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a451ffe268
The client code should never try to pass commands to the output via the MidiParser API. SCI currently does that though... Actually that shows that either our MidiParser API becomes more and more an MidiPlayer than just a parser or that the SCI design has its flaws here. svn-id: r49996
399 lines
15 KiB
C++
399 lines
15 KiB
C++
/* ScummVM - Graphic Adventure Engine
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*
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* ScummVM is the legal property of its developers, whose names
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* are too numerous to list here. Please refer to the COPYRIGHT
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* file distributed with this source distribution.
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation; either version 2
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* of the License, or (at your option) any later version.
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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*
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* $URL$
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* $Id$
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*
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*/
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/// \brief Declarations related to the MidiParser class
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#ifndef SOUND_MIDIPARSER_H
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#define SOUND_MIDIPARSER_H
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#include "common/scummsys.h"
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#include "common/endian.h"
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class MidiParser;
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class MidiDriver;
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//////////////////////////////////////////////////
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//
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// Support entities
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//
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//////////////////////////////////////////////////
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/**
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* Maintains time and position state within a MIDI stream.
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* A single Tracker struct is used by MidiParser to keep track
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* of its current position in the MIDI stream. The Tracker
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* struct, however, allows alternative locations to be cached.
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* See MidiParser::jumpToTick() for an example of tracking
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* multiple locations within a MIDI stream. NOTE: It is
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* important to also maintain pre-parsed EventInfo data for
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* each Tracker location.
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*/
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struct Tracker {
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byte * _play_pos; ///< A pointer to the next event to be parsed
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uint32 _play_time; ///< Current time in microseconds; may be in between event times
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uint32 _play_tick; ///< Current MIDI tick; may be in between event ticks
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uint32 _last_event_time; ///< The time, in microseconds, of the last event that was parsed
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uint32 _last_event_tick; ///< The tick at which the last parsed event occurs
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byte _running_status; ///< Cached MIDI command, for MIDI streams that rely on implied event codes
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Tracker() { clear(); }
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/// Copy constructor for each duplication of Tracker information.
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Tracker(const Tracker ©) :
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_play_pos(copy._play_pos),
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_play_time(copy._play_time),
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_play_tick(copy._play_tick),
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_last_event_time(copy._last_event_time),
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_last_event_tick(copy._last_event_tick),
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_running_status(copy._running_status)
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{ }
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/// Clears all data; used by the constructor for initialization.
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void clear() {
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_play_pos = 0;
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_play_time = 0;
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_play_tick = 0;
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_last_event_time = 0;
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_last_event_tick = 0;
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_running_status = 0;
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}
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};
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/**
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* Provides comprehensive information on the next event in the MIDI stream.
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* An EventInfo struct is instantiated by format-specific implementations
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* of MidiParser::parseNextEvent() each time another event is needed.
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*/
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struct EventInfo {
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byte * start; ///< Position in the MIDI stream where the event starts.
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///< For delta-based MIDI streams (e.g. SMF and XMIDI), this points to the delta.
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uint32 delta; ///< The number of ticks after the previous event that this event should occur.
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byte event; ///< Upper 4 bits are the command code, lower 4 bits are the MIDI channel.
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///< For META, event == 0xFF. For SysEx, event == 0xF0.
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union {
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struct {
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byte param1; ///< The first parameter in a simple MIDI message.
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byte param2; ///< The second parameter in a simple MIDI message.
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} basic;
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struct {
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byte type; ///< For META events, this indicates the META type.
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byte * data; ///< For META and SysEx events, this points to the start of the data.
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} ext;
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};
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uint32 length; ///< For META and SysEx blocks, this indicates the length of the data.
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///< For Note On events, a non-zero value indicates that no Note Off event
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///< will occur, and the MidiParser will have to generate one itself.
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///< For all other events, this value should always be zero.
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byte channel() { return event & 0x0F; } ///< Separates the MIDI channel from the event.
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byte command() { return event >> 4; } ///< Separates the command code from the event.
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};
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/**
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* Provides expiration tracking for hanging notes.
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* Hanging notes are used when a MIDI format does not include explicit Note Off
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* events, or when "Smart Jump" is enabled so that active notes are intelligently
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* expired when a jump occurs. The NoteTimer struct keeps track of how much
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* longer a note should remain active before being turned off.
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*/
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struct NoteTimer {
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byte channel; ///< The MIDI channel on which the note was played
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byte note; ///< The note number for the active note
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uint32 time_left; ///< The time, in microseconds, remaining before the note should be turned off
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NoteTimer() : channel(0), note(0), time_left(0) {}
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};
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//////////////////////////////////////////////////
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//
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// MidiParser declaration
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//
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//////////////////////////////////////////////////
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/**
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* A framework and common functionality for parsing event-based music streams.
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* The MidiParser provides a framework in which to load,
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* parse and traverse event-based music data. Note the
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* avoidance of the phrase "MIDI data." Despite its name,
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* MidiParser derivatives can be used to manage a wide
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* variety of event-based music formats. It is, however,
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* based on the premise that the format in question can
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* be played in the form of specification MIDI events.
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*
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* In order to use MidiParser to parse your music format,
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* follow these steps:
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*
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* <b>STEP 1: Write a MidiParser derivative.</b>
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* The MidiParser base class provides functionality
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* considered common to the task of parsing event-based
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* music. In order to parse a particular format, create
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* a derived class that implements, at minimum, the
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* following format-specific methods:
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* - loadMusic
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* - parseNextEvent
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*
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* In addition to the above functions, the derived class
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* may also override the default MidiParser behavior for
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* the following methods:
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* - resetTracking
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* - allNotesOff
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* - unloadMusic
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* - property
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* - getTick
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*
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* Please see the documentation for these individual
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* functions for more information on their use.
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*
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* The naming convention for classes derived from
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* MidiParser is MidiParser_XXX, where "XXX" is some
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* short designator for the format the class will
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* support. For instance, the MidiParser derivative
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* for parsing the Standard MIDI File format is
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* MidiParser_SMF.
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*
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* <b>STEP 2: Create an object of your derived class.</b>
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* Each MidiParser object can parse at most one (1) song
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* at a time. However, a MidiParser object can be reused
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* to play another song once it is no longer needed to
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* play whatever it was playing. In other words, MidiParser
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* objects do not have to be destroyed and recreated from
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* one song to the next.
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*
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* <b>STEP 3: Specify a MidiDriver to send events to.</b>
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* MidiParser works by sending MIDI and meta events to a
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* MidiDriver. In the simplest configuration, you can plug
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* a single MidiParser directly into the output MidiDriver
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* being used. However, you can only plug in one at a time;
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* otherwise channel conflicts will occur. Furthermore,
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* meta events that may be needed to interactively control
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* music flow cannot be handled because they are being
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* sent directly to the output device.
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*
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* If you need more control over the MidiParser while it's
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* playing, you can create your own "pseudo-MidiDriver" and
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* place it in between your MidiParser and the output
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* MidiDriver. The MidiParser will send events to your
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* pseudo-MidiDriver, which in turn must send them to the
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* output MidiDriver (or do whatever special handling is
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* required).
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*
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* To specify the MidiDriver to send music output to,
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* use the MidiParser::setMidiDriver method.
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*
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* <b>STEP 4: Specify the onTimer call rate.</b>
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* MidiParser bases the timing of its parsing on an external
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* clock. Every time MidiParser::onTimer is called, a bit
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* more music is parsed. You must specify how many
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* microseconds will occur between each call to onTimer,
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* in order to ensure an accurate music tempo.
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*
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* To set the onTimer call rate, in microseconds,
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* use the MidiParser::setTimerRate method. The onTimer
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* call rate will typically match the timer rate for
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* the output MidiDriver used. This rate can be obtained
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* by calling MidiDriver::getBaseTempo.
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*
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* <b>STEP 5: Load the music.</b>
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* MidiParser requires that the music data already be loaded
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* into memory. The client code is responsible for memory
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* management on this block of memory. That means that the
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* client code must ensure that the data remain in memory
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* while the MidiParser is using it, and properly freed
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* after it is no longer needed. Some MidiParser variants may
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* require internal buffers as well; memory management for those
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* buffers is the responsibility of the MidiParser object.
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*
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* To load the music into the MidiParser, use the
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* MidiParser::loadMusic method, specifying a memory pointer
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* to the music data and the size of the data. (NOTE: Some
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* MidiParser variants don't require a size, and 0 is fine.
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* However, when writing client code to use MidiParser, it is
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* best to assume that a valid size will be required.
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*
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* Convention requires that each implementation of
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* MidiParser::loadMusic automatically set up default tempo
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* and current track. This effectively means that the
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* MidiParser will start playing as soon as timer events
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* start coming in.
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*
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* <b>STEP 6: Activate a timer source for the MidiParser.</b>
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* The easiest timer source to use is the timer of the
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* output MidiDriver. You can attach the MidiDriver's
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* timer output directly to a MidiParser by calling
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* MidiDriver::setTimerCallback. In this case, the timer_proc
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* will be the static method MidiParser::timerCallback,
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* and timer_param will be a pointer to your MidiParser object.
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*
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* This configuration only allows one MidiParser to be driven
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* by the MidiDriver at a time. To drive more MidiDrivers, you
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* will need to create a "pseudo-MidiDriver" as described earlier,
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* In such a configuration, the pseudo-MidiDriver should be set
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* as the timer recipient in MidiDriver::setTimerCallback, and
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* could then call MidiParser::onTimer for each MidiParser object.
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*
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* <b>STEP 7: Music shall begin to play!</b>
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* Congratulations! At this point everything should be hooked up
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* and the MidiParser should generate music. Note that there is
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* no way to "stop" the MidiParser. You can "pause" the MidiParser
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* simply by not sending timer events to it, or you can call
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* MidiParser::unloadMusic to permanently stop the music. (This
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* method resets everything and detaches the MidiParser from the
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* memory block containing the music data.)
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*/
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class MidiParser {
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protected:
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uint16 _active_notes[128]; ///< Each uint16 is a bit mask for channels that have that note on.
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NoteTimer _hanging_notes[32]; ///< Maintains expiration info for up to 32 notes.
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///< Used for "Smart Jump" and MIDI formats that do not include explicit Note Off events.
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byte _hanging_notes_count; ///< Count of hanging notes, used to optimize expiration.
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MidiDriver *_driver; ///< The device to which all events will be transmitted.
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uint32 _timer_rate; ///< The time in microseconds between onTimer() calls. Obtained from the MidiDriver.
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uint32 _ppqn; ///< Pulses Per Quarter Note. (We refer to "pulses" as "ticks".)
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uint32 _tempo; ///< Microseconds per quarter note.
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uint32 _psec_per_tick; ///< Microseconds per tick (_tempo / _ppqn).
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bool _autoLoop; ///< For lightweight clients that don't provide their own flow control.
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bool _smartJump; ///< Support smart expiration of hanging notes when jumping
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bool _centerPitchWheelOnUnload; ///< Center the pitch wheels when unloading a song
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byte *_tracks[120]; ///< Multi-track MIDI formats are supported, up to 120 tracks.
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byte _num_tracks; ///< Count of total tracks for multi-track MIDI formats. 1 for single-track formats.
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byte _active_track; ///< Keeps track of the currently active track, in multi-track formats.
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Tracker _position; ///< The current time/position in the active track.
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EventInfo _next_event; ///< The next event to transmit. Events are preparsed
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///< so each event is parsed only once; this permits
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///< simulated events in certain formats.
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bool _abort_parse; ///< If a jump or other operation interrupts parsing, flag to abort.
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protected:
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static uint32 readVLQ(byte * &data);
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virtual void resetTracking();
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virtual void allNotesOff();
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virtual void parseNextEvent(EventInfo &info) = 0;
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void activeNote(byte channel, byte note, bool active);
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void hangingNote(byte channel, byte note, uint32 ticks_left, bool recycle = true);
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void hangAllActiveNotes();
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virtual void sendToDriver(uint32 b);
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void sendToDriver(byte status, byte firstOp, byte secondOp) {
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sendToDriver(status | ((uint32)firstOp << 8) | ((uint32)secondOp << 16));
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}
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/**
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* Platform independent BE uint32 read-and-advance.
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* This helper function reads Big Endian 32-bit numbers
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* from a memory pointer, at the same time advancing
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* the pointer.
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*/
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uint32 read4high(byte * &data) {
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uint32 val = READ_BE_UINT32(data);
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data += 4;
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return val;
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}
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/**
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* Platform independent LE uint16 read-and-advance.
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* This helper function reads Little Endian 16-bit numbers
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* from a memory pointer, at the same time advancing
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* the pointer.
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*/
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uint16 read2low(byte * &data) {
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uint16 val = READ_LE_UINT16(data);
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data += 2;
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return val;
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}
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public:
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/**
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* Configuration options for MidiParser
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* The following options can be set to modify MidiParser's
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* behavior.
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*/
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enum {
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/**
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* Events containing a pitch bend command should be treated as
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* single-byte padding before the real event. This allows the
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* MidiParser to work with some malformed SMF files from Simon 1/2.
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*/
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mpMalformedPitchBends = 1,
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/**
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* Sets auto-looping, which can be used by lightweight clients
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* that don't provide their own flow control.
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*/
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mpAutoLoop = 2,
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/**
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* Sets smart jumping, which intelligently expires notes that are
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* active when a jump is made, rather than just cutting them off.
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*/
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mpSmartJump = 3,
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/**
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* Center the pitch wheels when unloading music in preparation
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* for the next piece of music.
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*/
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mpCenterPitchWheelOnUnload = 4
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};
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public:
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typedef void (*XMidiCallbackProc)(byte eventData, void *refCon);
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MidiParser();
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virtual ~MidiParser() { allNotesOff(); }
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virtual bool loadMusic(byte *data, uint32 size) = 0;
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virtual void unloadMusic();
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virtual void property(int prop, int value);
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void setMidiDriver(MidiDriver *driver) { _driver = driver; }
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void setTimerRate(uint32 rate) { _timer_rate = rate; }
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void setTempo(uint32 tempo);
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void onTimer();
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bool isPlaying() const { return (_position._play_pos != 0); }
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void stopPlaying();
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bool setTrack(int track);
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bool jumpToTick(uint32 tick, bool fireEvents = false, bool stopNotes = true);
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uint32 getPPQN() { return _ppqn; }
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virtual uint32 getTick() { return _position._play_tick; }
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static void defaultXMidiCallback(byte eventData, void *refCon);
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static MidiParser *createParser_SMF();
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static MidiParser *createParser_XMIDI(XMidiCallbackProc proc = defaultXMidiCallback, void *refCon = 0);
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static void timerCallback(void *data) { ((MidiParser *) data)->onTimer(); }
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};
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#endif
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