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|
/***************************************************************************
* Copyright (C) 2010 Gabriele Gorla *
* Copyright (C) 2007 Ryan Schultz, PCSX-df Team, PCSX team *
* *
* 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., *
* 51 Franklin Street, Fifth Floor, Boston, MA 02111-1307 USA. *
***************************************************************************/
#include "mdec.h"
/* memory speed is 1 byte per MDEC_BIAS psx clock
* That mean (PSXCLK / MDEC_BIAS) B/s
* MDEC_BIAS = 2.0 => ~16MB/s
* MDEC_BIAS = 3.0 => ~11MB/s
* and so on ...
* I guess I have 50 images in 50Hz ... (could be 25 images ?)
* 320x240x24@50Hz => 11.52 MB/s
* 320x240x24@60Hz => 13.824 MB/s
* 320x240x16@50Hz => 7.68 MB/s
* 320x240x16@60Hz => 9.216 MB/s
* so 2.0 to 4.0 should be fine.
*/
#define MDEC_BIAS 2
#define DSIZE 8
#define DSIZE2 (DSIZE * DSIZE)
#define SCALE(x, n) ((x) >> (n))
#define SCALER(x, n) (((x) + ((1 << (n)) >> 1)) >> (n))
#define AAN_CONST_BITS 12
#define AAN_PRESCALE_BITS 16
#define AAN_CONST_SIZE 24
#define AAN_CONST_SCALE (AAN_CONST_SIZE - AAN_CONST_BITS)
#define AAN_PRESCALE_SIZE 20
#define AAN_PRESCALE_SCALE (AAN_PRESCALE_SIZE-AAN_PRESCALE_BITS)
#define AAN_EXTRA 12
#define FIX_1_082392200 SCALER(18159528, AAN_CONST_SCALE) // B6
#define FIX_1_414213562 SCALER(23726566, AAN_CONST_SCALE) // A4
#define FIX_1_847759065 SCALER(31000253, AAN_CONST_SCALE) // A2
#define FIX_2_613125930 SCALER(43840978, AAN_CONST_SCALE) // B2
#define MULS(var, const) (SCALE((var) * (const), AAN_CONST_BITS))
#define RLE_RUN(a) ((a) >> 10)
#define RLE_VAL(a) (((int)(a) << (sizeof(int) * 8 - 10)) >> (sizeof(int) * 8 - 10))
#if 0
static void printmatrixu8(u8 *m) {
int i;
for(i = 0; i < DSIZE2; i++) {
printf("%3d ",m[i]);
if((i+1) % 8 == 0) printf("\n");
}
}
#endif
static inline void fillcol(int *blk, int val) {
blk[0 * DSIZE] = blk[1 * DSIZE] = blk[2 * DSIZE] = blk[3 * DSIZE]
= blk[4 * DSIZE] = blk[5 * DSIZE] = blk[6 * DSIZE] = blk[7 * DSIZE] = val;
}
static inline void fillrow(int *blk, int val) {
blk[0] = blk[1] = blk[2] = blk[3]
= blk[4] = blk[5] = blk[6] = blk[7] = val;
}
static void idct(int *block,int used_col) {
int tmp0, tmp1, tmp2, tmp3, tmp4, tmp5, tmp6, tmp7;
int z5, z10, z11, z12, z13;
int *ptr;
int i;
// the block has only the DC coefficient
if (used_col == -1) {
int v = block[0];
for (i = 0; i < DSIZE2; i++) block[i] = v;
return;
}
// last_col keeps track of the highest column with non zero coefficients
ptr = block;
for (i = 0; i < DSIZE; i++, ptr++) {
if ((used_col & (1 << i)) == 0) {
// the column is empty or has only the DC coefficient
if (ptr[DSIZE * 0]) {
fillcol(ptr, ptr[0]);
used_col |= (1 << i);
}
continue;
}
// further optimization could be made by keeping track of
// last_row in rl2blk
z10 = ptr[DSIZE * 0] + ptr[DSIZE * 4]; // s04
z11 = ptr[DSIZE * 0] - ptr[DSIZE * 4]; // d04
z13 = ptr[DSIZE * 2] + ptr[DSIZE * 6]; // s26
z12 = MULS(ptr[DSIZE * 2] - ptr[DSIZE * 6], FIX_1_414213562) - z13;
//^^^^ d26=d26*2*A4-s26
tmp0 = z10 + z13; // os07 = s04 + s26
tmp3 = z10 - z13; // os34 = s04 - s26
tmp1 = z11 + z12; // os16 = d04 + d26
tmp2 = z11 - z12; // os25 = d04 - d26
z13 = ptr[DSIZE * 3] + ptr[DSIZE * 5]; //s53
z10 = ptr[DSIZE * 3] - ptr[DSIZE * 5]; //-d53
z11 = ptr[DSIZE * 1] + ptr[DSIZE * 7]; //s17
z12 = ptr[DSIZE * 1] - ptr[DSIZE * 7]; //d17
tmp7 = z11 + z13; // od07 = s17 + s53
z5 = (z12 - z10) * (FIX_1_847759065);
tmp6 = SCALE(z10*(FIX_2_613125930) + z5, AAN_CONST_BITS) - tmp7;
tmp5 = MULS(z11 - z13, FIX_1_414213562) - tmp6;
tmp4 = SCALE(z12*(FIX_1_082392200) - z5, AAN_CONST_BITS) + tmp5;
// path #1
//z5 = (z12 - z10)* FIX_1_847759065;
// tmp0 = (d17 + d53) * 2*A2
//tmp6 = DESCALE(z10*FIX_2_613125930 + z5, CONST_BITS) - tmp7;
// od16 = (d53*-2*B2 + tmp0) - od07
//tmp4 = DESCALE(z12*FIX_1_082392200 - z5, CONST_BITS) + tmp5;
// od34 = (d17*2*B6 - tmp0) + od25
// path #2
// od34 = d17*2*(B6-A2) - d53*2*A2
// od16 = d53*2*(A2-B2) + d17*2*A2
// end
// tmp5 = MULS(z11 - z13, FIX_1_414213562) - tmp6;
// od25 = (s17 - s53)*2*A4 - od16
ptr[DSIZE * 0] = (tmp0 + tmp7); // os07 + od07
ptr[DSIZE * 7] = (tmp0 - tmp7); // os07 - od07
ptr[DSIZE * 1] = (tmp1 + tmp6); // os16 + od16
ptr[DSIZE * 6] = (tmp1 - tmp6); // os16 - od16
ptr[DSIZE * 2] = (tmp2 + tmp5); // os25 + od25
ptr[DSIZE * 5] = (tmp2 - tmp5); // os25 - od25
ptr[DSIZE * 4] = (tmp3 + tmp4); // os34 + od34
ptr[DSIZE * 3] = (tmp3 - tmp4); // os34 - od34
}
ptr = block;
if (used_col == 1) {
for (i = 0; i < DSIZE; i++)
fillrow(block + DSIZE * i, block[DSIZE * i]);
} else {
for (i = 0; i < DSIZE; i++, ptr += DSIZE) {
z10 = ptr[0] + ptr[4];
z11 = ptr[0] - ptr[4];
z13 = ptr[2] + ptr[6];
z12 = MULS(ptr[2] - ptr[6], FIX_1_414213562) - z13;
tmp0 = z10 + z13;
tmp3 = z10 - z13;
tmp1 = z11 + z12;
tmp2 = z11 - z12;
z13 = ptr[3] + ptr[5];
z10 = ptr[3] - ptr[5];
z11 = ptr[1] + ptr[7];
z12 = ptr[1] - ptr[7];
tmp7 = z11 + z13;
z5 = (z12 - z10) * FIX_1_847759065;
tmp6 = SCALE(z10 * FIX_2_613125930 + z5, AAN_CONST_BITS) - tmp7;
tmp5 = MULS(z11 - z13, FIX_1_414213562) - tmp6;
tmp4 = SCALE(z12 * FIX_1_082392200 - z5, AAN_CONST_BITS) + tmp5;
ptr[0] = tmp0 + tmp7;
ptr[7] = tmp0 - tmp7;
ptr[1] = tmp1 + tmp6;
ptr[6] = tmp1 - tmp6;
ptr[2] = tmp2 + tmp5;
ptr[5] = tmp2 - tmp5;
ptr[4] = tmp3 + tmp4;
ptr[3] = tmp3 - tmp4;
}
}
}
// mdec0: command register
#define MDEC0_STP 0x02000000
#define MDEC0_RGB24 0x08000000
#define MDEC0_SIZE_MASK 0x0000FFFF
// mdec1: status register
#define MDEC1_BUSY 0x20000000
#define MDEC1_DREQ 0x18000000
#define MDEC1_FIFO 0xc0000000
#define MDEC1_RGB24 0x02000000
#define MDEC1_STP 0x00800000
#define MDEC1_RESET 0x80000000
struct _pending_dma1 {
u32 adr;
u32 bcr;
u32 chcr;
};
static struct {
u32 reg0;
u32 reg1;
u16 * rl;
u16 * rl_end;
u8 * block_buffer_pos;
u8 block_buffer[16*16*3];
struct _pending_dma1 pending_dma1;
} mdec;
static int iq_y[DSIZE2], iq_uv[DSIZE2];
static int zscan[DSIZE2] = {
0 , 1 , 8 , 16, 9 , 2 , 3 , 10,
17, 24, 32, 25, 18, 11, 4 , 5 ,
12, 19, 26, 33, 40, 48, 41, 34,
27, 20, 13, 6 , 7 , 14, 21, 28,
35, 42, 49, 56, 57, 50, 43, 36,
29, 22, 15, 23, 30, 37, 44, 51,
58, 59, 52, 45, 38, 31, 39, 46,
53, 60, 61, 54, 47, 55, 62, 63
};
static int aanscales[DSIZE2] = {
1048576, 1454417, 1370031, 1232995, 1048576, 823861, 567485, 289301,
1454417, 2017334, 1900287, 1710213, 1454417, 1142728, 787125, 401273,
1370031, 1900287, 1790031, 1610986, 1370031, 1076426, 741455, 377991,
1232995, 1710213, 1610986, 1449849, 1232995, 968758, 667292, 340183,
1048576, 1454417, 1370031, 1232995, 1048576, 823861, 567485, 289301,
823861, 1142728, 1076426, 968758, 823861, 647303, 445870, 227303,
567485, 787125, 741455, 667292, 567485, 445870, 307121, 156569,
289301, 401273, 377991, 340183, 289301, 227303, 156569, 79818
};
static void iqtab_init(int *iqtab, unsigned char *iq_y) {
int i;
for (i = 0; i < DSIZE2; i++) {
iqtab[i] = (iq_y[i] * SCALER(aanscales[zscan[i]], AAN_PRESCALE_SCALE));
}
}
#define MDEC_END_OF_DATA 0xfe00
static unsigned short *rl2blk(int *blk, unsigned short *mdec_rl) {
int i, k, q_scale, rl, used_col;
int *iqtab;
memset(blk, 0, 6 * DSIZE2 * sizeof(int));
iqtab = iq_uv;
for (i = 0; i < 6; i++) {
// decode blocks (Cr,Cb,Y1,Y2,Y3,Y4)
if (i == 2) iqtab = iq_y;
rl = SWAP16(*mdec_rl); mdec_rl++;
q_scale = RLE_RUN(rl);
blk[0] = SCALER(iqtab[0] * RLE_VAL(rl), AAN_EXTRA - 3);
for (k = 0, used_col = 0;;) {
rl = SWAP16(*mdec_rl); mdec_rl++;
if (rl == MDEC_END_OF_DATA) break;
k += RLE_RUN(rl) + 1; // skip zero-coefficients
if (k > 63) {
// printf("run lenght exceeded 64 enties\n");
break;
}
// zigzag transformation
blk[zscan[k]] = SCALER(RLE_VAL(rl) * iqtab[k] * q_scale, AAN_EXTRA);
// keep track of used columns to speed up the idtc
used_col |= (zscan[k] > 7) ? 1 << (zscan[k] & 7) : 0;
}
if (k == 0) used_col = -1;
// used_col is -1 for blocks with only the DC coefficient
// any other value is a bitmask of the columns that have
// at least one non zero cofficient in the rows 1-7
// single coefficients in row 0 are treted specially
// in the idtc function
idct(blk, used_col);
blk += DSIZE2;
}
return mdec_rl;
}
// full scale (JPEG)
// Y/Cb/Cr[0...255] -> R/G/B[0...255]
// R = 1.000 * (Y) + 1.400 * (Cr - 128)
// G = 1.000 * (Y) - 0.343 * (Cb - 128) - 0.711 (Cr - 128)
// B = 1.000 * (Y) + 1.765 * (Cb - 128)
#define MULR(a) ((1434 * (a)))
#define MULB(a) ((1807 * (a)))
#define MULG2(a, b) ((-351 * (a) - 728 * (b)))
#define MULY(a) ((a) << 10)
#define MAKERGB15(r, g, b, a) (SWAP16(a | ((b) << 10) | ((g) << 5) | (r)))
#define SCALE8(c) SCALER(c, 20)
#define SCALE5(c) SCALER(c, 23)
#define CLAMP5(c) ( ((c) < -16) ? 0 : (((c) > (31 - 16)) ? 31 : ((c) + 16)) )
#define CLAMP8(c) ( ((c) < -128) ? 0 : (((c) > (255 - 128)) ? 255 : ((c) + 128)) )
#define CLAMP_SCALE8(a) (CLAMP8(SCALE8(a)))
#define CLAMP_SCALE5(a) (CLAMP5(SCALE5(a)))
static inline void putlinebw15(u16 *image, int *Yblk) {
int i;
int A = (mdec.reg0 & MDEC0_STP) ? 0x8000 : 0;
for (i = 0; i < 8; i++, Yblk++) {
int Y = *Yblk;
// missing rounding
image[i] = SWAP16((CLAMP5(Y >> 3) * 0x421) | A);
}
}
static inline void putquadrgb15(u16 *image, int *Yblk, int Cr, int Cb) {
int Y, R, G, B;
int A = (mdec.reg0 & MDEC0_STP) ? 0x8000 : 0;
R = MULR(Cr);
G = MULG2(Cb, Cr);
B = MULB(Cb);
// added transparency
Y = MULY(Yblk[0]);
image[0] = MAKERGB15(CLAMP_SCALE5(Y + R), CLAMP_SCALE5(Y + G), CLAMP_SCALE5(Y + B), A);
Y = MULY(Yblk[1]);
image[1] = MAKERGB15(CLAMP_SCALE5(Y + R), CLAMP_SCALE5(Y + G), CLAMP_SCALE5(Y + B), A);
Y = MULY(Yblk[8]);
image[16] = MAKERGB15(CLAMP_SCALE5(Y + R), CLAMP_SCALE5(Y + G), CLAMP_SCALE5(Y + B), A);
Y = MULY(Yblk[9]);
image[17] = MAKERGB15(CLAMP_SCALE5(Y + R), CLAMP_SCALE5(Y + G), CLAMP_SCALE5(Y + B), A);
}
static inline void yuv2rgb15(int *blk, unsigned short *image) {
int x, y;
int *Yblk = blk + DSIZE2 * 2;
int *Crblk = blk;
int *Cbblk = blk + DSIZE2;
if (!Config.Mdec) {
for (y = 0; y < 16; y += 2, Crblk += 4, Cbblk += 4, Yblk += 8, image += 24) {
if (y == 8) Yblk += DSIZE2;
for (x = 0; x < 4; x++, image += 2, Crblk++, Cbblk++, Yblk += 2) {
putquadrgb15(image, Yblk, *Crblk, *Cbblk);
putquadrgb15(image + 8, Yblk + DSIZE2, *(Crblk + 4), *(Cbblk + 4));
}
}
} else {
for (y = 0; y < 16; y++, Yblk += 8, image += 16) {
if (y == 8) Yblk += DSIZE2;
putlinebw15(image, Yblk);
putlinebw15(image + 8, Yblk + DSIZE2);
}
}
}
static inline void putlinebw24(u8 * image, int *Yblk) {
int i;
unsigned char Y;
for (i = 0; i < 8 * 3; i += 3, Yblk++) {
Y = CLAMP8(*Yblk);
image[i + 0] = Y;
image[i + 1] = Y;
image[i + 2] = Y;
}
}
static inline void putquadrgb24(u8 * image, int *Yblk, int Cr, int Cb) {
int Y, R, G, B;
R = MULR(Cr);
G = MULG2(Cb,Cr);
B = MULB(Cb);
Y = MULY(Yblk[0]);
image[0 * 3 + 0] = CLAMP_SCALE8(Y + R);
image[0 * 3 + 1] = CLAMP_SCALE8(Y + G);
image[0 * 3 + 2] = CLAMP_SCALE8(Y + B);
Y = MULY(Yblk[1]);
image[1 * 3 + 0] = CLAMP_SCALE8(Y + R);
image[1 * 3 + 1] = CLAMP_SCALE8(Y + G);
image[1 * 3 + 2] = CLAMP_SCALE8(Y + B);
Y = MULY(Yblk[8]);
image[16 * 3 + 0] = CLAMP_SCALE8(Y + R);
image[16 * 3 + 1] = CLAMP_SCALE8(Y + G);
image[16 * 3 + 2] = CLAMP_SCALE8(Y + B);
Y = MULY(Yblk[9]);
image[17 * 3 + 0] = CLAMP_SCALE8(Y + R);
image[17 * 3 + 1] = CLAMP_SCALE8(Y + G);
image[17 * 3 + 2] = CLAMP_SCALE8(Y + B);
}
static void yuv2rgb24(int *blk, u8 *image) {
int x, y;
int *Yblk = blk + DSIZE2 * 2;
int *Crblk = blk;
int *Cbblk = blk + DSIZE2;
if (!Config.Mdec) {
for (y = 0; y < 16; y += 2, Crblk += 4, Cbblk += 4, Yblk += 8, image += 8 * 3 * 3) {
if (y == 8) Yblk += DSIZE2;
for (x = 0; x < 4; x++, image += 6, Crblk++, Cbblk++, Yblk += 2) {
putquadrgb24(image, Yblk, *Crblk, *Cbblk);
putquadrgb24(image + 8 * 3, Yblk + DSIZE2, *(Crblk + 4), *(Cbblk + 4));
}
}
} else {
for (y = 0; y < 16; y++, Yblk += 8, image += 16 * 3) {
if (y == 8) Yblk += DSIZE2;
putlinebw24(image, Yblk);
putlinebw24(image + 8 * 3, Yblk + DSIZE2);
}
}
}
void mdecInit(void) {
memset(&mdec, 0, sizeof(mdec));
memset(iq_y, 0, sizeof(iq_y));
memset(iq_uv, 0, sizeof(iq_uv));
mdec.rl = (u16 *)&psxM[0x100000];
}
// command register
void mdecWrite0(u32 data) {
mdec.reg0 = data;
}
u32 mdecRead0(void) {
return mdec.reg0;
}
// status register
void mdecWrite1(u32 data) {
if (data & MDEC1_RESET) { // mdec reset
mdec.reg0 = 0;
mdec.reg1 = 0;
mdec.pending_dma1.adr = 0;
mdec.block_buffer_pos = 0;
}
}
u32 mdecRead1(void) {
u32 v = mdec.reg1;
return v;
}
void psxDma0(u32 adr, u32 bcr, u32 chcr) {
int cmd = mdec.reg0;
int size;
if (chcr != 0x01000201) {
return;
}
/* mdec is STP till dma0 is released */
mdec.reg1 |= MDEC1_STP;
size = (bcr >> 16) * (bcr & 0xffff);
switch (cmd >> 28) {
case 0x3: // decode
mdec.rl = (u16 *) PSXM(adr);
/* now the mdec is busy till all data are decoded */
mdec.reg1 |= MDEC1_BUSY;
/* detect the end of decoding */
mdec.rl_end = mdec.rl + (size * 2);
/* sanity check */
if(mdec.rl_end <= mdec.rl) {
MDECINDMA_INT( size / 4 );
return;
}
/* process the pending dma1 */
if(mdec.pending_dma1.adr){
psxDma1(mdec.pending_dma1.adr, mdec.pending_dma1.bcr, mdec.pending_dma1.chcr);
}
mdec.pending_dma1.adr = 0;
return;
case 0x4: // quantization table upload
{
u8 *p = (u8 *)PSXM(adr);
// printf("uploading new quantization table\n");
// printmatrixu8(p);
// printmatrixu8(p + 64);
iqtab_init(iq_y, p);
iqtab_init(iq_uv, p + 64);
}
MDECINDMA_INT( size / 4 );
return;
case 0x6: // cosine table
// printf("mdec cosine table\n");
MDECINDMA_INT( size / 4 );
return;
default:
// printf("mdec unknown command\n");
break;
}
HW_DMA0_CHCR &= SWAP32(~0x01000000);
DMA_INTERRUPT(0);
}
void mdec0Interrupt()
{
if (HW_DMA0_CHCR & SWAP32(0x01000000))
{
HW_DMA0_CHCR &= SWAP32(~0x01000000);
DMA_INTERRUPT(0);
}
}
#define SIZE_OF_24B_BLOCK (16*16*3)
#define SIZE_OF_16B_BLOCK (16*16*2)
void psxDma1(u32 adr, u32 bcr, u32 chcr) {
int blk[DSIZE2 * 6];
u8 * image;
int size;
u32 words;
if (chcr != 0x01000200) return;
words = (bcr >> 16) * (bcr & 0xffff);
/* size in byte */
size = words * 4;
if (!(mdec.reg1 & MDEC1_BUSY)) {
/* add to pending */
mdec.pending_dma1.adr = adr;
mdec.pending_dma1.bcr = bcr;
mdec.pending_dma1.chcr = chcr;
/* do not free the dma */
} else {
image = (u8 *)PSXM(adr);
if (mdec.reg0 & MDEC0_RGB24) {
/* 16 bits decoding
* block are 16 px * 16 px, each px are 2 byte
*/
/* there is some partial block pending ? */
if(mdec.block_buffer_pos != 0) {
int n = mdec.block_buffer - mdec.block_buffer_pos + SIZE_OF_16B_BLOCK;
/* TODO: check if partial block do not larger than size */
memcpy(image, mdec.block_buffer_pos, n);
image += n;
size -= n;
mdec.block_buffer_pos = 0;
}
while(size >= SIZE_OF_16B_BLOCK) {
mdec.rl = rl2blk(blk, mdec.rl);
yuv2rgb15(blk, (u16 *)image);
image += SIZE_OF_16B_BLOCK;
size -= SIZE_OF_16B_BLOCK;
}
if(size != 0) {
mdec.rl = rl2blk(blk, mdec.rl);
yuv2rgb15(blk, (u16 *)mdec.block_buffer);
memcpy(image, mdec.block_buffer, size);
mdec.block_buffer_pos = mdec.block_buffer + size;
}
} else {
/* 24 bits decoding
* block are 16 px * 16 px, each px are 3 byte
*/
/* there is some partial block pending ? */
if(mdec.block_buffer_pos != 0) {
int n = mdec.block_buffer - mdec.block_buffer_pos + SIZE_OF_24B_BLOCK;
/* TODO: check if partial block do not larger than size */
memcpy(image, mdec.block_buffer_pos, n);
image += n;
size -= n;
mdec.block_buffer_pos = 0;
}
while(size >= SIZE_OF_24B_BLOCK) {
mdec.rl = rl2blk(blk, mdec.rl);
yuv2rgb24(blk, image);
image += SIZE_OF_24B_BLOCK;
size -= SIZE_OF_24B_BLOCK;
}
if(size != 0) {
mdec.rl = rl2blk(blk, mdec.rl);
yuv2rgb24(blk, mdec.block_buffer);
memcpy(image, mdec.block_buffer, size);
mdec.block_buffer_pos = mdec.block_buffer + size;
}
}
/* define the power of mdec */
MDECOUTDMA_INT(words * MDEC_BIAS);
}
}
void mdec1Interrupt() {
/* Author : gschwind
*
* in that case we have done all decoding stuff
* Note that : each block end with 0xfe00 flags
* the list of blocks end with the same 0xfe00 flags
* data loock like :
*
* data block ...
* 0xfe00
* data block ...
* 0xfe00
* a lost of block ..
*
* 0xfe00
* the last block
* 0xfe00
* 0xfe00
*
* OR
*
* if the 0xfe00 is not present the data size is important.
*
*/
/* MDEC_END_OF_DATA avoids read outside memory */
if (mdec.rl >= mdec.rl_end || SWAP16(*(mdec.rl)) == MDEC_END_OF_DATA) {
mdec.reg1 &= ~(MDEC1_STP|MDEC1_BUSY);
if (HW_DMA0_CHCR & SWAP32(0x01000000))
{
HW_DMA0_CHCR &= SWAP32(~0x01000000);
DMA_INTERRUPT(0);
}
}
if (HW_DMA1_CHCR & SWAP32(0x01000000))
{
HW_DMA1_CHCR &= SWAP32(~0x01000000);
DMA_INTERRUPT(1);
}
}
int mdecFreeze(void *f, int Mode) {
u8 *base = (u8 *)&psxM[0x100000];
u32 v;
gzfreeze(&mdec.reg0, sizeof(mdec.reg0));
gzfreeze(&mdec.reg1, sizeof(mdec.reg1));
// old code used to save raw pointers..
v = (u8 *)mdec.rl - base;
gzfreeze(&v, sizeof(v));
mdec.rl = (u16 *)(base + (v & 0xffffe));
v = (u8 *)mdec.rl_end - base;
gzfreeze(&v, sizeof(v));
mdec.rl_end = (u16 *)(base + (v & 0xffffe));
v = 0;
if (mdec.block_buffer_pos)
v = mdec.block_buffer_pos - base;
gzfreeze(&v, sizeof(v));
mdec.block_buffer_pos = 0;
if (v)
mdec.block_buffer_pos = base + (v & 0xfffff);
gzfreeze(&mdec.block_buffer, sizeof(mdec.block_buffer));
gzfreeze(&mdec.pending_dma1, sizeof(mdec.pending_dma1));
gzfreeze(iq_y, sizeof(iq_y));
gzfreeze(iq_uv, sizeof(iq_uv));
return 0;
}
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