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/* ====================================================================
* The Apache Software License, Version 1.1
*
* Copyright (c) 2000-2003 The Apache Software Foundation. All rights
* reserved.
*
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* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
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* if any, must include the following acknowledgment:
* "This product includes software developed by the
* Apache Software Foundation (http://www.apache.org/)."
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* ====================================================================
*
* This software consists of voluntary contributions made by many
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*/
#ifndef AP_FILTER_H
#define AP_FILTER_H
#include "apr.h"
#include "apr_buckets.h"
#include "httpd.h"
#if APR_HAVE_STDARG_H
#include <stdarg.h>
#endif
#ifdef __cplusplus
extern "C" {
#endif
/**
* @file util_filter.h
* @brief Apache filter library
*/
/** Returned by the bottom-most filter if no data was written.
* @see ap_pass_brigade(). */
#define AP_NOBODY_WROTE -1
/** Returned by the bottom-most filter if no data was read.
* @see ap_get_brigade(). */
#define AP_NOBODY_READ -2
/** Returned when?? @bug find out when! */
#define AP_FILTER_ERROR -3
/**
* input filtering modes
*/
typedef enum {
/** The filter should return at most readbytes data. */
AP_MODE_READBYTES,
/** The filter should return at most one line of CRLF data.
* (If a potential line is too long or no CRLF is found, the
* filter may return partial data).
*/
AP_MODE_GETLINE,
/** The filter should implicitly eat any CRLF pairs that it sees. */
AP_MODE_EATCRLF,
/** The filter read should be treated as speculative and any returned
* data should be stored for later retrieval in another mode. */
AP_MODE_SPECULATIVE,
/** The filter read should be exhaustive and read until it can not
* read any more.
* Use this mode with extreme caution.
*/
AP_MODE_EXHAUSTIVE,
/** The filter should initialize the connection if needed,
* NNTP or FTP over SSL for example.
*/
AP_MODE_INIT
} ap_input_mode_t;
/**
* @defgroup filter FILTER CHAIN
*
* Filters operate using a "chaining" mechanism. The filters are chained
* together into a sequence. When output is generated, it is passed through
* each of the filters on this chain, until it reaches the end (or "bottom")
* and is placed onto the network.
*
* The top of the chain, the code generating the output, is typically called
* a "content generator." The content generator's output is fed into the
* filter chain using the standard Apache output mechanisms: ap_rputs(),
* ap_rprintf(), ap_rwrite(), etc.
*
* Each filter is defined by a callback. This callback takes the output from
* the previous filter (or the content generator if there is no previous
* filter), operates on it, and passes the result to the next filter in the
* chain. This pass-off is performed using the ap_fc_* functions, such as
* ap_fc_puts(), ap_fc_printf(), ap_fc_write(), etc.
*
* When content generation is complete, the system will pass an "end of
* stream" marker into the filter chain. The filters will use this to flush
* out any internal state and to detect incomplete syntax (for example, an
* unterminated SSI directive).
*/
/* forward declare the filter type */
typedef struct ap_filter_t ap_filter_t;
/**
* @name Filter callbacks
*
* This function type is used for filter callbacks. It will be passed a
* pointer to "this" filter, and a "bucket" containing the content to be
* filtered.
*
* In filter->ctx, the callback will find its context. This context is
* provided here, so that a filter may be installed multiple times, each
* receiving its own per-install context pointer.
*
* Callbacks are associated with a filter definition, which is specified
* by name. See ap_register_input_filter() and ap_register_output_filter()
* for setting the association between a name for a filter and its
* associated callback (and other information).
*
* If the initialization function argument passed to the registration
* functions is non-NULL, it will be called iff the filter is in the input
* or output filter chains and before any data is generated to allow the
* filter to prepare for processing.
*
* The *bucket structure (and all those referenced by ->next and ->prev)
* should be considered "const". The filter is allowed to modify the
* next/prev to insert/remove/replace elements in the bucket list, but
* the types and values of the individual buckets should not be altered.
*
* For the input and output filters, the return value of a filter should be
* an APR status value. For the init function, the return value should
* be an HTTP error code or OK if it was successful.
*
* @ingroup filter
* @{
*/
typedef apr_status_t (*ap_out_filter_func)(ap_filter_t *f,
apr_bucket_brigade *b);
typedef apr_status_t (*ap_in_filter_func)(ap_filter_t *f,
apr_bucket_brigade *b,
ap_input_mode_t mode,
apr_read_type_e block,
apr_off_t readbytes);
typedef int (*ap_init_filter_func)(ap_filter_t *f);
typedef union ap_filter_func {
ap_out_filter_func out_func;
ap_in_filter_func in_func;
} ap_filter_func;
/** @} */
/**
* Filters have different types/classifications. These are used to group
* and sort the filters to properly sequence their operation.
*
* The types have a particular sort order, which allows us to insert them
* into the filter chain in a determistic order. Within a particular grouping,
* the ordering is equivalent to the order of calls to ap_add_*_filter().
*/
typedef enum {
/** These filters are used to alter the content that is passed through
* them. Examples are SSI or PHP. */
AP_FTYPE_RESOURCE = 10,
/** These filters are used to alter the content as a whole, but after all
* AP_FTYPE_RESOURCE filters are executed. These filters should not
* change the content-type. An example is deflate. */
AP_FTYPE_CONTENT_SET = 20,
/** These filters are used to handle the protocol between server and
* client. Examples are HTTP and POP. */
AP_FTYPE_PROTOCOL = 30,
/** These filters implement transport encodings (e.g., chunking). */
AP_FTYPE_TRANSCODE = 40,
/** These filters will alter the content, but in ways that are
* more strongly associated with the connection. Examples are
* splitting an HTTP connection into multiple requests and
* buffering HTTP responses across multiple requests.
*
* It is important to note that these types of filters are not
* allowed in a sub-request. A sub-request's output can certainly
* be filtered by ::AP_FTYPE_RESOURCE filters, but all of the "final
* processing" is determined by the main request. */
AP_FTYPE_CONNECTION = 50,
/** These filters don't alter the content. They are responsible for
* sending/receiving data to/from the client. */
AP_FTYPE_NETWORK = 60
} ap_filter_type;
/**
* This is the request-time context structure for an installed filter (in
* the output filter chain). It provides the callback to use for filtering,
* the request this filter is associated with (which is important when
* an output chain also includes sub-request filters), the context for this
* installed filter, and the filter ordering/chaining fields.
*
* Filter callbacks are free to use ->ctx as they please, to store context
* during the filter process. Generally, this is superior over associating
* the state directly with the request. A callback should not change any of
* the other fields.
*/
typedef struct ap_filter_rec_t ap_filter_rec_t;
/**
* This structure is used for recording information about the
* registered filters. It associates a name with the filter's callback
* and filter type.
*
* At the moment, these are simply linked in a chain, so a ->next pointer
* is available.
*/
struct ap_filter_rec_t {
/** The registered name for this filter */
const char *name;
/** The function to call when this filter is invoked. */
ap_filter_func filter_func;
/** The function to call before the handlers are invoked. */
ap_init_filter_func filter_init_func;
/** The type of filter, either AP_FTYPE_CONTENT or AP_FTYPE_CONNECTION.
* An AP_FTYPE_CONTENT filter modifies the data based on information
* found in the content. An AP_FTYPE_CONNECTION filter modifies the
* data based on the type of connection.
*/
ap_filter_type ftype;
/** The next filter_rec in the list */
struct ap_filter_rec_t *next;
};
/**
* The representation of a filter chain. Each request has a list
* of these structures which are called in turn to filter the data. Sub
* requests get an exact copy of the main requests filter chain.
*/
struct ap_filter_t {
/** The internal representation of this filter. This includes
* the filter's name, type, and the actual function pointer.
*/
ap_filter_rec_t *frec;
/** A place to store any data associated with the current filter */
void *ctx;
/** The next filter in the chain */
ap_filter_t *next;
/** The request_rec associated with the current filter. If a sub-request
* adds filters, then the sub-request is the request associated with the
* filter.
*/
request_rec *r;
/** The conn_rec associated with the current filter. This is analogous
* to the request_rec, except that it is used for input filtering.
*/
conn_rec *c;
};
/**
* Get the current bucket brigade from the next filter on the filter
* stack. The filter returns an apr_status_t value. If the bottom-most
* filter doesn't read from the network, then ::AP_NOBODY_READ is returned.
* The bucket brigade will be empty when there is nothing left to get.
* @param filter The next filter in the chain
* @param bucket The current bucket brigade
* @param mode The way in which the data should be read
* @param block How the operations should be performed
* ::APR_BLOCK_READ, ::APR_NONBLOCK_READ
* @param readbytes How many bytes to read from the next filter.
*/
AP_DECLARE(apr_status_t) ap_get_brigade(ap_filter_t *filter,
apr_bucket_brigade *bucket,
ap_input_mode_t mode,
apr_read_type_e block,
apr_off_t readbytes);
/**
* Pass the current bucket brigade down to the next filter on the filter
* stack. The filter returns an apr_status_t value. If the bottom-most
* filter doesn't write to the network, then ::AP_NOBODY_WROTE is returned.
* @param filter The next filter in the chain
* @param bucket The current bucket brigade
*/
AP_DECLARE(apr_status_t) ap_pass_brigade(ap_filter_t *filter,
apr_bucket_brigade *bucket);
/**
* This function is used to register an input filter with the system.
* After this registration is performed, then a filter may be added
* into the filter chain by using ap_add_input_filter() and simply
* specifying the name.
*
* @param name The name to attach to the filter function
* @param filter_func The filter function to name
* @param ftype The type of filter function, either ::AP_FTYPE_CONTENT or ::
* AP_FTYPE_CONNECTION
* @see add_input_filter()
*/
AP_DECLARE(ap_filter_rec_t *) ap_register_input_filter(const char *name,
ap_in_filter_func filter_func,
ap_init_filter_func filter_init,
ap_filter_type ftype);
/**
* This function is used to register an output filter with the system.
* After this registration is performed, then a filter may be added
* into the filter chain by using ap_add_output_filter() and simply
* specifying the name.
*
* @param name The name to attach to the filter function
* @param filter_func The filter function to name
* @param ftype The type of filter function, either ::AP_FTYPE_CONTENT or
* ::AP_FTYPE_CONNECTION
* @see ap_add_output_filter()
*/
AP_DECLARE(ap_filter_rec_t *) ap_register_output_filter(const char *name,
ap_out_filter_func filter_func,
ap_init_filter_func filter_init,
ap_filter_type ftype);
/**
* Adds a named filter into the filter chain on the specified request record.
* The filter will be installed with the specified context pointer.
*
* Filters added in this way will always be placed at the end of the filters
* that have the same type (thus, the filters have the same order as the
* calls to ap_add_filter). If the current filter chain contains filters
* from another request, then this filter will be added before those other
* filters.
*
* To re-iterate that last comment. This function is building a FIFO
* list of filters. Take note of that when adding your filter to the chain.
*
* @param name The name of the filter to add
* @param ctx Context data to provide to the filter
* @param r The request to add this filter for (or NULL if it isn't associated with a request)
* @param c The connection to add the fillter for
*/
AP_DECLARE(ap_filter_t *) ap_add_input_filter(const char *name, void *ctx,
request_rec *r, conn_rec *c);
/**
* Variant of ap_add_input_filter() that accepts a registered filter handle
* (as returned by ap_register_input_filter()) rather than a filter name
*
* @param f The filter handle to add
* @param ctx Context data to provide to the filter
* @param r The request to add this filter for (or NULL if it isn't associated with a request)
* @param c The connection to add the fillter for
*/
AP_DECLARE(ap_filter_t *) ap_add_input_filter_handle(ap_filter_rec_t *f,
void *ctx,
request_rec *r,
conn_rec *c);
/**
* Returns the filter handle for use with ap_add_input_filter_handle.
*
* @param name The filter name to look up
*/
AP_DECLARE(ap_filter_rec_t *) ap_get_input_filter_handle(const char *name);
/**
* Add a filter to the current request. Filters are added in a FIFO manner.
* The first filter added will be the first filter called.
* @param name The name of the filter to add
* @param ctx Context data to set in the filter
* @param r The request to add this filter for (or NULL if it isn't associated with a request)
* @param c The connection to add this filter for
*/
AP_DECLARE(ap_filter_t *) ap_add_output_filter(const char *name, void *ctx,
request_rec *r, conn_rec *c);
/**
* Variant of ap_add_output_filter() that accepts a registered filter handle
* (as returned by ap_register_output_filter()) rather than a filter name
*
* @param f The filter handle to add
* @param r The request to add this filter for (or NULL if it isn't associated with a request)
* @param c The connection to add the fillter for
*/
AP_DECLARE(ap_filter_t *) ap_add_output_filter_handle(ap_filter_rec_t *f,
void *ctx,
request_rec *r,
conn_rec *c);
/**
* Returns the filter handle for use with ap_add_output_filter_handle.
*
* @param name The filter name to look up
*/
AP_DECLARE(ap_filter_rec_t *) ap_get_output_filter_handle(const char *name);
/**
* Remove an input filter from either the request or connection stack
* it is associated with.
* @param f The filter to remove
*/
AP_DECLARE(void) ap_remove_input_filter(ap_filter_t *f);
/**
* Remove an output filter from either the request or connection stack
* it is associated with.
* @param f The filter to remove
*/
AP_DECLARE(void) ap_remove_output_filter(ap_filter_t *f);
/* The next two filters are for abstraction purposes only. They could be
* done away with, but that would require that we break modules if we ever
* want to change our filter registration method. The basic idea, is that
* all filters have a place to store data, the ctx pointer. These functions
* fill out that pointer with a bucket brigade, and retrieve that data on
* the next call. The nice thing about these functions, is that they
* automatically concatenate the bucket brigades together for you. This means
* that if you have already stored a brigade in the filters ctx pointer, then
* when you add more it will be tacked onto the end of that brigade. When
* you retrieve data, if you pass in a bucket brigade to the get function,
* it will append the current brigade onto the one that you are retrieving.
*/
/**
* prepare a bucket brigade to be setaside. If a different brigade was
* set-aside earlier, then the two brigades are concatenated together.
* @param f The current filter
* @param save_to The brigade that was previously set-aside. Regardless, the
* new bucket brigade is returned in this location.
* @param b The bucket brigade to save aside. This brigade is always empty
* on return
* @param p Ensure that all data in the brigade lives as long as this pool
*/
AP_DECLARE(apr_status_t) ap_save_brigade(ap_filter_t *f,
apr_bucket_brigade **save_to,
apr_bucket_brigade **b, apr_pool_t *p);
/**
* Flush function for apr_brigade_* calls. This calls ap_pass_brigade
* to flush the brigade if the brigade buffer overflows.
* @param bb The brigade to flush
* @param ctx The filter to pass the brigade to
*/
AP_DECLARE_NONSTD(apr_status_t) ap_filter_flush(apr_bucket_brigade *bb,
void *ctx);
/**
* Flush the current brigade down the filter stack.
* @param f The current filter
* @param bb The brigade to flush
*/
AP_DECLARE(apr_status_t) ap_fflush(ap_filter_t *f, apr_bucket_brigade *bb);
/**
* Write a buffer for the current filter, buffering if possible.
* @param f the filter doing the writing
* @param bb The brigade to buffer into
* @param data The data to write
* @param nbyte The number of bytes in the data
*/
#define ap_fwrite(f, bb, data, nbyte) \
apr_brigade_write(bb, ap_filter_flush, f, data, nbyte)
/**
* Write a buffer for the current filter, buffering if possible.
* @param f the filter doing the writing
* @param bb The brigade to buffer into
* @param str The string to write
*/
#define ap_fputs(f, bb, str) \
apr_brigade_puts(bb, ap_filter_flush, f, str)
/**
* Write a character for the current filter, buffering if possible.
* @param f the filter doing the writing
* @param bb The brigade to buffer into
* @param c The character to write
*/
#define ap_fputc(f, bb, c) \
apr_brigade_putc(bb, ap_filter_flush, f, c)
/**
* Write an unspecified number of strings to the current filter
* @param f the filter doing the writing
* @param bb The brigade to buffer into
* @param ... The strings to write
*/
AP_DECLARE_NONSTD(apr_status_t) ap_fputstrs(ap_filter_t *f,
apr_bucket_brigade *bb,
...);
/**
* Output data to the filter in printf format
* @param f the filter doing the writing
* @param bb The brigade to buffer into
* @param fmt The format string
* @param ... The argumets to use to fill out the format string
*/
AP_DECLARE_NONSTD(apr_status_t) ap_fprintf(ap_filter_t *f,
apr_bucket_brigade *bb,
const char *fmt,
...)
__attribute__((format(printf,3,4)));
#ifdef __cplusplus
}
#endif
#endif /* !AP_FILTER_H */
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