pokeemerald/gflib/bg.c

1257 lines
30 KiB
C

#include "global.h"
#include "bg.h"
#include "dma3.h"
#include "gpu_regs.h"
#define DISPCNT_ALL_BG_AND_MODE_BITS (DISPCNT_BG_ALL_ON | 0x7)
struct BgControl
{
struct BgConfig {
u16 visible:1;
u16 unknown_1:1;
u16 screenSize:2;
u16 priority:2;
u16 mosaic:1;
u16 wraparound:1;
u16 charBaseIndex:2;
u16 mapBaseIndex:5;
u16 paletteMode:1;
u8 unknown_2;
u8 unknown_3;
} configs[4];
u16 bgVisibilityAndMode;
};
struct BgConfig2
{
u32 baseTile:10;
u32 basePalette:4;
u32 unk_3:18;
void* tilemap;
s32 bg_x;
s32 bg_y;
};
static struct BgControl sGpuBgConfigs;
static struct BgConfig2 sGpuBgConfigs2[4];
static u32 sDmaBusyBitfield[4];
u32 gUnneededFireRedVariable;
static const struct BgConfig sZeroedBgControlStruct = { 0 };
void ResetBgs(void)
{
ResetBgControlStructs();
sGpuBgConfigs.bgVisibilityAndMode = 0;
SetTextModeAndHideBgs();
}
static void SetBgModeInternal(u8 bgMode)
{
sGpuBgConfigs.bgVisibilityAndMode &= 0xFFF8;
sGpuBgConfigs.bgVisibilityAndMode |= bgMode;
}
u8 GetBgMode(void)
{
return sGpuBgConfigs.bgVisibilityAndMode & 0x7;
}
void ResetBgControlStructs(void)
{
struct BgConfig* bgConfigs = &sGpuBgConfigs.configs[0];
struct BgConfig zeroedConfig = sZeroedBgControlStruct;
int i;
for (i = 0; i < 4; i++)
{
bgConfigs[i] = zeroedConfig;
}
}
void Unused_ResetBgControlStruct(u8 bg)
{
if (!IsInvalidBg(bg))
{
sGpuBgConfigs.configs[bg] = sZeroedBgControlStruct;
}
}
enum
{
BG_CTRL_ATTR_VISIBLE = 1,
BG_CTRL_ATTR_CHARBASEINDEX = 2,
BG_CTRL_ATTR_MAPBASEINDEX = 3,
BG_CTRL_ATTR_SCREENSIZE = 4,
BG_CTRL_ATTR_PALETTEMODE = 5,
BG_CTRL_ATTR_PRIORITY = 6,
BG_CTRL_ATTR_MOSAIC = 7,
BG_CTRL_ATTR_WRAPAROUND = 8,
};
static void SetBgControlAttributes(u8 bg, u8 charBaseIndex, u8 mapBaseIndex, u8 screenSize, u8 paletteMode, u8 priority, u8 mosaic, u8 wraparound)
{
if (!IsInvalidBg(bg))
{
if (charBaseIndex != 0xFF)
{
sGpuBgConfigs.configs[bg].charBaseIndex = charBaseIndex & 0x3;
}
if (mapBaseIndex != 0xFF)
{
sGpuBgConfigs.configs[bg].mapBaseIndex = mapBaseIndex & 0x1F;
}
if (screenSize != 0xFF)
{
sGpuBgConfigs.configs[bg].screenSize = screenSize & 0x3;
}
if (paletteMode != 0xFF)
{
sGpuBgConfigs.configs[bg].paletteMode = paletteMode;
}
if (priority != 0xFF)
{
sGpuBgConfigs.configs[bg].priority = priority & 0x3;
}
if (mosaic != 0xFF)
{
sGpuBgConfigs.configs[bg].mosaic = mosaic & 0x1;
}
if (wraparound != 0xFF)
{
sGpuBgConfigs.configs[bg].wraparound = wraparound;
}
sGpuBgConfigs.configs[bg].unknown_2 = 0;
sGpuBgConfigs.configs[bg].unknown_3 = 0;
sGpuBgConfigs.configs[bg].visible = 1;
}
}
static u16 GetBgControlAttribute(u8 bg, u8 attributeId)
{
if (!IsInvalidBg(bg) && sGpuBgConfigs.configs[bg].visible)
{
switch (attributeId)
{
case BG_CTRL_ATTR_VISIBLE:
return sGpuBgConfigs.configs[bg].visible;
case BG_CTRL_ATTR_CHARBASEINDEX:
return sGpuBgConfigs.configs[bg].charBaseIndex;
case BG_CTRL_ATTR_MAPBASEINDEX:
return sGpuBgConfigs.configs[bg].mapBaseIndex;
case BG_CTRL_ATTR_SCREENSIZE:
return sGpuBgConfigs.configs[bg].screenSize;
case BG_CTRL_ATTR_PALETTEMODE:
return sGpuBgConfigs.configs[bg].paletteMode;
case BG_CTRL_ATTR_PRIORITY:
return sGpuBgConfigs.configs[bg].priority;
case BG_CTRL_ATTR_MOSAIC:
return sGpuBgConfigs.configs[bg].mosaic;
case BG_CTRL_ATTR_WRAPAROUND:
return sGpuBgConfigs.configs[bg].wraparound;
}
}
return 0xFF;
}
u8 LoadBgVram(u8 bg, const void *src, u16 size, u16 destOffset, u8 mode)
{
u16 offset;
s8 cursor;
if (!IsInvalidBg(bg) && sGpuBgConfigs.configs[bg].visible)
{
switch (mode)
{
case 0x1:
offset = sGpuBgConfigs.configs[bg].charBaseIndex * BG_CHAR_SIZE;
break;
case 0x2:
offset = sGpuBgConfigs.configs[bg].mapBaseIndex * BG_SCREEN_SIZE;
break;
default:
cursor = -1;
goto end;
}
offset = destOffset + offset;
cursor = RequestDma3Copy(src, (void*)(offset + BG_VRAM), size, 0);
if (cursor == -1)
{
return -1;
}
}
else
{
return -1;
}
end:
return cursor;
}
static void ShowBgInternal(u8 bg)
{
u16 value;
if (!IsInvalidBg(bg) && sGpuBgConfigs.configs[bg].visible)
{
value = sGpuBgConfigs.configs[bg].priority |
(sGpuBgConfigs.configs[bg].charBaseIndex << 2) |
(sGpuBgConfigs.configs[bg].mosaic << 6) |
(sGpuBgConfigs.configs[bg].paletteMode << 7) |
(sGpuBgConfigs.configs[bg].mapBaseIndex << 8) |
(sGpuBgConfigs.configs[bg].wraparound << 13) |
(sGpuBgConfigs.configs[bg].screenSize << 14);
SetGpuReg((bg << 1) + REG_OFFSET_BG0CNT, value);
sGpuBgConfigs.bgVisibilityAndMode |= 1 << (bg + 8);
sGpuBgConfigs.bgVisibilityAndMode &= DISPCNT_ALL_BG_AND_MODE_BITS;
}
}
static void HideBgInternal(u8 bg)
{
if (!IsInvalidBg(bg))
{
sGpuBgConfigs.bgVisibilityAndMode &= ~(1 << (bg + 8));
sGpuBgConfigs.bgVisibilityAndMode &= DISPCNT_ALL_BG_AND_MODE_BITS;
}
}
static void SyncBgVisibilityAndMode(void)
{
SetGpuReg(REG_OFFSET_DISPCNT, (GetGpuReg(REG_OFFSET_DISPCNT) & ~DISPCNT_ALL_BG_AND_MODE_BITS) | sGpuBgConfigs.bgVisibilityAndMode);
}
void SetTextModeAndHideBgs(void)
{
SetGpuReg(REG_OFFSET_DISPCNT, GetGpuReg(REG_OFFSET_DISPCNT) & ~DISPCNT_ALL_BG_AND_MODE_BITS);
}
static void SetBgAffineInternal(u8 bg, s32 srcCenterX, s32 srcCenterY, s16 dispCenterX, s16 dispCenterY, s16 scaleX, s16 scaleY, u16 rotationAngle)
{
struct BgAffineSrcData src;
struct BgAffineDstData dest;
switch (sGpuBgConfigs.bgVisibilityAndMode & 0x7)
{
case 1:
if (bg != 2)
return;
break;
case 2:
if (bg < 2 || bg > 3)
return;
break;
case 0:
default:
return;
}
src.texX = srcCenterX;
src.texY = srcCenterY;
src.scrX = dispCenterX;
src.scrY = dispCenterY;
src.sx = scaleX;
src.sy = scaleY;
src.alpha = rotationAngle;
BgAffineSet(&src, &dest, 1);
SetGpuReg(REG_OFFSET_BG2PA, dest.pa);
SetGpuReg(REG_OFFSET_BG2PB, dest.pb);
SetGpuReg(REG_OFFSET_BG2PC, dest.pc);
SetGpuReg(REG_OFFSET_BG2PD, dest.pd);
SetGpuReg(REG_OFFSET_BG2PA, dest.pa);
SetGpuReg(REG_OFFSET_BG2X_L, (s16)(dest.dx));
SetGpuReg(REG_OFFSET_BG2X_H, (s16)(dest.dx >> 16));
SetGpuReg(REG_OFFSET_BG2Y_L, (s16)(dest.dy));
SetGpuReg(REG_OFFSET_BG2Y_H, (s16)(dest.dy >> 16));
}
bool8 IsInvalidBg(u8 bg)
{
if (bg > 3)
return TRUE;
else
return FALSE;
}
int DummiedOutFireRedLeafGreenTileAllocFunc(int a1, int a2, int a3, int a4)
{
return 0;
}
void ResetBgsAndClearDma3BusyFlags(u32 leftoverFireRedLeafGreenVariable)
{
int i;
ResetBgs();
for (i = 0; i < 4; i++)
{
sDmaBusyBitfield[i] = 0;
}
gUnneededFireRedVariable = leftoverFireRedLeafGreenVariable;
}
void InitBgsFromTemplates(u8 bgMode, const struct BgTemplate *templates, u8 numTemplates)
{
int i;
u8 bg;
SetBgModeInternal(bgMode);
ResetBgControlStructs();
for (i = 0; i < numTemplates; i++)
{
bg = templates[i].bg;
if (bg < 4)
{
SetBgControlAttributes(bg,
templates[i].charBaseIndex,
templates[i].mapBaseIndex,
templates[i].screenSize,
templates[i].paletteMode,
templates[i].priority,
0,
0);
sGpuBgConfigs2[bg].baseTile = templates[i].baseTile;
sGpuBgConfigs2[bg].basePalette = 0;
sGpuBgConfigs2[bg].unk_3 = 0;
sGpuBgConfigs2[bg].tilemap = NULL;
sGpuBgConfigs2[bg].bg_x = 0;
sGpuBgConfigs2[bg].bg_y = 0;
}
}
}
void InitBgFromTemplate(const struct BgTemplate *template)
{
u8 bg = template->bg;
if (bg < 4)
{
SetBgControlAttributes(bg,
template->charBaseIndex,
template->mapBaseIndex,
template->screenSize,
template->paletteMode,
template->priority,
0,
0);
sGpuBgConfigs2[bg].baseTile = template->baseTile;
sGpuBgConfigs2[bg].basePalette = 0;
sGpuBgConfigs2[bg].unk_3 = 0;
sGpuBgConfigs2[bg].tilemap = NULL;
sGpuBgConfigs2[bg].bg_x = 0;
sGpuBgConfigs2[bg].bg_y = 0;
}
}
void SetBgMode(u8 bgMode)
{
SetBgModeInternal(bgMode);
}
u16 LoadBgTiles(u8 bg, const void* src, u16 size, u16 destOffset)
{
u16 tileOffset;
u8 cursor;
if (GetBgControlAttribute(bg, BG_CTRL_ATTR_PALETTEMODE) == 0)
{
tileOffset = (sGpuBgConfigs2[bg].baseTile + destOffset) * 0x20;
}
else
{
tileOffset = (sGpuBgConfigs2[bg].baseTile + destOffset) * 0x40;
}
cursor = LoadBgVram(bg, src, size, tileOffset, DISPCNT_MODE_1);
if (cursor == 0xFF)
{
return -1;
}
sDmaBusyBitfield[cursor / 0x20] |= (1 << (cursor % 0x20));
if (gUnneededFireRedVariable == 1)
{
DummiedOutFireRedLeafGreenTileAllocFunc(bg, tileOffset / 0x20, size / 0x20, 1);
}
return cursor;
}
u16 LoadBgTilemap(u8 bg, const void *src, u16 size, u16 destOffset)
{
u8 cursor = LoadBgVram(bg, src, size, destOffset * 2, DISPCNT_MODE_2);
if (cursor == 0xFF)
{
return -1;
}
sDmaBusyBitfield[cursor / 0x20] |= (1 << (cursor % 0x20));
return cursor;
}
u16 Unused_LoadBgPalette(u8 bg, const void *src, u16 size, u16 destOffset)
{
s8 cursor;
if (!IsInvalidBg32(bg))
{
u16 paletteOffset = (sGpuBgConfigs2[bg].basePalette * 0x20) + (destOffset * 2);
cursor = RequestDma3Copy(src, (void*)(paletteOffset + BG_PLTT), size, 0);
if (cursor == -1)
{
return -1;
}
}
else
{
return -1;
}
sDmaBusyBitfield[cursor / 0x20] |= (1 << (cursor % 0x20));
return (u8)cursor;
}
bool8 IsDma3ManagerBusyWithBgCopy(void)
{
int i;
for (i = 0; i < 0x80; i++)
{
u8 div = i / 0x20;
u8 mod = i % 0x20;
if ((sDmaBusyBitfield[div] & (1 << mod)))
{
s8 reqSpace = CheckForSpaceForDma3Request(i);
if (reqSpace == -1)
{
return TRUE;
}
sDmaBusyBitfield[div] &= ~(1 << mod);
}
}
return FALSE;
}
void ShowBg(u8 bg)
{
ShowBgInternal(bg);
SyncBgVisibilityAndMode();
}
void HideBg(u8 bg)
{
HideBgInternal(bg);
SyncBgVisibilityAndMode();
}
void SetBgAttribute(u8 bg, u8 attributeId, u8 value)
{
switch (attributeId)
{
case BG_ATTR_CHARBASEINDEX:
SetBgControlAttributes(bg, value, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF);
break;
case BG_ATTR_MAPBASEINDEX:
SetBgControlAttributes(bg, 0xFF, value, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF);
break;
case BG_ATTR_SCREENSIZE:
SetBgControlAttributes(bg, 0xFF, 0xFF, value, 0xFF, 0xFF, 0xFF, 0xFF);
break;
case BG_ATTR_PALETTEMODE:
SetBgControlAttributes(bg, 0xFF, 0xFF, 0xFF, value, 0xFF, 0xFF, 0xFF);
break;
case BG_ATTR_PRIORITY:
SetBgControlAttributes(bg, 0xFF, 0xFF, 0xFF, 0xFF, value, 0xFF, 0xFF);
break;
case BG_ATTR_MOSAIC:
SetBgControlAttributes(bg, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, value, 0xFF);
break;
case BG_ATTR_WRAPAROUND:
SetBgControlAttributes(bg, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, value);
break;
}
}
u16 GetBgAttribute(u8 bg, u8 attributeId)
{
switch (attributeId)
{
case BG_ATTR_CHARBASEINDEX:
return GetBgControlAttribute(bg, BG_CTRL_ATTR_CHARBASEINDEX);
case BG_ATTR_MAPBASEINDEX:
return GetBgControlAttribute(bg, BG_CTRL_ATTR_MAPBASEINDEX);
case BG_ATTR_SCREENSIZE:
return GetBgControlAttribute(bg, BG_CTRL_ATTR_SCREENSIZE);
case BG_ATTR_PALETTEMODE:
return GetBgControlAttribute(bg, BG_CTRL_ATTR_PALETTEMODE);
case BG_ATTR_PRIORITY:
return GetBgControlAttribute(bg, BG_CTRL_ATTR_PRIORITY);
case BG_ATTR_MOSAIC:
return GetBgControlAttribute(bg, BG_CTRL_ATTR_MOSAIC);
case BG_ATTR_WRAPAROUND:
return GetBgControlAttribute(bg, BG_CTRL_ATTR_WRAPAROUND);
case BG_ATTR_METRIC:
switch (GetBgType(bg))
{
case 0:
return GetBgMetricTextMode(bg, 0) * 0x800;
case 1:
return GetBgMetricAffineMode(bg, 0) * 0x100;
default:
return 0;
}
case BG_ATTR_TYPE:
return GetBgType(bg);
case BG_ATTR_BASETILE:
return sGpuBgConfigs2[bg].baseTile;
default:
return -1;
}
}
s32 ChangeBgX(u8 bg, s32 value, u8 op)
{
u8 mode;
u16 temp1;
u16 temp2;
if (IsInvalidBg32(bg) || !GetBgControlAttribute(bg, BG_CTRL_ATTR_VISIBLE))
{
return -1;
}
switch (op)
{
case 0:
default:
sGpuBgConfigs2[bg].bg_x = value;
break;
case 1:
sGpuBgConfigs2[bg].bg_x += value;
break;
case 2:
sGpuBgConfigs2[bg].bg_x -= value;
break;
}
mode = GetBgMode();
switch (bg)
{
case 0:
temp1 = sGpuBgConfigs2[0].bg_x >> 0x8;
SetGpuReg(REG_OFFSET_BG0HOFS, temp1);
break;
case 1:
temp1 = sGpuBgConfigs2[1].bg_x >> 0x8;
SetGpuReg(REG_OFFSET_BG1HOFS, temp1);
break;
case 2:
if (mode == 0)
{
temp1 = sGpuBgConfigs2[2].bg_x >> 0x8;
SetGpuReg(REG_OFFSET_BG2HOFS, temp1);
}
else
{
temp1 = sGpuBgConfigs2[2].bg_x >> 0x10;
temp2 = sGpuBgConfigs2[2].bg_x & 0xFFFF;
SetGpuReg(REG_OFFSET_BG2X_H, temp1);
SetGpuReg(REG_OFFSET_BG2X_L, temp2);
}
break;
case 3:
if (mode == 0)
{
temp1 = sGpuBgConfigs2[3].bg_x >> 0x8;
SetGpuReg(REG_OFFSET_BG3HOFS, temp1);
}
else if (mode == 2)
{
temp1 = sGpuBgConfigs2[3].bg_x >> 0x10;
temp2 = sGpuBgConfigs2[3].bg_x & 0xFFFF;
SetGpuReg(REG_OFFSET_BG3X_H, temp1);
SetGpuReg(REG_OFFSET_BG3X_L, temp2);
}
break;
}
return sGpuBgConfigs2[bg].bg_x;
}
s32 GetBgX(u8 bg)
{
if (IsInvalidBg32(bg))
return -1;
else if (!GetBgControlAttribute(bg, BG_CTRL_ATTR_VISIBLE))
return -1;
else
return sGpuBgConfigs2[bg].bg_x;
}
s32 ChangeBgY(u8 bg, s32 value, u8 op)
{
u8 mode;
u16 temp1;
u16 temp2;
if (IsInvalidBg32(bg) || !GetBgControlAttribute(bg, BG_CTRL_ATTR_VISIBLE))
{
return -1;
}
switch (op)
{
case 0:
default:
sGpuBgConfigs2[bg].bg_y = value;
break;
case 1:
sGpuBgConfigs2[bg].bg_y += value;
break;
case 2:
sGpuBgConfigs2[bg].bg_y -= value;
break;
}
mode = GetBgMode();
switch (bg)
{
case 0:
temp1 = sGpuBgConfigs2[0].bg_y >> 0x8;
SetGpuReg(REG_OFFSET_BG0VOFS, temp1);
break;
case 1:
temp1 = sGpuBgConfigs2[1].bg_y >> 0x8;
SetGpuReg(REG_OFFSET_BG1VOFS, temp1);
break;
case 2:
if (mode == 0)
{
temp1 = sGpuBgConfigs2[2].bg_y >> 0x8;
SetGpuReg(REG_OFFSET_BG2VOFS, temp1);
}
else
{
temp1 = sGpuBgConfigs2[2].bg_y >> 0x10;
temp2 = sGpuBgConfigs2[2].bg_y & 0xFFFF;
SetGpuReg(REG_OFFSET_BG2Y_H, temp1);
SetGpuReg(REG_OFFSET_BG2Y_L, temp2);
}
break;
case 3:
if (mode == 0)
{
temp1 = sGpuBgConfigs2[3].bg_y >> 0x8;
SetGpuReg(REG_OFFSET_BG3VOFS, temp1);
}
else if (mode == 2)
{
temp1 = sGpuBgConfigs2[3].bg_y >> 0x10;
temp2 = sGpuBgConfigs2[3].bg_y & 0xFFFF;
SetGpuReg(REG_OFFSET_BG3Y_H, temp1);
SetGpuReg(REG_OFFSET_BG3Y_L, temp2);
}
break;
}
return sGpuBgConfigs2[bg].bg_y;
}
s32 ChangeBgY_ScreenOff(u8 bg, u32 value, u8 op)
{
u8 mode;
u16 temp1;
u16 temp2;
if (IsInvalidBg32(bg) || !GetBgControlAttribute(bg, BG_CTRL_ATTR_VISIBLE))
{
return -1;
}
switch (op)
{
case 0:
default:
sGpuBgConfigs2[bg].bg_y = value;
break;
case 1:
sGpuBgConfigs2[bg].bg_y += value;
break;
case 2:
sGpuBgConfigs2[bg].bg_y -= value;
break;
}
mode = GetBgMode();
switch (bg)
{
case 0:
temp1 = sGpuBgConfigs2[0].bg_y >> 0x8;
SetGpuReg_ForcedBlank(REG_OFFSET_BG0VOFS, temp1);
break;
case 1:
temp1 = sGpuBgConfigs2[1].bg_y >> 0x8;
SetGpuReg_ForcedBlank(REG_OFFSET_BG1VOFS, temp1);
break;
case 2:
if (mode == 0)
{
temp1 = sGpuBgConfigs2[2].bg_y >> 0x8;
SetGpuReg_ForcedBlank(REG_OFFSET_BG2VOFS, temp1);
}
else
{
temp1 = sGpuBgConfigs2[2].bg_y >> 0x10;
temp2 = sGpuBgConfigs2[2].bg_y & 0xFFFF;
SetGpuReg_ForcedBlank(REG_OFFSET_BG2Y_H, temp1);
SetGpuReg_ForcedBlank(REG_OFFSET_BG2Y_L, temp2);
}
break;
case 3:
if (mode == 0)
{
temp1 = sGpuBgConfigs2[3].bg_y >> 0x8;
SetGpuReg_ForcedBlank(REG_OFFSET_BG3VOFS, temp1);
}
else if (mode == 2)
{
temp1 = sGpuBgConfigs2[3].bg_y >> 0x10;
temp2 = sGpuBgConfigs2[3].bg_y & 0xFFFF;
SetGpuReg_ForcedBlank(REG_OFFSET_BG3Y_H, temp1);
SetGpuReg_ForcedBlank(REG_OFFSET_BG3Y_L, temp2);
}
break;
}
return sGpuBgConfigs2[bg].bg_y;
}
s32 GetBgY(u8 bg)
{
if (IsInvalidBg32(bg))
return -1;
else if (!GetBgControlAttribute(bg, BG_CTRL_ATTR_VISIBLE))
return -1;
else
return sGpuBgConfigs2[bg].bg_y;
}
void SetBgAffine(u8 bg, s32 srcCenterX, s32 srcCenterY, s16 dispCenterX, s16 dispCenterY, s16 scaleX, s16 scaleY, u16 rotationAngle)
{
SetBgAffineInternal(bg, srcCenterX, srcCenterY, dispCenterX, dispCenterY, scaleX, scaleY, rotationAngle);
}
u8 Unused_AdjustBgMosaic(u8 a1, u8 a2)
{
u16 result = GetGpuReg(REG_OFFSET_MOSAIC);
s16 test1 = result & 0xF;
s16 test2 = (result >> 4) & 0xF;
result &= 0xFF00;
switch (a2)
{
case 0:
default:
test1 = a1 & 0xF;
test2 = a1 >> 0x4;
break;
case 1:
test1 = a1 & 0xF;
break;
case 2:
if ((test1 + a1) > 0xF)
{
test1 = 0xF;
}
else
{
test1 += a1;
}
break;
case 3:
if ((test1 - a1) < 0)
{
test1 = 0x0;
}
else
{
test1 -= a1;
}
break;
case 4:
test2 = a1 & 0xF;
break;
case 5:
if ((test2 + a1) > 0xF)
{
test2 = 0xF;
}
else
{
test2 += a1;
}
break;
case 6:
if ((test2 - a1) < 0)
{
test2 = 0x0;
}
else
{
test2 -= a1;
}
break;
}
result |= ((test2 << 0x4) & 0xF0);
result |= (test1 & 0xF);
SetGpuReg(REG_OFFSET_MOSAIC, result);
return result;
}
void SetBgTilemapBuffer(u8 bg, void *tilemap)
{
if (!IsInvalidBg32(bg) && GetBgControlAttribute(bg, BG_CTRL_ATTR_VISIBLE))
{
sGpuBgConfigs2[bg].tilemap = tilemap;
}
}
void UnsetBgTilemapBuffer(u8 bg)
{
if (!IsInvalidBg32(bg) && GetBgControlAttribute(bg, BG_CTRL_ATTR_VISIBLE))
{
sGpuBgConfigs2[bg].tilemap = NULL;
}
}
void* GetBgTilemapBuffer(u8 bg)
{
if (IsInvalidBg32(bg))
return NULL;
else if (!GetBgControlAttribute(bg, BG_CTRL_ATTR_VISIBLE))
return NULL;
else
return sGpuBgConfigs2[bg].tilemap;
}
void CopyToBgTilemapBuffer(u8 bg, const void *src, u16 mode, u16 destOffset)
{
if (!IsInvalidBg32(bg) && !IsTileMapOutsideWram(bg))
{
if (mode != 0)
CpuCopy16(src, (void *)(sGpuBgConfigs2[bg].tilemap + (destOffset * 2)), mode);
else
LZ77UnCompWram(src, (void *)(sGpuBgConfigs2[bg].tilemap + (destOffset * 2)));
}
}
void CopyBgTilemapBufferToVram(u8 bg)
{
u16 sizeToLoad;
if (!IsInvalidBg32(bg) && !IsTileMapOutsideWram(bg))
{
switch (GetBgType(bg))
{
case 0:
sizeToLoad = GetBgMetricTextMode(bg, 0) * 0x800;
break;
case 1:
sizeToLoad = GetBgMetricAffineMode(bg, 0) * 0x100;
break;
default:
sizeToLoad = 0;
break;
}
LoadBgVram(bg, sGpuBgConfigs2[bg].tilemap, sizeToLoad, 0, 2);
}
}
void CopyToBgTilemapBufferRect(u8 bg, const void* src, u8 destX, u8 destY, u8 width, u8 height)
{
u16 destX16;
u16 destY16;
u16 mode;
if (!IsInvalidBg32(bg) && !IsTileMapOutsideWram(bg))
{
switch (GetBgType(bg))
{
case 0:
{
const u16 * srcCopy = src;
for (destY16 = destY; destY16 < (destY + height); destY16++)
{
for (destX16 = destX; destX16 < (destX + width); destX16++)
{
((u16*)sGpuBgConfigs2[bg].tilemap)[((destY16 * 0x20) + destX16)] = *srcCopy++;
}
}
break;
}
case 1:
{
const u8 * srcCopy = src;
mode = GetBgMetricAffineMode(bg, 0x1);
for (destY16 = destY; destY16 < (destY + height); destY16++)
{
for (destX16 = destX; destX16 < (destX + width); destX16++)
{
((u8*)sGpuBgConfigs2[bg].tilemap)[((destY16 * mode) + destX16)] = *srcCopy++;
}
}
break;
}
}
}
}
void CopyToBgTilemapBufferRect_ChangePalette(u8 bg, const void *src, u8 destX, u8 destY, u8 rectWidth, u8 rectHeight, u8 palette)
{
CopyRectToBgTilemapBufferRect(bg, src, 0, 0, rectWidth, rectHeight, destX, destY, rectWidth, rectHeight, palette, 0, 0);
}
void CopyRectToBgTilemapBufferRect(u8 bg, const void *src, u8 srcX, u8 srcY, u8 srcWidth, u8 unused, u8 srcHeight, u8 destX, u8 destY, u8 rectWidth, u8 rectHeight, s16 palette1, s16 tileOffset)
{
u16 screenWidth, screenHeight, screenSize;
u16 var;
const void *srcPtr;
u16 i, j;
if (!IsInvalidBg32(bg) && !IsTileMapOutsideWram(bg))
{
screenSize = GetBgControlAttribute(bg, BG_CTRL_ATTR_SCREENSIZE);
screenWidth = GetBgMetricTextMode(bg, 0x1) * 0x20;
screenHeight = GetBgMetricTextMode(bg, 0x2) * 0x20;
switch (GetBgType(bg))
{
case 0:
srcPtr = src + ((srcY * srcWidth) + srcX) * 2;
for (i = destX; i < (destX + rectWidth); i++)
{
for (j = srcHeight; j < (srcHeight + destY); j++)
{
u16 index = GetTileMapIndexFromCoords(j, i, screenSize, screenWidth, screenHeight);
CopyTileMapEntry(srcPtr, sGpuBgConfigs2[bg].tilemap + (index * 2), rectHeight, palette1, tileOffset);
srcPtr += 2;
}
srcPtr += (srcWidth - destY) * 2;
}
break;
case 1:
srcPtr = src + ((srcY * srcWidth) + srcX);
var = GetBgMetricAffineMode(bg, 0x1);
for (i = destX; i < (destX + rectWidth); i++)
{
for (j = srcHeight; j < (srcHeight + destY); j++)
{
*(u8*)(sGpuBgConfigs2[bg].tilemap + ((var * i) + j)) = *(u8*)(srcPtr) + palette1;
srcPtr++;
}
srcPtr += (srcWidth - destY);
}
break;
}
}
}
void FillBgTilemapBufferRect_Palette0(u8 bg, u16 tileNum, u8 x, u8 y, u8 width, u8 height)
{
u16 x16;
u16 y16;
u16 mode;
if (!IsInvalidBg32(bg) && !IsTileMapOutsideWram(bg))
{
switch (GetBgType(bg))
{
case 0:
for (y16 = y; y16 < (y + height); y16++)
{
for (x16 = x; x16 < (x + width); x16++)
{
((u16*)sGpuBgConfigs2[bg].tilemap)[((y16 * 0x20) + x16)] = tileNum;
}
}
break;
case 1:
mode = GetBgMetricAffineMode(bg, 0x1);
for (y16 = y; y16 < (y + height); y16++)
{
for (x16 = x; x16 < (x + width); x16++)
{
((u8*)sGpuBgConfigs2[bg].tilemap)[((y16 * mode) + x16)] = tileNum;
}
}
break;
}
}
}
void FillBgTilemapBufferRect(u8 bg, u16 tileNum, u8 x, u8 y, u8 width, u8 height, u8 palette)
{
WriteSequenceToBgTilemapBuffer(bg, tileNum, x, y, width, height, palette, 0);
}
void WriteSequenceToBgTilemapBuffer(u8 bg, u16 firstTileNum, u8 x, u8 y, u8 width, u8 height, u8 paletteSlot, s16 tileNumDelta)
{
u16 mode;
u16 mode2;
u16 attribute;
u16 mode3;
u16 x16, y16;
if (!IsInvalidBg32(bg) && !IsTileMapOutsideWram(bg))
{
attribute = GetBgControlAttribute(bg, BG_CTRL_ATTR_SCREENSIZE);
mode = GetBgMetricTextMode(bg, 0x1) * 0x20;
mode2 = GetBgMetricTextMode(bg, 0x2) * 0x20;
switch (GetBgType(bg))
{
case 0:
for (y16 = y; y16 < (y + height); y16++)
{
for (x16 = x; x16 < (x + width); x16++)
{
CopyTileMapEntry(&firstTileNum, &((u16*)sGpuBgConfigs2[bg].tilemap)[(u16)GetTileMapIndexFromCoords(x16, y16, attribute, mode, mode2)], paletteSlot, 0, 0);
firstTileNum = (firstTileNum & (METATILE_COLLISION_MASK | METATILE_ELEVATION_MASK)) + ((firstTileNum + tileNumDelta) & METATILE_ID_MASK);
}
}
break;
case 1:
mode3 = GetBgMetricAffineMode(bg, 0x1);
for (y16 = y; y16 < (y + height); y16++)
{
for (x16 = x; x16 < (x + width); x16++)
{
((u8*)sGpuBgConfigs2[bg].tilemap)[(y16 * mode3) + x16] = firstTileNum;
firstTileNum = (firstTileNum & (METATILE_COLLISION_MASK | METATILE_ELEVATION_MASK)) + ((firstTileNum + tileNumDelta) & METATILE_ID_MASK);
}
}
break;
}
}
}
u16 GetBgMetricTextMode(u8 bg, u8 whichMetric)
{
u8 screenSize = GetBgControlAttribute(bg, BG_CTRL_ATTR_SCREENSIZE);
switch (whichMetric)
{
case 0:
switch (screenSize)
{
case 0:
return 1;
case 1:
case 2:
return 2;
case 3:
return 4;
}
break;
case 1:
switch (screenSize)
{
case 0:
return 1;
case 1:
return 2;
case 2:
return 1;
case 3:
return 2;
}
break;
case 2:
switch (screenSize)
{
case 0:
case 1:
return 1;
case 2:
case 3:
return 2;
}
break;
}
return 0;
}
u32 GetBgMetricAffineMode(u8 bg, u8 whichMetric)
{
u8 screenSize = GetBgControlAttribute(bg, BG_CTRL_ATTR_SCREENSIZE);
switch (whichMetric)
{
case 0:
switch (screenSize)
{
case 0:
return 0x1;
case 1:
return 0x4;
case 2:
return 0x10;
case 3:
return 0x40;
}
break;
case 1:
case 2:
return 0x10 << screenSize;
}
return 0;
}
u32 GetTileMapIndexFromCoords(s32 x, s32 y, s32 screenSize, u32 screenWidth, u32 screenHeight)
{
x = x & (screenWidth - 1);
y = y & (screenHeight - 1);
switch (screenSize)
{
case 0:
case 2:
break;
case 3:
if (y >= 0x20)
y += 0x20;
case 1:
if (x >= 0x20)
{
x -= 0x20;
y += 0x20;
}
break;
}
return (y * 0x20) + x;
}
void CopyTileMapEntry(const u16 *src, u16 *dest, s32 palette1, s32 tileOffset, s32 palette2)
{
u16 var;
if (palette1 == 16)
goto CASE_16;
switch (palette1)
{
case 0 ... 16:
var = ((*src + tileOffset) & 0xFFF) + ((palette1 + palette2) << 12);
break;
CASE_16:
var = *dest;
var &= 0xFC00;
var += palette2 << 12;
var |= (*src + tileOffset) & 0x3FF;
break;
default:
var = *src + tileOffset + (palette2 << 12);
break;
}
*dest = var;
}
u32 GetBgType(u8 bg)
{
u8 mode = GetBgMode();
switch (bg)
{
case 0:
case 1:
switch (mode)
{
case 0:
case 1:
return 0;
}
break;
case 2:
switch (mode)
{
case 0:
return 0;
case 1:
case 2:
return 1;
}
break;
case 3:
switch (mode)
{
case 0:
return 0;
case 2:
return 1;
}
break;
}
return 0xFFFF;
}
bool32 IsInvalidBg32(u8 bg)
{
if (bg > 3)
return TRUE;
else
return FALSE;
}
bool32 IsTileMapOutsideWram(u8 bg)
{
if (sGpuBgConfigs2[bg].tilemap > (void*)IWRAM_END)
return TRUE;
else if (sGpuBgConfigs2[bg].tilemap == NULL)
return TRUE;
else
return FALSE;
}