// Project64 - A Nintendo 64 emulator
// http://www.pj64-emu.com/
// Copyright(C) 2001-2021 Project64
// Copyright(C) 2013 Bobby Smiles
// GNU/GPLv2 licensed: https://gnu.org/licenses/gpl-2.0.html
#include "stdafx.h"
#include <string.h>
#include "arithmetics.h"
#include "audio.h"
#include "mem.h"
// Various constants
enum { SUBFRAME_SIZE = 192 };
enum { MAX_VOICES = 32 };
enum { SAMPLE_BUFFER_SIZE = 0x200 };
enum
{
SFD_SFX_INDEX = 0x2,
SFD_VOICE_BITMASK = 0x4,
SFD_STATE_PTR = 0x8,
SFD_SFX_PTR = 0xc,
SFD_VOICES = 0x10,
// v2 only
SFD2_10_PTR = 0x10,
SFD2_14_BITMASK = 0x14,
SFD2_15_BITMASK = 0x15,
SFD2_16_BITMASK = 0x16,
SFD2_18_PTR = 0x18,
SFD2_1C_PTR = 0x1c,
SFD2_20_PTR = 0x20,
SFD2_24_PTR = 0x24,
SFD2_VOICES = 0x28
};
enum
{
VOICE_ENV_BEGIN = 0x00,
VOICE_ENV_STEP = 0x10,
VOICE_PITCH_Q16 = 0x20,
VOICE_PITCH_SHIFT = 0x22,
VOICE_CATSRC_0 = 0x24,
VOICE_CATSRC_1 = 0x30,
VOICE_ADPCM_FRAMES = 0x3c,
VOICE_SKIP_SAMPLES = 0x3e,
// For PCM16
VOICE_U16_40 = 0x40,
VOICE_U16_42 = 0x42,
// For ADPCM
VOICE_ADPCM_TABLE_PTR = 0x40,
VOICE_INTERLEAVED_PTR = 0x44,
VOICE_END_POINT = 0x48,
VOICE_RESTART_POINT = 0x4a,
VOICE_U16_4E = 0x4e,
VOICE_SIZE = 0x50
};
enum
{
CATSRC_PTR1 = 0x00,
CATSRC_PTR2 = 0x04,
CATSRC_SIZE1 = 0x08,
CATSRC_SIZE2 = 0x0a
};
enum
{
STATE_LAST_SAMPLE = 0x0,
STATE_BASE_VOL = 0x100,
STATE_CC0 = 0x110,
STATE_740_LAST4_V1 = 0x290,
STATE_740_LAST4_V2 = 0x110
};
enum
{
SFX_CBUFFER_PTR = 0x00,
SFX_CBUFFER_LENGTH = 0x04,
SFX_TAP_COUNT = 0x08,
SFX_FIR4_HGAIN = 0x0a,
SFX_TAP_DELAYS = 0x0c,
SFX_TAP_GAINS = 0x2c,
SFX_U16_3C = 0x3c,
SFX_U16_3E = 0x3e,
SFX_FIR4_HCOEFFS = 0x40
};
// Struct definition
typedef struct
{
// Internal sub-frames
int16_t left[SUBFRAME_SIZE];
int16_t right[SUBFRAME_SIZE];
int16_t cc0[SUBFRAME_SIZE];
int16_t e50[SUBFRAME_SIZE];
// Internal sub-frames base volumes
int32_t base_vol[4];
// TODO: comment?
int16_t subframe_740_last4[4];
} musyx_t;
typedef void (*mix_sfx_with_main_subframes_t)(musyx_t *musyx, const int16_t *subframe, const uint16_t* gains);
// Helper functions prototypes
static void load_base_vol(CHle * hle, int32_t *base_vol, uint32_t address);
static void save_base_vol(CHle * hle, const int32_t *base_vol, uint32_t address);
static void update_base_vol(CHle * hle, int32_t *base_vol, uint32_t voice_mask, uint32_t last_sample_ptr, uint8_t mask_15, uint32_t ptr_24);
static void init_subframes_v1(musyx_t *musyx);
static void init_subframes_v2(musyx_t *musyx);
static uint32_t voice_stage(CHle * hle, musyx_t *musyx, uint32_t voice_ptr, uint32_t last_sample_ptr);
static void dma_cat8(CHle * hle, uint8_t *dst, uint32_t catsrc_ptr);
static void dma_cat16(CHle * hle, uint16_t *dst, uint32_t catsrc_ptr);
static void sfx_stage(CHle * hle, mix_sfx_with_main_subframes_t mix_sfx_with_main_subframes, musyx_t *musyx, uint32_t sfx_ptr, uint16_t idx);
static void load_samples_PCM16(CHle * hle, uint32_t voice_ptr, int16_t *samples, unsigned *segbase, unsigned *offset);
static void load_samples_ADPCM(CHle * hle, uint32_t voice_ptr, int16_t *samples, unsigned *segbase, unsigned *offset);
static void mix_voice_samples(CHle * hle, musyx_t *musyx, uint32_t voice_ptr, const int16_t *samples, unsigned segbase, unsigned offset, uint32_t last_sample_ptr);
static void adpcm_decode_frames(CHle * hle, int16_t *dst, const uint8_t *src, const int16_t *table, uint8_t count, uint8_t skip_samples);
static void adpcm_predict_frame(int16_t *dst, const uint8_t *src, const uint8_t *nibbles, unsigned int rshift);
static void mix_sfx_with_main_subframes_v1(musyx_t *musyx, const int16_t *subframe, const uint16_t* gains);
static void mix_sfx_with_main_subframes_v2(musyx_t *musyx, const int16_t *subframe, const uint16_t* gains);
static void mix_samples(int16_t *y, int16_t x, int16_t hgain);
static void mix_subframes(int16_t *y, const int16_t *x, int16_t hgain);
static void mix_fir4(int16_t *y, const int16_t *x, int16_t hgain, const int16_t *hcoeffs);
static void interleave_stage_v1(CHle * hle, musyx_t *musyx, uint32_t output_ptr);
static void interleave_stage_v2(CHle * hle, musyx_t *musyx, uint16_t mask_16, uint32_t ptr_18, uint32_t ptr_1c, uint32_t output_ptr);
static int32_t dot4(const int16_t *x, const int16_t *y)
{
int32_t accu = 0;
for (size_t i = 0; i < 4; ++i)
{
accu = clamp_s16(accu + (((int32_t)x[i] * (int32_t)y[i]) >> 15));
}
return accu;
}
// MusyX v1 audio microcode
void musyx_v1_task(CHle * hle)
{
uint32_t sfd_ptr = *dmem_u32(hle, TASK_DATA_PTR);
uint32_t sfd_count = *dmem_u32(hle, TASK_DATA_SIZE);
uint32_t state_ptr;
musyx_t musyx;
hle->VerboseMessage("musyx_v1_task: *data=%x, #SF=%d", sfd_ptr,sfd_count);
state_ptr = *dram_u32(hle, sfd_ptr + SFD_STATE_PTR);
// Load initial state
load_base_vol(hle, musyx.base_vol, state_ptr + STATE_BASE_VOL);
dram_load_u16(hle, (uint16_t *)musyx.cc0, state_ptr + STATE_CC0, SUBFRAME_SIZE);
dram_load_u16(hle, (uint16_t *)musyx.subframe_740_last4, state_ptr + STATE_740_LAST4_V1, 4);
for (;;)
{
// Parse SFD structure
uint16_t sfx_index = *dram_u16(hle, sfd_ptr + SFD_SFX_INDEX);
uint32_t voice_mask = *dram_u32(hle, sfd_ptr + SFD_VOICE_BITMASK);
uint32_t sfx_ptr = *dram_u32(hle, sfd_ptr + SFD_SFX_PTR);
uint32_t voice_ptr = sfd_ptr + SFD_VOICES;
uint32_t last_sample_ptr = state_ptr + STATE_LAST_SAMPLE;
uint32_t output_ptr;
// Initialize internal sub-frames using updated base volumes
update_base_vol(hle, musyx.base_vol, voice_mask, last_sample_ptr, 0, 0);
init_subframes_v1(&musyx);
// Active voices get mixed into L,R,cc0,e50 subframes (optional)
output_ptr = voice_stage(hle, &musyx, voice_ptr, last_sample_ptr);
// Apply delay-based effects (optional)
sfx_stage(hle, mix_sfx_with_main_subframes_v1, &musyx, sfx_ptr, sfx_index);
// Emit interleaved L,R sub-frames
interleave_stage_v1(hle, &musyx, output_ptr);
--sfd_count;
if (sfd_count == 0)
{
break;
}
sfd_ptr += SFD_VOICES + MAX_VOICES * VOICE_SIZE;
state_ptr = *dram_u32(hle, sfd_ptr + SFD_STATE_PTR);
}
// Writeback updated state
save_base_vol(hle, musyx.base_vol, state_ptr + STATE_BASE_VOL);
dram_store_u16(hle, (uint16_t *)musyx.cc0, state_ptr + STATE_CC0, SUBFRAME_SIZE);
dram_store_u16(hle, (uint16_t *)musyx.subframe_740_last4, state_ptr + STATE_740_LAST4_V1, 4);
}
// MusyX v2 audio microcode
void musyx_v2_task(CHle * hle)
{
uint32_t sfd_ptr = *dmem_u32(hle, TASK_DATA_PTR);
uint32_t sfd_count = *dmem_u32(hle, TASK_DATA_SIZE);
musyx_t musyx;
hle->VerboseMessage("musyx_v2_task: *data=%x, #SF=%d", sfd_ptr, sfd_count);
for (;;)
{
// Parse SFD structure
uint16_t sfx_index = *dram_u16(hle, sfd_ptr + SFD_SFX_INDEX);
uint32_t voice_mask = *dram_u32(hle, sfd_ptr + SFD_VOICE_BITMASK);
uint32_t state_ptr = *dram_u32(hle, sfd_ptr + SFD_STATE_PTR);
uint32_t sfx_ptr = *dram_u32(hle, sfd_ptr + SFD_SFX_PTR);
uint32_t voice_ptr = sfd_ptr + SFD2_VOICES;
uint32_t ptr_10 = *dram_u32(hle, sfd_ptr + SFD2_10_PTR);
uint8_t mask_14 = *dram_u8 (hle, sfd_ptr + SFD2_14_BITMASK);
uint8_t mask_15 = *dram_u8 (hle, sfd_ptr + SFD2_15_BITMASK);
uint16_t mask_16 = *dram_u16(hle, sfd_ptr + SFD2_16_BITMASK);
uint32_t ptr_18 = *dram_u32(hle, sfd_ptr + SFD2_18_PTR);
uint32_t ptr_1c = *dram_u32(hle, sfd_ptr + SFD2_1C_PTR);
uint32_t ptr_20 = *dram_u32(hle, sfd_ptr + SFD2_20_PTR);
uint32_t ptr_24 = *dram_u32(hle, sfd_ptr + SFD2_24_PTR);
uint32_t last_sample_ptr = state_ptr + STATE_LAST_SAMPLE;
uint32_t output_ptr;
// Load state
load_base_vol(hle, musyx.base_vol, state_ptr + STATE_BASE_VOL);
dram_load_u16(hle, (uint16_t *)musyx.subframe_740_last4, state_ptr + STATE_740_LAST4_V2, 4);
// Initialize internal sub-frames using updated base volumes
update_base_vol(hle, musyx.base_vol, voice_mask, last_sample_ptr, mask_15, ptr_24);
init_subframes_v2(&musyx);
if (ptr_10)
{
// TODO:
hle->WarnMessage("ptr_10=%08x mask_14=%02x ptr_24=%08x", ptr_10, mask_14, ptr_24);
}
// Active voices get mixed into L,R,cc0,e50 sub-frames (optional)
output_ptr = voice_stage(hle, &musyx, voice_ptr, last_sample_ptr);
// Apply delay-based effects (optional)
sfx_stage(hle, mix_sfx_with_main_subframes_v2, &musyx, sfx_ptr, sfx_index);
dram_store_u16(hle, (uint16_t*)musyx.left, output_ptr , SUBFRAME_SIZE);
dram_store_u16(hle, (uint16_t*)musyx.right, output_ptr + 2*SUBFRAME_SIZE, SUBFRAME_SIZE);
dram_store_u16(hle, (uint16_t*)musyx.cc0, output_ptr + 4*SUBFRAME_SIZE, SUBFRAME_SIZE);
// Store state
save_base_vol(hle, musyx.base_vol, state_ptr + STATE_BASE_VOL);
dram_store_u16(hle, (uint16_t*)musyx.subframe_740_last4, state_ptr + STATE_740_LAST4_V2, 4);
if (mask_16)
{
interleave_stage_v2(hle, &musyx, mask_16, ptr_18, ptr_1c, ptr_20);
}
--sfd_count;
if (sfd_count == 0)
{
break;
}
sfd_ptr += SFD2_VOICES + MAX_VOICES * VOICE_SIZE;
}
}
static void load_base_vol(CHle * hle, int32_t *base_vol, uint32_t address)
{
base_vol[0] = ((uint32_t)(*dram_u16(hle, address)) << 16) | (*dram_u16(hle, address + 8));
base_vol[1] = ((uint32_t)(*dram_u16(hle, address + 2)) << 16) | (*dram_u16(hle, address + 10));
base_vol[2] = ((uint32_t)(*dram_u16(hle, address + 4)) << 16) | (*dram_u16(hle, address + 12));
base_vol[3] = ((uint32_t)(*dram_u16(hle, address + 6)) << 16) | (*dram_u16(hle, address + 14));
}
static void save_base_vol(CHle * hle, const int32_t *base_vol, uint32_t address)
{
unsigned k;
for (k = 0; k < 4; ++k)
{
*dram_u16(hle, address) = (uint16_t)(base_vol[k] >> 16);
address += 2;
}
for (k = 0; k < 4; ++k)
{
*dram_u16(hle, address) = (uint16_t)(base_vol[k]);
address += 2;
}
}
static void update_base_vol(CHle * hle, int32_t *base_vol,
uint32_t voice_mask, uint32_t last_sample_ptr,
uint8_t mask_15, uint32_t ptr_24)
{
unsigned i, k;
uint32_t mask;
hle->VerboseMessage("base_vol voice_mask = %08x", voice_mask);
hle->VerboseMessage("BEFORE: base_vol = %08x %08x %08x %08x", base_vol[0], base_vol[1], base_vol[2], base_vol[3]);
// optimization: skip voices contributions entirely if voice_mask is empty
if (voice_mask != 0)
{
for (i = 0, mask = 1; i < MAX_VOICES; ++i, mask <<= 1, last_sample_ptr += 8)
{
if ((voice_mask & mask) == 0)
{
continue;
}
for (k = 0; k < 4; ++k)
{
base_vol[k] += (int16_t)*dram_u16(hle, last_sample_ptr + k * 2);
}
}
}
// optimization: skip contributions entirely if mask_15 is empty
if (mask_15 != 0)
{
for(i = 0, mask = 1; i < 4; ++i, mask <<= 1, ptr_24 += 8)
{
if ((mask_15 & mask) == 0)
{
continue;
}
for(k = 0; k < 4; ++k)
{
base_vol[k] += (int16_t)*dram_u16(hle, ptr_24 + k * 2);
}
}
}
// Apply 3% decay
for (k = 0; k < 4; ++k)
{
base_vol[k] = (base_vol[k] * 0x0000f850) >> 16;
}
hle->VerboseMessage("AFTER: base_vol = %08x %08x %08x %08x", base_vol[0], base_vol[1], base_vol[2], base_vol[3]);
}
static void init_subframes_v1(musyx_t *musyx)
{
unsigned i;
int16_t base_cc0 = clamp_s16(musyx->base_vol[2]);
int16_t base_e50 = clamp_s16(musyx->base_vol[3]);
int16_t *left = musyx->left;
int16_t *right = musyx->right;
int16_t *cc0 = musyx->cc0;
int16_t *e50 = musyx->e50;
for (i = 0; i < SUBFRAME_SIZE; ++i)
{
*(e50++) = base_e50;
*(left++) = clamp_s16(*cc0 + base_cc0);
*(right++) = clamp_s16(-*cc0 - base_cc0);
*(cc0++) = 0;
}
}
static void init_subframes_v2(musyx_t *musyx)
{
unsigned i,k;
int16_t values[4];
int16_t* subframes[4];
for(k = 0; k < 4; ++k)
{
values[k] = clamp_s16(musyx->base_vol[k]);
}
subframes[0] = musyx->left;
subframes[1] = musyx->right;
subframes[2] = musyx->cc0;
subframes[3] = musyx->e50;
for (i = 0; i < SUBFRAME_SIZE; ++i)
{
for(k = 0; k < 4; ++k)
{
*(subframes[k]++) = values[k];
}
}
}
// Process voices, and returns interleaved sub-frame destination address
static uint32_t voice_stage(CHle * hle, musyx_t *musyx, uint32_t voice_ptr, uint32_t last_sample_ptr)
{
uint32_t output_ptr;
int i = 0;
// Voice stage can be skipped if first voice has no samples
if (*dram_u16(hle, voice_ptr + VOICE_CATSRC_0 + CATSRC_SIZE1) == 0)
{
hle->VerboseMessage("Skipping voice stage");
output_ptr = *dram_u32(hle, voice_ptr + VOICE_INTERLEAVED_PTR);
}
else
{
// Otherwise process voices until a non null output_ptr is encountered
for (;;)
{
// Load voice samples (PCM16 or APDCM)
int16_t samples[SAMPLE_BUFFER_SIZE];
unsigned segbase;
unsigned offset;
hle->VerboseMessage("Processing voice #%d", i);
if (*dram_u8(hle, voice_ptr + VOICE_ADPCM_FRAMES) == 0)
{
load_samples_PCM16(hle, voice_ptr, samples, &segbase, &offset);
}
else
{
load_samples_ADPCM(hle, voice_ptr, samples, &segbase, &offset);
}
// Mix them with each internal sub-frame
mix_voice_samples(hle, musyx, voice_ptr, samples, segbase, offset, last_sample_ptr + i * 8);
// Check break condition
output_ptr = *dram_u32(hle, voice_ptr + VOICE_INTERLEAVED_PTR);
if (output_ptr != 0)
{
break;
}
// Next voice
++i;
voice_ptr += VOICE_SIZE;
}
}
return output_ptr;
}
static void dma_cat8(CHle * hle, uint8_t *dst, uint32_t catsrc_ptr)
{
uint32_t ptr1 = *dram_u32(hle, catsrc_ptr + CATSRC_PTR1);
uint32_t ptr2 = *dram_u32(hle, catsrc_ptr + CATSRC_PTR2);
uint16_t size1 = *dram_u16(hle, catsrc_ptr + CATSRC_SIZE1);
uint16_t size2 = *dram_u16(hle, catsrc_ptr + CATSRC_SIZE2);
size_t count1 = size1;
size_t count2 = size2;
hle->VerboseMessage("dma_cat: %08x %08x %04x %04x", ptr1, ptr2, size1, size2);
dram_load_u8(hle, dst, ptr1, count1);
if (size2 == 0)
{
return;
}
dram_load_u8(hle, dst + count1, ptr2, count2);
}
static void dma_cat16(CHle * hle, uint16_t *dst, uint32_t catsrc_ptr)
{
uint32_t ptr1 = *dram_u32(hle, catsrc_ptr + CATSRC_PTR1);
uint32_t ptr2 = *dram_u32(hle, catsrc_ptr + CATSRC_PTR2);
uint16_t size1 = *dram_u16(hle, catsrc_ptr + CATSRC_SIZE1);
uint16_t size2 = *dram_u16(hle, catsrc_ptr + CATSRC_SIZE2);
size_t count1 = size1 >> 1;
size_t count2 = size2 >> 1;
hle->VerboseMessage("dma_cat: %08x %08x %04x %04x", ptr1, ptr2, size1, size2);
dram_load_u16(hle, dst, ptr1, count1);
if (size2 == 0)
{
return;
}
dram_load_u16(hle, dst + count1, ptr2, count2);
}
static void load_samples_PCM16(CHle * hle, uint32_t voice_ptr, int16_t *samples, unsigned *segbase, unsigned *offset)
{
uint8_t u8_3e = *dram_u8(hle, voice_ptr + VOICE_SKIP_SAMPLES);
uint16_t u16_40 = *dram_u16(hle, voice_ptr + VOICE_U16_40);
uint16_t u16_42 = *dram_u16(hle, voice_ptr + VOICE_U16_42);
unsigned count = align(u16_40 + u8_3e, 4);
hle->VerboseMessage("Format: PCM16");
*segbase = SAMPLE_BUFFER_SIZE - count;
*offset = u8_3e;
dma_cat16(hle, (uint16_t *)samples + *segbase, voice_ptr + VOICE_CATSRC_0);
if (u16_42 != 0)
{
dma_cat16(hle, (uint16_t *)samples, voice_ptr + VOICE_CATSRC_1);
}
}
static void load_samples_ADPCM(CHle * hle, uint32_t voice_ptr, int16_t *samples, unsigned *segbase, unsigned *offset)
{
// Decompressed samples cannot exceed 0x400 bytes
// ADPCM has a compression ratio of 5/16
uint8_t buffer[SAMPLE_BUFFER_SIZE * 2 * 5 / 16];
int16_t adpcm_table[128];
uint8_t u8_3c = *dram_u8(hle, voice_ptr + VOICE_ADPCM_FRAMES );
uint8_t u8_3d = *dram_u8(hle, voice_ptr + VOICE_ADPCM_FRAMES + 1);
uint8_t u8_3e = *dram_u8(hle, voice_ptr + VOICE_SKIP_SAMPLES );
uint8_t u8_3f = *dram_u8(hle, voice_ptr + VOICE_SKIP_SAMPLES + 1);
uint32_t adpcm_table_ptr = *dram_u32(hle, voice_ptr + VOICE_ADPCM_TABLE_PTR);
unsigned count;
hle->VerboseMessage("Format: ADPCM");
hle->VerboseMessage("Loading ADPCM table: %08x", adpcm_table_ptr);
dram_load_u16(hle, (uint16_t *)adpcm_table, adpcm_table_ptr, 128);
count = u8_3c << 5;
*segbase = SAMPLE_BUFFER_SIZE - count;
*offset = u8_3e & 0x1f;
dma_cat8(hle, buffer, voice_ptr + VOICE_CATSRC_0);
adpcm_decode_frames(hle, samples + *segbase, buffer, adpcm_table, u8_3c, u8_3e);
if (u8_3d != 0)
{
dma_cat8(hle, buffer, voice_ptr + VOICE_CATSRC_1);
adpcm_decode_frames(hle, samples, buffer, adpcm_table, u8_3d, u8_3f);
}
}
static void adpcm_decode_frames(CHle * hle, int16_t *dst, const uint8_t *src, const int16_t *table, uint8_t count, uint8_t skip_samples)
{
int16_t frame[32];
const uint8_t *nibbles = src + 8;
unsigned i;
bool jump_gap = false;
hle->VerboseMessage("ADPCM decode: count=%d, skip=%d", count, skip_samples);
if (skip_samples >= 32)
{
jump_gap = true;
nibbles += 16;
src += 4;
}
for (i = 0; i < count; ++i)
{
uint8_t c2 = nibbles[0];
const int16_t *book = (c2 & 0xf0) + table;
unsigned int rshift = (c2 & 0x0f);
adpcm_predict_frame(frame, src, nibbles, rshift);
memcpy(dst, frame, 2 * sizeof(frame[0]));
adpcm_compute_residuals(dst + 2, frame + 2, book, dst , 6);
adpcm_compute_residuals(dst + 8, frame + 8, book, dst + 6, 8);
adpcm_compute_residuals(dst + 16, frame + 16, book, dst + 14, 8);
adpcm_compute_residuals(dst + 24, frame + 24, book, dst + 22, 8);
if (jump_gap)
{
nibbles += 8;
src += 32;
}
jump_gap = !jump_gap;
nibbles += 16;
src += 4;
dst += 32;
}
}
static void adpcm_predict_frame(int16_t *dst, const uint8_t *src, const uint8_t *nibbles, unsigned int rshift)
{
unsigned int i;
*(dst++) = (src[0] << 8) | src[1];
*(dst++) = (src[2] << 8) | src[3];
for (i = 1; i < 16; ++i)
{
uint8_t byte = nibbles[i];
*(dst++) = adpcm_predict_sample(byte, 0xf0, 8, rshift);
*(dst++) = adpcm_predict_sample(byte, 0x0f, 12, rshift);
}
}
static void mix_voice_samples(CHle * hle, musyx_t *musyx, uint32_t voice_ptr, const int16_t *samples, unsigned segbase, unsigned offset, uint32_t last_sample_ptr)
{
int i, k;
// Parse VOICE structure
const uint16_t pitch_q16 = *dram_u16(hle, voice_ptr + VOICE_PITCH_Q16);
const uint16_t pitch_shift = *dram_u16(hle, voice_ptr + VOICE_PITCH_SHIFT); // Q4.12
const uint16_t end_point = *dram_u16(hle, voice_ptr + VOICE_END_POINT);
const uint16_t restart_point = *dram_u16(hle, voice_ptr + VOICE_RESTART_POINT);
const uint16_t u16_4e = *dram_u16(hle, voice_ptr + VOICE_U16_4E);
// Initialize values and pointers
const int16_t *sample = samples + segbase + offset + u16_4e;
const int16_t *const sample_end = samples + segbase + end_point;
const int16_t *const sample_restart = samples + (restart_point & 0x7fff) +
(((restart_point & 0x8000) != 0) ? 0x000 : segbase);
uint32_t pitch_accu = pitch_q16;
uint32_t pitch_step = pitch_shift << 4;
int32_t v4_env[4];
int32_t v4_env_step[4];
int16_t *v4_dst[4];
int16_t v4[4];
dram_load_u32(hle, (uint32_t *)v4_env, voice_ptr + VOICE_ENV_BEGIN, 4);
dram_load_u32(hle, (uint32_t *)v4_env_step, voice_ptr + VOICE_ENV_STEP, 4);
v4_dst[0] = musyx->left;
v4_dst[1] = musyx->right;
v4_dst[2] = musyx->cc0;
v4_dst[3] = musyx->e50;
hle->VerboseMessage("Voice debug: segbase=%d" "\tu16_4e=%04x\n" "\tpitch: frac0=%04x shift=%04x\n" "\tend_point=%04x restart_point=%04x\n" "\tenv = %08x %08x %08x %08x\n" "\tenv_step = %08x %08x %08x %08x\n", segbase, u16_4e, pitch_q16, pitch_shift, end_point, restart_point, v4_env[0], v4_env[1], v4_env[2], v4_env[3], v4_env_step[0], v4_env_step[1], v4_env_step[2], v4_env_step[3]);
for (i = 0; i < SUBFRAME_SIZE; ++i)
{
// Update sample and LUT pointers and then pitch_accu
const int16_t *lut = (RESAMPLE_LUT + ((pitch_accu & 0xfc00) >> 8));
int dist;
int16_t v;
sample += (pitch_accu >> 16);
pitch_accu &= 0xffff;
pitch_accu += pitch_step;
// Handle end/restart points
dist = sample - sample_end;
if (dist >= 0)
{
sample = sample_restart + dist;
}
// Apply resample filter
v = clamp_s16(dot4(sample, lut));
for (k = 0; k < 4; ++k)
{
// Envmix
int32_t accu = (v * (v4_env[k] >> 16)) >> 15;
v4[k] = clamp_s16(accu);
*(v4_dst[k]) = clamp_s16(accu + *(v4_dst[k]));
// Update envelopes and DST pointers
++(v4_dst[k]);
v4_env[k] += v4_env_step[k];
}
}
// Save last resampled sample
dram_store_u16(hle, (uint16_t *)v4, last_sample_ptr, 4);
hle->VerboseMessage("last_sample = %04x %04x %04x %04x", v4[0], v4[1], v4[2], v4[3]);
}
static void sfx_stage(CHle * hle, mix_sfx_with_main_subframes_t mix_sfx_with_main_subframes, musyx_t *musyx, uint32_t sfx_ptr, uint16_t idx)
{
unsigned int i;
int16_t buffer[SUBFRAME_SIZE + 4];
int16_t *subframe = buffer + 4;
uint32_t tap_delays[8];
int16_t tap_gains[8];
int16_t fir4_hcoeffs[4];
int16_t delayed[SUBFRAME_SIZE];
int dpos, dlength;
const uint32_t pos = idx * SUBFRAME_SIZE;
uint32_t cbuffer_ptr;
uint32_t cbuffer_length;
uint16_t tap_count;
int16_t fir4_hgain;
uint16_t sfx_gains[2];
hle->VerboseMessage("SFX: %08x, idx=%d", sfx_ptr, idx);
if (sfx_ptr == 0)
{
return;
}
// Load SFX parameters
cbuffer_ptr = *dram_u32(hle, sfx_ptr + SFX_CBUFFER_PTR);
cbuffer_length = *dram_u32(hle, sfx_ptr + SFX_CBUFFER_LENGTH);
tap_count = *dram_u16(hle, sfx_ptr + SFX_TAP_COUNT);
dram_load_u32(hle, tap_delays, sfx_ptr + SFX_TAP_DELAYS, 8);
dram_load_u16(hle, (uint16_t *)tap_gains, sfx_ptr + SFX_TAP_GAINS, 8);
fir4_hgain = *dram_u16(hle, sfx_ptr + SFX_FIR4_HGAIN);
dram_load_u16(hle, (uint16_t *)fir4_hcoeffs, sfx_ptr + SFX_FIR4_HCOEFFS, 4);
sfx_gains[0] = *dram_u16(hle, sfx_ptr + SFX_U16_3C);
sfx_gains[1] = *dram_u16(hle, sfx_ptr + SFX_U16_3E);
hle->VerboseMessage("cbuffer: ptr=%08x length=%x", cbuffer_ptr, cbuffer_length);
hle->VerboseMessage("fir4: hgain=%04x hcoeff=%04x %04x %04x %04x", fir4_hgain, fir4_hcoeffs[0], fir4_hcoeffs[1], fir4_hcoeffs[2], fir4_hcoeffs[3]);
hle->VerboseMessage("tap count=%d\n" "delays: %08x %08x %08x %08x %08x %08x %08x %08x\n" "gains: %04x %04x %04x %04x %04x %04x %04x %04x", tap_count, tap_delays[0], tap_delays[1], tap_delays[2], tap_delays[3], tap_delays[4], tap_delays[5], tap_delays[6], tap_delays[7], tap_gains[0], tap_gains[1], tap_gains[2], tap_gains[3], tap_gains[4], tap_gains[5], tap_gains[6], tap_gains[7]);
hle->VerboseMessage("sfx_gains=%04x %04x", sfx_gains[0], sfx_gains[1]);
// Mix up to 8 delayed sub-frames
memset(subframe, 0, SUBFRAME_SIZE * sizeof(subframe[0]));
for (i = 0; i < tap_count; ++i)
{
dpos = pos - tap_delays[i];
if (dpos <= 0)
{
dpos += cbuffer_length;
}
dlength = SUBFRAME_SIZE;
if ((uint32_t)(dpos + SUBFRAME_SIZE) > cbuffer_length)
{
dlength = cbuffer_length - dpos;
dram_load_u16(hle, (uint16_t *)delayed + dlength, cbuffer_ptr, SUBFRAME_SIZE - dlength);
}
dram_load_u16(hle, (uint16_t *)delayed, cbuffer_ptr + dpos * 2, dlength);
mix_subframes(subframe, delayed, tap_gains[i]);
}
// Add resulting sub-frame to main sub-frames
mix_sfx_with_main_subframes(musyx, subframe, sfx_gains);
// Apply FIR4 filter and writeback filtered result
memcpy(buffer, musyx->subframe_740_last4, 4 * sizeof(int16_t));
memcpy(musyx->subframe_740_last4, subframe + SUBFRAME_SIZE - 4, 4 * sizeof(int16_t));
mix_fir4(musyx->e50, buffer + 1, fir4_hgain, fir4_hcoeffs);
dram_store_u16(hle, (uint16_t *)musyx->e50, cbuffer_ptr + pos * 2, SUBFRAME_SIZE);
}
static void mix_sfx_with_main_subframes_v1(musyx_t *musyx, const int16_t *subframe, const uint16_t* UNUSED(gains))
{
unsigned i;
for (i = 0; i < SUBFRAME_SIZE; ++i)
{
int16_t v = subframe[i];
musyx->left[i] = clamp_s16(musyx->left[i] + v);
musyx->right[i] = clamp_s16(musyx->right[i] + v);
}
}
static void mix_sfx_with_main_subframes_v2(musyx_t *musyx, const int16_t *subframe, const uint16_t* gains)
{
unsigned i;
for (i = 0; i < SUBFRAME_SIZE; ++i)
{
int16_t v = subframe[i];
int16_t v1 = (int32_t)(v * gains[0]) >> 16;
int16_t v2 = (int32_t)(v * gains[1]) >> 16;
musyx->left[i] = clamp_s16(musyx->left[i] + v1);
musyx->right[i] = clamp_s16(musyx->right[i] + v1);
musyx->cc0[i] = clamp_s16(musyx->cc0[i] + v2);
}
}
static void mix_samples(int16_t *y, int16_t x, int16_t hgain)
{
*y = clamp_s16(*y + ((x * hgain + 0x4000) >> 15));
}
static void mix_subframes(int16_t *y, const int16_t *x, int16_t hgain)
{
for (unsigned int i = 0; i < SUBFRAME_SIZE; ++i)
{
mix_samples(&y[i], x[i], hgain);
}
}
static void mix_fir4(int16_t *y, const int16_t *x, int16_t hgain, const int16_t *hcoeffs)
{
unsigned int i;
int32_t h[4];
h[0] = (hgain * hcoeffs[0]) >> 15;
h[1] = (hgain * hcoeffs[1]) >> 15;
h[2] = (hgain * hcoeffs[2]) >> 15;
h[3] = (hgain * hcoeffs[3]) >> 15;
for (i = 0; i < SUBFRAME_SIZE; ++i)
{
int32_t v = (h[0] * x[i] + h[1] * x[i + 1] + h[2] * x[i + 2] + h[3] * x[i + 3]) >> 15;
y[i] = clamp_s16(y[i] + v);
}
}
static void interleave_stage_v1(CHle * hle, musyx_t *musyx, uint32_t output_ptr)
{
size_t i;
int16_t base_left;
int16_t base_right;
int16_t *left;
int16_t *right;
uint32_t *dst;
hle->VerboseMessage("interleave: %08x", output_ptr);
base_left = clamp_s16(musyx->base_vol[0]);
base_right = clamp_s16(musyx->base_vol[1]);
left = musyx->left;
right = musyx->right;
dst = dram_u32(hle, output_ptr);
for (i = 0; i < SUBFRAME_SIZE; ++i)
{
uint16_t l = clamp_s16(*(left++) + base_left);
uint16_t r = clamp_s16(*(right++) + base_right);
*(dst++) = (l << 16) | r;
}
}
static void interleave_stage_v2(CHle * hle, musyx_t *musyx, uint16_t mask_16, uint32_t ptr_18, uint32_t ptr_1c, uint32_t output_ptr)
{
unsigned i, k;
int16_t subframe[SUBFRAME_SIZE];
uint32_t *dst;
uint16_t mask;
hle->VerboseMessage("mask_16=%04x ptr_18=%08x ptr_1c=%08x output_ptr=%08x", mask_16, ptr_18, ptr_1c, output_ptr);
// Compute L_total, R_total and update sub-frame @ptr_1c
memset(subframe, 0, SUBFRAME_SIZE*sizeof(subframe[0]));
for(i = 0; i < SUBFRAME_SIZE; ++i)
{
int16_t v = *dram_u16(hle, ptr_1c + i*2);
musyx->left[i] = v;
musyx->right[i] = clamp_s16(-v);
}
for (k = 0, mask = 1; k < 8; ++k, mask <<= 1, ptr_18 += 8)
{
int16_t hgain;
uint32_t address;
if ((mask_16 & mask) == 0)
{
continue;
}
address = *dram_u32(hle, ptr_18);
hgain = *dram_u16(hle, ptr_18 + 4);
for(i = 0; i < SUBFRAME_SIZE; ++i, address += 2)
{
mix_samples(&musyx->left[i], *dram_u16(hle, address), hgain);
mix_samples(&musyx->right[i], *dram_u16(hle, address + 2*SUBFRAME_SIZE), hgain);
mix_samples(&subframe[i], *dram_u16(hle, address + 4*SUBFRAME_SIZE), hgain);
}
}
// Interleave L_total and R_total
dst = dram_u32(hle, output_ptr);
for(i = 0; i < SUBFRAME_SIZE; ++i)
{
uint16_t l = musyx->left[i];
uint16_t r = musyx->right[i];
*(dst++) = (l << 16) | r;
}
// Writeback sub-frame @ptr_1c
dram_store_u16(hle, (uint16_t*)subframe, ptr_1c, SUBFRAME_SIZE);
}