pcsx2/plugins/zzogl-pg/opengl/GS.h

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/* ZeroGS KOSMOS
* Copyright (C) 2005-2006 zerofrog@gmail.com
*
* 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 02110-1301, USA
*/
#ifndef __GS_H__
#define __GS_H__
#define USE_OLD_REGS
#include "Util.h"
#include "GifTransfer.h"
extern float fFPS;
using namespace std;
#ifdef _WIN32
#define GL_WIN32_WINDOW
#else
#define GL_X11_WINDOW
#endif
#undef CreateWindow // Undo Windows.h global namespace pollution
#ifdef GL_X11_WINDOW
#include <X11/extensions/xf86vmode.h>
#endif
class GLWindow
{
private:
#ifdef GL_X11_WINDOW
Display *glDisplay;
Window glWindow;
int glScreen;
GLXContext context;
XSetWindowAttributes attr;
XF86VidModeModeInfo deskMode;
#endif
bool fullScreen, doubleBuffered;
s32 x, y;
u32 width, height, depth;
public:
void SwapGLBuffers();
void SetTitle(char *strtitle);
bool CreateWindow(void *pDisplay);
bool ReleaseWindow();
void CloseWindow();
bool DisplayWindow(int _width, int _height);
void ResizeCheck();
};
extern GLWindow GLWin;
struct Vector_16F
{
u16 x, y, z, w;
};
REG64_(GSReg, BGCOLOR)
u32 R:8;
u32 G:8;
u32 B:8;
u32 _PAD1:8;
u32 _PAD2:32;
REG_END
REG64_(GSReg, BUSDIR)
u32 DIR:1;
u32 _PAD1:31;
u32 _PAD2:32;
REG_END
REG64_(GSReg, CSR)
u32 SIGNAL:1;
u32 FINISH:1;
u32 HSINT:1;
u32 VSINT:1;
u32 EDWINT:1;
u32 ZERO1:1;
u32 ZERO2:1;
u32 _PAD1:1;
u32 FLUSH:1;
u32 RESET:1;
u32 _PAD2:2;
u32 NFIELD:1;
u32 FIELD:1;
u32 FIFO:2;
u32 REV:8;
u32 ID:8;
u32 _PAD3:32;
REG_END
REG64_(GSReg, DISPFB) // (-1/2)
u32 FBP:9;
u32 FBW:6;
u32 PSM:5;
u32 _PAD:12;
u32 DBX:11;
u32 DBY:11;
u32 _PAD2:10;
REG_END
REG64_(GSReg, DISPLAY) // (-1/2)
u32 DX:12;
u32 DY:11;
u32 MAGH:4;
u32 MAGV:2;
u32 _PAD:3;
u32 DW:12;
u32 DH:11;
u32 _PAD2:9;
REG_END
REG64_(GSReg, EXTBUF)
u32 EXBP:14;
u32 EXBW:6;
u32 FBIN:2;
u32 WFFMD:1;
u32 EMODA:2;
u32 EMODC:2;
u32 _PAD1:5;
u32 WDX:11;
u32 WDY:11;
u32 _PAD2:10;
REG_END
REG64_(GSReg, EXTDATA)
u32 SX:12;
u32 SY:11;
u32 SMPH:4;
u32 SMPV:2;
u32 _PAD1:3;
u32 WW:12;
u32 WH:11;
u32 _PAD2:9;
REG_END
REG64_(GSReg, EXTWRITE)
u32 WRITE;
u32 _PAD2:32;
REG_END
REG64_(GSReg, IMR)
u32 _PAD1:8;
u32 SIGMSK:1;
u32 FINISHMSK:1;
u32 HSMSK:1;
u32 VSMSK:1;
u32 EDWMSK:1;
u32 _PAD2:19;
u32 _PAD3:32;
REG_END
REG64_(GSReg, PMODE)
u32 EN1:1;
u32 EN2:1;
u32 CRTMD:3;
u32 MMOD:1;
u32 AMOD:1;
u32 SLBG:1;
u32 ALP:8;
u32 _PAD:16;
u32 _PAD1:32;
REG_END
REG64_(GSReg, SIGLBLID)
u32 SIGID:32;
u32 LBLID:32;
REG_END
REG64_(GSReg, SMODE1)
u32 RC:3;
u32 LC:7;
u32 T1248:2;
u32 SLCK:1;
u32 CMOD:2;
u32 EX:1;
u32 PRST:1;
u32 SINT:1;
u32 XPCK:1;
u32 PCK2:2;
u32 SPML:4;
u32 GCONT:1;
u32 PHS:1;
u32 PVS:1;
u32 PEHS:1;
u32 PEVS:1;
u32 CLKSEL:2;
u32 NVCK:1;
u32 SLCK2:1;
u32 VCKSEL:2;
u32 VHP:1;
u32 _PAD1:27;
REG_END
REG64_(GSReg, SMODE2)
u32 INT:1;
u32 FFMD:1;
u32 DPMS:2;
u32 _PAD2:28;
u32 _PAD3:32;
REG_END
REG64_(GSReg, SIGBLID)
u32 SIGID;
u32 LBLID;
REG_END
extern int g_LastCRC;
extern u8* g_pBasePS2Mem;
#define PMODE ((GSRegPMODE*)(g_pBasePS2Mem+0x0000))
#define SMODE1 ((GSRegSMODE1*)(g_pBasePS2Mem+0x0010))
#define SMODE2 ((GSRegSMODE2*)(g_pBasePS2Mem+0x0020))
// SRFSH
#define SYNCH1 ((GSRegSYNCH1*)(g_pBasePS2Mem+0x0040))
#define SYNCH2 ((GSRegSYNCH2*)(g_pBasePS2Mem+0x0050))
#define SYNCV ((GSRegSYNCV*)(g_pBasePS2Mem+0x0060))
#define DISPFB1 ((GSRegDISPFB*)(g_pBasePS2Mem+0x0070))
#define DISPLAY1 ((GSRegDISPLAY*)(g_pBasePS2Mem+0x0080))
#define DISPFB2 ((GSRegDISPFB*)(g_pBasePS2Mem+0x0090))
#define DISPLAY2 ((GSRegDISPLAY*)(g_pBasePS2Mem+0x00a0))
#define EXTBUF ((GSRegEXTBUF*)(g_pBasePS2Mem+0x00b0))
#define EXTDATA ((GSRegEXTDATA*)(g_pBasePS2Mem+0x00c0))
#define EXTWRITE ((GSRegEXTWRITE*)(g_pBasePS2Mem+0x00d0))
#define BGCOLOR ((GSRegBGCOLOR*)(g_pBasePS2Mem+0x00e0))
#define CSR ((GSRegCSR*)(g_pBasePS2Mem+0x1000))
#define IMR ((GSRegIMR*)(g_pBasePS2Mem+0x1010))
#define BUSDIR ((GSRegBUSDIR*)(g_pBasePS2Mem+0x1040))
#define SIGLBLID ((GSRegSIGBLID*)(g_pBasePS2Mem+0x1080))
#define GET_GSFPS (((SMODE1->CMOD&1) ? 50 : 60) / (SMODE2->INT ? 1 : 2))
//
// sps2tags.h
//
#define GET_GIF_REG(tag, reg) \
(((tag).ai32[2 + ((reg) >> 3)] >> (((reg) & 7) << 2)) & 0xf)
// PS2 vertex
struct VertexGPU
{
// gained from XYZ2, XYZ3, XYZF2, XYZF3,
// X -- bits 0-15, Y-16-31. Z - 32-63 if no F used, 32-55 otherwise, F (fog) - 56-63
// X, Y stored in 12d3 format,
s16 x, y, f, resv0; // note: xy is 12d3
// Vertex color settings. RGB -- luminance of red/green/blue, A -- alpha. 1.0 == 0x80.
// Goes grom RGBAQ register, bits 0-7, 8-15, 16-23 and 24-31 accordingly
u32 rgba;
u32 z;
// Texture coordinates. S & T going from ST register (bits 0-31, and 32-63).
// Q goes from RGBAQ register, bits 32-63
float s, t, q;
};
// Almost same with previous, controlled by prim.fst flagf
struct Vertex
{
u16 x, y, f, resv0; // note: xy is 12d3
u32 rgba;
u32 z;
float s, t, q;
// Texel coordinate of vertex. Used if prim.fst == 1
// Bits 0-14 and 16-30 of UV
u16 u, v;
};
extern GSconf conf;
// PSM values
// PSM types == Texture Storage Format
enum PSM_value
{
PSMCT32 = 0, // 000000
PSMCT24 = 1, // 000001
PSMCT16 = 2, // 000010
PSMCT16S = 10, // 001010
PSMT8 = 19, // 010011
PSMT4 = 20, // 010100
PSMT8H = 27, // 011011
PSMT4HL = 36, // 100100
PSMT4HH = 44, // 101100
PSMT32Z = 48, // 110000
PSMT24Z = 49, // 110001
PSMT16Z = 50, // 110010
PSMT16SZ = 58, // 111010
};
// Check target bit mode. PSMCT32 and 32Z return 0, 24 and 24Z - 1
// 16, 16S, 16Z, 16SZ -- 2, PSMT8 and 8H - 3, PSMT4, 4HL, 4HH -- 4.
inline int PSMT_BITMODE(int psm) {return (psm & 0x7);}
// CLUT = Color look up table. Set proper color to table according CLUT table.
// Used for PSMT8, PSMT8H, PSMT4, PSMT4HH, PSMT4HL textures
inline bool PSMT_ISCLUT(int psm) { return (PSMT_BITMODE(psm) > 2);}
// PSMCT16, PSMCT16S, PSMT16Z, PSMT16SZ is 16-bit targets and usually there is
// two of them in each 32-bit word.
inline bool PSMT_IS16BIT(int psm) { return (PSMT_BITMODE(psm) == 2);}
// PSMT32Z, PSMT24Z, PSMT16Z, PSMT16SZ is Z-buffer textures
inline bool PSMT_ISZTEX(int psm) {return ((psm & 0x30) == 0x30);}
// PSMCT16, PSMCT16S, PSMT8, PSMT8H, PSMT16Z and PSMT16SZ use only half 16 bit per pixel.
inline bool PSMT_ISHALF(int psm) {return ((psm & 2) == 2);}
// PSMT8 and PSMT8H use IDTEX8 CLUT, PSMT4H, PSMT4HL, PSMT4HH -- IDTEX4.
// Don't use it on non clut entries, please!
inline bool PSMT_IS8CLUT(int psm) {return ((psm & 3) == 3);}
// PSM16Z and PSMT16SZ use -1 offset to z-buff. Need to check this thesis.
inline bool PSMT_IS16Z(int psm) {return ((psm & 0x32) == 0x32);}
// Check to see if it is 32 bits. According to code comments, anyways.
// I'll have to look closer at it, because it'd seem like it'd return true for 24 bits.
inline bool PSMT_IS32BIT(int psm) {return !!(psm <= 1);}
//----------------------- Data from registers -----------------------
typedef union
{
s64 SD;
u64 UD;
s32 SL[2];
u32 UL[2];
s16 SS[4];
u16 US[4];
s8 SC[8];
u8 UC[8];
} reg64;
/* general purpose regs structs */
typedef struct
{
int fbp;
int fbw;
int fbh;
int psm;
u32 fbm;
} frameInfo;
// Create frame structure from known data
inline frameInfo CreateFrame(int fbp, int fbw, int fbh, int psm, u32 fbm)
{
frameInfo frame;
frame.fbp = fbp;
frame.fbw = fbw;
frame.fbh = fbh;
frame.psm = psm;
frame.fbm = fbm;
return frame;
}
typedef struct
{
u16 prim;
union
{
struct
{
u16 iip : 1;
u16 tme : 1;
u16 fge : 1;
u16 abe : 1;
u16 aa1 : 1;
u16 fst : 1;
u16 ctxt : 1;
u16 fix : 1;
u16 resv : 8;
};
u16 _val;
};
} primInfo;
extern primInfo *prim;
typedef union
{
struct
{
u32 ate : 1;
u32 atst : 3;
u32 aref : 8;
u32 afail : 2;
u32 date : 1;
u32 datm : 1;
u32 zte : 1;
u32 ztst : 2;
u32 resv : 13;
};
u32 _val;
} pixTest;
typedef struct
{
int bp;
int bw;
int psm;
} bufInfo;
typedef struct
{
int tbp0;
int tbw;
int cbp;
u16 tw, th;
u8 psm;
u8 tcc;
u8 tfx;
u8 cpsm;
u8 csm;
u8 csa;
u8 cld;
} tex0Info;
union tex_0_info
{
struct
{
u64 tbp0 : 14;
u64 tbw : 6;
u64 psm : 6;
u64 tw : 4;
u64 th : 4;
u64 tcc : 1;
u64 tfx : 2;
u64 cbp : 14;
u64 cpsm : 4;
u64 csm : 1;
u64 csa : 5;
u64 cld : 3;
};
u64 _u64;
u32 _u32[2];
u16 _u16[4];
u8 _u8[8];
tex_0_info(u64 data) { _u64 = data; }
tex_0_info(u32 data) { _u32[0] = data; _u32[1] = 0; }
tex_0_info(u32 data0, u32 data1) { _u32[0] = data0; _u32[1] = data1; }
u32 tbw_mult()
{
if (tbw == 0)
return 64;
else
return ((u32)tbw << 6);
}
u32 psm_fix()
{
// printf ("psm %d\n", psm);
if (psm == 9) return 1;
return psm;
}
u32 tw_exp()
{
if (tw > 10) return (1 << 10);
return (1 << tw);
}
u32 th_exp()
{
if (th > 10) return (1 << 10);
return (1 << th);
}
u32 cpsm_fix()
{
return cpsm & 0xe;
}
u32 csa_fix()
{
if (cpsm < 2)
return (csa & 0xf);
else
return (csa & 0x1f);
}
};
#define TEX_MODULATE 0
#define TEX_DECAL 1
#define TEX_HIGHLIGHT 2
#define TEX_HIGHLIGHT2 3
typedef struct
{
int lcm;
int mxl;
int mmag;
int mmin;
int mtba;
int l;
int k;
} tex1Info;
typedef struct
{
int wms;
int wmt;
int minu;
int maxu;
int minv;
int maxv;
} clampInfo;
typedef struct
{
int cbw;
int cou;
int cov;
} clutInfo;
typedef struct
{
int tbp[3];
int tbw[3];
} miptbpInfo;
typedef struct
{
u16 aem;
u8 ta[2];
float fta[2];
} texaInfo;
typedef struct
{
int sx;
int sy;
int dx;
int dy;
#ifdef USE_OLD_REGS
int dir;
#else
int diry;
int dirx;
#endif
} trxposInfo;
typedef struct
{
union
{
struct
{
u8 a : 2;
u8 b : 2;
u8 c : 2;
u8 d : 2;
};
u8 abcd;
};
u8 fix : 8;
} alphaInfo;
typedef struct
{
u16 zbp; // u16 address / 64
u8 psm;
u8 zmsk;
} zbufInfo;
typedef struct
{
int fba;
} fbaInfo;
typedef struct
{
Vertex gsvertex[3];
u32 rgba;
float q;
Vertex vertexregs;
int primC; // number of verts current storing
int primIndex; // current prim index
int nTriFanVert;
int prac;
int dthe;
int colclamp;
int fogcol;
int smask;
int pabe;
u64 buff[2];
int buffsize;
int cbp[2]; // internal cbp registers
u32 CSRw;
primInfo _prim[2];
bufInfo srcbuf, srcbufnew;
bufInfo dstbuf, dstbufnew;
clutInfo clut;
texaInfo texa;
trxposInfo trxpos, trxposnew;
int imageWtemp, imageHtemp;
int imageTransfer;
int imageWnew, imageHnew, imageX, imageY, imageEndX, imageEndY;
pathInfo path[3];
void setRGBA(u32 r, u32 g, u32 b, u32 a)
{
rgba = (r & 0xff) |
((g & 0xff) << 8) |
((b & 0xff) << 16) |
((a & 0xff) << 24);
}
} GSinternal;
extern GSinternal gs;
static __forceinline u16 RGBA32to16(u32 c)
{
return (u16)((((c) & 0x000000f8) >> 3) |
(((c) & 0x0000f800) >> 6) |
(((c) & 0x00f80000) >> 9) |
(((c) & 0x80000000) >> 16));
}
static __forceinline u32 RGBA16to32(u16 c)
{
return (((c) & 0x001f) << 3) |
(((c) & 0x03e0) << 6) |
(((c) & 0x7c00) << 9) |
(((c) & 0x8000) ? 0xff000000 : 0);
}
// converts float16 [0,1] to BYTE [0,255] (assumes value is in range, otherwise will take lower 8bits)
// f is a u16
static __forceinline u16 Float16ToBYTE(u16 f)
{
//assert( !(f & 0x8000) );
if (f & 0x8000) return 0;
u16 d = ((((f & 0x3ff) | 0x400) * 255) >> (10 - ((f >> 10) & 0x1f) + 15));
return d > 255 ? 255 : d;
}
static __forceinline u16 Float16ToALPHA(u16 f)
{
//assert( !(f & 0x8000) );
if (f & 0x8000) return 0;
// round up instead of down (crash and burn), too much and charlie breaks
u16 d = (((((f & 0x3ff) | 0x400)) * 255) >> (10 - ((f >> 10) & 0x1f) + 15));
d = (d) >> 1;
return d > 255 ? 255 : d;
}
#ifndef COLOR_ARGB
#define COLOR_ARGB(a,r,g,b) \
((u32)((((a)&0xff)<<24)|(((r)&0xff)<<16)|(((g)&0xff)<<8)|((b)&0xff)))
#endif
// assumes that positive in [1,2] (then extracts fraction by just looking at the specified bits)
#define Float16ToBYTE_2(f) ((u8)(*(u16*)&f>>2))
#define Float16To5BIT(f) (Float16ToBYTE(f)>>3)
#define Float16Alpha(f) (((*(u16*)&f&0x7c00)>=0x3900)?0x8000:0) // alpha is >= 1
// converts an array of 4 u16s to a u32 color
// f is a pointer to a u16
#define Float16ToARGB(f) COLOR_ARGB(Float16ToALPHA(f.w), Float16ToBYTE(f.x), Float16ToBYTE(f.y), Float16ToBYTE(f.z));
#define Float16ToARGB16(f) (Float16Alpha(f.w)|(Float16To5BIT(f.x)<<10)|(Float16To5BIT(f.y)<<5)|Float16To5BIT(f.z))
// used for Z values
#define Float16ToARGB_Z(f) COLOR_ARGB((u32)Float16ToBYTE_2(f.w), Float16ToBYTE_2(f.x), Float16ToBYTE_2(f.y), Float16ToBYTE_2(f.z))
#define Float16ToARGB16_Z(f) ((Float16ToBYTE_2(f.y)<<8)|Float16ToBYTE_2(f.z))
inline float Clamp(float fx, float fmin, float fmax)
{
if (fx < fmin) return fmin;
return fx > fmax ? fmax : fx;
}
// PSMT16, 16S have shorter color per pixel, also cluted textures with half storage.
inline bool PSMT_ISHALF_STORAGE(const tex0Info& tex0)
{
if (PSMT_IS16BIT(tex0.psm) || (PSMT_ISCLUT(tex0.psm) && tex0.cpsm > 1))
return true;
else
return false;
}
//--------------------------- Inlines for bitwise ops
//--------------------------- textures
// Tex0Info (TEXD_x registers) bits, lower word
// The register is really 64-bit, but we use 2 32bit ones to represent it
// Obtain tbp0 -- Texture Buffer Base Pointer (Word Address/64) -- from data. Bits 0-13.
static __forceinline int ZZOglGet_tbp0_TexBits(u32 data)
{
//return tex_0_info(data).tbp0;
return (data) & 0x3fff;
}
// Obtain tbw -- Texture Buffer Width (Texels/64) -- from data, do not multiply to 64. Bits 14-19
// ( data & 0xfc000 ) >> 14
static __forceinline int ZZOglGet_tbw_TexBits(u32 data)
{
//return tex_0_info(data).tbw;
return (data >> 14) & 0x3f;
}
// Obtain tbw -- Texture Buffer Width (Texels) -- from data, do multiply to 64, never return 0.
static __forceinline int ZZOglGet_tbw_TexBitsMult(u32 data)
{
//return text_0_info(data).tbw_mult();
int result = ZZOglGet_tbw_TexBits(data);
if (result == 0)
return 64;
else
return (result << 6);
}
// Obtain psm -- Pixel Storage Format -- from data. Bits 20-25.
// (data & 0x3f00000) >> 20
static __forceinline int ZZOglGet_psm_TexBits(u32 data)
{
//return tex_0_info(data).psm;
return ((data >> 20) & 0x3f);
}
// Obtain psm -- Pixel Storage Format -- from data. Bits 20-25. Fix incorrect psm == 9
static __forceinline int ZZOglGet_psm_TexBitsFix(u32 data)
{
//return tex_0_info(data).psm_fix();
int result = ZZOglGet_psm_TexBits(data) ;
// printf ("result %d\n", result);
if (result == 9) result = 1;
return result;
}
// Obtain tw -- Texture Width (Width = 2^TW) -- from data. Bits 26-29
// (data & 0x3c000000)>>26
static __forceinline u16 ZZOglGet_tw_TexBits(u32 data)
{
//return tex_0_info(data).tw;
return ((data >> 26) & 0xf);
}
// Obtain tw -- Texture Width (Width = TW) -- from data. Width could newer be more than 1024.
static __forceinline u16 ZZOglGet_tw_TexBitsExp(u32 data)
{
//return tex_0_info(data).tw_exp();
u16 result = ZZOglGet_tw_TexBits(data);
if (result > 10) result = 10;
return (1 << result);
}
// TH set at the border of upper and higher words.
// Obtain th -- Texture Height (Height = 2^TH) -- from data. Bits 30-31 lower, 0-1 higher
// (dataLO & 0xc0000000) >> 30 + (dataHI & 0x3) * 0x4
static __forceinline u16 ZZOglGet_th_TexBits(u32 dataLO, u32 dataHI)
{
//return tex_0_info(dataLO, dataHI).th;
return (((dataLO >> 30) & 0x3) | ((dataHI & 0x3) << 2));
}
// Obtain th --Texture Height (Height = 2^TH) -- from data. Height could newer be more than 1024.
static __forceinline u16 ZZOglGet_th_TexBitsExp(u32 dataLO, u32 dataHI)
{
//return tex_0_info(dataLO, dataHI).th_exp();
u16 result = ZZOglGet_th_TexBits(dataLO, dataHI);
if (result > 10) result = 10;
return (1 << result);
}
// Tex0Info bits, higher word.
// Obtain tcc -- Texture Color Component 0=RGB, 1=RGBA + use Alpha from TEXA reg when not in PSM -- from data. Bit 3
// (data & 0x4)>>2
static __forceinline u8 ZZOglGet_tcc_TexBits(u32 data)
{
//return tex_0_info(0, data).tcc;
return ((data >> 2) & 0x1);
}
// Obtain tfx -- Texture Function (0=modulate, 1=decal, 2=hilight, 3=hilight2) -- from data. Bit 4-5
// (data & 0x18)>>3
static __forceinline u8 ZZOglGet_tfx_TexBits(u32 data)
{
//return tex_0_info(0, data).tfx;
return ((data >> 3) & 0x3);
}
// Obtain cbp from data -- Clut Buffer Base Pointer (Address/256) -- Bits 5-18
// (data & 0x7ffe0)>>5
static __forceinline int ZZOglGet_cbp_TexBits(u32 data)
{
//return tex_0_info(0, data).cbp;
return ((data >> 5) & 0x3fff);
}
// Obtain cpsm from data -- Clut pixel Storage Format -- Bits 19-22. 22nd is at no use.
// (data & 0x700000)>>19
// 0000 - psmct32; 0010 - psmct16; 1010 - psmct16s.
static __forceinline u8 ZZOglGet_cpsm_TexBits(u32 data)
{
//return (tex_0_info(0, data).cpsm & 0xe);
return ((data >> 19) & 0xe);
}
// Obtain csm -- I don't know what is it -- from data. Bit 23
// (data & 0x800000)>>23
// csm is the clut storage mode. 0 for CSM1, 1 for CSM2.
static __forceinline u8 ZZOglGet_csm_TexBits(u32 data)
{
//return tex_0_info(0, data).csm;
return ((data >> 23) & 0x1);
}
// Obtain csa -- -- from data. Bits 24-28
// (data & 0x1f000000)>>24
static __forceinline u8 ZZOglGet_csa_TexBits(u32 data)
{
//return tex_0_info(0, data).csa_fix();
if ((data & 0x700000) == 0) // it is cpsm < 2 check
return ((data >> 24) & 0xf);
else
return ((data >> 24) & 0x1f);
}
// Obtain cld -- -- from data. Bits 29-31
// (data & 0xe0000000)>>29
static __forceinline u8 ZZOglGet_cld_TexBits(u32 data)
{
//return tex_0_info(0, data).cld;
return ((data >> 29) & 0x7);
}
//-------------------------- frames
// FrameInfo bits.
// Obtain fbp -- frame Buffer Base Pointer (Word Address/2048) -- from data. Bits 0-15
inline int ZZOglGet_fbp_FrameBits(u32 data)
{
return ((data) & 0x1ff);
}
// So we got address / 64, henceby frame fbp and tex tbp have the same dimension -- "real address" is x64.
inline int ZZOglGet_fbp_FrameBitsMult(u32 data)
{
return (ZZOglGet_fbp_FrameBits(data) << 5);
}
// Obtain fbw -- width (Texels/64) -- from data. Bits 16-23
inline int ZZOglGet_fbw_FrameBits(u32 data)
{
return ((data >> 16) & 0x3f);
}
inline int ZZOglGet_fbw_FrameBitsMult(u32 data)
{
return (ZZOglGet_fbw_FrameBits(data) << 6);
}
// Obtain psm -- Pixel Storage Format -- from data. Bits 24-29.
// (data & 0x3f000000) >> 24
inline int ZZOglGet_psm_FrameBits(u32 data)
{
return ((data >> 24) & 0x3f);
}
// Function for calculating overal height from frame data.
inline int ZZOgl_fbh_Calc(int fbp, int fbw, int psm)
{
int fbh = (1024 * 1024 - 64 * fbp) / fbw;
fbh &= ~0x1f;
if (PSMT_ISHALF(psm)) fbh *= 2;
if (fbh > 1024) fbh = 1024;
//ZZLog::Debug_Log("ZZOgl_fbh_Calc: 0x%x", fbh);
return fbh;
}
inline int ZZOgl_fbh_Calc(frameInfo frame)
{
return ZZOgl_fbh_Calc(frame.fbp, frame.fbw, frame.psm);
}
// Calculate fbh from data, It does not set in register
inline int ZZOglGet_fbh_FrameBitsCalc(u32 data)
{
int fbh = 0;
int fbp = ZZOglGet_fbp_FrameBits(data);
int fbw = ZZOglGet_fbw_FrameBits(data);
int psm = ZZOglGet_psm_FrameBits(data);
if (fbw > 0) fbh = ZZOgl_fbh_Calc(fbp, fbw, psm) ;
return fbh ;
}
// Obtain fbm -- frame mask -- from data. All higher word.
inline u32 ZZOglGet_fbm_FrameBits(u32 data)
{
return (data);
}
// Obtain fbm -- frame mask -- from data. All higher word. Fixed from psm == PCMT24 (without alpha)
inline u32 ZZOglGet_fbm_FrameBitsFix(u32 dataLO, u32 dataHI)
{
if (PSMT_BITMODE(ZZOglGet_psm_FrameBits(dataLO)) == 1)
return (dataHI | 0xff000000);
else
return dataHI;
}
// obtain colormask RED
inline u32 ZZOglGet_fbmRed_FrameBits(u32 data)
{
return (data & 0xff);
}
// obtain colormask Green
inline u32 ZZOglGet_fbmGreen_FrameBits(u32 data)
{
return ((data >> 8) & 0xff);
}
// obtain colormask Blue
inline u32 ZZOglGet_fbmBlue_FrameBits(u32 data)
{
return ((data >> 16) & 0xff);
}
// obtain colormask Alpha
inline u32 ZZOglGet_fbmAlpha_FrameBits(u32 data)
{
return ((data >> 24) & 0xff);
}
// obtain colormask Alpha
inline u32 ZZOglGet_fbmHighByte(u32 data)
{
return (!!(data & 0x80000000));
}
//-------------------------- tex0 comparison
// Check if old and new tex0 registers have only clut difference
inline bool ZZOglAllExceptClutIsSame(u32* oldtex, u32* newtex)
{
return ((oldtex[0] == newtex[0]) && ((oldtex[1] & 0x1f) == (newtex[1] & 0x1f)));
}
// Check if the CLUT registers are same, except CLD
inline bool ZZOglClutMinusCLDunchanged(u32* oldtex, u32* newtex)
{
return ((oldtex[1] & 0x1fffffe0) == (newtex[1] & 0x1fffffe0));
}
// Check if CLUT storage mode is not changed (CSA, CSM and CSPM)
inline bool ZZOglClutStorageUnchanged(u32* oldtex, u32* newtex)
{
return ((oldtex[1] & 0x1ff10000) == (newtex[1] & 0x1ff10000));
}
// CSA and CPSM bitmask 0001 1111 0111 1000 ...
// 60 56 52
#define CPSM_CSA_BITMASK 0x1f780000
#define CPSM_CSA_NOTMASK 0xe0870000
#endif