// --------------------------------------------------------------------------- // This file is part of reSID, a MOS6581 SID emulator engine. // Copyright (C) 2004 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA // --------------------------------------------------------------------------- #ifndef __SID_H__ #define __SID_H__ #include "siddefs.h" #include "voice.h" #include "filter.h" #include "extfilt.h" #include "pot.h" RESID_NAMESPACE_START class SID { public: SID(); ~SID(); void set_chip_model(chip_model model); void enable_filter(bool enable); void enable_external_filter(bool enable); bool set_sampling_parameters(double clock_freq, sampling_method method, double sample_freq, double pass_freq = -1, double filter_scale = 0.97); void adjust_sampling_frequency(double sample_freq); void fc_default(const fc_point*& points, int& count); PointPlotter fc_plotter(); void clock(); void clock(cycle_count delta_t); int clock(cycle_count& delta_t, short* buf, int n, int interleave = 1); void reset(); // Read/write registers. reg8 read(reg8 offset); void write(reg8 offset, reg8 value); void mute(reg8 channel, bool enable); // Read/write state. class State { public: State(); char sid_register[0x20]; reg8 bus_value; cycle_count bus_value_ttl; reg24 accumulator[3]; reg24 shift_register[3]; reg16 rate_counter[3]; reg16 rate_counter_period[3]; reg16 exponential_counter[3]; reg16 exponential_counter_period[3]; reg8 envelope_counter[3]; EnvelopeGenerator::State envelope_state[3]; bool hold_zero[3]; }; State read_state(); void write_state(const State& state); // 16-bit input (EXT IN). void input(int sample); // 16-bit output (AUDIO OUT). int output(); // n-bit output. int output(int bits); protected: static double I0(double x); RESID_INLINE int clock_fast(cycle_count& delta_t, short* buf, int n, int interleave); RESID_INLINE int clock_interpolate(cycle_count& delta_t, short* buf, int n, int interleave); RESID_INLINE int clock_resample_interpolate(cycle_count& delta_t, short* buf, int n, int interleave); RESID_INLINE int clock_resample_fast(cycle_count& delta_t, short* buf, int n, int interleave); Voice voice[3]; Filter filter; ExternalFilter extfilt; Potentiometer potx; Potentiometer poty; reg8 bus_value; cycle_count bus_value_ttl; double clock_frequency; // External audio input. int ext_in; // Resampling constants. static const int FIR_N; static const int FIR_RES_INTERPOLATE; static const int FIR_RES_FAST; static const int FIR_SHIFT; static const int RINGSIZE; // Fixpoint constants. static const int FIXP_SHIFT; static const int FIXP_MASK; // Sampling variables. sampling_method sampling; cycle_count cycles_per_sample; cycle_count sample_offset; int sample_index; short sample_prev; int fir_N; int fir_RES; // Ring buffer with overflow for contiguous storage of RINGSIZE samples. short* sample; // FIR_RES filter tables (FIR_N*FIR_RES). short* fir; }; RESID_NAMESPACE_STOP #endif // not __SID_H__