/* * This file is part of libsidplayfp, a SID player engine. * * Copyright 2011-2022 Leandro Nini * Copyright 2018 VICE Project * Copyright 2007-2010 Antti Lankila * Copyright 2004,2010 Dag Lem * * 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; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #ifndef ENVELOPEGENERATOR_H #define ENVELOPEGENERATOR_H #include "siddefs-fp.h" namespace reSIDfp { /** * A 15 bit [LFSR] is used to implement the envelope rates, in effect dividing * the clock to the envelope counter by the currently selected rate period. * * In addition, another 5 bit counter is used to implement the exponential envelope decay, * in effect further dividing the clock to the envelope counter. * The period of this counter is set to 1, 2, 4, 8, 16, 30 at the envelope counter * values 255, 93, 54, 26, 14, 6, respectively. * * [LFSR]: https://en.wikipedia.org/wiki/Linear_feedback_shift_register */ class EnvelopeGenerator { private: /** * The envelope state machine's distinct states. In addition to this, * envelope has a hold mode, which freezes envelope counter to zero. */ enum class State { ATTACK, DECAY_SUSTAIN, RELEASE }; private: /// XOR shift register for ADSR prescaling. unsigned int lfsr = 0x7fff; /// Comparison value (period) of the rate counter before next event. unsigned int rate = 0; /** * During release mode, the SID approximates envelope decay via piecewise * linear decay rate. */ unsigned int exponential_counter = 0; /** * Comparison value (period) of the exponential decay counter before next * decrement. */ unsigned int exponential_counter_period = 1; unsigned int new_exponential_counter_period = 0; unsigned int state_pipeline = 0; /// unsigned int envelope_pipeline = 0; unsigned int exponential_pipeline = 0; /// Current envelope state State state = State::RELEASE; State next_state = State::RELEASE; /// Whether counter is enabled. Only switching to ATTACK can release envelope. bool counter_enabled = true; /// Gate bit bool gate = false; /// bool resetLfsr = false; /// The current digital value of envelope output. unsigned char envelope_counter = 0xaa; /// Attack register unsigned char attack = 0; /// Decay register unsigned char decay = 0; /// Sustain register unsigned char sustain = 0; /// Release register unsigned char release = 0; /// The ENV3 value, sampled at the first phase of the clock unsigned char env3 = 0; private: static const unsigned int adsrtable[16]; private: void set_exponential_counter(); void state_change(); public: /** * SID clocking. */ void clock(); /** * Get the Envelope Generator digital output. */ unsigned int output() const { return envelope_counter; } /** * SID reset. */ void reset(); /** * Write control register. * * @param control * control register value */ void writeCONTROL_REG(unsigned char control); /** * Write Attack/Decay register. * * @param attack_decay * attack/decay value */ void writeATTACK_DECAY(unsigned char attack_decay); /** * Write Sustain/Release register. * * @param sustain_release * sustain/release value */ void writeSUSTAIN_RELEASE(unsigned char sustain_release); /** * Return the envelope current value. * * @return envelope counter value */ unsigned char readENV() const { return env3; } }; } // namespace reSIDfp #if RESID_INLINING || defined(ENVELOPEGENERATOR_CPP) namespace reSIDfp { RESID_INLINE void EnvelopeGenerator::clock() { env3 = envelope_counter; if (unlikely(new_exponential_counter_period > 0)) { exponential_counter_period = new_exponential_counter_period; new_exponential_counter_period = 0; } if (unlikely(state_pipeline)) { state_change(); } if (unlikely(envelope_pipeline != 0) && (--envelope_pipeline == 0)) { if (likely(counter_enabled)) { if (state == State::ATTACK) { if (++envelope_counter==0xff) { next_state = State::DECAY_SUSTAIN; state_pipeline = 3; } } else if ((state == State::DECAY_SUSTAIN) || (state == State::RELEASE)) { if (--envelope_counter==0x00) { counter_enabled = false; } } set_exponential_counter(); } } else if (unlikely(exponential_pipeline != 0) && (--exponential_pipeline == 0)) { exponential_counter = 0; if (((state == State::DECAY_SUSTAIN) && (envelope_counter != sustain)) || (state == State::RELEASE)) { // The envelope counter can flip from 0x00 to 0xff by changing state to // attack, then to release. The envelope counter will then continue // counting down in the release state. // This has been verified by sampling ENV3. envelope_pipeline = 1; } } else if (unlikely(resetLfsr)) { lfsr = 0x7fff; resetLfsr = false; if (state == State::ATTACK) { // The first envelope step in the attack state also resets the exponential // counter. This has been verified by sampling ENV3. exponential_counter = 0; // NOTE this is actually delayed one cycle, not modeled // The envelope counter can flip from 0xff to 0x00 by changing state to // release, then to attack. The envelope counter is then frozen at // zero; to unlock this situation the state must be changed to release, // then to attack. This has been verified by sampling ENV3. envelope_pipeline = 2; } else { if (counter_enabled && (++exponential_counter == exponential_counter_period)) exponential_pipeline = exponential_counter_period != 1 ? 2 : 1; } } // ADSR delay bug. // If the rate counter comparison value is set below the current value of the // rate counter, the counter will continue counting up until it wraps around // to zero at 2^15 = 0x8000, and then count rate_period - 1 before the // envelope can constly be stepped. // This has been verified by sampling ENV3. // check to see if LFSR matches table value if (likely(lfsr != rate)) { // it wasn't a match, clock the LFSR once // by performing XOR on last 2 bits const unsigned int feedback = ((lfsr << 14) ^ (lfsr << 13)) & 0x4000; lfsr = (lfsr >> 1) | feedback; } else { resetLfsr = true; } } /** * This is what happens on chip during state switching, * based on die reverse engineering and transistor level * emulation. * * Attack * * 0 - Gate on * 1 - Counting direction changes * During this cycle the decay rate is "accidentally" activated * 2 - Counter is being inverted * Now the attack rate is correctly activated * Counter is enabled * 3 - Counter will be counting upward from now on * * Decay * * 0 - Counter == $ff * 1 - Counting direction changes * The attack state is still active * 2 - Counter is being inverted * During this cycle the decay state is activated * 3 - Counter will be counting downward from now on * * Release * * 0 - Gate off * 1 - During this cycle the release state is activated if coming from sustain/decay * *2 - Counter is being inverted, the release state is activated * *3 - Counter will be counting downward from now on * * (* only if coming directly from Attack state) * * Freeze * * 0 - Counter == $00 * 1 - Nothing * 2 - Counter is disabled */ RESID_INLINE void EnvelopeGenerator::state_change() { state_pipeline--; switch (next_state) { case State::ATTACK: if (state_pipeline == 1) { // The decay rate is "accidentally" enabled during first cycle of attack phase rate = adsrtable[decay]; } else if (state_pipeline == 0) { state = State::ATTACK; // The attack rate is correctly enabled during second cycle of attack phase rate = adsrtable[attack]; counter_enabled = true; } break; case State::DECAY_SUSTAIN: if (state_pipeline == 0) { state = State::DECAY_SUSTAIN; rate = adsrtable[decay]; } break; case State::RELEASE: if (((state == State::ATTACK) && (state_pipeline == 0)) || ((state == State::DECAY_SUSTAIN) && (state_pipeline == 1))) { state = State::RELEASE; rate = adsrtable[release]; } break; } } RESID_INLINE void EnvelopeGenerator::set_exponential_counter() { // Check for change of exponential counter period. // // For a detailed description see: // http://ploguechipsounds.blogspot.it/2010/03/sid-6581r3-adsr-tables-up-close.html switch (envelope_counter) { case 0xff: case 0x00: new_exponential_counter_period = 1; break; case 0x5d: new_exponential_counter_period = 2; break; case 0x36: new_exponential_counter_period = 4; break; case 0x1a: new_exponential_counter_period = 8; break; case 0x0e: new_exponential_counter_period = 16; break; case 0x06: new_exponential_counter_period = 30; break; } } } // namespace reSIDfp #endif #endif