nolibgs_hello_worlds/hello_sprt/hello_sprt.c

#include <sys/types.h>
#include <stdio.h>
#include <libgte.h>
#include <libetc.h>
#include <libgpu.h>

#define VMODE 0         // Video Mode : 0 : NTSC, 1: PAL

#define SCREENXRES 320
#define SCREENYRES 240

#define CENTERX SCREENXRES/2
#define CENTERY SCREENYRES/2

#define MARGINX 32      // margins for text display
#define MARGINY 44

#define FONTSIZE 8 * 3          // Text Field Height

#define OTLEN 8              // Ordering Table Length 

DISPENV disp[2];             // Double buffered DISPENV and DRAWENV
DRAWENV draw[2];

u_long ot[2][OTLEN];     // double ordering table of length 8 * 32 = 256 bits / 32 bytes

char primbuff[2][32768] = {1};     // double primitive buffer of length 32768 * 8 =  262.144 bits / 32,768 Kbytes

char *nextpri = primbuff[0]; // pointer to the next primitive in primbuff. Initially, points to the first bit of primbuff[0]

short db = 0;                // index of which buffer is used, values 0, 1

// Embed TIM files

// See https://github.com/ABelliqueux/nolibgs_hello_worlds#embedding-binary-data-in-a-ps-exe

// 16bpp TIM
extern unsigned long _binary____TIM_TIM16_tim_start[];
extern unsigned long _binary____TIM_TIM16_tim_end[];
extern unsigned long _binary____TIM_TIM16_tim_length;

// 8bpp TIM
extern unsigned long _binary____TIM_TIM8_tim_start[];
extern unsigned long _binary____TIM_TIM8_tim_end[];
extern unsigned long _binary____TIM_TIM8_TIM_length;

// 4bpp TIM
extern unsigned long _binary____TIM_TIM4_tim_start[];
extern unsigned long _binary____TIM_TIM4_tim_end[];
extern unsigned long _binary____TIM_TIM4_tim_length;


TIM_IMAGE TIM_16;
TIM_IMAGE TIM_8;
TIM_IMAGE TIM_4;


void LoadTexture(u_long * tim, TIM_IMAGE * tparam){     // This part is from Lameguy64's tutorial series : lameguy64.net/svn/pstutorials/chapter1/3-textures.html login/pw: annoyingmous
        OpenTIM(tim);                                   // Open the tim binary data, feed it the address of the data in memory
        ReadTIM(tparam);                                // This read the header of the TIM data and sets the corresponding members of the TIM_IMAGE structure
        
        LoadImage(tparam->prect, tparam->paddr);        // Transfer the data from memory to VRAM at position prect.x, prect.y
        DrawSync(0);                                    // Wait for the drawing to end
        
        if (tparam->mode & 0x8){ // check 4th bit       // If 4th bit == 1, TIM has a CLUT
            LoadImage(tparam->crect, tparam->caddr);    // Load it to VRAM at position crect.x, crect.y
            DrawSync(0);                                // Wait for drawing to end
    }
}

void init(void)
{
    ResetGraph(0);
    
    SetDefDispEnv(&disp[0], 0, 0, SCREENXRES, SCREENYRES);
    SetDefDispEnv(&disp[1], 0, SCREENYRES, SCREENXRES, SCREENYRES);
    
    SetDefDrawEnv(&draw[0], 0, SCREENYRES, SCREENXRES, SCREENYRES);
    SetDefDrawEnv(&draw[1], 0, 0, SCREENXRES, SCREENYRES);
    
    if (VMODE)
    {
        SetVideoMode(MODE_PAL);
        disp[0].screen.y += 8;
        disp[1].screen.y += 8;
        }

    SetDispMask(1);                 // Display on screen    

    setRGB0(&draw[0], 50, 50, 50);
    setRGB0(&draw[1], 50, 50, 50);
    
    draw[0].isbg = 1;
    draw[1].isbg = 1;
    
    PutDispEnv(&disp[db]);
    PutDrawEnv(&draw[db]);
    
    FntLoad(960, 0);
    FntOpen(MARGINX, SCREENYRES - MARGINY - FONTSIZE, SCREENXRES - MARGINX * 2, FONTSIZE, 0, 280 );
    
    
}

void display(void)
{
    DrawSync(0);
    VSync(0);
    
    PutDispEnv(&disp[db]);
    PutDrawEnv(&draw[db]);
    
    DrawOTag(&ot[db][OTLEN - 1]);
    
    db = !db;
    
    nextpri = primbuff[db];
}


int main(void)
{
    
    SPRT * sprt_16b;                // Define 3 pointers to SPRT struct
    SPRT * sprt_8b;
    SPRT * sprt_4b;
    
    DR_TPAGE * tpage_16b;           // Define 3 pointers to DR_TPAGE struct. We need three because our images are on three 
    DR_TPAGE * tpage_8b;            // different texture pages.
    DR_TPAGE * tpage_4b;
    
    init();
    
    LoadTexture(_binary____TIM_TIM16_tim_start, &TIM_16); // Load everything to vram
    LoadTexture(_binary____TIM_TIM8_tim_start, &TIM_8);
    LoadTexture(_binary____TIM_TIM4_tim_start, &TIM_4);
    
    while (1)
    {
        ClearOTagR(ot[db], OTLEN);
        
        // Loading a 16 bit TIM 
        
        sprt_16b = (SPRT *)nextpri;                 // Cast whats at nexpri as a SPRT named sprt_16b
                
        setSprt(sprt_16b);                          // Initialize the SPRT struct
        setRGB0(sprt_16b, 128, 128, 128);           // Set RGB color. 128,128,128 is neutral. You can color the image by adjusting these values
        setXY0(sprt_16b, 28, MARGINY);              // Set sprite position
        setWH(sprt_16b, 64, 128 );                  // Set sprite width and height

        addPrim(ot[db], sprt_16b);                  // add the sprite primitive to the ordering table
        
        nextpri += sizeof(SPRT);                    // increment nextpri so that it points just after sprt_16b in the primitive buffer
        
        // Set Texture page for the 16bit tim : 768, 0 - No CLUT
        
        // Note :  You need to use setDrawTPage each time you want to use a texture that's on a different texture page
        
        tpage_16b = (DR_TPAGE*)nextpri;
        
        setDrawTPage(tpage_16b, 0, 1,               // Set the Texture Page the texture we want resides on.
            getTPage(TIM_16.mode&0x3, 0,            // Here we are using bitmasking to deduce the picture mode : &0x3
            TIM_16.prect->x, TIM_16.prect->y));     // In binary, 3 is 11, so we only keep the first two bits
                                                    // Values can be 00 (0), 01 (1), 10(2), respectively, 4bpp, 8bpp, 15bpp, 24bpp. See Fileformat47.pdf, p.180
                                                    // Similarly, we could use bitmasking to deduce if there is a CLUT by bitmasking the 4th bit : if(TIM_IMAGE.mode & 0x8) LoadImage... :  
                                                    
        addPrim(ot[db], tpage_16b);                 // add the sprite primitive to the ordering table

        nextpri += sizeof(DR_TPAGE);                // Advance next primitive address
        
        // Loading a 8 bit TIM
        
        sprt_8b = (SPRT *)nextpri;
                
        setSprt(sprt_8b);
        setRGB0(sprt_8b, 128, 128, 128);        
        setXY0(sprt_8b, sprt_16b->x0 + sprt_16b->w + 32, MARGINY);
        setWH(sprt_8b, 64, 128 );
        setClut(sprt_8b, TIM_8.crect->x, TIM_8.crect->y);       // Only difference here is we set the CLUT to the position of the VRAM we loaded the palette earlier (see LoadTexture())
        
        addPrim(ot[db], sprt_8b);
        
        nextpri += sizeof(SPRT);
        
        // Set Texture page for the 8bit tim : 512, 256 - CLUT is at 0, 480
        
        tpage_8b = (DR_TPAGE*)nextpri;
        
        setDrawTPage(tpage_8b, 0, 1,               
            getTPage(TIM_8.mode&0x3, 0,            
            TIM_8.prect->x, TIM_8.prect->y));

        addPrim(ot[db], tpage_8b);                 
        nextpri += sizeof(DR_TPAGE);               
    
        // Loading a 4 bit TIM
        
        sprt_4b = (SPRT *)nextpri;
                
        setSprt(sprt_4b);
        setRGB0(sprt_4b, 128, 128, 128);        
        setXY0(sprt_4b, sprt_8b->x0 + sprt_8b->w + 32, MARGINY);
        setWH(sprt_4b, 64, 128 );
        setClut(sprt_4b, TIM_4.crect->x, TIM_4.crect->y);
        
        addPrim(ot[db], sprt_4b);
        
        nextpri += sizeof(SPRT);
        
        // Set Texture page for the 4bit tim : 512, 256 - CLUT is at 0, 480
        
        tpage_4b = (DR_TPAGE*)nextpri;
        
        setDrawTPage(tpage_4b, 0, 1,                
            getTPage(TIM_4.mode&0x3, 0,             
            TIM_4.prect->x, TIM_4.prect->y));

        addPrim(ot[db], tpage_4b);                  

        nextpri += sizeof(DR_TPAGE);                
    
        FntPrint("16 Bit!     ");
        FntPrint("8 Bit!      ");
        FntPrint("4 Bit!\n\n");
        FntPrint("Check VRAM in emu to see the dif");
    
        FntFlush(-1);
        
        display();
        }
    return 0;
    }
Revert "Remove old files" This reverts commit 2bd77289c028e7950c17972b22ac1f0002e404e8. 2021-07-10 15:48:45 +02:00			`#include <sys/types.h>`
			`#include <stdio.h>`
			`#include <libgte.h>`
			`#include <libetc.h>`
			`#include <libgpu.h>`

			`#define VMODE 0 // Video Mode : 0 : NTSC, 1: PAL`

			`#define SCREENXRES 320`
			`#define SCREENYRES 240`

			`#define CENTERX SCREENXRES/2`
			`#define CENTERY SCREENYRES/2`

			`#define MARGINX 32 // margins for text display`
			`#define MARGINY 44`

			`#define FONTSIZE 8 * 3 // Text Field Height`

			`#define OTLEN 8 // Ordering Table Length`

			`DISPENV disp[2]; // Double buffered DISPENV and DRAWENV`
			`DRAWENV draw[2];`

			`u_long ot[2][OTLEN]; // double ordering table of length 8 * 32 = 256 bits / 32 bytes`

			`char primbuff[2][32768] = {1}; // double primitive buffer of length 32768 * 8 = 262.144 bits / 32,768 Kbytes`

			`char *nextpri = primbuff[0]; // pointer to the next primitive in primbuff. Initially, points to the first bit of primbuff[0]`

			`short db = 0; // index of which buffer is used, values 0, 1`

			`// Embed TIM files`

			`// See https://github.com/ABelliqueux/nolibgs_hello_worlds#embedding-binary-data-in-a-ps-exe`

			`// 16bpp TIM`
			`extern unsigned long _binary____TIM_TIM16_tim_start[];`
			`extern unsigned long _binary____TIM_TIM16_tim_end[];`
			`extern unsigned long _binary____TIM_TIM16_tim_length;`

			`// 8bpp TIM`
			`extern unsigned long _binary____TIM_TIM8_tim_start[];`
			`extern unsigned long _binary____TIM_TIM8_tim_end[];`
			`extern unsigned long _binary____TIM_TIM8_TIM_length;`

			`// 4bpp TIM`
			`extern unsigned long _binary____TIM_TIM4_tim_start[];`
			`extern unsigned long _binary____TIM_TIM4_tim_end[];`
			`extern unsigned long _binary____TIM_TIM4_tim_length;`


			`TIM_IMAGE TIM_16;`
			`TIM_IMAGE TIM_8;`
			`TIM_IMAGE TIM_4;`


			`void LoadTexture(u_long * tim, TIM_IMAGE * tparam){ // This part is from Lameguy64's tutorial series : lameguy64.net/svn/pstutorials/chapter1/3-textures.html login/pw: annoyingmous`
			`OpenTIM(tim); // Open the tim binary data, feed it the address of the data in memory`
			`ReadTIM(tparam); // This read the header of the TIM data and sets the corresponding members of the TIM_IMAGE structure`

			`LoadImage(tparam->prect, tparam->paddr); // Transfer the data from memory to VRAM at position prect.x, prect.y`
			`DrawSync(0); // Wait for the drawing to end`

			`if (tparam->mode & 0x8){ // check 4th bit // If 4th bit == 1, TIM has a CLUT`
			`LoadImage(tparam->crect, tparam->caddr); // Load it to VRAM at position crect.x, crect.y`
			`DrawSync(0); // Wait for drawing to end`
			`}`
			`}`

			`void init(void)`
			`{`
			`ResetGraph(0);`

			`SetDefDispEnv(&disp[0], 0, 0, SCREENXRES, SCREENYRES);`
			`SetDefDispEnv(&disp[1], 0, SCREENYRES, SCREENXRES, SCREENYRES);`

			`SetDefDrawEnv(&draw[0], 0, SCREENYRES, SCREENXRES, SCREENYRES);`
			`SetDefDrawEnv(&draw[1], 0, 0, SCREENXRES, SCREENYRES);`

			`if (VMODE)`
			`{`
			`SetVideoMode(MODE_PAL);`
			`disp[0].screen.y += 8;`
			`disp[1].screen.y += 8;`
			`}`
Move SetDispMask() to init() 2021-07-22 10:40:41 +02:00
			`SetDispMask(1); // Display on screen`

Revert "Remove old files" This reverts commit 2bd77289c028e7950c17972b22ac1f0002e404e8. 2021-07-10 15:48:45 +02:00			`setRGB0(&draw[0], 50, 50, 50);`
			`setRGB0(&draw[1], 50, 50, 50);`

			`draw[0].isbg = 1;`
			`draw[1].isbg = 1;`

			`PutDispEnv(&disp[db]);`
			`PutDrawEnv(&draw[db]);`

			`FntLoad(960, 0);`
			`FntOpen(MARGINX, SCREENYRES - MARGINY - FONTSIZE, SCREENXRES - MARGINX * 2, FONTSIZE, 0, 280 );`


			`}`

			`void display(void)`
			`{`
			`DrawSync(0);`
			`VSync(0);`

			`PutDispEnv(&disp[db]);`
			`PutDrawEnv(&draw[db]);`

Better syntax for ot access, as per @nicolasnoble suggestion 2021-07-23 17:24:06 +02:00			`DrawOTag(&ot[db][OTLEN - 1]);`
Revert "Remove old files" This reverts commit 2bd77289c028e7950c17972b22ac1f0002e404e8. 2021-07-10 15:48:45 +02:00
			`db = !db;`

			`nextpri = primbuff[db];`
			`}`


			`int main(void)`
			`{`

			`SPRT * sprt_16b; // Define 3 pointers to SPRT struct`
			`SPRT * sprt_8b;`
			`SPRT * sprt_4b;`

			`DR_TPAGE * tpage_16b; // Define 3 pointers to DR_TPAGE struct. We need three because our images are on three`
			`DR_TPAGE * tpage_8b; // different texture pages.`
			`DR_TPAGE * tpage_4b;`

			`init();`

			`LoadTexture(_binary____TIM_TIM16_tim_start, &TIM_16); // Load everything to vram`
			`LoadTexture(_binary____TIM_TIM8_tim_start, &TIM_8);`
			`LoadTexture(_binary____TIM_TIM4_tim_start, &TIM_4);`

			`while (1)`
			`{`
			`ClearOTagR(ot[db], OTLEN);`

			`// Loading a 16 bit TIM`

			`sprt_16b = (SPRT *)nextpri; // Cast whats at nexpri as a SPRT named sprt_16b`

			`setSprt(sprt_16b); // Initialize the SPRT struct`
			`setRGB0(sprt_16b, 128, 128, 128); // Set RGB color. 128,128,128 is neutral. You can color the image by adjusting these values`
			`setXY0(sprt_16b, 28, MARGINY); // Set sprite position`
			`setWH(sprt_16b, 64, 128 ); // Set sprite width and height`

			`addPrim(ot[db], sprt_16b); // add the sprite primitive to the ordering table`

			`nextpri += sizeof(SPRT); // increment nextpri so that it points just after sprt_16b in the primitive buffer`

			`// Set Texture page for the 16bit tim : 768, 0 - No CLUT`

			`// Note : You need to use setDrawTPage each time you want to use a texture that's on a different texture page`

			`tpage_16b = (DR_TPAGE*)nextpri;`

			`setDrawTPage(tpage_16b, 0, 1, // Set the Texture Page the texture we want resides on.`
			`getTPage(TIM_16.mode&0x3, 0, // Here we are using bitmasking to deduce the picture mode : &0x3`
			`TIM_16.prect->x, TIM_16.prect->y)); // In binary, 3 is 11, so we only keep the first two bits`
			`// Values can be 00 (0), 01 (1), 10(2), respectively, 4bpp, 8bpp, 15bpp, 24bpp. See Fileformat47.pdf, p.180`
			`// Similarly, we could use bitmasking to deduce if there is a CLUT by bitmasking the 4th bit : if(TIM_IMAGE.mode & 0x8) LoadImage... :`

			`addPrim(ot[db], tpage_16b); // add the sprite primitive to the ordering table`

			`nextpri += sizeof(DR_TPAGE); // Advance next primitive address`

			`// Loading a 8 bit TIM`

			`sprt_8b = (SPRT *)nextpri;`

			`setSprt(sprt_8b);`
			`setRGB0(sprt_8b, 128, 128, 128);`
			`setXY0(sprt_8b, sprt_16b->x0 + sprt_16b->w + 32, MARGINY);`
			`setWH(sprt_8b, 64, 128 );`
			`setClut(sprt_8b, TIM_8.crect->x, TIM_8.crect->y); // Only difference here is we set the CLUT to the position of the VRAM we loaded the palette earlier (see LoadTexture())`

			`addPrim(ot[db], sprt_8b);`

			`nextpri += sizeof(SPRT);`

			`// Set Texture page for the 8bit tim : 512, 256 - CLUT is at 0, 480`

			`tpage_8b = (DR_TPAGE*)nextpri;`

			`setDrawTPage(tpage_8b, 0, 1,`
			`getTPage(TIM_8.mode&0x3, 0,`
			`TIM_8.prect->x, TIM_8.prect->y));`

			`addPrim(ot[db], tpage_8b);`
			`nextpri += sizeof(DR_TPAGE);`

			`// Loading a 4 bit TIM`

			`sprt_4b = (SPRT *)nextpri;`

			`setSprt(sprt_4b);`
			`setRGB0(sprt_4b, 128, 128, 128);`
			`setXY0(sprt_4b, sprt_8b->x0 + sprt_8b->w + 32, MARGINY);`
			`setWH(sprt_4b, 64, 128 );`
			`setClut(sprt_4b, TIM_4.crect->x, TIM_4.crect->y);`

			`addPrim(ot[db], sprt_4b);`

			`nextpri += sizeof(SPRT);`

			`// Set Texture page for the 4bit tim : 512, 256 - CLUT is at 0, 480`

			`tpage_4b = (DR_TPAGE*)nextpri;`

			`setDrawTPage(tpage_4b, 0, 1,`
			`getTPage(TIM_4.mode&0x3, 0,`
			`TIM_4.prect->x, TIM_4.prect->y));`

			`addPrim(ot[db], tpage_4b);`

			`nextpri += sizeof(DR_TPAGE);`

			`FntPrint("16 Bit! ");`
			`FntPrint("8 Bit! ");`
			`FntPrint("4 Bit!\n\n");`
			`FntPrint("Check VRAM in emu to see the dif");`

			`FntFlush(-1);`

			`display();`
			`}`
			`return 0;`
			`}`