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4a089a19dc1ed243f4f033d1d0eb91fae683bbe3
lmms/plugins/LOMM/LOMM.cpp
Fawn 4a089a19dc Update math functions to C++ standard library (#7685) 
* use c++ std::* math functions
This updates usages of sin, cos, tan, pow, exp, log, log10, sqrt, fmod, fabs, and fabsf,
excluding any usages that look like they might be part of a submodule or 3rd-party code.
There's probably some std math functions not listed here that haven't been updated yet.

* fix std::sqrt typo

lmao one always sneaks by

* Apply code review suggestions
- std::pow(2, x) -> std::exp2(x)
- std::pow(10, x) -> lmms::fastPow10f(x)
- std::pow(x, 2) -> x * x, std::pow(x, 3) -> x * x * x, etc.
- Resolve TODOs, fix typos, and so forth

Co-authored-by: Rossmaxx <74815851+Rossmaxx@users.noreply.github.com>

* Fix double -> float truncation, DrumSynth fix

I mistakenly introduced a bug in my recent PR regarding template
constants, in which a -1 that was supposed to appear outside of an abs()
instead was moved inside it, screwing up the generated waveform. I fixed
that and also simplified the function by factoring out the phase domain
wrapping using the new `ediv()` function from this PR. It should behave
how it's supposed to now... assuming all my parentheses are in the right
place lol

* Annotate magic numbers with TODOs for C++20

* On second thought, why wait?

What else is lmms::numbers for?

* begone inline

Co-authored-by: Rossmaxx <74815851+Rossmaxx@users.noreply.github.com>

* begone other inline

Co-authored-by: Rossmaxx <74815851+Rossmaxx@users.noreply.github.com>

* Re-inline function in lmms_math.h

For functions, constexpr implies inline so this just re-adds inline to
the one that isn't constexpr yet

* Formatting fixes, readability improvements

Co-authored-by: Dalton Messmer <messmer.dalton@gmail.com>

* Fix previously missed pow() calls, cleanup

Co-authored-by: Dalton Messmer <messmer.dalton@gmail.com>

* Just delete ediv() entirely lmao

No ediv(), no std::fmod(), no std::remainder(), just std::floor().
It should all work for negative phase inputs as well. If I end up
needing ediv() in the future, I can add it then.

* Simplify DrumSynth triangle waveform

This reuses more work and is also a lot more easy to visualize.

It's probably a meaningless micro-optimization, but it might be worth changing it back to a switch-case and just calculating ph_tau and saw01 at the beginning of the function in all code paths, even if it goes unused for the first two cases. Guess I'll see if anybody has strong opinions about it.

* Move multiplication inside abs()

* Clean up a few more pow(x, 2) -> x * x

* Remove numbers::inv_pi, numbers::inv_tau

* delete spooky leading 0

Co-authored-by: Dalton Messmer <messmer.dalton@gmail.com>

---------

Co-authored-by: Rossmaxx <74815851+Rossmaxx@users.noreply.github.com>
Co-authored-by: Dalton Messmer <messmer.dalton@gmail.com>
2025-02-08 23:50:02 -05:00

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/*
* LOMM.cpp
*
* Copyright (c) 2023 Lost Robot <r94231/at/gmail/dot/com>
*
* This file is part of LMMS - https://lmms.io
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This program 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
* General Public License for more details.
*
* You should have received a copy of the GNU General Public
* License along with this program (see COPYING); if not, write to the
* Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
* Boston, MA 02110-1301 USA.
*
*/
#include "LOMM.h"
#include "embed.h"
#include "plugin_export.h"
namespace lmms
{
extern "C"
{
Plugin::Descriptor PLUGIN_EXPORT lomm_plugin_descriptor =
{
LMMS_STRINGIFY(PLUGIN_NAME),
"LOMM",
QT_TRANSLATE_NOOP("PluginBrowser", "Upwards/downwards multiband compression plugin powered by the eldritch elder god LOMMUS."),
"Lost Robot <r94231/at/gmail/dot/com>",
0x0100,
Plugin::Type::Effect,
new PluginPixmapLoader("logo"),
nullptr,
nullptr
};
}
LOMMEffect::LOMMEffect(Model* parent, const Descriptor::SubPluginFeatures::Key* key) :
Effect(&lomm_plugin_descriptor, parent, key),
m_lommControls(this),
m_sampleRate(Engine::audioEngine()->outputSampleRate()),
m_lp1(m_sampleRate),
m_lp2(m_sampleRate),
m_hp1(m_sampleRate),
m_hp2(m_sampleRate),
m_ap(m_sampleRate),
m_needsUpdate(true),
m_coeffPrecalc(-0.05f),
m_crestTimeConst(0.999f),
m_lookWrite(0),
m_lookBufLength(2)
{
autoQuitModel()->setValue(autoQuitModel()->maxValue());
m_ap.setFilterType(BasicFilters<2>::FilterType::AllPass);
connect(Engine::audioEngine(), SIGNAL(sampleRateChanged()), this, SLOT(changeSampleRate()));
changeSampleRate();
}
void LOMMEffect::changeSampleRate()
{
m_sampleRate = Engine::audioEngine()->outputSampleRate();
m_lp1.setSampleRate(m_sampleRate);
m_lp2.setSampleRate(m_sampleRate);
m_hp1.setSampleRate(m_sampleRate);
m_hp2.setSampleRate(m_sampleRate);
m_ap.setSampleRate(m_sampleRate);
m_coeffPrecalc = -2.2f / (m_sampleRate * 0.001f);
m_needsUpdate = true;
m_crestTimeConst = std::exp(-1.f / (0.2f * m_sampleRate));
m_lookBufLength = std::ceil((LOMM_MAX_LOOKAHEAD / 1000.f) * m_sampleRate) + 2;
for (int i = 0; i < 2; ++i)
{
for (int j = 0; j < 3; ++j)
{
m_inLookBuf[j][i].resize(m_lookBufLength);
m_scLookBuf[j][i].resize(m_lookBufLength, LOMM_MIN_FLOOR);
}
}
std::fill(m_yL.begin(), m_yL.end(), std::array<float, 2>{LOMM_MIN_FLOOR, LOMM_MIN_FLOOR});
m_rms = m_gainResult = m_displayIn = m_displayOut = m_prevOut = m_yL;
m_crestPeakVal[0] = m_crestPeakVal[1] = LOMM_MIN_FLOOR;
m_crestRmsVal = m_crestFactorVal = m_crestPeakVal;
}
Effect::ProcessStatus LOMMEffect::processImpl(SampleFrame* buf, const fpp_t frames)
{
if (m_needsUpdate || m_lommControls.m_split1Model.isValueChanged())
{
m_lp1.setLowpass(m_lommControls.m_split1Model.value());
m_hp1.setHighpass(m_lommControls.m_split1Model.value());
m_ap.calcFilterCoeffs(m_lommControls.m_split1Model.value(), 0.70710678118f);
}
if (m_needsUpdate || m_lommControls.m_split2Model.isValueChanged())
{
m_lp2.setLowpass(m_lommControls.m_split2Model.value());
m_hp2.setHighpass(m_lommControls.m_split2Model.value());
}
m_needsUpdate = false;
const float d = dryLevel();
const float w = wetLevel();
const float depth = m_lommControls.m_depthModel.value();
const float time = m_lommControls.m_timeModel.value();
const float inVol = dbfsToAmp(m_lommControls.m_inVolModel.value());
const float outVol = dbfsToAmp(m_lommControls.m_outVolModel.value());
const float upward = m_lommControls.m_upwardModel.value();
const float downward = m_lommControls.m_downwardModel.value();
const bool split1Enabled = m_lommControls.m_split1EnabledModel.value();
const bool split2Enabled = m_lommControls.m_split2EnabledModel.value();
const bool band1Enabled = m_lommControls.m_band1EnabledModel.value();
const bool band2Enabled = m_lommControls.m_band2EnabledModel.value();
const bool band3Enabled = m_lommControls.m_band3EnabledModel.value();
const float inHigh = dbfsToAmp(m_lommControls.m_inHighModel.value());
const float inMid = dbfsToAmp(m_lommControls.m_inMidModel.value());
const float inLow = dbfsToAmp(m_lommControls.m_inLowModel.value());
float inBandVol[3] = {inHigh, inMid, inLow};
const float outHigh = dbfsToAmp(m_lommControls.m_outHighModel.value());
const float outMid = dbfsToAmp(m_lommControls.m_outMidModel.value());
const float outLow = dbfsToAmp(m_lommControls.m_outLowModel.value());
float outBandVol[3] = {outHigh, outMid, outLow};
const float aThreshH = m_lommControls.m_aThreshHModel.value();
const float aThreshM = m_lommControls.m_aThreshMModel.value();
const float aThreshL = m_lommControls.m_aThreshLModel.value();
float aThresh[3] = {aThreshH, aThreshM, aThreshL};
const float aRatioH = m_lommControls.m_aRatioHModel.value();
const float aRatioM = m_lommControls.m_aRatioMModel.value();
const float aRatioL = m_lommControls.m_aRatioLModel.value();
float aRatio[3] = {1.f / aRatioH, 1.f / aRatioM, 1.f / aRatioL};
const float bThreshH = m_lommControls.m_bThreshHModel.value();
const float bThreshM = m_lommControls.m_bThreshMModel.value();
const float bThreshL = m_lommControls.m_bThreshLModel.value();
float bThresh[3] = {bThreshH, bThreshM, bThreshL};
const float bRatioH = m_lommControls.m_bRatioHModel.value();
const float bRatioM = m_lommControls.m_bRatioMModel.value();
const float bRatioL = m_lommControls.m_bRatioLModel.value();
float bRatio[3] = {1.f / bRatioH, 1.f / bRatioM, 1.f / bRatioL};
const float atkH = m_lommControls.m_atkHModel.value() * time;
const float atkM = m_lommControls.m_atkMModel.value() * time;
const float atkL = m_lommControls.m_atkLModel.value() * time;
const float atkCoefH = msToCoeff(atkH);
const float atkCoefM = msToCoeff(atkM);
const float atkCoefL = msToCoeff(atkL);
float atk[3] = {atkH, atkM, atkL};
float atkCoef[3] = {atkCoefH, atkCoefM, atkCoefL};
const float relH = m_lommControls.m_relHModel.value() * time;
const float relM = m_lommControls.m_relMModel.value() * time;
const float relL = m_lommControls.m_relLModel.value() * time;
const float relCoefH = msToCoeff(relH);
const float relCoefM = msToCoeff(relM);
const float relCoefL = msToCoeff(relL);
float rel[3] = {relH, relM, relL};
float relCoef[3] = {relCoefH, relCoefM, relCoefL};
const float rmsTime = m_lommControls.m_rmsTimeModel.value();
const float rmsTimeConst = (rmsTime == 0) ? 0 : std::exp(-1.f / (rmsTime * 0.001f * m_sampleRate));
const float knee = m_lommControls.m_kneeModel.value() * 0.5f;
const float range = m_lommControls.m_rangeModel.value();
const float rangeAmp = dbfsToAmp(range);
const float balance = m_lommControls.m_balanceModel.value();
const float balanceAmpTemp = dbfsToAmp(balance);
const float balanceAmp[2] = {1.f / balanceAmpTemp, balanceAmpTemp};
const bool depthScaling = m_lommControls.m_depthScalingModel.value();
const bool stereoLink = m_lommControls.m_stereoLinkModel.value();
const float autoTime = m_lommControls.m_autoTimeModel.value() * m_lommControls.m_autoTimeModel.value();
const float mix = m_lommControls.m_mixModel.value();
const bool midside = m_lommControls.m_midsideModel.value();
const bool lookaheadEnable = m_lommControls.m_lookaheadEnableModel.value();
const int lookahead = std::ceil((m_lommControls.m_lookaheadModel.value() / 1000.f) * m_sampleRate);
const bool feedback = m_lommControls.m_feedbackModel.value() && !lookaheadEnable;
const bool lowSideUpwardSuppress = m_lommControls.m_lowSideUpwardSuppressModel.value() && midside;
for (fpp_t f = 0; f < frames; ++f)
{
std::array<sample_t, 2> s = {buf[f][0], buf[f][1]};
// Convert left/right to mid/side. Side channel is intentionally made
// to be 6 dB louder to bring it into volume ranges comparable to the mid channel.
if (midside)
{
float tempS0 = s[0];
s[0] = (s[0] + s[1]) * 0.5f;
s[1] = tempS0 - s[1];
}
std::array<std::array<float, 2>, 3> bands = {{}};
std::array<std::array<float, 2>, 3> bandsDry = {{}};
for (int i = 0; i < 2; ++i)// Channels
{
// These values are for the Auto time knob. Higher crest factor allows for faster attack/release.
float inSquared = s[i] * s[i];
m_crestPeakVal[i] = std::max(std::max(LOMM_MIN_FLOOR, inSquared), m_crestTimeConst * m_crestPeakVal[i] + (1 - m_crestTimeConst) * (inSquared));
m_crestRmsVal[i] = std::max(LOMM_MIN_FLOOR, m_crestTimeConst * m_crestRmsVal[i] + ((1 - m_crestTimeConst) * (inSquared)));
m_crestFactorVal[i] = m_crestPeakVal[i] / m_crestRmsVal[i];
float crestFactorValTemp = ((m_crestFactorVal[i] - LOMM_AUTO_TIME_ADJUST) * autoTime) + LOMM_AUTO_TIME_ADJUST;
// Crossover filters
bands[2][i] = m_lp2.update(s[i], i);
bands[1][i] = m_hp2.update(s[i], i);
bands[0][i] = m_hp1.update(bands[1][i], i);
bands[1][i] = m_lp1.update(bands[1][i], i);
bands[2][i] = m_ap.update(bands[2][i], i);
if (!split1Enabled)
{
bands[1][i] += bands[0][i];
bands[0][i] = 0;
}
if (!split2Enabled)
{
bands[1][i] += bands[2][i];
bands[2][i] = 0;
}
// Mute disabled bands
bands[0][i] *= band1Enabled;
bands[1][i] *= band2Enabled;
bands[2][i] *= band3Enabled;
std::array<float, 3> detect = {0, 0, 0};
for (int j = 0; j < 3; ++j)// Bands
{
bandsDry[j][i] = bands[j][i];
if (feedback && !lookaheadEnable)
{
bands[j][i] = m_prevOut[j][i];
}
bands[j][i] *= inBandVol[j] * inVol * balanceAmp[i];
if (rmsTime > 0)// RMS
{
m_rms[j][i] = rmsTimeConst * m_rms[j][i] + ((1 - rmsTimeConst) * (bands[j][i] * bands[j][i]));
detect[j] = std::max(LOMM_MIN_FLOOR, std::sqrt(m_rms[j][i]));
}
else// Peak
{
detect[j] = std::max(LOMM_MIN_FLOOR, std::abs(bands[j][i]));
}
if (detect[j] > m_yL[j][i])// Attack phase
{
// Calculate attack value depending on crest factor
const float currentAttack = autoTime
? msToCoeff(LOMM_AUTO_TIME_ADJUST * atk[j] / crestFactorValTemp)
: atkCoef[j];
m_yL[j][i] = m_yL[j][i] * currentAttack + (1 - currentAttack) * detect[j];
}
else// Release phase
{
// Calculate release value depending on crest factor
const float currentRelease = autoTime
? msToCoeff(LOMM_AUTO_TIME_ADJUST * rel[j] / crestFactorValTemp)
: relCoef[j];
m_yL[j][i] = m_yL[j][i] * currentRelease + (1 - currentRelease) * detect[j];
}
m_yL[j][i] = std::max(LOMM_MIN_FLOOR, m_yL[j][i]);
float yAmp = m_yL[j][i];
if (lookaheadEnable)
{
float temp = yAmp;
// Lookahead is calculated by picking the largest value between
// the current sidechain signal and the delayed sidechain signal.
yAmp = std::max(m_scLookBuf[j][i][m_lookWrite], m_scLookBuf[j][i][(m_lookWrite + m_lookBufLength - lookahead) % m_lookBufLength]);
m_scLookBuf[j][i][m_lookWrite] = temp;
}
const float yDbfs = ampToDbfs(yAmp);
float aboveGain = 0;
float belowGain = 0;
// Downward compression
if (yDbfs - aThresh[j] < -knee)// Below knee
{
aboveGain = yDbfs;
}
else if (yDbfs - aThresh[j] < knee)// Within knee
{
const float temp = yDbfs - aThresh[j] + knee;
aboveGain = yDbfs + (aRatio[j] - 1) * temp * temp / (4 * knee);
}
else// Above knee
{
aboveGain = aThresh[j] + (yDbfs - aThresh[j]) * aRatio[j];
}
if (aboveGain < yDbfs)
{
if (downward * depth <= 1)
{
aboveGain = linearInterpolate(yDbfs, aboveGain, downward * depth);
}
else
{
aboveGain = linearInterpolate(aboveGain, aThresh[j], downward * depth - 1);
}
}
// Upward compression
if (yDbfs - bThresh[j] > knee)// Above knee
{
belowGain = yDbfs;
}
else if (bThresh[j] - yDbfs < knee)// Within knee
{
const float temp = bThresh[j] - yDbfs + knee;
belowGain = yDbfs + (1 - bRatio[j]) * temp * temp / (4 * knee);
}
else// Below knee
{
belowGain = bThresh[j] + (yDbfs - bThresh[j]) * bRatio[j];
}
if (belowGain > yDbfs)
{
if (upward * depth <= 1)
{
belowGain = linearInterpolate(yDbfs, belowGain, upward * depth);
}
else
{
belowGain = linearInterpolate(belowGain, bThresh[j], upward * depth - 1);
}
}
m_displayIn[j][i] = yDbfs;
m_gainResult[j][i] = (dbfsToAmp(aboveGain) / yAmp) * (dbfsToAmp(belowGain) / yAmp);
if (lowSideUpwardSuppress && m_gainResult[j][i] > 1 && j == 2 && i == 1) //undo upward compression if low side band
{
m_gainResult[j][i] = 1;
}
m_gainResult[j][i] = std::min(m_gainResult[j][i], rangeAmp);
m_displayOut[j][i] = ampToDbfs(std::max(LOMM_MIN_FLOOR, yAmp * m_gainResult[j][i]));
// Apply the same gain reduction to both channels if stereo link is enabled.
if (stereoLink && i == 1)
{
if (m_gainResult[j][1] < m_gainResult[j][0])
{
m_gainResult[j][0] = m_gainResult[j][1];
m_displayOut[j][0] = m_displayIn[j][0] - (m_displayIn[j][1] - m_displayOut[j][1]);
}
else
{
m_gainResult[j][1] = m_gainResult[j][0];
m_displayOut[j][1] = m_displayIn[j][1] - (m_displayIn[j][0] - m_displayOut[j][0]);
}
}
}
}
for (int i = 0; i < 2; ++i)// Channels
{
for (int j = 0; j < 3; ++j)// Bands
{
if (lookaheadEnable)
{
float temp = bands[j][i];
bands[j][i] = m_inLookBuf[j][i][m_lookWrite];
m_inLookBuf[j][i][m_lookWrite] = temp;
bandsDry[j][i] = bands[j][i];
}
else if (feedback)
{
bands[j][i] = bandsDry[j][i] * inBandVol[j] * inVol * balanceAmp[i];
}
// Apply gain reduction
bands[j][i] *= m_gainResult[j][i];
// Store for Feedback
m_prevOut[j][i] = bands[j][i];
bands[j][i] *= outBandVol[j];
bands[j][i] = linearInterpolate(bandsDry[j][i], bands[j][i], mix);
}
s[i] = bands[0][i] + bands[1][i] + bands[2][i];
s[i] *= linearInterpolate(1.f, outVol, mix * (depthScaling ? depth : 1));
}
// Convert mid/side back to left/right.
// Note that the side channel was intentionally made to be 6 dB louder prior to compression.
if (midside)
{
float tempS0 = s[0];
s[0] = s[0] + (s[1] * 0.5f);
s[1] = tempS0 - (s[1] * 0.5f);
}
if (--m_lookWrite < 0) { m_lookWrite = m_lookBufLength - 1; }
buf[f][0] = d * buf[f][0] + w * s[0];
buf[f][1] = d * buf[f][1] + w * s[1];
}
return ProcessStatus::ContinueIfNotQuiet;
}
extern "C"
{
// necessary for getting instance out of shared lib
PLUGIN_EXPORT Plugin * lmms_plugin_main(Model* parent, void* data)
{
return new LOMMEffect(parent, static_cast<const Plugin::Descriptor::SubPluginFeatures::Key *>(data));
}
}
} // namespace lmms
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