/** * Reverb for the OpenAL cross platform audio library * Copyright (C) 2008-2009 by Christopher Fitzgerald. * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., 59 Temple Place - Suite 330, * Boston, MA 02111-1307, USA. * Or go to http://www.gnu.org/copyleft/lgpl.html */ #include "config.h" #include #include #include "AL/al.h" #include "AL/alc.h" #include "alMain.h" #include "alAuxEffectSlot.h" #include "alEffect.h" #include "alError.h" #include "alu.h" typedef struct DelayLine { // The delay lines use sample lengths that are powers of 2 to allow // bitmasking instead of modulus wrapping. ALuint Mask; ALfloat *Line; } DelayLine; typedef struct ALverbState { // Must be first in all effects! ALeffectState state; // All delay lines are allocated as a single buffer to reduce memory // fragmentation and management code. ALfloat *SampleBuffer; // Master effect low-pass filter (2 chained 1-pole filters). FILTER LpFilter; ALfloat LpHistory[2]; // Initial effect delay and decorrelation. DelayLine Delay; // The tap points for the initial delay. First tap goes to early // reflections, the last four decorrelate to late reverb. ALuint Tap[5]; struct { // Total gain for early reflections. ALfloat Gain; // Early reflections are done with 4 delay lines. ALfloat Coeff[4]; DelayLine Delay[4]; ALuint Offset[4]; // The gain for each output channel based on 3D panning. ALfloat PanGain[OUTPUTCHANNELS]; } Early; struct { // Total gain for late reverb. ALfloat Gain; // Attenuation to compensate for modal density and decay rate. ALfloat DensityGain; // The feed-back and feed-forward all-pass coefficient. ALfloat ApFeedCoeff; // Mixing matrix coefficient. ALfloat MixCoeff; // Late reverb has 4 parallel all-pass filters. ALfloat ApCoeff[4]; DelayLine ApDelay[4]; ALuint ApOffset[4]; // In addition to 4 cyclical delay lines. ALfloat Coeff[4]; DelayLine Delay[4]; ALuint Offset[4]; // The cyclical delay lines are 1-pole low-pass filtered. ALfloat LpCoeff[4]; ALfloat LpSample[4]; // The gain for each output channel based on 3D panning. ALfloat PanGain[OUTPUTCHANNELS]; } Late; // The current read offset for all delay lines. ALuint Offset; } ALverbState; // All delay line lengths are specified in seconds. // The lengths of the early delay lines. static const ALfloat EARLY_LINE_LENGTH[4] = { 0.0015f, 0.0045f, 0.0135f, 0.0405f }; // The lengths of the late all-pass delay lines. static const ALfloat ALLPASS_LINE_LENGTH[4] = { 0.0151f, 0.0167f, 0.0183f, 0.0200f, }; // The lengths of the late cyclical delay lines. static const ALfloat LATE_LINE_LENGTH[4] = { 0.0211f, 0.0311f, 0.0461f, 0.0680f }; // The late cyclical delay lines have a variable length dependent on the // effect's density parameter (inverted for some reason) and this multiplier. static const ALfloat LATE_LINE_MULTIPLIER = 4.0f; // Input into the late reverb is decorrelated between four channels. Their // timings are dependent on a fraction and multiplier. See VerbUpdate() for // the calculations involved. static const ALfloat DECO_FRACTION = 1.0f / 32.0f; static const ALfloat DECO_MULTIPLIER = 2.0f; // The maximum length of initial delay for the master delay line (a sum of // the maximum early reflection and late reverb delays). static const ALfloat MASTER_LINE_LENGTH = 0.3f + 0.1f; // Find the next power of 2. Actually, this will return the input value if // it is already a power of 2. static ALuint NextPowerOf2(ALuint value) { ALuint powerOf2 = 1; if(value) { value--; while(value) { value >>= 1; powerOf2 <<= 1; } } return powerOf2; } // Basic delay line input/output routines. static __inline ALfloat DelayLineOut(DelayLine *Delay, ALuint offset) { return Delay->Line[offset&Delay->Mask]; } static __inline ALvoid DelayLineIn(DelayLine *Delay, ALuint offset, ALfloat in) { Delay->Line[offset&Delay->Mask] = in; } // Delay line output routine for early reflections. static __inline ALfloat EarlyDelayLineOut(ALverbState *State, ALuint index) { return State->Early.Coeff[index] * DelayLineOut(&State->Early.Delay[index], State->Offset - State->Early.Offset[index]); } // Given an input sample, this function produces stereo output for early // reflections. static __inline ALvoid EarlyReflection(ALverbState *State, ALfloat in, ALfloat *out) { ALfloat d[4], v, f[4]; // Obtain the decayed results of each early delay line. d[0] = EarlyDelayLineOut(State, 0); d[1] = EarlyDelayLineOut(State, 1); d[2] = EarlyDelayLineOut(State, 2); d[3] = EarlyDelayLineOut(State, 3); /* The following uses a lossless scattering junction from waveguide * theory. It actually amounts to a householder mixing matrix, which * will produce a maximally diffuse response, and means this can probably * be considered a simple feedback delay network (FDN). * N * --- * \ * v = 2/N / d_i * --- * i=1 */ v = (d[0] + d[1] + d[2] + d[3]) * 0.5f; // The junction is loaded with the input here. v += in; // Calculate the feed values for the delay lines. f[0] = v - d[0]; f[1] = v - d[1]; f[2] = v - d[2]; f[3] = v - d[3]; // Refeed the delay lines. DelayLineIn(&State->Early.Delay[0], State->Offset, f[0]); DelayLineIn(&State->Early.Delay[1], State->Offset, f[1]); DelayLineIn(&State->Early.Delay[2], State->Offset, f[2]); DelayLineIn(&State->Early.Delay[3], State->Offset, f[3]); // Output the results of the junction for all four lines. out[0] = State->Early.Gain * f[0]; out[1] = State->Early.Gain * f[1]; out[2] = State->Early.Gain * f[2]; out[3] = State->Early.Gain * f[3]; } // All-pass input/output routine for late reverb. static __inline ALfloat LateAllPassInOut(ALverbState *State, ALuint index, ALfloat in) { ALfloat out; out = State->Late.ApCoeff[index] * DelayLineOut(&State->Late.ApDelay[index], State->Offset - State->Late.ApOffset[index]); out -= (State->Late.ApFeedCoeff * in); DelayLineIn(&State->Late.ApDelay[index], State->Offset, (State->Late.ApFeedCoeff * out) + in); return out; } // Delay line output routine for late reverb. static __inline ALfloat LateDelayLineOut(ALverbState *State, ALuint index) { return State->Late.Coeff[index] * DelayLineOut(&State->Late.Delay[index], State->Offset - State->Late.Offset[index]); } // Low-pass filter input/output routine for late reverb. static __inline ALfloat LateLowPassInOut(ALverbState *State, ALuint index, ALfloat in) { State->Late.LpSample[index] = in + ((State->Late.LpSample[index] - in) * State->Late.LpCoeff[index]); return State->Late.LpSample[index]; } // Given four decorrelated input samples, this function produces stereo // output for late reverb. static __inline ALvoid LateReverb(ALverbState *State, ALfloat *in, ALfloat *out) { ALfloat d[4], f[4]; // Obtain the decayed results of the cyclical delay lines, and add the // corresponding input channels attenuated by density. Then pass the // results through the low-pass filters. d[0] = LateLowPassInOut(State, 0, (State->Late.DensityGain * in[0]) + LateDelayLineOut(State, 0)); d[1] = LateLowPassInOut(State, 1, (State->Late.DensityGain * in[1]) + LateDelayLineOut(State, 1)); d[2] = LateLowPassInOut(State, 2, (State->Late.DensityGain * in[2]) + LateDelayLineOut(State, 2)); d[3] = LateLowPassInOut(State, 3, (State->Late.DensityGain * in[3]) + LateDelayLineOut(State, 3)); // To help increase diffusion, run each line through an all-pass filter. // The order of the all-pass filters is selected so that the shortest // all-pass filter will feed the shortest delay line. d[0] = LateAllPassInOut(State, 1, d[0]); d[1] = LateAllPassInOut(State, 3, d[1]); d[2] = LateAllPassInOut(State, 0, d[2]); d[3] = LateAllPassInOut(State, 2, d[3]); /* Late reverb is done with a modified feedback delay network (FDN) * topology. Four input lines are each fed through their own all-pass * filter and then into the mixing matrix. The four outputs of the * mixing matrix are then cycled back to the inputs. Each output feeds * a different input to form a circlular feed cycle. * * The mixing matrix used is a 4D skew-symmetric rotation matrix derived * using a single unitary rotational parameter: * * [ d, a, b, c ] 1 = a^2 + b^2 + c^2 + d^2 * [ -a, d, c, -b ] * [ -b, -c, d, a ] * [ -c, b, -a, d ] * * The rotation is constructed from the effect's diffusion parameter, * yielding: 1 = x^2 + 3 y^2; where a, b, and c are the coefficient y * with differing signs, and d is the coefficient x. The matrix is thus: * * [ x, y, -y, y ] x = 1 - (0.5 diffusion^3) * [ -y, x, y, y ] y = sqrt((1 - x^2) / 3) * [ y, -y, x, y ] * [ -y, -y, -y, x ] * * To reduce the number of multiplies, the x coefficient is applied with * the cyclical delay line coefficients. Thus only the y coefficient is * applied when mixing, and is modified to be: y / x. */ f[0] = d[0] + (State->Late.MixCoeff * ( d[1] - d[2] + d[3])); f[1] = d[1] + (State->Late.MixCoeff * (-d[0] + d[2] + d[3])); f[2] = d[2] + (State->Late.MixCoeff * ( d[0] - d[1] + d[3])); f[3] = d[3] + (State->Late.MixCoeff * (-d[0] - d[1] - d[2])); // Output the results of the matrix for all four cyclical delay lines, // attenuated by the late reverb gain (which is attenuated by the 'x' // mix coefficient). out[0] = State->Late.Gain * f[0]; out[1] = State->Late.Gain * f[1]; out[2] = State->Late.Gain * f[2]; out[3] = State->Late.Gain * f[3]; // The delay lines are fed circularly in the order: // 0 -> 1 -> 3 -> 2 -> 0 ... DelayLineIn(&State->Late.Delay[0], State->Offset, f[2]); DelayLineIn(&State->Late.Delay[1], State->Offset, f[0]); DelayLineIn(&State->Late.Delay[2], State->Offset, f[3]); DelayLineIn(&State->Late.Delay[3], State->Offset, f[1]); } // Process the reverb for a given input sample, resulting in separate four- // channel output for both early reflections and late reverb. static __inline ALvoid ReverbInOut(ALverbState *State, ALfloat in, ALfloat *early, ALfloat *late) { ALfloat taps[4]; // Low-pass filter the incoming sample. in = lpFilter2P(&State->LpFilter, 0, in); // Feed the initial delay line. DelayLineIn(&State->Delay, State->Offset, in); // Calculate the early reflection from the first delay tap. in = DelayLineOut(&State->Delay, State->Offset - State->Tap[0]); EarlyReflection(State, in, early); // Calculate the late reverb from the last four delay taps. taps[0] = DelayLineOut(&State->Delay, State->Offset - State->Tap[1]); taps[1] = DelayLineOut(&State->Delay, State->Offset - State->Tap[2]); taps[2] = DelayLineOut(&State->Delay, State->Offset - State->Tap[3]); taps[3] = DelayLineOut(&State->Delay, State->Offset - State->Tap[4]); LateReverb(State, taps, late); // Step all delays forward one sample. State->Offset++; } // This destroys the reverb state. It should be called only when the effect // slot has a different (or no) effect loaded over the reverb effect. ALvoid VerbDestroy(ALeffectState *effect) { ALverbState *State = (ALverbState*)effect; if(State) { free(State->SampleBuffer); State->SampleBuffer = NULL; free(State); } } // NOTE: Temp, remove later. static __inline ALint aluCart2LUTpos(ALfloat re, ALfloat im) { ALint pos = 0; ALfloat denom = aluFabs(re) + aluFabs(im); if(denom > 0.0f) pos = (ALint)(QUADRANT_NUM*aluFabs(im) / denom + 0.5); if(re < 0.0) pos = 2 * QUADRANT_NUM - pos; if(im < 0.0) pos = LUT_NUM - pos; return pos%LUT_NUM; } // This updates the reverb state. This is called any time the reverb effect // is loaded into a slot. ALvoid VerbUpdate(ALeffectState *effect, ALCcontext *Context, ALeffect *Effect) { ALverbState *State = (ALverbState*)effect; ALuint index; ALfloat length, mixCoeff, cw, g, coeff; ALfloat hfRatio = Effect->Reverb.DecayHFRatio; // Calculate the master low-pass filter (from the master effect HF gain). cw = cos(2.0 * M_PI * Effect->Reverb.HFReference / Context->Frequency); g = __max(Effect->Reverb.GainHF, 0.0001f); State->LpFilter.coeff = 0.0f; if(g < 0.9999f) // 1-epsilon State->LpFilter.coeff = (1 - g*cw - aluSqrt(2*g*(1-cw) - g*g*(1 - cw*cw))) / (1 - g); // Calculate the initial delay taps. length = Effect->Reverb.ReflectionsDelay; State->Tap[0] = (ALuint)(length * Context->Frequency); length += Effect->Reverb.LateReverbDelay; /* The four inputs to the late reverb are decorrelated to smooth the * initial reverb and reduce harsh echos. The timings are calculated as * multiples of a fraction of the smallest cyclical delay time. This * result is then adjusted so that the first tap occurs immediately (all * taps are reduced by the shortest fraction). * * offset[index] = ((FRACTION MULTIPLIER^index) - 1) delay */ for(index = 0;index < 4;index++) { length += LATE_LINE_LENGTH[0] * (1.0f + (Effect->Reverb.Density * LATE_LINE_MULTIPLIER)) * (DECO_FRACTION * (pow(DECO_MULTIPLIER, (ALfloat)index) - 1.0f)); State->Tap[1 + index] = (ALuint)(length * Context->Frequency); } // Calculate the early reflections gain (from the master effect gain, and // reflections gain parameters). State->Early.Gain = Effect->Reverb.Gain * Effect->Reverb.ReflectionsGain; // Calculate the gain (coefficient) for each early delay line. for(index = 0;index < 4;index++) State->Early.Coeff[index] = pow(10.0f, EARLY_LINE_LENGTH[index] / Effect->Reverb.LateReverbDelay * -60.0f / 20.0f); // Calculate the first mixing matrix coefficient (x). mixCoeff = 1.0f - (0.5f * pow(Effect->Reverb.Diffusion, 3.0f)); // Calculate the late reverb gain (from the master effect gain, and late // reverb gain parameters). Since the output is tapped prior to the // application of the delay line coefficients, this gain needs to be // attenuated by the 'x' mix coefficient from above. State->Late.Gain = Effect->Reverb.Gain * Effect->Reverb.LateReverbGain * mixCoeff; /* To compensate for changes in modal density and decay time of the late * reverb signal, the input is attenuated based on the maximal energy of * the outgoing signal. This is calculated as the ratio between a * reference value and the current approximation of energy for the output * signal. * * Reverb output matches exponential decay of the form Sum(a^n), where a * is the attenuation coefficient, and n is the sample ranging from 0 to * infinity. The signal energy can thus be approximated using the area * under this curve, calculated as: 1 / (1 - a). * * The reference energy is calculated from a signal at the lowest (effect * at 1.0) density with a decay time of one second. * * The coefficient is calculated as the average length of the cyclical * delay lines. This produces a better result than calculating the gain * for each line individually (most likely a side effect of diffusion). * * The final result is the square root of the ratio bound to a maximum * value of 1 (no amplification). */ length = (LATE_LINE_LENGTH[0] + LATE_LINE_LENGTH[1] + LATE_LINE_LENGTH[2] + LATE_LINE_LENGTH[3]); g = length * (1.0f + LATE_LINE_MULTIPLIER) * 0.25f; g = pow(10.0f, g * -60.0f / 20.0f); g = 1.0f / (1.0f - (g * g)); length *= 1.0f + (Effect->Reverb.Density * LATE_LINE_MULTIPLIER) * 0.25f; length = pow(10.0f, length / Effect->Reverb.DecayTime * -60.0f / 20.0f); length = 1.0f / (1.0f - (length * length)); State->Late.DensityGain = __min(aluSqrt(g / length), 1.0f); // Calculate the all-pass feed-back and feed-forward coefficient. State->Late.ApFeedCoeff = 0.6f * pow(Effect->Reverb.Diffusion, 3.0f); // Calculate the mixing matrix coefficient (y / x). g = aluSqrt((1.0f - (mixCoeff * mixCoeff)) / 3.0f); State->Late.MixCoeff = g / mixCoeff; for(index = 0;index < 4;index++) { // Calculate the gain (coefficient) for each all-pass line. State->Late.ApCoeff[index] = pow(10.0f, ALLPASS_LINE_LENGTH[index] / Effect->Reverb.DecayTime * -60.0f / 20.0f); } // If the HF limit parameter is flagged, calculate an appropriate limit // based on the air absorption parameter. if(Effect->Reverb.DecayHFLimit && Effect->Reverb.AirAbsorptionGainHF < 1.0f) { ALfloat limitRatio; // For each of the cyclical delays, find the attenuation due to air // absorption in dB (converting delay time to meters using the speed // of sound). Then reversing the decay equation, solve for HF ratio. // The delay length is cancelled out of the equation, so it can be // calculated once for all lines. limitRatio = 1.0f / (log10(Effect->Reverb.AirAbsorptionGainHF) * SPEEDOFSOUNDMETRESPERSEC * Effect->Reverb.DecayTime / -60.0f * 20.0f); // Need to limit the result to a minimum of 0.1, just like the HF // ratio parameter. limitRatio = __max(limitRatio, 0.1f); // Using the limit calculated above, apply the upper bound to the // HF ratio. hfRatio = __min(hfRatio, limitRatio); } // Calculate the low-pass filter frequency. cw = cos(2.0f * M_PI * Effect->Reverb.HFReference / Context->Frequency); for(index = 0;index < 4;index++) { // Calculate the length (in seconds) of each cyclical delay line. length = LATE_LINE_LENGTH[index] * (1.0f + (Effect->Reverb.Density * LATE_LINE_MULTIPLIER)); // Calculate the delay offset for the cyclical delay lines. State->Late.Offset[index] = (ALuint)(length * Context->Frequency); // Calculate the gain (coefficient) for each cyclical line. State->Late.Coeff[index] = pow(10.0f, length / Effect->Reverb.DecayTime * -60.0f / 20.0f); // Eventually this should boost the high frequencies when the ratio // exceeds 1. coeff = 0.0f; if (hfRatio < 1.0f) { // Calculate the decay equation for each low-pass filter. g = pow(10.0f, length / (Effect->Reverb.DecayTime * hfRatio) * -60.0f / 20.0f) / State->Late.Coeff[index]; g = __max(g, 0.1f); g *= g; // Calculate the gain (coefficient) for each low-pass filter. if(g < 0.9999f) // 1-epsilon coeff = (1 - g*cw - aluSqrt(2*g*(1-cw) - g*g*(1 - cw*cw))) / (1 - g); // Very low decay times will produce minimal output, so apply an // upper bound to the coefficient. coeff = __min(coeff, 0.98f); } State->Late.LpCoeff[index] = coeff; // Attenuate the cyclical line coefficients by the mixing coefficient // (x). State->Late.Coeff[index] *= mixCoeff; } // Calculate the 3D-panning gains for the early reflections and late // reverb (for EAX mode). { ALfloat earlyPan[3] = { Effect->Reverb.ReflectionsPan[0], Effect->Reverb.ReflectionsPan[1], Effect->Reverb.ReflectionsPan[2] }; ALfloat latePan[3] = { Effect->Reverb.LateReverbPan[0], Effect->Reverb.LateReverbPan[1], Effect->Reverb.LateReverbPan[2] }; ALfloat *speakerGain, dirGain, ambientGain; ALfloat length; ALint pos; length = earlyPan[0]*earlyPan[0] + earlyPan[1]*earlyPan[1] + earlyPan[2]*earlyPan[2]; if(length > 1.0f) { length = 1.0f / aluSqrt(length); earlyPan[0] *= length; earlyPan[1] *= length; earlyPan[2] *= length; } length = latePan[0]*latePan[0] + latePan[1]*latePan[1] + latePan[2]*latePan[2]; if(length > 1.0f) { length = 1.0f / aluSqrt(length); latePan[0] *= length; latePan[1] *= length; latePan[2] *= length; } // This code applies directional reverb just like the mixer applies // directional sources. It diffuses the sound toward all speakers // as the magnitude of the panning vector drops, which is only an // approximation of the expansion of sound across the speakers from // the panning direction. pos = aluCart2LUTpos(earlyPan[2], earlyPan[0]); speakerGain = &Context->PanningLUT[OUTPUTCHANNELS * pos]; dirGain = aluSqrt((earlyPan[0] * earlyPan[0]) + (earlyPan[2] * earlyPan[2])); ambientGain = (1.0 - dirGain); for(index = 0;index < OUTPUTCHANNELS;index++) State->Early.PanGain[index] = dirGain * speakerGain[index] + ambientGain; pos = aluCart2LUTpos(latePan[2], latePan[0]); speakerGain = &Context->PanningLUT[OUTPUTCHANNELS * pos]; dirGain = aluSqrt((latePan[0] * latePan[0]) + (latePan[2] * latePan[2])); ambientGain = (1.0 - dirGain); for(index = 0;index < OUTPUTCHANNELS;index++) State->Late.PanGain[index] = dirGain * speakerGain[index] + ambientGain; } } // This processes the reverb state, given the input samples and an output // buffer. ALvoid VerbProcess(ALeffectState *effect, const ALeffectslot *Slot, ALuint SamplesToDo, const ALfloat *SamplesIn, ALfloat (*SamplesOut)[OUTPUTCHANNELS]) { ALverbState *State = (ALverbState*)effect; ALuint index; ALfloat early[4], late[4], out[4]; ALfloat gain = Slot->Gain; for(index = 0;index < SamplesToDo;index++) { // Process reverb for this sample. ReverbInOut(State, SamplesIn[index], early, late); // Mix early reflections and late reverb. out[0] = (early[0] + late[0]) * gain; out[1] = (early[1] + late[1]) * gain; out[2] = (early[2] + late[2]) * gain; out[3] = (early[3] + late[3]) * gain; // Output the results. SamplesOut[index][FRONT_LEFT] += out[0]; SamplesOut[index][FRONT_RIGHT] += out[1]; SamplesOut[index][FRONT_CENTER] += out[3]; SamplesOut[index][SIDE_LEFT] += out[0]; SamplesOut[index][SIDE_RIGHT] += out[1]; SamplesOut[index][BACK_LEFT] += out[0]; SamplesOut[index][BACK_RIGHT] += out[1]; SamplesOut[index][BACK_CENTER] += out[2]; } } // This processes the EAX reverb state, given the input samples and an output // buffer. ALvoid EAXVerbProcess(ALeffectState *effect, const ALeffectslot *Slot, ALuint SamplesToDo, const ALfloat *SamplesIn, ALfloat (*SamplesOut)[OUTPUTCHANNELS]) { ALverbState *State = (ALverbState*)effect; ALuint index; ALfloat early[4], late[4]; ALfloat gain = Slot->Gain; for(index = 0;index < SamplesToDo;index++) { // Process reverb for this sample. ReverbInOut(State, SamplesIn[index], early, late); // Unfortunately, while the number and configuration of gains for // panning adjust according to OUTPUTCHANNELS, the output from the // reverb engine is not so scalable. SamplesOut[index][FRONT_LEFT] += (State->Early.PanGain[FRONT_LEFT]*early[0] + State->Late.PanGain[FRONT_LEFT]*late[0]) * gain; SamplesOut[index][FRONT_RIGHT] += (State->Early.PanGain[FRONT_RIGHT]*early[1] + State->Late.PanGain[FRONT_RIGHT]*late[1]) * gain; SamplesOut[index][FRONT_CENTER] += (State->Early.PanGain[FRONT_CENTER]*early[3] + State->Late.PanGain[FRONT_CENTER]*late[3]) * gain; SamplesOut[index][SIDE_LEFT] += (State->Early.PanGain[SIDE_LEFT]*early[0] + State->Late.PanGain[SIDE_LEFT]*late[0]) * gain; SamplesOut[index][SIDE_RIGHT] += (State->Early.PanGain[SIDE_RIGHT]*early[1] + State->Late.PanGain[SIDE_RIGHT]*late[1]) * gain; SamplesOut[index][BACK_LEFT] += (State->Early.PanGain[BACK_LEFT]*early[0] + State->Late.PanGain[BACK_LEFT]*late[0]) * gain; SamplesOut[index][BACK_RIGHT] += (State->Early.PanGain[BACK_RIGHT]*early[1] + State->Late.PanGain[BACK_RIGHT]*late[1]) * gain; SamplesOut[index][BACK_CENTER] += (State->Early.PanGain[BACK_CENTER]*early[2] + State->Late.PanGain[BACK_CENTER]*late[2]) * gain; } } // This creates the reverb state. It should be called only when the reverb // effect is loaded into a slot that doesn't already have a reverb effect. ALeffectState *VerbCreate(ALCcontext *Context) { ALverbState *State = NULL; ALuint samples, length[13], totalLength, index; State = malloc(sizeof(ALverbState)); if(!State) { alSetError(AL_OUT_OF_MEMORY); return NULL; } State->state.Destroy = VerbDestroy; State->state.Update = VerbUpdate; State->state.Process = VerbProcess; // All line lengths are powers of 2, calculated from their lengths, with // an additional sample in case of rounding errors. // See VerbUpdate() for an explanation of the additional calculation // added to the master line length. samples = (ALuint) ((MASTER_LINE_LENGTH + (LATE_LINE_LENGTH[0] * (1.0f + LATE_LINE_MULTIPLIER) * (DECO_FRACTION * ((DECO_MULTIPLIER * DECO_MULTIPLIER * DECO_MULTIPLIER) - 1.0f)))) * Context->Frequency) + 1; length[0] = NextPowerOf2(samples); totalLength = length[0]; for(index = 0;index < 4;index++) { samples = (ALuint)(EARLY_LINE_LENGTH[index] * Context->Frequency) + 1; length[1 + index] = NextPowerOf2(samples); totalLength += length[1 + index]; } for(index = 0;index < 4;index++) { samples = (ALuint)(ALLPASS_LINE_LENGTH[index] * Context->Frequency) + 1; length[5 + index] = NextPowerOf2(samples); totalLength += length[5 + index]; } for(index = 0;index < 4;index++) { samples = (ALuint)(LATE_LINE_LENGTH[index] * (1.0f + LATE_LINE_MULTIPLIER) * Context->Frequency) + 1; length[9 + index] = NextPowerOf2(samples); totalLength += length[9 + index]; } // All lines share a single sample buffer and have their masks and start // addresses calculated once. State->SampleBuffer = malloc(totalLength * sizeof(ALfloat)); if(!State->SampleBuffer) { free(State); alSetError(AL_OUT_OF_MEMORY); return NULL; } for(index = 0; index < totalLength;index++) State->SampleBuffer[index] = 0.0f; State->LpFilter.coeff = 0.0f; State->LpFilter.history[0] = 0.0f; State->LpFilter.history[1] = 0.0f; State->Delay.Mask = length[0] - 1; State->Delay.Line = &State->SampleBuffer[0]; totalLength = length[0]; State->Tap[0] = 0; State->Tap[1] = 0; State->Tap[2] = 0; State->Tap[3] = 0; State->Tap[4] = 0; State->Early.Gain = 0.0f; for(index = 0;index < 4;index++) { State->Early.Coeff[index] = 0.0f; State->Early.Delay[index].Mask = length[1 + index] - 1; State->Early.Delay[index].Line = &State->SampleBuffer[totalLength]; totalLength += length[1 + index]; // The early delay lines have their read offsets calculated once. State->Early.Offset[index] = (ALuint)(EARLY_LINE_LENGTH[index] * Context->Frequency); } State->Late.Gain = 0.0f; State->Late.DensityGain = 0.0f; State->Late.ApFeedCoeff = 0.0f; State->Late.MixCoeff = 0.0f; for(index = 0;index < 4;index++) { State->Late.ApCoeff[index] = 0.0f; State->Late.ApDelay[index].Mask = length[5 + index] - 1; State->Late.ApDelay[index].Line = &State->SampleBuffer[totalLength]; totalLength += length[5 + index]; // The late all-pass lines have their read offsets calculated once. State->Late.ApOffset[index] = (ALuint)(ALLPASS_LINE_LENGTH[index] * Context->Frequency); } for(index = 0;index < 4;index++) { State->Late.Coeff[index] = 0.0f; State->Late.Delay[index].Mask = length[9 + index] - 1; State->Late.Delay[index].Line = &State->SampleBuffer[totalLength]; totalLength += length[9 + index]; State->Late.Offset[index] = 0; State->Late.LpCoeff[index] = 0.0f; State->Late.LpSample[index] = 0.0f; } // Panning is applied as an independent gain for each output channel. for(index = 0;index < OUTPUTCHANNELS;index++) { State->Early.PanGain[index] = 0.0f; State->Late.PanGain[index] = 0.0f; } State->Offset = 0; return &State->state; } ALeffectState *EAXVerbCreate(ALCcontext *Context) { ALeffectState *State = VerbCreate(Context); if(State) State->Process = EAXVerbProcess; return State; }