#ifdef DSP_CPP int DSP::calc_fir(int i, bool channel) { int s = state.echo_hist[channel][state.echo_hist_pos + i + 1]; return (s * (int8)REG(fir + i * 0x10)) >> 6; } int DSP::echo_output(bool channel) { int output = (int16)((state.t_main_out[channel] * (int8)REG(mvoll + channel * 0x10)) >> 7) + (int16)((state.t_echo_in [channel] * (int8)REG(evoll + channel * 0x10)) >> 7); return sclamp<16>(output); } void DSP::echo_read(bool channel) { unsigned addr = state.t_echo_ptr + channel * 2; uint8 lo = smp.apuram[(uint16)(addr + 0)]; uint8 hi = smp.apuram[(uint16)(addr + 1)]; int s = (int16)((hi << 8) + lo); state.echo_hist[channel].write(state.echo_hist_pos, s >> 1); } void DSP::echo_write(bool channel) { if(!(state.t_echo_disabled & 0x20)) { unsigned addr = state.t_echo_ptr + channel * 2; int s = state.t_echo_out[channel]; smp.apuram[(uint16)(addr + 0)] = s; smp.apuram[(uint16)(addr + 1)] = s >> 8; } state.t_echo_out[channel] = 0; } void DSP::echo_22() { //history state.echo_hist_pos++; if(state.echo_hist_pos >= echo_hist_size) state.echo_hist_pos = 0; state.t_echo_ptr = (uint16)((state.t_esa << 8) + state.echo_offset); echo_read(0); //FIR int l = calc_fir(0, 0); int r = calc_fir(0, 1); state.t_echo_in[0] = l; state.t_echo_in[1] = r; } void DSP::echo_23() { int l = calc_fir(1, 0) + calc_fir(2, 0); int r = calc_fir(1, 1) + calc_fir(2, 1); state.t_echo_in[0] += l; state.t_echo_in[1] += r; echo_read(1); } void DSP::echo_24() { int l = calc_fir(3, 0) + calc_fir(4, 0) + calc_fir(5, 0); int r = calc_fir(3, 1) + calc_fir(4, 1) + calc_fir(5, 1); state.t_echo_in[0] += l; state.t_echo_in[1] += r; } void DSP::echo_25() { int l = state.t_echo_in[0] + calc_fir(6, 0); int r = state.t_echo_in[1] + calc_fir(6, 1); l = (int16)l; r = (int16)r; l += (int16)calc_fir(7, 0); r += (int16)calc_fir(7, 1); state.t_echo_in[0] = sclamp<16>(l) & ~1; state.t_echo_in[1] = sclamp<16>(r) & ~1; } void DSP::echo_26() { //left output volumes //(save sample for next clock so we can output both together) state.t_main_out[0] = echo_output(0); //echo feedback int l = state.t_echo_out[0] + (int16)((state.t_echo_in[0] * (int8)REG(efb)) >> 7); int r = state.t_echo_out[1] + (int16)((state.t_echo_in[1] * (int8)REG(efb)) >> 7); state.t_echo_out[0] = sclamp<16>(l) & ~1; state.t_echo_out[1] = sclamp<16>(r) & ~1; } void DSP::echo_27() { //output int outl = state.t_main_out[0]; int outr = echo_output(1); state.t_main_out[0] = 0; state.t_main_out[1] = 0; //TODO: global muting isn't this simple //(turns DAC on and off or something, causing small ~37-sample pulse when first muted) if(REG(flg) & 0x40) { outl = 0; outr = 0; } //output sample to DAC audio.sample(outl, outr); } void DSP::echo_28() { state.t_echo_disabled = REG(flg); } void DSP::echo_29() { state.t_esa = REG(esa); if(!state.echo_offset) state.echo_length = (REG(edl) & 0x0f) << 11; state.echo_offset += 4; if(state.echo_offset >= state.echo_length) state.echo_offset = 0; //write left echo echo_write(0); state.t_echo_disabled = REG(flg); } void DSP::echo_30() { //write right echo echo_write(1); } #endif