#include SquawkSynthSD SquawkSD; class StreamFile : public SquawkStream { private: Fat16 f; public: StreamFile(Fat16 file = Fat16()) { f = file; } uint8_t read() { return f.read(); } void seek(size_t offset) { f.seekSet(offset); } }; static StreamFile file; extern uint16_t period_tbl[84] PROGMEM; void SquawkSynthSD::play(Fat16 melody) { SquawkSynth::pause(); file = StreamFile(melody); SquawkSynth::play(&file); } /* void SquawkSynthSD::convert(Fat16 in, Fat16 out) { unsigned int n; uint8_t patterns = 0, order_count; unsigned int ptn, row, chn; uint8_t temp; uint8_t fxc[4], fxp[4], note[4], sample[4]; uint16_t period; out.write('S'); // ID out.write('Q'); out.write('M'); out.write('1'); out.write((uint8_t)0); // No meta data out.write((uint8_t)0); // Write order list, count patterns in.seek(0x3B6); order_count = in.read(); out.write(order_count); in.seek(0x3B8); for(n = 0; n < order_count; n++) { temp = in.read(); if(temp >= patterns) patterns = temp + 1; out.write(temp); } // Write patterns in.seek(0x43C); for(ptn = 0; ptn < patterns; ptn++) { for(row = 0; row < 64; row++) { for(chn = 0; chn < 4; chn++) { // Basic extraction temp = in.read(); // sample.msb and period.msb period = (temp & 0x0F) << 8; sample[chn] = temp & 0xF0; period |= in.read(); // period.lsb temp = in.read(); // sample.lsb and effect sample[chn] |= temp >> 4; fxc[chn] = (temp & 0x0F) << 4; fxp[chn] = in.read(); // parameters if(fxc[chn] == 0xE0) { fxc[chn] |= fxp[chn] >> 4; // extended parameters fxp[chn] &= 0x0F; } #define DIF(A, B) ((A) > (B) ? ((int32_t)(A) - (int32_t)(B)) : ((int32_t)(B) - (int32_t)(A))) // Find closest matching period if(period == 0) { note[chn] = 0x7F; } else { int16_t best = DIF(period, pgm_read_word(&period_tbl[0])); note[chn] = 0; for(n = 0; n < sizeof(period_tbl) / sizeof(uint16_t); n++) { if(DIF(period, pgm_read_word(&period_tbl[n])) < best) { note[chn] = n; best = DIF(period, pgm_read_word(&period_tbl[n])); } } } // Crunch volume/decimal commands if(fxc[chn] == 0x50 || fxc[chn] == 0x60 || fxc[chn] == 0xA0) { fxp[chn] = (fxp[chn] >> 1) & 0x77; } else if(fxc[chn] == 0x70) { fxp[chn] = (fxp[chn] & 0xF0) | ((fxp[chn] & 0x0F) >> 1); } else if(fxc[chn] == 0xC0 || fxc[chn] == 0xEA || fxc[chn] == 0xEB) { fxp[chn] >>= 1; } else if(fxc[chn] == 0xD0) { fxp[chn] = ((fxp[chn] >> 4) * 10) | (fxp[chn] & 0x0F); } // Re-nibblify - it's a word! if(chn != 3) { if((fxc[chn] & 0xF0) == 0xE0) fxp[chn] |= fxc[chn] << 4; fxc[chn] >>= 4; } } // Ghetto crunch the last channel to save a byte switch(fxc[3]) { case 0x50: case 0x60: case 0xA0: fxc[3] = 0x1; if((fxp[3] >> 4) >= (fxp[3] & 0x0F)) { fxp[3] = 0x80 + ((fxp[3] >> 4) - (fxp[3] & 0x0F)); } else { fxp[3] = ((fxp[3] & 0x0F) - (fxp[3] >> 4)); } break; case 0x70: fxc[3] = (fxp[3] & 0x4) ? 0x3 : 0x2; fxp[3] = (fxp[3] >> 4) | ((fxp[3] & 0x03) << 4); break; case 0xC0: fxc[3] = 0x4; fxp[3] &= 0x1F; break; case 0xB0: fxc[3] = 0x5; fxp[3] &= 0x1F; break; case 0xD0: fxc[3] = 0x6; if(fxp[3] > 63) fxp[3] = 0; break; case 0xF0: if(fxp[3] > 0x20) { fxc[3] = 0x0; fxp[3] = 0x00; } else { fxc[3] = 0x7; } break; case 0xE7: fxc[3] = 0x8; break; case 0xE9: fxc[3] = 0x9; break; case 0xEA: fxc[3] = 0xA; fxp[3] |= 0x08; break; case 0xEB: fxc[3] = 0xA; break; case 0xEC: fxc[3] = 0xB; break; case 0xED: fxc[3] = 0xB; fxp[3] |= 0x10; break; case 0xEE: fxc[3] = 0xC; break; default: fxc[3] = 0; fxp[3] = 0; } if(note[3] != 0x7F) fxp[3] |= 0x80; if(sample[3]) fxp[3] |= 0x40; // Write out out.write((fxc[0]) | fxc[1] << 4); out.write(fxp[0]); out.write(fxp[1]); out.write((fxc[2]) | fxc[3] << 4); out.write(fxp[2]); out.write(fxp[3]); out.write(note[0] | (sample[0] == 0 ? 0x00 : 0x80)); out.write(note[1] | (sample[1] == 0 ? 0x00 : 0x80)); out.write(note[2] | (sample[2] == 0 ? 0x00 : 0x80)); } } }*/