/[svn]/libgig/trunk/src/gig.h
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* improved handling of fixed length info strings

1 schoenebeck 2 /***************************************************************************
2     * *
3 schoenebeck 933 * libgig - C++ cross-platform Gigasampler format file access library *
4 schoenebeck 2 * *
5 schoenebeck 1081 * Copyright (C) 2003-2007 by Christian Schoenebeck *
6 schoenebeck 384 * <cuse@users.sourceforge.net> *
7 schoenebeck 2 * *
8     * This library is free software; you can redistribute it and/or modify *
9     * it under the terms of the GNU General Public License as published by *
10     * the Free Software Foundation; either version 2 of the License, or *
11     * (at your option) any later version. *
12     * *
13     * This library is distributed in the hope that it will be useful, *
14     * but WITHOUT ANY WARRANTY; without even the implied warranty of *
15     * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
16     * GNU General Public License for more details. *
17     * *
18     * You should have received a copy of the GNU General Public License *
19     * along with this library; if not, write to the Free Software *
20     * Foundation, Inc., 59 Temple Place, Suite 330, Boston, *
21     * MA 02111-1307 USA *
22     ***************************************************************************/
23    
24     #ifndef __GIG_H__
25     #define __GIG_H__
26    
27     #include "DLS.h"
28    
29 schoenebeck 11 #if WORDS_BIGENDIAN
30 schoenebeck 2 # define LIST_TYPE_3PRG 0x33707267
31     # define LIST_TYPE_3EWL 0x3365776C
32 schoenebeck 929 # define LIST_TYPE_3GRI 0x33677269
33     # define LIST_TYPE_3GNL 0x33676E6C
34 schoenebeck 2 # define CHUNK_ID_SMPL 0x736D706C
35     # define CHUNK_ID_3GIX 0x33676978
36     # define CHUNK_ID_3EWA 0x33657761
37     # define CHUNK_ID_3LNK 0x336C6E6B
38     # define CHUNK_ID_3EWG 0x33657767
39     # define CHUNK_ID_EWAV 0x65776176
40 schoenebeck 929 # define CHUNK_ID_3GNM 0x33676E6D
41 schoenebeck 2 #else // little endian
42     # define LIST_TYPE_3PRG 0x67727033
43     # define LIST_TYPE_3EWL 0x6C776533
44 schoenebeck 929 # define LIST_TYPE_3GRI 0x69726733
45     # define LIST_TYPE_3GNL 0x6C6E6733
46 schoenebeck 2 # define CHUNK_ID_SMPL 0x6C706D73
47     # define CHUNK_ID_3GIX 0x78696733
48     # define CHUNK_ID_3EWA 0x61776533
49     # define CHUNK_ID_3LNK 0x6B6E6C33
50     # define CHUNK_ID_3EWG 0x67776533
51     # define CHUNK_ID_EWAV 0x76617765
52 schoenebeck 929 # define CHUNK_ID_3GNM 0x6D6E6733
53 schoenebeck 2 #endif // WORDS_BIGENDIAN
54    
55     /** Gigasampler specific classes and definitions */
56     namespace gig {
57    
58     typedef std::string String;
59    
60     /** Lower and upper limit of a range. */
61     struct range_t {
62     uint8_t low; ///< Low value of range.
63     uint8_t high; ///< High value of range.
64     };
65    
66     /** Pointer address and size of a buffer. */
67     struct buffer_t {
68     void* pStart; ///< Points to the beginning of the buffer.
69     unsigned long Size; ///< Size of the actual data in the buffer in bytes.
70     unsigned long NullExtensionSize; ///< The buffer might be bigger than the actual data, if that's the case that unused space at the end of the buffer is filled with NULLs and NullExtensionSize reflects that unused buffer space in bytes. Those NULL extensions are mandatory for differential algorithms that have to take the following data words into account, thus have to access past the buffer's boundary. If you don't know what I'm talking about, just forget this variable. :)
71 schoenebeck 384 buffer_t() {
72     pStart = NULL;
73     Size = 0;
74     NullExtensionSize = 0;
75     }
76 schoenebeck 2 };
77    
78     /** Standard types of sample loops. */
79     typedef enum {
80     loop_type_normal = 0x00000000, ///< Loop forward (normal)
81     loop_type_bidirectional = 0x00000001, ///< Alternating loop (forward/backward, also known as Ping Pong)
82     loop_type_backward = 0x00000002 ///< Loop backward (reverse)
83     } loop_type_t;
84    
85     /** Society of Motion Pictures and Television E time format. */
86     typedef enum {
87     smpte_format_no_offset = 0x00000000, ///< no SMPTE offset
88     smpte_format_24_frames = 0x00000018, ///< 24 frames per second
89     smpte_format_25_frames = 0x00000019, ///< 25 frames per second
90     smpte_format_30_frames_dropping = 0x0000001D, ///< 30 frames per second with frame dropping (30 drop)
91     smpte_format_30_frames = 0x0000001E ///< 30 frames per second
92     } smpte_format_t;
93    
94     /** Defines the shape of a function graph. */
95     typedef enum {
96     curve_type_nonlinear = 0,
97     curve_type_linear = 1,
98     curve_type_special = 2,
99     curve_type_unknown = 0xffffffff
100     } curve_type_t;
101    
102     /** Dimensions allow to bypass one of the following controllers. */
103     typedef enum {
104     dim_bypass_ctrl_none,
105     dim_bypass_ctrl_94, ///< Effect 4 Depth (MIDI Controller 94)
106     dim_bypass_ctrl_95 ///< Effect 5 Depth (MIDI Controller 95)
107     } dim_bypass_ctrl_t;
108    
109     /** Defines how LFO3 is controlled by. */
110     typedef enum {
111     lfo3_ctrl_internal = 0x00, ///< Only internally controlled.
112     lfo3_ctrl_modwheel = 0x01, ///< Only controlled by external modulation wheel.
113     lfo3_ctrl_aftertouch = 0x02, ///< Only controlled by aftertouch controller.
114     lfo3_ctrl_internal_modwheel = 0x03, ///< Controlled internally and by external modulation wheel.
115     lfo3_ctrl_internal_aftertouch = 0x04 ///< Controlled internally and by aftertouch controller.
116     } lfo3_ctrl_t;
117    
118     /** Defines how LFO2 is controlled by. */
119     typedef enum {
120     lfo2_ctrl_internal = 0x00, ///< Only internally controlled.
121     lfo2_ctrl_modwheel = 0x01, ///< Only controlled by external modulation wheel.
122     lfo2_ctrl_foot = 0x02, ///< Only controlled by external foot controller.
123     lfo2_ctrl_internal_modwheel = 0x03, ///< Controlled internally and by external modulation wheel.
124     lfo2_ctrl_internal_foot = 0x04 ///< Controlled internally and by external foot controller.
125     } lfo2_ctrl_t;
126    
127     /** Defines how LFO1 is controlled by. */
128     typedef enum {
129     lfo1_ctrl_internal = 0x00, ///< Only internally controlled.
130     lfo1_ctrl_modwheel = 0x01, ///< Only controlled by external modulation wheel.
131     lfo1_ctrl_breath = 0x02, ///< Only controlled by external breath controller.
132     lfo1_ctrl_internal_modwheel = 0x03, ///< Controlled internally and by external modulation wheel.
133     lfo1_ctrl_internal_breath = 0x04 ///< Controlled internally and by external breath controller.
134     } lfo1_ctrl_t;
135    
136     /** Defines how the filter cutoff frequency is controlled by. */
137     typedef enum {
138     vcf_cutoff_ctrl_none = 0x00,
139 persson 834 vcf_cutoff_ctrl_none2 = 0x01, ///< The difference between none and none2 is unknown
140 schoenebeck 2 vcf_cutoff_ctrl_modwheel = 0x81, ///< Modulation Wheel (MIDI Controller 1)
141     vcf_cutoff_ctrl_effect1 = 0x8c, ///< Effect Controller 1 (Coarse, MIDI Controller 12)
142     vcf_cutoff_ctrl_effect2 = 0x8d, ///< Effect Controller 2 (Coarse, MIDI Controller 13)
143     vcf_cutoff_ctrl_breath = 0x82, ///< Breath Controller (Coarse, MIDI Controller 2)
144     vcf_cutoff_ctrl_foot = 0x84, ///< Foot Pedal (Coarse, MIDI Controller 4)
145     vcf_cutoff_ctrl_sustainpedal = 0xc0, ///< Sustain Pedal (MIDI Controller 64)
146     vcf_cutoff_ctrl_softpedal = 0xc3, ///< Soft Pedal (MIDI Controller 67)
147     vcf_cutoff_ctrl_genpurpose7 = 0xd2, ///< General Purpose Controller 7 (Button, MIDI Controller 82)
148     vcf_cutoff_ctrl_genpurpose8 = 0xd3, ///< General Purpose Controller 8 (Button, MIDI Controller 83)
149     vcf_cutoff_ctrl_aftertouch = 0x80 ///< Key Pressure
150     } vcf_cutoff_ctrl_t;
151    
152     /** Defines how the filter resonance is controlled by. */
153     typedef enum {
154     vcf_res_ctrl_none = 0xffffffff,
155     vcf_res_ctrl_genpurpose3 = 0, ///< General Purpose Controller 3 (Slider, MIDI Controller 18)
156     vcf_res_ctrl_genpurpose4 = 1, ///< General Purpose Controller 4 (Slider, MIDI Controller 19)
157     vcf_res_ctrl_genpurpose5 = 2, ///< General Purpose Controller 5 (Button, MIDI Controller 80)
158     vcf_res_ctrl_genpurpose6 = 3 ///< General Purpose Controller 6 (Button, MIDI Controller 81)
159     } vcf_res_ctrl_t;
160 schoenebeck 55
161 schoenebeck 36 /**
162     * Defines a controller that has a certain contrained influence on a
163     * particular synthesis parameter (used to define attenuation controller,
164     * EG1 controller and EG2 controller).
165     *
166     * You should use the respective <i>typedef</i> (means either
167     * attenuation_ctrl_t, eg1_ctrl_t or eg2_ctrl_t) in your code!
168     */
169     struct leverage_ctrl_t {
170     typedef enum {
171     type_none = 0x00, ///< No controller defined
172     type_channelaftertouch = 0x2f, ///< Channel Key Pressure
173     type_velocity = 0xff, ///< Key Velocity
174     type_controlchange = 0xfe ///< Ordinary MIDI control change controller, see field 'controller_number'
175     } type_t;
176 schoenebeck 55
177 schoenebeck 36 type_t type; ///< Controller type
178     uint controller_number; ///< MIDI controller number if this controller is a control change controller, 0 otherwise
179     };
180 schoenebeck 55
181 schoenebeck 36 /**
182     * Defines controller influencing attenuation.
183     *
184     * @see leverage_ctrl_t
185     */
186     typedef leverage_ctrl_t attenuation_ctrl_t;
187 schoenebeck 55
188 schoenebeck 36 /**
189     * Defines controller influencing envelope generator 1.
190     *
191     * @see leverage_ctrl_t
192     */
193     typedef leverage_ctrl_t eg1_ctrl_t;
194 schoenebeck 55
195 schoenebeck 36 /**
196     * Defines controller influencing envelope generator 2.
197     *
198     * @see leverage_ctrl_t
199     */
200     typedef leverage_ctrl_t eg2_ctrl_t;
201 schoenebeck 2
202     /**
203     * Defines the type of dimension, that is how the dimension zones (and
204     * thus how the dimension regions are selected by. The number of
205     * dimension zones is always a power of two. All dimensions can have up
206     * to 32 zones (except the layer dimension with only up to 8 zones and
207     * the samplechannel dimension which currently allows only 2 zones).
208     */
209     typedef enum {
210     dimension_none = 0x00, ///< Dimension not in use.
211     dimension_samplechannel = 0x80, ///< If used sample has more than one channel (thus is not mono).
212     dimension_layer = 0x81, ///< For layering of up to 8 instruments (and eventually crossfading of 2 or 4 layers).
213 persson 1076 dimension_velocity = 0x82, ///< Key Velocity (this is the only dimension in gig2 where the ranges can exactly be defined).
214 schoenebeck 2 dimension_channelaftertouch = 0x83, ///< Channel Key Pressure
215     dimension_releasetrigger = 0x84, ///< Special dimension for triggering samples on releasing a key.
216 schoenebeck 353 dimension_keyboard = 0x85, ///< Dimension for keyswitching
217 persson 437 dimension_roundrobin = 0x86, ///< Different samples triggered each time a note is played, dimension regions selected in sequence
218     dimension_random = 0x87, ///< Different samples triggered each time a note is played, random order
219 persson 1076 dimension_smartmidi = 0x88, ///< For MIDI tools like legato and repetition mode
220     dimension_roundrobinkeyboard = 0x89, ///< Different samples triggered each time a note is played, any key advances the counter
221 schoenebeck 2 dimension_modwheel = 0x01, ///< Modulation Wheel (MIDI Controller 1)
222     dimension_breath = 0x02, ///< Breath Controller (Coarse, MIDI Controller 2)
223     dimension_foot = 0x04, ///< Foot Pedal (Coarse, MIDI Controller 4)
224     dimension_portamentotime = 0x05, ///< Portamento Time (Coarse, MIDI Controller 5)
225     dimension_effect1 = 0x0c, ///< Effect Controller 1 (Coarse, MIDI Controller 12)
226     dimension_effect2 = 0x0d, ///< Effect Controller 2 (Coarse, MIDI Controller 13)
227     dimension_genpurpose1 = 0x10, ///< General Purpose Controller 1 (Slider, MIDI Controller 16)
228     dimension_genpurpose2 = 0x11, ///< General Purpose Controller 2 (Slider, MIDI Controller 17)
229     dimension_genpurpose3 = 0x12, ///< General Purpose Controller 3 (Slider, MIDI Controller 18)
230     dimension_genpurpose4 = 0x13, ///< General Purpose Controller 4 (Slider, MIDI Controller 19)
231     dimension_sustainpedal = 0x40, ///< Sustain Pedal (MIDI Controller 64)
232     dimension_portamento = 0x41, ///< Portamento (MIDI Controller 65)
233     dimension_sostenutopedal = 0x42, ///< Sostenuto Pedal (MIDI Controller 66)
234     dimension_softpedal = 0x43, ///< Soft Pedal (MIDI Controller 67)
235     dimension_genpurpose5 = 0x30, ///< General Purpose Controller 5 (Button, MIDI Controller 80)
236     dimension_genpurpose6 = 0x31, ///< General Purpose Controller 6 (Button, MIDI Controller 81)
237     dimension_genpurpose7 = 0x32, ///< General Purpose Controller 7 (Button, MIDI Controller 82)
238     dimension_genpurpose8 = 0x33, ///< General Purpose Controller 8 (Button, MIDI Controller 83)
239     dimension_effect1depth = 0x5b, ///< Effect 1 Depth (MIDI Controller 91)
240     dimension_effect2depth = 0x5c, ///< Effect 2 Depth (MIDI Controller 92)
241     dimension_effect3depth = 0x5d, ///< Effect 3 Depth (MIDI Controller 93)
242     dimension_effect4depth = 0x5e, ///< Effect 4 Depth (MIDI Controller 94)
243     dimension_effect5depth = 0x5f ///< Effect 5 Depth (MIDI Controller 95)
244     } dimension_t;
245    
246     /**
247     * Intended for internal usage: will be used to convert a dimension value
248     * into the corresponding dimension bit number.
249     */
250     typedef enum {
251 persson 858 split_type_normal, ///< dimension value between 0-127
252 schoenebeck 2 split_type_bit ///< dimension values are already the sought bit number
253     } split_type_t;
254    
255     /** General dimension definition. */
256     struct dimension_def_t {
257     dimension_t dimension; ///< Specifies which source (usually a MIDI controller) is associated with the dimension.
258     uint8_t bits; ///< Number of "bits" (1 bit = 2 splits/zones, 2 bit = 4 splits/zones, 3 bit = 8 splits/zones,...).
259     uint8_t zones; ///< Number of zones the dimension has.
260     split_type_t split_type; ///< Intended for internal usage: will be used to convert a dimension value into the corresponding dimension bit number.
261 persson 774 float zone_size; ///< Intended for internal usage: reflects the size of each zone (128/zones) for normal split types only, 0 otherwise.
262 schoenebeck 2 };
263    
264     /** Defines which frequencies are filtered by the VCF. */
265     typedef enum {
266     vcf_type_lowpass = 0x00,
267     vcf_type_lowpassturbo = 0xff, ///< More poles than normal lowpass
268     vcf_type_bandpass = 0x01,
269     vcf_type_highpass = 0x02,
270     vcf_type_bandreject = 0x03
271     } vcf_type_t;
272    
273 schoenebeck 345 /**
274     * Defines the envelope of a crossfade.
275     *
276     * Note: The default value for crossfade points is 0,0,0,0. Layers with
277     * such a default value should be treated as if they would not have a
278 schoenebeck 353 * crossfade.
279 schoenebeck 345 */
280 schoenebeck 2 struct crossfade_t {
281     #if WORDS_BIGENDIAN
282 schoenebeck 345 uint8_t out_end; ///< End postition of fade out.
283     uint8_t out_start; ///< Start position of fade out.
284     uint8_t in_end; ///< End position of fade in.
285 schoenebeck 2 uint8_t in_start; ///< Start position of fade in.
286 schoenebeck 345 #else // little endian
287     uint8_t in_start; ///< Start position of fade in.
288 schoenebeck 2 uint8_t in_end; ///< End position of fade in.
289     uint8_t out_start; ///< Start position of fade out.
290     uint8_t out_end; ///< End postition of fade out.
291     #endif // WORDS_BIGENDIAN
292     };
293    
294 schoenebeck 24 /** Reflects the current playback state for a sample. */
295     struct playback_state_t {
296     unsigned long position; ///< Current position within the sample.
297     bool reverse; ///< If playback direction is currently backwards (in case there is a pingpong or reverse loop defined).
298     unsigned long loop_cycles_left; ///< How many times the loop has still to be passed, this value will be decremented with each loop cycle.
299     };
300    
301 schoenebeck 515 /**
302     * @brief Used for indicating the progress of a certain task.
303     *
304     * The function pointer argument has to be supplied with a valid
305     * function of the given signature which will then be called on
306 schoenebeck 516 * progress changes. An equivalent progress_t structure will be passed
307     * back as argument to the callback function on each progress change.
308     * The factor field of the supplied progress_t structure will then
309     * reflect the current progress as value between 0.0 and 1.0. You might
310     * want to use the custom field for data needed in your callback
311     * function.
312 schoenebeck 515 */
313     struct progress_t {
314 schoenebeck 516 void (*callback)(progress_t*); ///< Callback function pointer which has to be assigned to a function for progress notification.
315     float factor; ///< Reflects current progress as value between 0.0 and 1.0.
316     void* custom; ///< This pointer can be used for arbitrary data.
317     float __range_min; ///< Only for internal usage, do not modify!
318     float __range_max; ///< Only for internal usage, do not modify!
319 schoenebeck 515 progress_t();
320     };
321    
322 schoenebeck 2 // just symbol prototyping
323     class File;
324     class Instrument;
325     class Sample;
326 capela 310 class Region;
327 schoenebeck 929 class Group;
328 schoenebeck 2
329 schoenebeck 1093 /** @brief Encapsulates articulation information of a dimension region.
330 schoenebeck 2 *
331     * Every Gigasampler Instrument has at least one dimension region
332     * (exactly then when it has no dimension defined).
333     *
334     * Gigasampler provides three Envelope Generators and Low Frequency
335     * Oscillators:
336     *
337     * - EG1 and LFO1, both controlling sample amplitude
338     * - EG2 and LFO2, both controlling filter cutoff frequency
339     * - EG3 and LFO3, both controlling sample pitch
340     */
341     class DimensionRegion : protected DLS::Sampler {
342     public:
343 persson 1070 uint8_t VelocityUpperLimit; ///< Defines the upper velocity value limit of a velocity split (only if an user defined limit was set, thus a value not equal to 128/NumberOfSplits, else this value is 0). Only for gig2, otherwise the DimensionUpperLimts are used instead.
344 schoenebeck 2 Sample* pSample; ///< Points to the Sample which is assigned to the dimension region.
345     // Sample Amplitude EG/LFO
346     uint16_t EG1PreAttack; ///< Preattack value of the sample amplitude EG (0 - 1000 permille).
347     double EG1Attack; ///< Attack time of the sample amplitude EG (0.000 - 60.000s).
348     double EG1Decay1; ///< Decay time of the sample amplitude EG (0.000 - 60.000s).
349     double EG1Decay2; ///< Only if <i>EG1InfiniteSustain == false</i>: 2nd decay stage time of the sample amplitude EG (0.000 - 60.000s).
350     bool EG1InfiniteSustain; ///< If <i>true</i>, instead of going into Decay2 phase, Decay1 level will be hold until note will be released.
351     uint16_t EG1Sustain; ///< Sustain value of the sample amplitude EG (0 - 1000 permille).
352     double EG1Release; ///< Release time of the sample amplitude EG (0.000 - 60.000s).
353     bool EG1Hold; ///< If <i>true</i>, Decay1 stage should be postponed until the sample reached the sample loop start.
354     eg1_ctrl_t EG1Controller; ///< MIDI Controller which has influence on sample amplitude EG parameters (attack, decay, release).
355     bool EG1ControllerInvert; ///< Invert values coming from defined EG1 controller.
356 schoenebeck 36 uint8_t EG1ControllerAttackInfluence; ///< Amount EG1 Controller has influence on the EG1 Attack time (0 - 3, where 0 means off).
357     uint8_t EG1ControllerDecayInfluence; ///< Amount EG1 Controller has influence on the EG1 Decay time (0 - 3, where 0 means off).
358     uint8_t EG1ControllerReleaseInfluence; ///< Amount EG1 Controller has influence on the EG1 Release time (0 - 3, where 0 means off).
359 schoenebeck 2 double LFO1Frequency; ///< Frequency of the sample amplitude LFO (0.10 - 10.00 Hz).
360     uint16_t LFO1InternalDepth; ///< Firm pitch of the sample amplitude LFO (0 - 1200 cents).
361     uint16_t LFO1ControlDepth; ///< Controller depth influencing sample amplitude LFO pitch (0 - 1200 cents).
362     lfo1_ctrl_t LFO1Controller; ///< MIDI Controller which controls sample amplitude LFO.
363     bool LFO1FlipPhase; ///< Inverts phase of the sample amplitude LFO wave.
364     bool LFO1Sync; ///< If set to <i>true</i> only one LFO should be used for all voices.
365     // Filter Cutoff Frequency EG/LFO
366     uint16_t EG2PreAttack; ///< Preattack value of the filter cutoff EG (0 - 1000 permille).
367     double EG2Attack; ///< Attack time of the filter cutoff EG (0.000 - 60.000s).
368     double EG2Decay1; ///< Decay time of the filter cutoff EG (0.000 - 60.000s).
369     double EG2Decay2; ///< Only if <i>EG2InfiniteSustain == false</i>: 2nd stage decay time of the filter cutoff EG (0.000 - 60.000s).
370     bool EG2InfiniteSustain; ///< If <i>true</i>, instead of going into Decay2 phase, Decay1 level will be hold until note will be released.
371     uint16_t EG2Sustain; ///< Sustain value of the filter cutoff EG (0 - 1000 permille).
372     double EG2Release; ///< Release time of the filter cutoff EG (0.000 - 60.000s).
373     eg2_ctrl_t EG2Controller; ///< MIDI Controller which has influence on filter cutoff EG parameters (attack, decay, release).
374     bool EG2ControllerInvert; ///< Invert values coming from defined EG2 controller.
375 schoenebeck 36 uint8_t EG2ControllerAttackInfluence; ///< Amount EG2 Controller has influence on the EG2 Attack time (0 - 3, where 0 means off).
376     uint8_t EG2ControllerDecayInfluence; ///< Amount EG2 Controller has influence on the EG2 Decay time (0 - 3, where 0 means off).
377     uint8_t EG2ControllerReleaseInfluence; ///< Amount EG2 Controller has influence on the EG2 Release time (0 - 3, where 0 means off).
378 schoenebeck 2 double LFO2Frequency; ///< Frequency of the filter cutoff LFO (0.10 - 10.00 Hz).
379     uint16_t LFO2InternalDepth; ///< Firm pitch of the filter cutoff LFO (0 - 1200 cents).
380     uint16_t LFO2ControlDepth; ///< Controller depth influencing filter cutoff LFO pitch (0 - 1200).
381     lfo2_ctrl_t LFO2Controller; ///< MIDI Controlle which controls the filter cutoff LFO.
382     bool LFO2FlipPhase; ///< Inverts phase of the filter cutoff LFO wave.
383     bool LFO2Sync; ///< If set to <i>true</i> only one LFO should be used for all voices.
384     // Sample Pitch EG/LFO
385     double EG3Attack; ///< Attack time of the sample pitch EG (0.000 - 10.000s).
386     int16_t EG3Depth; ///< Depth of the sample pitch EG (-1200 - +1200).
387     double LFO3Frequency; ///< Frequency of the sample pitch LFO (0.10 - 10.00 Hz).
388     int16_t LFO3InternalDepth; ///< Firm depth of the sample pitch LFO (-1200 - +1200 cents).
389     int16_t LFO3ControlDepth; ///< Controller depth of the sample pitch LFO (-1200 - +1200 cents).
390     lfo3_ctrl_t LFO3Controller; ///< MIDI Controller which controls the sample pitch LFO.
391     bool LFO3Sync; ///< If set to <i>true</i> only one LFO should be used for all voices.
392     // Filter
393     bool VCFEnabled; ///< If filter should be used.
394     vcf_type_t VCFType; ///< Defines the general filter characteristic (lowpass, highpass, bandpass, etc.).
395     vcf_cutoff_ctrl_t VCFCutoffController; ///< Specifies which external controller has influence on the filter cutoff frequency.
396 persson 728 bool VCFCutoffControllerInvert; ///< Inverts values coming from the defined cutoff controller
397 schoenebeck 2 uint8_t VCFCutoff; ///< Max. cutoff frequency.
398     curve_type_t VCFVelocityCurve; ///< Defines a transformation curve for the incoming velocity values, affecting the VCF.
399 persson 728 uint8_t VCFVelocityScale; ///< (0-127) Amount velocity controls VCF cutoff frequency (only if no other VCF cutoff controller is defined, otherwise this is the minimum cutoff).
400 schoenebeck 2 uint8_t VCFVelocityDynamicRange; ///< 0x04 = lowest, 0x00 = highest
401     uint8_t VCFResonance; ///< Firm internal filter resonance weight.
402     bool VCFResonanceDynamic; ///< If <i>true</i>: Increases the resonance Q according to changes of controllers that actually control the VCF cutoff frequency (EG2, ext. VCF MIDI controller).
403     vcf_res_ctrl_t VCFResonanceController; ///< Specifies which external controller has influence on the filter resonance Q.
404     bool VCFKeyboardTracking; ///< If <i>true</i>: VCF cutoff frequence will be dependend to the note key position relative to the defined breakpoint value.
405     uint8_t VCFKeyboardTrackingBreakpoint; ///< See VCFKeyboardTracking (0 - 127).
406     // Key Velocity Transformations
407 schoenebeck 231 curve_type_t VelocityResponseCurve; ///< Defines a transformation curve to the incoming velocity values affecting amplitude (usually you don't have to interpret this parameter, use GetVelocityAttenuation() instead).
408     uint8_t VelocityResponseDepth; ///< Dynamic range of velocity affecting amplitude (0 - 4) (usually you don't have to interpret this parameter, use GetVelocityAttenuation() instead).
409     uint8_t VelocityResponseCurveScaling; ///< 0 - 127 (usually you don't have to interpret this parameter, use GetVelocityAttenuation() instead)
410 schoenebeck 2 curve_type_t ReleaseVelocityResponseCurve; ///< Defines a transformation curve to the incoming release veloctiy values affecting envelope times.
411     uint8_t ReleaseVelocityResponseDepth; ///< Dynamic range of release velocity affecting envelope time (0 - 4).
412     uint8_t ReleaseTriggerDecay; ///< 0 - 8
413     // Mix / Layer
414     crossfade_t Crossfade;
415     bool PitchTrack; ///< If <i>true</i>: sample will be pitched according to the key position (this will be disabled for drums for example).
416     dim_bypass_ctrl_t DimensionBypass; ///< If defined, the MIDI controller can switch on/off the dimension in realtime.
417     int8_t Pan; ///< Panorama / Balance (-64..0..63 <-> left..middle..right)
418     bool SelfMask; ///< If <i>true</i>: high velocity notes will stop low velocity notes at the same note, with that you can save voices that wouldn't be audible anyway.
419 schoenebeck 36 attenuation_ctrl_t AttenuationController; ///< MIDI Controller which has influence on the volume level of the sample (or entire sample group).
420     bool InvertAttenuationController; ///< Inverts the values coming from the defined Attenuation Controller.
421     uint8_t AttenuationControllerThreshold;///< 0-127
422 schoenebeck 2 uint8_t ChannelOffset; ///< Audio output where the audio signal of the dimension region should be routed to (0 - 9).
423     bool SustainDefeat; ///< If <i>true</i>: Sustain pedal will not hold a note.
424     bool MSDecode; ///< Gigastudio flag: defines if Mid Side Recordings should be decoded.
425     uint16_t SampleStartOffset; ///< Number of samples the sample start should be moved (0 - 2000).
426 persson 406 double SampleAttenuation; ///< Sample volume (calculated from DLS::Sampler::Gain)
427 persson 1070 uint8_t DimensionUpperLimits[8]; ///< gig3: defines the upper limit of the dimension values for this dimension region
428 persson 406
429 schoenebeck 2 // derived attributes from DLS::Sampler
430     DLS::Sampler::UnityNote;
431     DLS::Sampler::FineTune;
432     DLS::Sampler::Gain;
433     DLS::Sampler::SampleLoops;
434     DLS::Sampler::pSampleLoops;
435    
436 schoenebeck 809 // own methods
437 schoenebeck 16 double GetVelocityAttenuation(uint8_t MIDIKeyVelocity);
438 persson 613 double GetVelocityRelease(uint8_t MIDIKeyVelocity);
439 persson 728 double GetVelocityCutoff(uint8_t MIDIKeyVelocity);
440 schoenebeck 1155 // derived methods
441     DLS::Sampler::AddSampleLoop;
442     DLS::Sampler::DeleteSampleLoop;
443 schoenebeck 809 // overridden methods
444     virtual void UpdateChunks();
445 schoenebeck 16 protected:
446 persson 858 uint8_t* VelocityTable; ///< For velocity dimensions with custom defined zone ranges only: used for fast converting from velocity MIDI value to dimension bit number.
447 schoenebeck 2 DimensionRegion(RIFF::List* _3ewl);
448 schoenebeck 16 ~DimensionRegion();
449     friend class Region;
450     private:
451 schoenebeck 36 typedef enum { ///< Used to decode attenuation, EG1 and EG2 controller
452     _lev_ctrl_none = 0x00,
453     _lev_ctrl_modwheel = 0x03, ///< Modulation Wheel (MIDI Controller 1)
454     _lev_ctrl_breath = 0x05, ///< Breath Controller (Coarse, MIDI Controller 2)
455     _lev_ctrl_foot = 0x07, ///< Foot Pedal (Coarse, MIDI Controller 4)
456     _lev_ctrl_effect1 = 0x0d, ///< Effect Controller 1 (Coarse, MIDI Controller 12)
457     _lev_ctrl_effect2 = 0x0f, ///< Effect Controller 2 (Coarse, MIDI Controller 13)
458     _lev_ctrl_genpurpose1 = 0x11, ///< General Purpose Controller 1 (Slider, MIDI Controller 16)
459     _lev_ctrl_genpurpose2 = 0x13, ///< General Purpose Controller 2 (Slider, MIDI Controller 17)
460     _lev_ctrl_genpurpose3 = 0x15, ///< General Purpose Controller 3 (Slider, MIDI Controller 18)
461     _lev_ctrl_genpurpose4 = 0x17, ///< General Purpose Controller 4 (Slider, MIDI Controller 19)
462     _lev_ctrl_portamentotime = 0x0b, ///< Portamento Time (Coarse, MIDI Controller 5)
463     _lev_ctrl_sustainpedal = 0x01, ///< Sustain Pedal (MIDI Controller 64)
464     _lev_ctrl_portamento = 0x19, ///< Portamento (MIDI Controller 65)
465     _lev_ctrl_sostenutopedal = 0x1b, ///< Sostenuto Pedal (MIDI Controller 66)
466     _lev_ctrl_softpedal = 0x09, ///< Soft Pedal (MIDI Controller 67)
467     _lev_ctrl_genpurpose5 = 0x1d, ///< General Purpose Controller 5 (Button, MIDI Controller 80)
468     _lev_ctrl_genpurpose6 = 0x1f, ///< General Purpose Controller 6 (Button, MIDI Controller 81)
469     _lev_ctrl_genpurpose7 = 0x21, ///< General Purpose Controller 7 (Button, MIDI Controller 82)
470     _lev_ctrl_genpurpose8 = 0x23, ///< General Purpose Controller 8 (Button, MIDI Controller 83)
471     _lev_ctrl_effect1depth = 0x25, ///< Effect 1 Depth (MIDI Controller 91)
472     _lev_ctrl_effect2depth = 0x27, ///< Effect 2 Depth (MIDI Controller 92)
473     _lev_ctrl_effect3depth = 0x29, ///< Effect 3 Depth (MIDI Controller 93)
474     _lev_ctrl_effect4depth = 0x2b, ///< Effect 4 Depth (MIDI Controller 94)
475     _lev_ctrl_effect5depth = 0x2d, ///< Effect 5 Depth (MIDI Controller 95)
476     _lev_ctrl_channelaftertouch = 0x2f, ///< Channel Key Pressure
477     _lev_ctrl_velocity = 0xff ///< Key Velocity
478 schoenebeck 55 } _lev_ctrl_t;
479 schoenebeck 16 typedef std::map<uint32_t, double*> VelocityTableMap;
480    
481     static uint Instances; ///< Number of DimensionRegion instances.
482     static VelocityTableMap* pVelocityTables; ///< Contains the tables corresponding to the various velocity parameters (VelocityResponseCurve and VelocityResponseDepth).
483     double* pVelocityAttenuationTable; ///< Points to the velocity table corresponding to the velocity parameters of this DimensionRegion.
484 persson 613 double* pVelocityReleaseTable; ///< Points to the velocity table corresponding to the release velocity parameters of this DimensionRegion
485 persson 728 double* pVelocityCutoffTable; ///< Points to the velocity table corresponding to the filter velocity parameters of this DimensionRegion
486 schoenebeck 55
487 schoenebeck 36 leverage_ctrl_t DecodeLeverageController(_lev_ctrl_t EncodedController);
488 schoenebeck 809 _lev_ctrl_t EncodeLeverageController(leverage_ctrl_t DecodedController);
489 persson 613 double* GetVelocityTable(curve_type_t curveType, uint8_t depth, uint8_t scaling);
490 schoenebeck 308 double* CreateVelocityTable(curve_type_t curveType, uint8_t depth, uint8_t scaling);
491 schoenebeck 2 };
492    
493 schoenebeck 809 /** @brief Encapsulates sample waves used for playback.
494     *
495     * In case you created a new sample with File::AddSample(), you should
496     * first update all attributes with the desired meta informations
497     * (amount of channels, bit depth, sample rate, etc.), then call
498     * Resize() with the desired sample size, followed by File::Save(), this
499     * will create the mandatory RIFF chunk which will hold the sample wave
500     * data and / or resize the file so you will be able to Write() the
501     * sample data directly to disk.
502 schoenebeck 1154 *
503     * @e Caution: for gig synthesis, most looping relevant information are
504     * retrieved from the respective DimensionRegon instead from the Sample
505     * itself. This was made for allowing different loop definitions for the
506     * same sample under different conditions.
507 schoenebeck 809 */
508 schoenebeck 2 class Sample : public DLS::Sample {
509     public:
510     uint32_t Manufacturer; ///< Specifies the MIDI Manufacturer's Association (MMA) Manufacturer code for the sampler intended to receive this file's waveform. If no particular manufacturer is to be specified, a value of 0 should be used.
511     uint32_t Product; ///< Specifies the MIDI model ID defined by the manufacturer corresponding to the Manufacturer field. If no particular manufacturer's product is to be specified, a value of 0 should be used.
512 schoenebeck 809 uint32_t SamplePeriod; ///< Specifies the duration of time that passes during the playback of one sample in nanoseconds (normally equal to 1 / Samples Per Second, where Samples Per Second is the value found in the format chunk), don't bother to update this attribute, it won't be saved.
513 schoenebeck 2 uint32_t MIDIUnityNote; ///< Specifies the musical note at which the sample will be played at it's original sample rate.
514 schoenebeck 21 uint32_t FineTune; ///< Specifies the fraction of a semitone up from the specified MIDI unity note field. A value of 0x80000000 means 1/2 semitone (50 cents) and a value of 0x00000000 means no fine tuning between semitones.
515 schoenebeck 2 smpte_format_t SMPTEFormat; ///< Specifies the Society of Motion Pictures and Television E time format used in the following <i>SMPTEOffset</i> field. If a value of 0 is set, <i>SMPTEOffset</i> should also be set to 0.
516     uint32_t SMPTEOffset; ///< The SMPTE Offset value specifies the time offset to be used for the synchronization / calibration to the first sample in the waveform. This value uses a format of 0xhhmmssff where hh is a signed value that specifies the number of hours (-23 to 23), mm is an unsigned value that specifies the number of minutes (0 to 59), ss is an unsigned value that specifies the number of seconds (0 to 59) and ff is an unsigned value that specifies the number of frames (0 to -1).
517 schoenebeck 1154 uint32_t Loops; ///< @e Caution: Use the respective field in the DimensionRegion instead of this one! (Intended purpose: Number of defined sample loops. So far only seen single loops in gig files - please report if you encounter more!)
518 schoenebeck 21 uint32_t LoopID; ///< Specifies the unique ID that corresponds to one of the defined cue points in the cue point list (only if Loops > 0), as the Gigasampler format only allows one loop definition at the moment, this attribute isn't really useful for anything.
519 schoenebeck 1154 loop_type_t LoopType; ///< @e Caution: Use the respective field in the DimensionRegion instead of this one! (Intended purpose: The type field defines how the waveform samples will be looped.)
520     uint32_t LoopStart; ///< @e Caution: Use the respective field in the DimensionRegion instead of this one! (Intended purpose: The start value specifies the offset [in sample points] in the waveform data of the first sample to be played in the loop [only if Loops > 0].)
521     uint32_t LoopEnd; ///< @e Caution: Use the respective field in the DimensionRegion instead of this one! (Intended purpose: The end value specifies the offset [in sample points] in the waveform data which represents the end of the loop [only if Loops > 0].)
522     uint32_t LoopSize; ///< @e Caution: Use the respective fields in the DimensionRegion instead of this one! (Intended purpose: Length of the looping area [in sample points] which is equivalent to @code LoopEnd - LoopStart @endcode.)
523     uint32_t LoopFraction; ///< The fractional value specifies a fraction of a sample at which to loop. This allows a loop to be fine tuned at a resolution greater than one sample. A value of 0 means no fraction, a value of 0x80000000 means 1/2 of a sample length. 0xFFFFFFFF is the smallest fraction of a sample that can be represented.
524     uint32_t LoopPlayCount; ///< Number of times the loop should be played (a value of 0 = infinite).
525 schoenebeck 2 bool Compressed; ///< If the sample wave is compressed (probably just interesting for instrument and sample editors, as this library already handles the decompression in it's sample access methods anyway).
526 persson 437 uint32_t TruncatedBits; ///< For 24-bit compressed samples only: number of bits truncated during compression (0, 4 or 6)
527     bool Dithered; ///< For 24-bit compressed samples only: if dithering was used during compression with bit reduction
528 schoenebeck 2
529     // own methods
530     buffer_t LoadSampleData();
531     buffer_t LoadSampleData(unsigned long SampleCount);
532     buffer_t LoadSampleDataWithNullSamplesExtension(uint NullSamplesCount);
533     buffer_t LoadSampleDataWithNullSamplesExtension(unsigned long SampleCount, uint NullSamplesCount);
534     buffer_t GetCache();
535 schoenebeck 384 // own static methods
536     static buffer_t CreateDecompressionBuffer(unsigned long MaxReadSize);
537     static void DestroyDecompressionBuffer(buffer_t& DecompressionBuffer);
538 schoenebeck 2 // overridden methods
539     void ReleaseSampleData();
540 schoenebeck 809 void Resize(int iNewSize);
541 schoenebeck 2 unsigned long SetPos(unsigned long SampleCount, RIFF::stream_whence_t Whence = RIFF::stream_start);
542     unsigned long GetPos();
543 schoenebeck 384 unsigned long Read(void* pBuffer, unsigned long SampleCount, buffer_t* pExternalDecompressionBuffer = NULL);
544 persson 864 unsigned long ReadAndLoop(void* pBuffer, unsigned long SampleCount, playback_state_t* pPlaybackState, DimensionRegion* pDimRgn, buffer_t* pExternalDecompressionBuffer = NULL);
545 schoenebeck 809 unsigned long Write(void* pBuffer, unsigned long SampleCount);
546 schoenebeck 930 Group* GetGroup() const;
547 schoenebeck 809 virtual void UpdateChunks();
548 schoenebeck 2 protected:
549     static unsigned int Instances; ///< Number of instances of class Sample.
550 schoenebeck 384 static buffer_t InternalDecompressionBuffer; ///< Buffer used for decompression as well as for truncation of 24 Bit -> 16 Bit samples.
551 schoenebeck 930 Group* pGroup; ///< pointer to the Group this sample belongs to (always not-NULL)
552 schoenebeck 2 unsigned long FrameOffset; ///< Current offset (sample points) in current sample frame (for decompression only).
553     unsigned long* FrameTable; ///< For positioning within compressed samples only: stores the offset values for each frame.
554     unsigned long SamplePos; ///< For compressed samples only: stores the current position (in sample points).
555 persson 365 unsigned long SamplesInLastFrame; ///< For compressed samples only: length of the last sample frame.
556     unsigned long WorstCaseFrameSize; ///< For compressed samples only: size (in bytes) of the largest possible sample frame.
557     unsigned long SamplesPerFrame; ///< For compressed samples only: number of samples in a full sample frame.
558 schoenebeck 2 buffer_t RAMCache; ///< Buffers samples (already uncompressed) in RAM.
559 persson 666 unsigned long FileNo; ///< File number (> 0 when sample is stored in an extension file, 0 when it's in the gig)
560 schoenebeck 809 RIFF::Chunk* pCk3gix;
561     RIFF::Chunk* pCkSmpl;
562 schoenebeck 2
563 persson 666 Sample(File* pFile, RIFF::List* waveList, unsigned long WavePoolOffset, unsigned long fileNo = 0);
564 schoenebeck 2 ~Sample();
565 persson 365
566     // Guess size (in bytes) of a compressed sample
567     inline unsigned long GuessSize(unsigned long samples) {
568     // 16 bit: assume all frames are compressed - 1 byte
569     // per sample and 5 bytes header per 2048 samples
570    
571     // 24 bit: assume next best compression rate - 1.5
572     // bytes per sample and 13 bytes header per 256
573     // samples
574     const unsigned long size =
575     BitDepth == 24 ? samples + (samples >> 1) + (samples >> 8) * 13
576     : samples + (samples >> 10) * 5;
577     // Double for stereo and add one worst case sample
578     // frame
579     return (Channels == 2 ? size << 1 : size) + WorstCaseFrameSize;
580     }
581 schoenebeck 384
582     // Worst case amount of sample points that can be read with the
583     // given decompression buffer.
584     inline unsigned long WorstCaseMaxSamples(buffer_t* pDecompressionBuffer) {
585     return (unsigned long) ((float)pDecompressionBuffer->Size / (float)WorstCaseFrameSize * (float)SamplesPerFrame);
586     }
587 schoenebeck 2 private:
588     void ScanCompressedSample();
589     friend class File;
590     friend class Region;
591 schoenebeck 930 friend class Group; // allow to modify protected member pGroup
592 schoenebeck 2 };
593    
594     // TODO: <3dnl> list not used yet - not important though (just contains optional descriptions for the dimensions)
595     /** Defines <i>Region</i> information of an <i>Instrument</i>. */
596     class Region : public DLS::Region {
597     public:
598 schoenebeck 809 unsigned int Dimensions; ///< Number of defined dimensions, do not alter!
599 schoenebeck 926 dimension_def_t pDimensionDefinitions[8]; ///< Defines the five (gig2) or eight (gig3) possible dimensions (the dimension's controller and number of bits/splits). Use AddDimension() and DeleteDimension() to create a new dimension or delete an existing one.
600 schoenebeck 809 uint32_t DimensionRegions; ///< Total number of DimensionRegions this Region contains, do not alter!
601 schoenebeck 926 DimensionRegion* pDimensionRegions[256]; ///< Pointer array to the 32 (gig2) or 256 (gig3) possible dimension regions (reflects NULL for dimension regions not in use). Avoid to access the array directly and better use GetDimensionRegionByValue() instead, but of course in some cases it makes sense to use the array (e.g. iterating through all DimensionRegions). Use AddDimension() and DeleteDimension() to create a new dimension or delete an existing one (which will create or delete the respective dimension region(s) automatically).
602 schoenebeck 809 unsigned int Layers; ///< Amount of defined layers (1 - 32). A value of 1 actually means no layering, a value > 1 means there is Layer dimension. The same information can of course also be obtained by accessing pDimensionDefinitions. Do not alter this value!
603 schoenebeck 2
604 schoenebeck 347 DimensionRegion* GetDimensionRegionByValue(const uint DimValues[8]);
605     DimensionRegion* GetDimensionRegionByBit(const uint8_t DimBits[8]);
606 schoenebeck 2 Sample* GetSample();
607 schoenebeck 809 void AddDimension(dimension_def_t* pDimDef);
608     void DeleteDimension(dimension_def_t* pDimDef);
609     virtual void UpdateChunks();
610 schoenebeck 2 protected:
611     Region(Instrument* pInstrument, RIFF::List* rgnList);
612     void LoadDimensionRegions(RIFF::List* rgn);
613 persson 858 void UpdateVelocityTable();
614 schoenebeck 515 Sample* GetSampleFromWavePool(unsigned int WavePoolTableIndex, progress_t* pProgress = NULL);
615 schoenebeck 2 ~Region();
616     friend class Instrument;
617     };
618    
619     /** Provides all neccessary information for the synthesis of an <i>Instrument</i>. */
620     class Instrument : protected DLS::Instrument {
621     public:
622     // derived attributes from DLS::Resource
623     DLS::Resource::pInfo;
624     DLS::Resource::pDLSID;
625     // derived attributes from DLS::Instrument
626     DLS::Instrument::IsDrum;
627     DLS::Instrument::MIDIBank;
628     DLS::Instrument::MIDIBankCoarse;
629     DLS::Instrument::MIDIBankFine;
630     DLS::Instrument::MIDIProgram;
631     DLS::Instrument::Regions;
632     // own attributes
633     int32_t Attenuation; ///< in dB
634     uint16_t EffectSend;
635     int16_t FineTune; ///< in cents
636     uint16_t PitchbendRange; ///< Number of semitones pitchbend controller can pitch (default is 2).
637     bool PianoReleaseMode;
638     range_t DimensionKeyRange; ///< 0-127 (where 0 means C1 and 127 means G9)
639    
640    
641     // derived methods from DLS::Resource
642     DLS::Resource::GetParent;
643 persson 1102 // derived methods from DLS::Instrument
644     DLS::Instrument::MoveRegion;
645 schoenebeck 2 // overridden methods
646     Region* GetFirstRegion();
647     Region* GetNextRegion();
648 schoenebeck 809 Region* AddRegion();
649     void DeleteRegion(Region* pRegion);
650     virtual void UpdateChunks();
651 schoenebeck 2 // own methods
652     Region* GetRegion(unsigned int Key);
653     protected:
654     Region* RegionKeyTable[128]; ///< fast lookup for the corresponding Region of a MIDI key
655    
656 schoenebeck 515 Instrument(File* pFile, RIFF::List* insList, progress_t* pProgress = NULL);
657 schoenebeck 2 ~Instrument();
658 schoenebeck 809 void UpdateRegionKeyTable();
659 schoenebeck 2 friend class File;
660     };
661    
662 schoenebeck 929 /** @brief Group of Gigasampler objects
663     *
664     * Groups help to organize a huge collection of Gigasampler objects.
665     * Groups are not concerned at all for the synthesis, but they help
666     * sound library developers when working on complex instruments with an
667     * instrument editor (as long as that instrument editor supports it ;-).
668     *
669     * At the moment, it seems as only samples can be grouped together in
670     * the Gigasampler format yet. If this is false in the meantime, please
671     * tell us !
672 schoenebeck 930 *
673     * A sample is always assigned to exactly one Group. This also means
674     * there is always at least one Group in a .gig file, no matter if you
675     * created one yet or not.
676 schoenebeck 929 */
677     class Group {
678     public:
679     String Name; ///< Stores the name of this Group.
680 schoenebeck 930
681     Sample* GetFirstSample();
682     Sample* GetNextSample();
683     void AddSample(Sample* pSample);
684 schoenebeck 929 protected:
685 schoenebeck 930 Group(File* file, RIFF::Chunk* ck3gnm);
686 schoenebeck 929 virtual ~Group();
687     virtual void UpdateChunks();
688 schoenebeck 930 void MoveAll();
689 schoenebeck 929 friend class File;
690     private:
691 schoenebeck 930 File* pFile;
692 schoenebeck 929 RIFF::Chunk* pNameChunk;
693     };
694    
695 schoenebeck 2 /** Parses Gigasampler files and provides abstract access to the data. */
696     class File : protected DLS::File {
697     public:
698     // derived attributes from DLS::Resource
699     DLS::Resource::pInfo;
700     DLS::Resource::pDLSID;
701     // derived attributes from DLS::File
702     DLS::File::pVersion;
703     DLS::File::Instruments;
704    
705     // derived methods from DLS::Resource
706     DLS::Resource::GetParent;
707 schoenebeck 809 // derived methods from DLS::File
708     DLS::File::Save;
709 schoenebeck 2 // overridden methods
710 schoenebeck 809 File();
711 schoenebeck 2 File(RIFF::File* pRIFF);
712 schoenebeck 515 Sample* GetFirstSample(progress_t* pProgress = NULL); ///< Returns a pointer to the first <i>Sample</i> object of the file, <i>NULL</i> otherwise.
713 schoenebeck 2 Sample* GetNextSample(); ///< Returns a pointer to the next <i>Sample</i> object of the file, <i>NULL</i> otherwise.
714 schoenebeck 809 Sample* AddSample();
715     void DeleteSample(Sample* pSample);
716 schoenebeck 929 Instrument* GetFirstInstrument(); ///< Returns a pointer to the first <i>Instrument</i> object of the file, <i>NULL</i> otherwise.
717 schoenebeck 2 Instrument* GetNextInstrument(); ///< Returns a pointer to the next <i>Instrument</i> object of the file, <i>NULL</i> otherwise.
718 schoenebeck 515 Instrument* GetInstrument(uint index, progress_t* pProgress = NULL);
719 schoenebeck 809 Instrument* AddInstrument();
720     void DeleteInstrument(Instrument* pInstrument);
721 schoenebeck 929 Group* GetFirstGroup(); ///< Returns a pointer to the first <i>Group</i> object of the file, <i>NULL</i> otherwise.
722     Group* GetNextGroup(); ///< Returns a pointer to the next <i>Group</i> object of the file, <i>NULL</i> otherwise.
723     Group* GetGroup(uint index);
724     Group* AddGroup();
725     void DeleteGroup(Group* pGroup);
726 schoenebeck 1081 void DeleteGroupOnly(Group* pGroup);
727 schoenebeck 929 virtual ~File();
728 schoenebeck 1098 virtual void UpdateChunks();
729 schoenebeck 2 protected:
730 schoenebeck 823 // overridden protected methods from DLS::File
731     virtual void LoadSamples();
732     virtual void LoadInstruments();
733 schoenebeck 929 virtual void LoadGroups();
734 schoenebeck 823 // own protected methods
735     virtual void LoadSamples(progress_t* pProgress);
736     virtual void LoadInstruments(progress_t* pProgress);
737 schoenebeck 2 friend class Region;
738 schoenebeck 929 friend class Sample;
739 schoenebeck 930 friend class Group; // so Group can access protected member pRIFF
740 schoenebeck 929 private:
741 persson 1180 static const DLS::Info::FixedStringLength FixedStringLengths[];
742 schoenebeck 929 std::list<Group*>* pGroups;
743     std::list<Group*>::iterator GroupsIterator;
744 schoenebeck 2 };
745    
746 schoenebeck 1093 /**
747     * Will be thrown whenever a gig specific error occurs while trying to
748     * access a Gigasampler File. Note: In your application you should
749     * better catch for RIFF::Exception rather than this one, except you
750     * explicitly want to catch and handle gig::Exception, DLS::Exception
751     * and RIFF::Exception independently, which usually shouldn't be
752     * necessary though.
753     */
754 schoenebeck 2 class Exception : public DLS::Exception {
755     public:
756     Exception(String Message);
757     void PrintMessage();
758     };
759    
760 schoenebeck 518 String libraryName();
761     String libraryVersion();
762    
763 schoenebeck 2 } // namespace gig
764    
765     #endif // __GIG_H__

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