/
cfg->local = 1;
trace_add(cmd->server, NULL, cfg, "cmd_ptt()");
return NULL;
}
/*--------------------------------------------------------------------------*/
/* */
/* Now we declare our content handlers, which are invoked when the server */
/* encounters a document which our module is supposed to have a chance to */
/* see. (See mod_mime's SetHandler and AddHandler directives, and the */
/* mod_info and mod_status examples, for more details.) */
/* */
/* Since content handlers are dumping data directly into the connexion */
/* (using the r*() routines, such as rputs() and rprintf()) without */
/* intervention by other parts of the server, they need to make */
/* sure any accumulated HTTP headers are sent first. This is done by */
/* calling send_http_header(). Otherwise, no header will be sent at all, */
/* and the output sent to the client will actually be HTTP-uncompliant. */
/*--------------------------------------------------------------------------*/
/*
* Sample content handler. All this does is display the call list that has
* been built up so far.
*
* The return value instructs the caller concerning what happened and what to
* do next:
* OK ("we did our thing")
* DECLINED ("this isn't something with which we want to get involved")
* HTTP_mumble ("an error status should be reported")
*/
static int ptt_handler(request_rec *r)
{
int i;
excfg *dcfg;
dcfg = our_dconfig(r);
trace_add(r->server, r, dcfg, "ptt_handler()");
/*
* We're about to start sending content, so we need to force the HTTP
* headers to be sent at this point. Otherwise, no headers will be sent
* at all. We can set any we like first, of course. **NOTE** Here's
* where you set the "Content-type" header, and you do so by putting it in
* r->content_type, *not* r->headers_out("Content-type"). If you don't
* set it, it will be filled in with the server's default type (typically
* "text/plain"). You *must* also ensure that r->content_type is lower
* case.
*
* We also need to start a timer so the server can know if the connexion
* is broken.
*/
r->content_type = "text/html";
ap_soft_timeout("send ptt call trace", r);
ap_send_http_header(r);
#ifdef CHARSET_EBCDIC
/* Server-generated response, converted */
ap_bsetflag(r->connection->client, B_EBCDIC2ASCII, r->ebcdic.conv_out = 1);
#endif
/*
* If we're only supposed to send header information (HEAD request), we're
* already there.
*/
if (r->header_only) {
ap_kill_timeout(r);
return OK;
}
/*
* Now send our actual output. Since we tagged this as being
* "text/html", we need to embed any HTML.
*/
ap_rputs(" ptt3 <P>\n", r);
ap_rprintf(r, " Apache HTTP Server version: \"%s\"\n",
ap_get_server_version());
ap_rprintf(r,"r->filename : %s <br>",r->filename);
ap_rprintf(r,"r->request_time : %s <br>",ctime(&r->request_time));
ap_rprintf(r,"r->method : %s <br>",r->method);
ap_rprintf(r,"r->method_number : %d <br>",r->method_number);
ap_rprintf(r,"r->path_info : %s <br>",r->path_info);
ap_rprintf(r,"r->args : %s <br>",r->args);
ap_rprintf(r,"r->unparsed_uri : %s <br>",r->unparsed_uri);
ap_rprintf(r,"r->handler : %s <br>",r->handler);
ap_rprintf(r,"r->content_type : %s <br>",r->content_type);
ap_rprintf(r, " Server built: \"%s\"\n", ap_get_server_built());
for(i = 0; i++ < numboards; i++)
ap_rprintf(r,"%s %s<br>",bcache[i].brdname,bcache[i].title);
/*
* We're all done, so cancel the timeout we set. Since this is probably
* the end of the request we *could* assume this would be done during
* post-processing - but it's possible that another handler might be
* called and inherit our outstanding timer. Not good; to each its own.
*/
ap_kill_timeout(r);
/*
* We did what we wanted to do, so tell the rest of the server we
* succeeded.
*/
return OK;
}
/*--------------------------------------------------------------------------*/
/* */
/* Now let's declare routines for each of the callback phase in order. */
/* (That's the order in which they're listed in the callback list, *not */
/* the order in which the server calls them! See the command_rec */
/* declaration near the bottom of this file.) Note that these may be */
/* called for situations that don't relate primarily to our function - in */
/* other words, the fixup handler shouldn't assume that the request has */
/* to do with "example" stuff. */
/* */
/* With the exception of the content handler, all of our routines will be */
/* called for each request, unless an earlier handler from another module */
/* aborted the sequence. */
/* */
/* Handlers that are declared as "int" can return the following: */
/* */
/* OK Handler accepted the request and did its thing with it. */
/* DECLINED Handler took no action. */
/* HTTP_mumble Handler looked at request and found it wanting. */
/* */
/* What the server does after calling a module handler depends upon the */
/* handler's return value. In all cases, if the handler returns */
/* DECLINED, the server will continue to the next module with an handler */
/* for the current phase. However, if the handler return a non-OK, */
/* non-DECLINED status, the server aborts the request right there. If */
/* the handler returns OK, the server's next action is phase-specific; */
/* see the individual handler comments below for details. */
/* */
/*--------------------------------------------------------------------------*/
/*
* This function is called during server initialisation. Any information
* that needs to be recorded must be in static cells, since there's no
* configuration record.
*
* There is no return value.
*/
/*
* All our module-initialiser does is add its trace to the log.
*/
static void ptt_init(server_rec *s, pool *p)
{
char *note;
char *sname = s->server_hostname;
/*
* Set up any module cells that ought to be initialised.
*/
setup_module_cells();
/*
* The arbitrary text we add to our trace entry indicates for which server
* we're being called.
*/
sname = (sname != NULL) ? sname : "";
note = ap_pstrcat(p, "ptt_init(", sname, ")", NULL);
trace_add(s, NULL, NULL, note);
}
/*
* This function is called during server initialisation when an heavy-weight
* process (such as a child) is being initialised. As with the
* module-initialisation function, any information that needs to be recorded
* must be in static cells, since there's no configuration record.
*
* There is no return value.
*/
/*
* All our process-initialiser does is add its trace to the log.
*/
static void ptt_child_init(server_rec *s, pool *p)
{
char *note;
char *sname = s->server_hostname;
resolve_utmp();
resolve_boards();
resolve_garbage();
resolve_fcache();
/*
* Set up any module cells that ought to be initialised.
*/
setup_module_cells();
/*
* The arbitrary text we add to our trace entry indicates for which server
* we're being called.
*/
sname = (sname != NULL) ? sname : "";
note = ap_pstrcat(p, "ptt_child_init(", sname, ")", NULL);
trace_add(s, NULL, NULL, note);
}
/*
* This function is called when an heavy-weight process (such as a child) is
* being run down or destroyed. As with the child-initialisation function,
* any information that needs to be recorded must be in static cells, since
* there's no configuration record.
*
* There is no return value.
*/
/*
* All our process-death routine does is add its trace to the log.
*/
static void ptt_child_exit(server_rec *s, pool *p)
{
char *note;
char *sname = s->server_hostname;
/*
* The arbitrary text we add to our trace entry indicates for which server
* we're being called.
*/
sname = (sname != NULL) ? sname : "";
note = ap_pstrcat(p, "ptt_child_exit(", sname, ")", NULL);
trace_add(s, NULL, NULL, note);
}
/*
* This function gets called to create a per-directory configuration
* record. This will be called for the "default" server environment, and for
* each directory for which the parser finds any of our directives applicable.
* If a directory doesn't have any of our directives involved (i.e., they
* aren't in the .htaccess file, or a <Location>, <Directory>, or related
* block), this routine will *not* be called - the configuration for the
* closest ancestor is used.
*
* The return value is a pointer to the created module-specific
* structure.
*/
static void *ptt_create_dir_config(pool *p, char *dirspec)
{
excfg *cfg;
char *dname = dirspec;
/*
* Allocate the space for our record from the pool supplied.
*/
cfg = (excfg *) ap_pcalloc(p, sizeof(excfg));
/*
* Now fill in the defaults. If there are any `parent' configuration
* records, they'll get merged as part of a separate callback.
*/
cfg->local = 0;
cfg->congenital = 0;
cfg->cmode = CONFIG_MODE_DIRECTORY;
/*
* Finally, add our trace to the callback list.
*/
dname = (dname != NULL) ? dname : "";
cfg->loc = ap_pstrcat(p, "DIR(", dname, ")", NULL);
trace_add(NULL, NULL, cfg, "ptt_create_dir_config()");
return (void *) cfg;
}
/*
* This function gets called to merge two per-directory configuration
* records. This is typically done to cope with things like .htaccess files
* or <Location> directives for directories that are beneath one for which a
* configuration record was already created. The routine has the
* responsibility of creating a new record and merging the contents of the
* other two into it appropriately. If the module doesn't declare a merge
* routine, the record for the closest ancestor location (that has one) is
* used exclusively.
*
* The routine MUST NOT modify any of its arguments!
*
* The return value is a pointer to the created module-specific structure
* containing the merged values.
*/
static void *ptt_merge_dir_config(pool *p, void *parent_conf,
void *newloc_conf)
{
excfg *merged_config = (excfg *) ap_pcalloc(p, sizeof(excfg));
excfg *pconf = (excfg *) parent_conf;
excfg *nconf = (excfg *) newloc_conf;
char *note;
/*
* Some things get copied directly from the more-specific record, rather
* than getting merged.
*/
merged_config->local = nconf->local;
merged_config->loc = ap_pstrdup(p, nconf->loc);
/*
* Others, like the setting of the `congenital' flag, get ORed in. The
* setting of that particular flag, for instance, is TRUE if it was ever
* true anywhere in the upstream configuration.
*/
merged_config->congenital = (pconf->congenital | pconf->local);
/*
* If we're merging records for two different types of environment (server
* and directory), mark the new record appropriately. Otherwise, inherit
* the current value.
*/
merged_config->cmode =
(pconf->cmode == nconf->cmode) ? pconf->cmode : CONFIG_MODE_COMBO;
/*
* Now just record our being called in the trace list. Include the
* locations we were asked to merge.
*/
note = ap_pstrcat(p, "ptt_merge_dir_config(\"", pconf->loc, "\",\"",
nconf->loc, "\")", NULL);
trace_add(NULL, NULL, merged_config, note);
return (void *) merged_config;
}
/*
* This function gets called to create a per-server configuration
* record. It will always be called for the "default" server.
*
* The return value is a pointer to the created module-specific
* structure.
*/
static void *ptt_create_server_config(pool *p, server_rec *s)
{
excfg *cfg;
char *sname = s->server_hostname;
/*
* As with the ptt_create_dir_config() reoutine, we allocate and fill
* in an empty record.
*/
cfg = (excfg *) ap_pcalloc(p, sizeof(excfg));
cfg->local = 0;
cfg->congenital = 0;
cfg->cmode = CONFIG_MODE_SERVER;
/*
* Note that we were called in the trace list.
*/
sname = (sname != NULL) ? sname : "";
cfg->loc = ap_pstrcat(p, "SVR(", sname, ")", NULL);
trace_add(s, NULL, cfg, "ptt_create_server_config()");
return (void *) cfg;
}
/*
* This function gets called to merge two per-server configuration
* records. This is typically done to cope with things like virtual hosts and
* the default server configuration The routine has the responsibility of
* creating a new record and merging the contents of the other two into it
* appropriately. If the module doesn't declare a merge routine, the more
* specific existing record is used exclusively.
*
* The routine MUST NOT modify any of its arguments!
*
* The return value is a pointer to the created module-specific structure
* containing the merged values.
*/
static void *ptt_merge_server_config(pool *p, void *server1_conf,
void *server2_conf)
{
excfg *merged_config = (excfg *) ap_pcalloc(p, sizeof(excfg));
excfg *s1conf = (excfg *) server1_conf;
excfg *s2conf = (excfg *) server2_conf;
char *note;
/*
* Our inheritance rules are our own, and part of our module's semantics.
* Basically, just note whence we came.
*/
merged_config->cmode =
(s1conf->cmode == s2conf->cmode) ? s1conf->cmode : CONFIG_MODE_COMBO;
merged_config->local = s2conf->local;
merged_config->congenital = (s1conf->congenital | s1conf->local);
merged_config->loc = ap_pstrdup(p, s2conf->loc);
/*
* Trace our call, including what we were asked to merge.
*/
note = ap_pstrcat(p, "ptt_merge_server_config(\"", s1conf->loc, "\",\"",
s2conf->loc, "\")", NULL);
trace_add(NULL, NULL, merged_config, note);
return (void *) merged_config;
}
/*
* This routine is called after the request has been read but before any other
* phases have been processed. This allows us to make decisions based upon
* the input header fields.
*
* The return value is OK, DECLINED, or HTTP_mumble. If we return OK, no
* further modules are called for this phase.
*/
static int ptt_post_read_request(request_rec *r)
{
excfg *cfg;
cfg = our_dconfig(r);
/*
* We don't actually *do* anything here, except note the fact that we were
* called.
*/
trace_add(r->server, r, cfg, "ptt_post_read_request()");
return DECLINED;
}
/*
* This routine gives our module an opportunity to translate the URI into an
* actual filename. If we don't do anything special, the server's default
* rules (Alias directives and the like) will continue to be followed.
*
* The return value is OK, DECLINED, or HTTP_mumble. If we return OK, no
* further modules are called for this phase.
*/
static int ptt_translate_handler(request_rec *r)
{
excfg *cfg;
cfg = our_dconfig(r);
/*
* We don't actually *do* anything here, except note the fact that we were
* called.
*/
trace_add(r->server, r, cfg, "ptt_translate_handler()");
return DECLINED;
}
/*
* This routine is called to check the authentication information sent with
* the request (such as looking up the user in a database and verifying that
* the [encrypted] password sent matches the one in the database).
*
* The return value is OK, DECLINED, or some HTTP_mumble error (typically
* HTTP_UNAUTHORIZED). If we return OK, no other modules are given a chance
* at the request during this phase.
*/
static int ptt_check_user_id(request_rec *r)
{
excfg *cfg;
cfg = our_dconfig(r);
/*
* Don't do anything except log the call.
*/
trace_add(r->server, r, cfg, "ptt_check_user_id()");
return DECLINED;
}
/*
* This routine is called to check to see if the resource being requested
* requires authorisation.
*
* The return value is OK, DECLINED, or HTTP_mumble. If we return OK, no
* other modules are called during this phase.
*
* If *all* modules return DECLINED, the request is aborted with a server
* error.
*/
static int ptt_auth_checker(request_rec *r)
{
excfg *cfg;
cfg = our_dconfig(r);
/*
* Log the call and return OK, or access will be denied (even though we
* didn't actually do anything).
*/
trace_add(r->server, r, cfg, "ptt_auth_checker()");
return DECLINED;
}
/*
* This routine is called to check for any module-specific restrictions placed
* upon the requested resource. (See the mod_access module for an example.)
*
* The return value is OK, DECLINED, or HTTP_mumble. All modules with an
* handler for this phase are called regardless of whether their predecessors
* return OK or DECLINED. The first one to return any other status, however,
* will abort the sequence (and the request) as usual.
*/
static int ptt_access_checker(request_rec *r)
{
excfg *cfg;
cfg = our_dconfig(r);
trace_add(r->server, r, cfg, "ptt_access_checker()");
return DECLINED;
}
/*
* This routine is called to determine and/or set the various document type
* information bits, like Content-type (via r->content_type), language, et
* cetera.
*
* The return value is OK, DECLINED, or HTTP_mumble. If we return OK, no
* further modules are given a chance at the request for this phase.
*/
static int ptt_type_checker(request_rec *r)
{
excfg *cfg;
cfg = our_dconfig(r);
/*
* Log the call, but don't do anything else - and report truthfully that
* we didn't do anything.
*/
trace_add(r->server, r, cfg, "ptt_type_checker()");
return DECLINED;
}
/*
* This routine is called to perform any module-specific fixing of header
* fields, et cetera. It is invoked just before any content-handler.
*
* The return value is OK, DECLINED, or HTTP_mumble. If we return OK, the
* server will still call any remaining modules with an handler for this
* phase.
*/
static int ptt_fixer_upper(request_rec *r)
{
excfg *cfg;
cfg = our_dconfig(r);
/*
* Log the call and exit.
*/
trace_add(r->server, r, cfg, "ptt_fixer_upper()");
return OK;
}
/*
* This routine is called to perform any module-specific logging activities
* over and above the normal server things.
*
* The return value is OK, DECLINED, or HTTP_mumble. If we return OK, any
* remaining modules with an handler for this phase will still be called.
*/
static int ptt_logger(request_rec *r)
{
excfg *cfg;
cfg = our_dconfig(r);
trace_add(r->server, r, cfg, "ptt_logger()");
return DECLINED;
}
/*
* This routine is called to give the module a chance to look at the request
* headers and take any appropriate specific actions early in the processing
* sequence.
*
* The return value is OK, DECLINED, or HTTP_mumble. If we return OK, any
* remaining modules with handlers for this phase will still be called.
*/
static int ptt_header_parser(request_rec *r)
{
excfg *cfg;
cfg = our_dconfig(r);
trace_add(r->server, r, cfg, "ptt_header_parser()");
return DECLINED;
}
/*--------------------------------------------------------------------------*/
/* */
/* All of the routines have been declared now. Here's the list of */
/* directives specific to our module, and information about where they */
/* may appear and how the command parser should pass them to us for */
/* processing. Note that care must be taken to ensure that there are NO */
/* collisions of directive names between modules. */
/* */
/*--------------------------------------------------------------------------*/
/*
* List of directives specific to our module.
*/
static const command_rec ptt_cmds[] =
{
{
"ptt", /* directive name */
cmd_ptt, /* config action routine */
NULL, /* argument to include in call */
OR_OPTIONS, /* where available */
NO_ARGS, /* arguments */
"Example directive - no arguments"
/* directive description */
},
{NULL}
};
/*--------------------------------------------------------------------------*/
/* */
/* Now the list of content handlers available from this module. */
/* */
/*--------------------------------------------------------------------------*/
/*
* List of content handlers our module supplies. Each handler is defined by
* two parts: a name by which it can be referenced (such as by
* {Add,Set}Handler), and the actual routine name. The list is terminated by
* a NULL block, since it can be of variable length.
*
* Note that content-handlers are invoked on a most-specific to least-specific
* basis; that is, a handler that is declared for "text/plain" will be
* invoked before one that was declared for "text / *". Note also that
* if a content-handler returns anything except DECLINED, no other
* content-handlers will be called.
*/
static const handler_rec ptt_handlers[] =
{
{"ptt-handler", ptt_handler},
{NULL}
};
/*--------------------------------------------------------------------------*/
/* */
/* Finally, the list of callback routines and data structures that */
/* provide the hooks into our module from the other parts of the server. */
/* */
/*--------------------------------------------------------------------------*/
/*
* Module definition for configuration. If a particular callback is not
* needed, replace its routine name below with the word NULL.
*
* The number in brackets indicates the order in which the routine is called
* during request processing. Note that not all routines are necessarily
* called (such as if a resource doesn't have access restrictions).
*/
module MODULE_VAR_EXPORT ptt_module =
{
STANDARD_MODULE_STUFF,
ptt_init, /* module initializer */
ptt_create_dir_config, /* per-directory config creator */
ptt_merge_dir_config, /* dir config merger */
ptt_create_server_config, /* server config creator */
ptt_merge_server_config, /* server config merger */
ptt_cmds, /* command table */
ptt_handlers, /* [9] list of handlers */
ptt_translate_handler, /* [2] filename-to-URI translation */
ptt_check_user_id, /* [5] check/validate user_id */
ptt_auth_checker, /* [6] check user_id is valid *here* */
ptt_access_checker, /* [4] check access by host address */
ptt_type_checker, /* [7] MIME type checker/setter */
ptt_fixer_upper, /* [8] fixups */
ptt_logger, /* [10] logger */
#if MODULE_MAGIC_NUMBER >= 19970103
ptt_header_parser, /* [3] header parser */
#endif
#if MODULE_MAGIC_NUMBER >= 19970719
ptt_child_init, /* process initializer */
#endif
#if MODULE_MAGIC_NUMBER >= 19970728
ptt_child_exit, /* process exit/cleanup */
#endif
#if MODULE_MAGIC_NUMBER >= 19970902
ptt_post_read_request /* [1] post read_request handling */
#endif
};