/* * PicoDrive * (C) notaz, 2009,2010,2013 * * This work is licensed under the terms of MAME license. * See COPYING file in the top-level directory. */ #include "../pico_int.h" static struct { int cycles; int mult; int ptr; int irq_reload; int doing_fifo; int silent; short current[2]; } pwm; void p32x_pwm_ctl_changed(void) { int control = Pico32x.regs[0x30 / 2]; int cycles = Pico32x.regs[0x32 / 2]; cycles = (cycles - 1) & 0x0fff; pwm.cycles = cycles; // supposedly we should stop FIFO when xMd is 0, // but mars test disagrees pwm.mult = 0; if ((control & 0x0f) != 0) pwm.mult = 0x10000 / cycles; pwm.irq_reload = (control & 0x0f00) >> 8; pwm.irq_reload = ((pwm.irq_reload - 1) & 0x0f) + 1; if (Pico32x.pwm_irq_cnt == 0) Pico32x.pwm_irq_cnt = pwm.irq_reload; } static void do_pwm_irq(SH2 *sh2, unsigned int m68k_cycles) { p32x_trigger_irq(sh2, m68k_cycles, P32XI_PWM); if (Pico32x.regs[0x30 / 2] & P32XP_RTP) { p32x_event_schedule(m68k_cycles, P32X_EVENT_PWM, pwm.cycles / 3 + 1); // note: might recurse p32x_dreq1_trigger(); } } static int convert_sample(unsigned int v) { if (v == 0) return 0; if (v > pwm.cycles) v = pwm.cycles; return (v * 2 - pwm.cycles) / 2 * pwm.mult; } #define consume_fifo(sh2, m68k_cycles) { \ int cycles_diff = ((m68k_cycles) * 3) - Pico32x.pwm_cycle_p; \ if (cycles_diff >= pwm.cycles) \ consume_fifo_do(sh2, m68k_cycles, cycles_diff); \ } static void consume_fifo_do(SH2 *sh2, unsigned int m68k_cycles, int sh2_cycles_diff) { struct Pico32xMem *mem = Pico32xMem; unsigned short *fifo_l = mem->pwm_fifo[0]; unsigned short *fifo_r = mem->pwm_fifo[1]; int sum = 0; if (pwm.cycles == 0 || pwm.doing_fifo) return; elprintf(EL_PWM, "pwm: %u: consume %d/%d, %d,%d ptr %d", m68k_cycles, sh2_cycles_diff, sh2_cycles_diff / pwm.cycles, Pico32x.pwm_p[0], Pico32x.pwm_p[1], pwm.ptr); // this is for recursion from dreq1 writes pwm.doing_fifo = 1; for (; sh2_cycles_diff >= pwm.cycles; sh2_cycles_diff -= pwm.cycles) { if (Pico32x.pwm_p[0] > 0) { mem->pwm_index[0] = (mem->pwm_index[0]+1) % 4; Pico32x.pwm_p[0]--; pwm.current[0] = convert_sample(fifo_l[mem->pwm_index[0]]); sum |=pwm.current[0]; } if (Pico32x.pwm_p[1] > 0) { mem->pwm_index[1] = (mem->pwm_index[1]+1) % 4; Pico32x.pwm_p[1]--; pwm.current[1] = convert_sample(fifo_r[mem->pwm_index[1]]); sum |= pwm.current[1]; } mem->pwm[pwm.ptr * 2 ] = pwm.current[0]; mem->pwm[pwm.ptr * 2 + 1] = pwm.current[1]; pwm.ptr = (pwm.ptr + 1) & (PWM_BUFF_LEN - 1); if (--Pico32x.pwm_irq_cnt == 0) { Pico32x.pwm_irq_cnt = pwm.irq_reload; do_pwm_irq(sh2, m68k_cycles); } } Pico32x.pwm_cycle_p = m68k_cycles * 3 - sh2_cycles_diff; pwm.doing_fifo = 0; if (sum != 0) pwm.silent = 0; } static int p32x_pwm_schedule_(SH2 *sh2, unsigned int m68k_now) { unsigned int pwm_now = m68k_now * 3; int cycles_diff_sh2; if (pwm.cycles == 0) return 0; cycles_diff_sh2 = pwm_now - Pico32x.pwm_cycle_p; if (cycles_diff_sh2 >= pwm.cycles) consume_fifo_do(sh2, m68k_now, cycles_diff_sh2); if (!((Pico32x.sh2irq_mask[0] | Pico32x.sh2irq_mask[1]) & 1)) return 0; // masked by everyone cycles_diff_sh2 = pwm_now - Pico32x.pwm_cycle_p; return (Pico32x.pwm_irq_cnt * pwm.cycles - cycles_diff_sh2) / 3 + 1; } void p32x_pwm_schedule(unsigned int m68k_now) { int after = p32x_pwm_schedule_(NULL, m68k_now); if (after != 0) p32x_event_schedule(m68k_now, P32X_EVENT_PWM, after); } void p32x_pwm_schedule_sh2(SH2 *sh2) { int after = p32x_pwm_schedule_(sh2, sh2_cycles_done_m68k(sh2)); if (after != 0) p32x_event_schedule_sh2(sh2, P32X_EVENT_PWM, after); } void p32x_pwm_sync_to_sh2(SH2 *sh2) { int m68k_cycles = sh2_cycles_done_m68k(sh2); consume_fifo(sh2, m68k_cycles); } void p32x_pwm_irq_event(unsigned int m68k_now) { p32x_pwm_schedule(m68k_now); } unsigned int p32x_pwm_read16(unsigned int a, SH2 *sh2, unsigned int m68k_cycles) { unsigned int d = 0; consume_fifo(sh2, m68k_cycles); a &= 0x0e; switch (a/2) { case 0/2: // control case 2/2: // cycle d = Pico32x.regs[(0x30 + a) / 2]; break; case 4/2: // L ch if (Pico32x.pwm_p[0] == 3) d |= P32XP_FULL; else if (Pico32x.pwm_p[0] == 0) d |= P32XP_EMPTY; break; case 6/2: // R ch case 8/2: // MONO if (Pico32x.pwm_p[1] == 3) d |= P32XP_FULL; else if (Pico32x.pwm_p[1] == 0) d |= P32XP_EMPTY; break; } elprintf(EL_PWM, "pwm: %u: r16 %02x %04x (p %d %d)", m68k_cycles, a, d, Pico32x.pwm_p[0], Pico32x.pwm_p[1]); return d; } void p32x_pwm_write16(unsigned int a, unsigned int d, SH2 *sh2, unsigned int m68k_cycles) { unsigned short *fifo; int idx; elprintf(EL_PWM, "pwm: %u: w16 %02x %04x (p %d %d)", m68k_cycles, a & 0x0e, d, Pico32x.pwm_p[0], Pico32x.pwm_p[1]); consume_fifo(sh2, m68k_cycles); a &= 0x0e; switch (a/2) { case 0/2: // control // avoiding pops.. if ((Pico32x.regs[0x30 / 2] & 0x0f) == 0) Pico32xMem->pwm_fifo[0][0] = Pico32xMem->pwm_fifo[1][0] = 0; Pico32x.regs[0x30 / 2] = d; p32x_pwm_ctl_changed(); Pico32x.pwm_irq_cnt = pwm.irq_reload; // ? break; case 2/2: // cycle Pico32x.regs[0x32 / 2] = d & 0x0fff; p32x_pwm_ctl_changed(); break; case 8/2: // MONO case 6/2: // R ch fifo = Pico32xMem->pwm_fifo[1]; idx = Pico32xMem->pwm_index[1]; if (Pico32x.pwm_p[1] < 3) Pico32x.pwm_p[1]++; else { // fifo[(idx+1) % 4] = fifo[idx]; idx = (idx+1) % 4; Pico32xMem->pwm_index[0] = idx; } fifo[(idx+Pico32x.pwm_p[1]) % 4] = (d - 1) & 0x0fff; if (a != 8) break; // fallthrough if MONO case 4/2: // L ch fifo = Pico32xMem->pwm_fifo[0]; idx = Pico32xMem->pwm_index[0]; if (Pico32x.pwm_p[0] < 3) Pico32x.pwm_p[0]++; else { // fifo[(idx+1) % 4] = fifo[idx]; idx = (idx+1) % 4; Pico32xMem->pwm_index[0] = idx; } fifo[(idx+Pico32x.pwm_p[0]) % 4] = (d - 1) & 0x0fff; break; } } void p32x_pwm_update(int *buf32, int length, int stereo) { short *pwmb; int step; int p = 0; int xmd; consume_fifo(NULL, SekCyclesDone()); xmd = Pico32x.regs[0x30 / 2] & 0x0f; if (xmd == 0 || xmd == 0x06 || xmd == 0x09 || xmd == 0x0f) goto out; // invalid? if (pwm.silent) return; step = (pwm.ptr << 16) / length; pwmb = Pico32xMem->pwm; if (stereo) { if (xmd == 0x05) { // normal while (length-- > 0) { *buf32++ += pwmb[0]; *buf32++ += pwmb[1]; p += step; pwmb += (p >> 16) * 2; p &= 0xffff; } } else if (xmd == 0x0a) { // channel swap while (length-- > 0) { *buf32++ += pwmb[1]; *buf32++ += pwmb[0]; p += step; pwmb += (p >> 16) * 2; p &= 0xffff; } } else { // mono - LMD, RMD specify dst if (xmd & 0x06) // src is R pwmb++; if (xmd & 0x0c) // dst is R buf32++; while (length-- > 0) { *buf32 += *pwmb; p += step; pwmb += (p >> 16) * 2; p &= 0xffff; buf32 += 2; } } } else { // mostly unused while (length-- > 0) { *buf32++ += pwmb[0]; p += step; pwmb += (p >> 16) * 2; p &= 0xffff; } } elprintf(EL_PWM, "pwm_update: pwm.ptr %d, len %d, step %04x, done %d", pwm.ptr, length, step, (pwmb - Pico32xMem->pwm) / 2); out: pwm.ptr = 0; pwm.silent = pwm.current[0] == 0 && pwm.current[1] == 0; } void p32x_pwm_state_loaded(void) { int cycles_diff_sh2; p32x_pwm_ctl_changed(); // for old savestates cycles_diff_sh2 = Pico.t.m68c_cnt * 3 - Pico32x.pwm_cycle_p; if (cycles_diff_sh2 >= pwm.cycles || cycles_diff_sh2 < 0) { Pico32x.pwm_irq_cnt = pwm.irq_reload; Pico32x.pwm_cycle_p = Pico.t.m68c_cnt * 3; p32x_pwm_schedule(Pico.t.m68c_cnt); } } // vim:shiftwidth=2:ts=2:expandtab