mpv/filters/filter.h

470 lines
22 KiB
C

#pragma once
#include <stdbool.h>
#include "frame.h"
struct mpv_global;
struct mp_filter;
// A filter input or output. These always come in pairs: one mp_pin is for
// input, the other is for output. (The separation is mostly for checking
// their API use, and for the connection functions.)
// Effectively, this is a 1-frame queue. The data flow rules have the goal to
// reduce the number of buffered frames and the amount of time they are
// buffered.
// A mp_pin must be connected to be usable. The default state of a mp_pin is
// a manual connection, which means you use the mp_pin_*() functions to
// manually read or write data.
struct mp_pin;
enum mp_pin_dir {
MP_PIN_INVALID = 0, // used as a placeholder value
MP_PIN_IN, // you write data to the pin
MP_PIN_OUT, // you read data from the pin
};
// The established direction for this pin. The direction of a pin is immutable.
// You must use the mp_pin_in_*() and mp_pin_out_*() functions on the correct
// pin type - mismatching it is an API violation.
enum mp_pin_dir mp_pin_get_dir(struct mp_pin *p);
// True if a new frame should be written to the pin.
bool mp_pin_in_needs_data(struct mp_pin *p);
// Write a frame to the pin. If the input was not accepted, false is returned
// (does not normally happen, as long as mp_pin_in_needs_data() returned true).
// The callee owns the reference to the frame data, even on failure.
// Writing a MP_FRAME_NONE has no effect (and returns false).
// If you did not call mp_pin_in_needs_data() before this, it's likely a bug.
bool mp_pin_in_write(struct mp_pin *p, struct mp_frame frame);
// True if a frame is actually available for reading right now, and
// mp_pin_out_read() will return success. If this returns false, the pin is
// flagged for needing data (the filter might either produce output the next
// time it's run, or request new input).
// You should call this only if you can immediately consume the data. The goal
// is to have no redundant buffering in the filter graph, and leaving frames
// buffered in mp_pins goes against this.
bool mp_pin_out_request_data(struct mp_pin *p);
// Same as mp_pin_out_request_data(), but call the filter's process() function
// next time even if there is new data. the intention is that the filter reads
// the data in the next iteration, without checking for the data now.
void mp_pin_out_request_data_next(struct mp_pin *p);
// Same as mp_pin_out_request_data(), but does not attempt to procure new frames
// if the return value is false.
bool mp_pin_out_has_data(struct mp_pin *p);
// Read a frame. Returns MP_FRAME_NONE if currently no frame is available.
// You need to call mp_pin_out_request_data() and wait until the frame is ready
// to be sure this returns a frame. (This call implicitly calls _request if no
// frame is available, but to get proper data flow in filters, you should
// probably follow the preferred conventions.)
// If no frame is returned, a frame is automatically requested via
// mp_pin_out_request_data() (so it might be returned in the future).
// If a frame is returned, no new frame is automatically requested (this is
// usually not wanted, because it could lead to additional buffering).
// This is guaranteed to return a non-NONE frame if mp_pin_out_has_data()
// returned true and no other filter functions were called.
// The caller owns the reference to the returned data.
struct mp_frame mp_pin_out_read(struct mp_pin *p);
// Undo mp_pin_out_read(). This should be only used in special cases. Normally,
// you should make an effort to reduce buffering, which means you signal that
// you need a frame only once you know that you can use it (meaning you'll
// really use it and have no need to "undo" the read). But in special cases,
// especially if the behavior depends on the exact frame data, using this might
// be justified.
// If this is called, the next mp_pin_out_read() call will return the same frame
// again. You must not have called mp_pin_out_request_data() on this pin and
// you must not have disconnected or changed the pin in any way.
// This does not mark the filter for progress, i.e. the filter's process()
// function won't be repeated (unless other pins change). If you really need
// that, call mp_filter_internal_mark_progress() manually in addition.
void mp_pin_out_unread(struct mp_pin *p, struct mp_frame frame);
// A helper to make draining on MP_FRAME_EOF frames easier. For filters which
// buffer data, but have no easy way to buffer MP_FRAME_EOF frames natively.
// This is to be used as follows:
// 1. caller receives MP_FRAME_EOF
// 2. initiates draining (or continues, see step 4.)
// 2b. if there are no more buffered frames, just propagates the EOF frame and
// exits
// 3. calls mp_pin_out_repeat_eof(pin)
// 4. returns a buffered frame normally, and continues normally
// 4b. pin returns "repeated" MP_FRAME_EOF, jump to 1.
// 5. if there's nothing more to do, stop
// 5b. there might be a sporadic wakeup, and an unwanted wait for output (in
// a typical filter implementation)
// You must not have requested data before calling this. (Usually you'd call
// this after mp_pin_out_read(). Requesting data after queuing the repeat EOF
// is OK and idempotent.)
// This is equivalent to mp_pin_out_unread(p, MP_EOF_FRAME). See that function
// for further remarks.
void mp_pin_out_repeat_eof(struct mp_pin *p);
// Trivial helper to determine whether src is readable and dst is writable right
// now. Defers or requests new data if not ready. This means it has the side
// effect of telling the filters that you want to transfer data.
// You use this in a filter process() function. If the result is false, it will
// have requested new output from src, and your process() function will be
// called again once src has output and dst is accepts input (the latest).
bool mp_pin_can_transfer_data(struct mp_pin *dst, struct mp_pin *src);
// Trivial helper to copy data between two manual pins. This uses filter data
// flow - so if data can't be copied, it requests the pins to make it possible
// on the next filter run. This implies you call this either from a filter
// process() function, or call it manually when needed. Also see
// mp_pin_can_transfer_data(). Returns whether a transfer happened.
bool mp_pin_transfer_data(struct mp_pin *dst, struct mp_pin *src);
// Connect src and dst, for automatic data flow. Pin src will reflect the request
// state of pin dst, and accept and pass down frames to dst when appropriate.
// src must be MP_PIN_OUT, dst must be MP_PIN_IN.
// Previous connections are always removed. If the pins were already connected,
// no action is taken.
// Creating circular connections will just cause infinite recursion or such.
// Both API user and filter implementations can use this, but always only on
// the pins they're allowed to access.
void mp_pin_connect(struct mp_pin *dst, struct mp_pin *src);
// Enable manual filter access. This means you want to directly use the
// mp_pin_in*() and mp_pin_out_*() functions for data flow.
// Always severs previous connections.
void mp_pin_set_manual_connection(struct mp_pin *p, bool connected);
// Enable manual filter access, like mp_pin_set_manual_connection(). In
// addition, this specifies which filter's process function should be invoked
// on pin state changes. Using mp_pin_set_manual_connection() will default to
// the parent filter for this.
// Passing f=NULL disconnects.
void mp_pin_set_manual_connection_for(struct mp_pin *p, struct mp_filter *f);
// Return the manual connection for this pin, or NULL if none.
struct mp_filter *mp_pin_get_manual_connection(struct mp_pin *p);
// Disconnect the pin, possibly breaking connections.
void mp_pin_disconnect(struct mp_pin *p);
// Return whether a connection was set on this pin. Note that this is not
// transitive (if the pin is connected to an pin with no further connections,
// there is no active connection, but this still returns true).
bool mp_pin_is_connected(struct mp_pin *p);
// Return a symbolic name of the pin. Usually it will be something redundant
// (like "in" or "out"), or something the user set.
// The returned pointer is valid as long as the mp_pin is allocated.
const char *mp_pin_get_name(struct mp_pin *p);
/**
* A filter converts input frames to output frames (mp_frame, usually audio or
* video data). It can support multiple inputs and outputs. Data always flows
* through mp_pin instances.
*
* --- General rules for data flow:
*
* All data goes through mp_pin (present in the mp_filter inputs/outputs list).
* Actual work is done in the filter's process() function. This function
* queries whether input mp_pins have data and output mp_pins require data. If
* both is the case, a frame is read, filtered, and written to the output.
* Depending on the filter type, the filter might internally buffer data (e.g.
* things that require readahead). But in general, a filter should not request
* input before output is needed.
*
* The general goal is to reduce the amount of data buffered. This is why
* mp_pins buffer at most 1 frame, and the API is designed such that queued
* data in pins will be immediately passed to the next filter. If buffering is
* actually desired, explicit filters for buffering have to be introduced into
* the filter chain.
*
* Typically a filter will do something like this:
*
* process(struct mp_filter *f) {
* if (!mp_pin_in_needs_data(f->ppins[1]))
* return; // reader needs no output yet, so stop filtering
* if (!have_enough_data_for_output) {
* // Could check mp_pin_out_request_data(), but often just trying to
* // read is enough, as a failed read will request more data.
* struct mp_frame fr = mp_pin_out_read_data(f->ppins[0]);
* if (!fr.type)
* return; // no frame was returned - data was requested, and will
* // be queued when available, and invoke process() again
* ... do something with fr here ...
* }
* ... produce output frame (i.e. actual filtering) ...
* mp_pin_in_write(f->ppins[1], output_frame);
* }
*
* Simpler filters can use utility functions like mp_pin_can_transfer_data(),
* which reduce the boilerplate. Such filters also may not need to buffer data
* as internal state.
*
* --- Driving filters:
*
* The filter root (created by mp_filter_create_root()) will internally create
* a graph runner, that can be entered with mp_filter_graph_run(). This will
* check if any filter/pin has unhandled requests, and call filter process()
* functions accordingly. Outside of the filter, this can be triggered
* implicitly via the mp_pin_* functions.
*
* Multiple filters are driven by letting mp_pin flag filters which need
* process() to be called. The process starts by requesting output from the
* last filter. The requests will "bubble up" by iteratively calling process()
* on each filter, which will request further input, until input on the first
* filter's input pin is requested. The API user feeds it a frame, which will
* call the first filter's process() function, which will filter and output
* the frame, and the frame is iteratively filtered until it reaches the output.
*
* --- General rules for thread safety:
*
* Filters are by default not thread safe. However, some filters can be
* partially thread safe and allow certain functions to be accessed from
* foreign threads. The common filter code itself is not thread safe, except
* for some utility functions explicitly marked as such, and which are meant
* to make implementing threaded filters easier.
*
* (Semi-)automatic filter communication such as pins must always be within the
* same root filter. This is meant to help with ensuring thread-safety. Every
* thread that wants to run filters "on its own" should use a different filter
* graph, and disallowing different root filters ensures these graphs are not
* accidentally connected using non-thread safe mechanisms. Actual threaded
* filter graphs would use several independent graphs connected by asynchronous
* helpers (such as mp_async_queue instead of mp_pin connections).
*
* --- Rules for manual connections:
*
* A pin can be marked for manual connection via mp_pin_set_manual_connection().
* It's also the default. These have two uses:
*
* 1. filter internal (the filter actually does something with a frame)
* 2. filter user manually feeding/retrieving frames
*
* Basically, a manual connection means someone uses the mp_pin_in_*() or
* mp_pin_out_*() functions on a pin. The alternative is an automatic connection
* made via mp_pin_connect(). Manual connections need special considerations
* for wakeups:
*
* Internal manual pins (within a filter) will invoke the filter's process()
* function, and the filter polls the state of all pins to see if anything
* needs to be filtered or requested.
*
* External manual pins (filter user) require the user to poll all manual pins
* that are part of the graph. In addition, the filter's wakeup callback must be
* set, and trigger repolling all pins. This is needed in case any filters do
* async filtering internally.
*
* --- Rules for filters with multiple inputs or outputs:
*
* The generic filter code does not do any kind of scheduling. It's the filter's
* responsibility to request frames from input when needed, and to avoid
* internal excessive buffering if outputs aren't read.
*
* --- Rules for async filters:
*
* Async filters will have a synchronous interface with asynchronous waiting.
* They change mp_pin data flow to being poll based, with a wakeup mechanism to
* avoid active waiting. Once polling results in no change, the API user can go
* to sleep, and wait until the wakeup callback set via mp_filter_create_root()
* is invoked. Then it can poll the filters again. Internally, filters use
* mp_filter_wakeup() to get their process() function invoked on the user
* thread, and update the mp_pin states.
*
* For running parts of a filter graph on a different thread, f_async_queue.h
* can be used.
*
* With different filter graphs working asynchronously, reset handling and start
* of filtering becomes more difficult. Since filtering is always triggered by
* requesting output from a filter, a simple way to solve this is to trigger
* resets from the consumer, and to synchronously reset the producer.
*
* --- Format conversions and mid-stream format changes:
*
* Generally, all filters must support all formats, as well as mid-stream
* format changes. If they don't, they will have to error out. There are some
* helpers for dealing with these two things.
*
* mp_pin_out_unread() can temporarily put back an input frame. If the input
* format changed, and you have to drain buffered data, you can put back the
* frame every time you output a buffered frame. Once all buffered data is
* drained this way, you can actually change the internal filter state to the
* new format, and actually consume the input frame.
*
* There is an f_autoconvert filter, which lets you transparently convert to
* a set of target formats (and which passes through the data if no conversion
* is needed).
*
* --- Rules for format negotiation:
*
* Since libavfilter does not provide _any_ kind of format negotiation to the
* user, and most filters use the libavfilter wrapper anyway, this is pretty
* broken and rudimentary. (The only thing libavfilter provides is that you
* can try to create a filter with a specific input format. Then you get
* either failure, or an output format. It involves actually initializing all
* filters, so a try run is not cheap or even side effect free.)
*/
struct mp_filter {
// Private state for the filter implementation. API users must not access
// this.
void *priv;
struct mpv_global *global;
struct mp_log *log;
// Array of public pins. API users can read this, but are not allowed to
// modify the array. Filter implementations use mp_filter_add_pin() to add
// pins to the array. The array is in order of the add calls.
// Most filters will use pins[0] for input (MP_PIN_IN), and pins[1] for
// output (MP_PIN_OUT). This is the default convention for filters. Some
// filters may have more complex usage, and assign pin entries with
// different meanings.
// The filter implementation must not use this. It must access ppins[]
// instead.
struct mp_pin **pins;
int num_pins;
// Internal pins, for access by the filter implementation. The meaning of
// in/out is swapped from the public interface: inputs use MP_PIN_OUT,
// because the filter reads from the inputs, and outputs use MP_PIN_IN,
// because the filter writes to them. ppins[n] always corresponds to pin[n],
// with swapped direction, and implicit data flow between the two.
// Outside API users must not access this.
struct mp_pin **ppins;
// Dumb garbage.
struct mp_stream_info *stream_info;
// Private state for the generic filter code.
struct mp_filter_internal *in;
};
// Return a symbolic name, which is set at init time. NULL if no name.
// Valid until filter is destroyed or next mp_filter_set_name() call.
const char *mp_filter_get_name(struct mp_filter *f);
// Change mp_filter_get_name() return value.
void mp_filter_set_name(struct mp_filter *f, const char *name);
// Set filter priority. A higher priority gets processed first. Also, high
// priority filters disable "interrupting" the filter graph.
void mp_filter_set_high_priority(struct mp_filter *filter, bool pri);
// Get a pin from f->pins[] for which mp_pin_get_name() returns the same name.
// If name is NULL, always return NULL.
struct mp_pin *mp_filter_get_named_pin(struct mp_filter *f, const char *name);
// Return true if the filter has failed in some fatal way that does not allow
// it to continue. This resets the error state (but does not reset the child
// failed status on any parent filter).
bool mp_filter_has_failed(struct mp_filter *filter);
// Invoke mp_filter_info.reset on this filter and all children (but not
// other filters connected via pins).
void mp_filter_reset(struct mp_filter *filter);
enum mp_filter_command_type {
MP_FILTER_COMMAND_TEXT = 1,
MP_FILTER_COMMAND_GET_META,
MP_FILTER_COMMAND_SET_SPEED,
MP_FILTER_COMMAND_SET_SPEED_RESAMPLE,
MP_FILTER_COMMAND_SET_SPEED_DROP,
MP_FILTER_COMMAND_IS_ACTIVE,
};
struct mp_filter_command {
enum mp_filter_command_type type;
// For MP_FILTER_COMMAND_TEXT
const char *cmd;
const char *arg;
// For MP_FILTER_COMMAND_GET_META
void *res; // must point to struct mp_tags*, will be set to new instance
// For MP_FILTER_COMMAND_SET_SPEED and MP_FILTER_COMMAND_SET_SPEED_RESAMPLE
double speed;
// For MP_FILTER_COMMAND_IS_ACTIVE
bool is_active;
};
// Run a command on the filter. Returns success. For libavfilter.
bool mp_filter_command(struct mp_filter *f, struct mp_filter_command *cmd);
// Specific information about a sub-tree in a filter graph. Currently, this is
// mostly used to give filters access to VO mechanisms and capabilities.
struct mp_stream_info {
void *priv; // for use by whoever implements the callbacks
double (*get_display_fps)(struct mp_stream_info *i);
void (*get_display_res)(struct mp_stream_info *i, int *res);
struct mp_hwdec_devices *hwdec_devs;
struct osd_state *osd;
bool rotate90;
struct vo *dr_vo; // for calling vo_get_image()
};
// Search for a parent filter (including f) that has this set, and return it.
struct mp_stream_info *mp_filter_find_stream_info(struct mp_filter *f);
struct mp_hwdec_ctx *mp_filter_load_hwdec_device(struct mp_filter *f, int imgfmt);
// Perform filtering. This runs until the filter graph is blocked (due to
// missing external input or unread output). It returns whether any outside
// pins have changed state.
// Can be called on the root filter only.
bool mp_filter_graph_run(struct mp_filter *root);
// Set the maximum time mp_filter_graph_run() should block. If the maximum time
// expires, the effect is the same as calling mp_filter_graph_interrupt() while
// the function is running. See that function for further details.
// The default is seconds==INFINITY. Values <=0 make it return after 1 iteration.
// Can be called on the root filter only.
void mp_filter_graph_set_max_run_time(struct mp_filter *root, double seconds);
// Interrupt mp_filter_graph_run() asynchronously. This does not stop filtering
// in a destructive way, but merely suspends it. In practice, this will make
// mp_filter_graph_run() return after the current filter's process() function has
// finished. Filtering can be resumed with subsequent mp_filter_graph_run() calls.
// When mp_filter_graph_run() is interrupted, it will trigger the filter graph
// wakeup callback, which in turn ensures that the user will call
// mp_filter_graph_run() again.
// If it is called if not in mp_filter_graph_run(), the next mp_filter_graph_run()
// call is interrupted and no filtering is done for that call.
// Calling this too often will starve filtering.
// This does not call the graph wakeup callback directly, which will avoid
// potential reentrancy issues. (But mp_filter_graph_run() will call it in
// reaction to it, as described above.)
// Explicitly thread-safe.
// Can be called on the root filter only.
void mp_filter_graph_interrupt(struct mp_filter *root);
// Create a root dummy filter with no inputs or outputs. This fulfills the
// following functions:
// - creating a new filter graph (attached to the root filter)
// - passing it as parent filter to top-level filters
// - driving the filter loop between the shared filters
// - setting the wakeup callback for async filtering
// - implicitly passing down global data like mpv_global and keeping filter
// constructor functions simple
// Note that you can still connect pins of filters with different parents or
// root filters, but then you may have to manually invoke mp_filter_graph_run()
// on the root filters of the connected filters to drive data flow.
struct mp_filter *mp_filter_create_root(struct mpv_global *global);
// Asynchronous filters may need to wakeup the user thread if the status of any
// mp_pin has changed. If this is called, the callback provider should get the
// user's thread to call mp_filter_graph_run() again.
// The wakeup callback must not recursively call into any filter APIs, or do
// blocking waits on the filter API (deadlocks will happen).
// A wakeup callback should always set a "wakeup" flag, that is reset only when
// mp_filter_graph_run() is going to be called again with no wait time.
// Can be called on the root filter only.
void mp_filter_graph_set_wakeup_cb(struct mp_filter *root,
void (*wakeup_cb)(void *ctx), void *ctx);
// Debugging internal stuff.
void mp_filter_dump_states(struct mp_filter *f);