ReC98/th01/hardware/graph.cpp

#pragma option -Z

extern "C" {
#include <dos.h>
#include "ReC98.h"
#include "th01/hardware/vsync.h"
#include "th01/hardware/graph.h"
#include "th01/hardware/palette.hpp"

/// VRAM plane "structures"
/// -----------------------
#define Planes_declare(var) \
	planar8_t *var##_B = reinterpret_cast<planar8_t *>(MK_FP(SEG_PLANE_B, 0)); \
	planar8_t *var##_R = reinterpret_cast<planar8_t *>(MK_FP(SEG_PLANE_R, 0)); \
	planar8_t *var##_G = reinterpret_cast<planar8_t *>(MK_FP(SEG_PLANE_G, 0)); \
	planar8_t *var##_E = reinterpret_cast<planar8_t *>(MK_FP(SEG_PLANE_E, 0));

#define Planes_next_row(var) \
	var##_B += ROW_SIZE; \
	var##_R += ROW_SIZE; \
	var##_G += ROW_SIZE; \
	var##_E += ROW_SIZE;

#define Planes_offset(var, x, y) \
	var##_B += (x / 8) + (y * ROW_SIZE); \
	var##_R += (x / 8) + (y * ROW_SIZE); \
	var##_G += (x / 8) + (y * ROW_SIZE); \
	var##_E += (x / 8) + (y * ROW_SIZE);

#define PlanarRow_declare(var) \
	planar8_t var##_B[ROW_SIZE]; \
	planar8_t var##_R[ROW_SIZE]; \
	planar8_t var##_G[ROW_SIZE]; \
	planar8_t var##_E[ROW_SIZE]; \

#define PlanarRow_blit(dst, src, bytes) \
	memcpy(dst##_B, src##_B, bytes); \
	memcpy(dst##_R, src##_R, bytes); \
	memcpy(dst##_G, src##_G, bytes); \
	memcpy(dst##_E, src##_E, bytes);
/// -----------------------

/// Pages
/// -----
extern page_t page_back;
/// -----

/// Restorable line drawing
/// -----------------------
// Never read from, so it's supposedly only there for debugging purposes?
extern Point graph_r_last_line_end;
// `true` copies the pixels to be drawn from the same position on page 1, thus
// restoring them with the background image. `false` (the default) draws them
// regularly the given [col].
extern bool graph_r_restore_from_1;
// Not used for purely horizontal lines.
extern planar16_t graph_r_pattern;
/// -----------------------

void graph_copy_byterect_back_to_front(
	int left, int top, int right, int bottom
)
{
	int w = (right - left) / 8;
	int h = (bottom - top);
	Planes_declare(p);
	page_t page_front = page_back ^ 1;
	int row;
	PlanarRow_declare(tmp);

	Planes_offset(p, left, top);
	for(row = 0; row < h; row++) {
		PlanarRow_blit(tmp, p, w);
		graph_accesspage(page_front);
		PlanarRow_blit(p, tmp, w);
		graph_accesspage(page_back);
		Planes_next_row(p);
	}
}

void graph_move_byterect_interpage(
	int src_left, int src_top, int src_right, int src_bottom,
	int dst_left, int dst_top,
	page_t src, page_t dst
)
{
	int w = (src_right - src_left) / 8;
	int h = (src_bottom - src_top);
	Planes_declare(src);
	Planes_declare(dst);
	int row;
	PlanarRow_declare(tmp);

	Planes_offset(src, src_left, src_top);
	Planes_offset(dst, dst_left, dst_top);
	for(row = 0; row < h; row++) {
		PlanarRow_blit(tmp, src, w);
		graph_accesspage(dst);
		PlanarRow_blit(dst, tmp, w);
		graph_accesspage(src);
		Planes_next_row(src);
		Planes_next_row(dst);
	}
	graph_accesspage(page_back);
}

void z_palette_fade_from(
	uint4_t from_r, uint4_t from_g, uint4_t from_b,
	int keep[COLOR_COUNT],
	unsigned int step_ms
)
{
	RGB4 fadepal[COLOR_COUNT];
	int i;
	int col;
	int comp;

	memset(&fadepal, 0x0, sizeof(fadepal));
	for(i = 0; i < COLOR_COUNT; i++) {
		if(!keep[i]) {
			fadepal[i].c.r = from_r;
			fadepal[i].c.g = from_g;
			fadepal[i].c.b = from_b;
		} else {
			fadepal[i].c.r = z_Palettes.colors[i].c.r;
			fadepal[i].c.g = z_Palettes.colors[i].c.g;
			fadepal[i].c.b = z_Palettes.colors[i].c.b;
		}
	}
	for(i = 0; i < 16; i++) {
		z_vsync_wait();
		for(col = 0; col < COLOR_COUNT; col++) {
			for(comp = 0; comp < sizeof(RGB4); comp++) {
				if(fadepal[col].v[comp] != z_Palettes.colors[col].v[comp]) {
					fadepal[col].v[comp] +=
						(fadepal[col].v[comp] < z_Palettes.colors[col].v[comp])
						?  1
						: -1;
				}
			}
			/* TODO: Replace with the decompiled call
			 * z_palette_show_single_col(col, fadepal[col]);
			 * once that function is part of this translation unit */
			__asm {
#define push_comp(comp) \
	mov 	bx, col; \
	db 0x6B, 0xDB, 0x03; /* IMUL BX, 3, which Turbo C++ can't into? */	\
	lea 	ax, fadepal[comp]; \
	db 0x03, 0xD8; /* Turbo C++'s preferred opcode for ADD BX, AX */ \
	mov 	al, ss:[bx]; \
	cbw; \
	push	ax;
				push_comp(2)
				push_comp(1)
				push_comp(0)
				push	col
				push	cs
				call	near ptr z_palette_show_single
				add 	sp, 8
			}
		}
		delay(step_ms);
	}
}

// Resident palette
// ----------------
#define RESPAL_ID "pal98 grb"
struct hack { char x[sizeof(RESPAL_ID)]; }; // XXX
extern const hack PAL98_GRB;

#pragma option -a1
// MASTER.MAN suggests that GBR ordering is some sort of standard on PC-98.
// It does match the order of the hardware's palette register ports, after
// all. (0AAh = green, 0ACh = red, 0AEh = blue)
struct grb_t {
	uint4_t g, r, b;
};

struct respal_t {
	char id[sizeof(RESPAL_ID)];
	unsigned char tone;
	int8_t padding[5];
	grb_t pal[COLOR_COUNT];
};
// ----------------

// Memory Control Block
// Adapted from FreeDOS' kernel/hdr/mcb.h
// --------------------
#define MCB_NORMAL 0x4d
#define MCB_LAST   0x5a

struct mcb_t {
	uint8_t m_type;	// mcb type - chain or end
	uint16_t __seg* m_psp;	// owner id via psp segment
	uint16_t m_size;	// size of segment in paragraphs
	uint8_t m_fill[3];
	uint8_t m_name[8];
};
#pragma option -a.

respal_t __seg* z_respal_exist(void)
{
	union REGS regs;
	struct SREGS sregs;
	const hack ID = PAL98_GRB;
	seg_t mcb;
	int i;

#define MCB reinterpret_cast<mcb_t __seg *>(mcb)	/* For easy derefencing */
#define MCB_PARAS (sizeof(mcb_t) / 16)	/* For segment pointer arithmetic */

	// "Get list of lists"
	segread(&sregs);
	regs.h.ah = 0x52;
	intdosx(&regs, &regs, &sregs);

	mcb = *reinterpret_cast<seg_t *>(MK_FP(sregs.es, regs.w.bx - 2));
	while(1) {
		if(MCB->m_psp != 0) {
			for(i = 0; i < sizeof(ID); i++) {
				if(reinterpret_cast<respal_t *>(MCB + 1)->id[i] != ID.x[i]) {
					break;
				}
			}
			if(i == sizeof(ID)) {
				return reinterpret_cast<respal_t __seg *>(mcb + MCB_PARAS);
			}
		}
		if(MCB->m_type != MCB_NORMAL) {
			return 0;
		}
		mcb += MCB_PARAS + MCB->m_size;
	};

#undef MCB_PARAS
#undef MCB
}

int z_respal_get_show(void)
{
	int i;
	respal_t __seg *respal_seg = z_respal_exist();
	if(respal_seg) {
		grb_t *respal = respal_seg->pal;
		for(i = 0; i < COLOR_COUNT; i++) {
			/* TODO: Replace with the decompiled call
			 * z_palette_set_show(i, respal->r, respal->g, respal->b);
			 * once that function is part of this translation unit */
			__asm {
				les 	bx, respal
				mov 	al, es:[bx+2]
				cbw
				push	ax
				mov 	al, es:[bx+0]
				cbw
				push	ax
				mov 	al, es:[bx+1]
				cbw
				push	ax
				// Spelling out PUSH SI causes Turbo C++ to interpret SI as
				// reserved, and it then moves [i] to DI rather than SI
				db	0x56
				push	cs
				call	near ptr z_palette_set_show
				add 	sp, 8
			}
			respal++;
		}
		return 0;
	}
	return 1;
}

int z_respal_set(void)
{
	int i;
	respal_t __seg *respal_seg = z_respal_exist();
	if(respal_seg) {
		grb_t *respal = respal_seg->pal;
		for(i = 0; i < COLOR_COUNT; i++) {
			respal->g = z_Palettes.colors[i].c.g;
			respal->r = z_Palettes.colors[i].c.r;
			respal->b = z_Palettes.colors[i].c.b;
			respal++;
		}
		return 0;
	}
	return 1;
}

}
[Decompilation] [th01] master.lib resident palette function reimplementations Which store colors as GRB, as suggested by the structure's ID string. Even master.lib's own functions add an additional XCHG AH, AL instruction to get colors into and out of this format. MASTER.MAN suggests that it's some sort of standard on PC-98. It does match the order of ths hardware's palette register ports, after all. (0AAh = green, 0ACh = red, 0AEh = blue) Now we also know why __seg* wasn't used more commonly, as lamented in c8e8e98. Turbo C++ simply doesn't support a lot of arithmetic on segment pointers. And then that undecompilable far call to a function within the same segment, but inside a different translation unit… Also, thanks again to Egor for the SCOPY@ hack that debuted in 0460072. Would have probably struggled with this a lot more without that. And then you realize that TH01 effectively doesn't even use the resident palette. 😐 And yes, we're procrastinating the whole issue of potentially using a single translation unit for all three binaries by using a common segment name, because it really isn't that easy. Completes P0066, funded by Keyblade Wiedling Neko and Splashman. 2020-01-05 15:10:00 +00:00			`#pragma option -Z`

			`extern "C" {`
			`#include <dos.h>`
			`#include "ReC98.h"`
[Decompilation] [th01] Blocking palette fade-ins from a custom start color ❎ Unused… Part of P0067, funded by Splashman. 2020-01-06 11:07:53 +00:00			`#include "th01/hardware/vsync.h"`
[Decompilation] [th01] Inter-page rectangle moves Semi-unused, that is, the one use of this function doesn't actually move the rectangle to a different position. Ironically, the non-moving back-to-front function immediately above is unused… Also, too bad that stack order is the only reason we can't use structs to combine all plane variables into a single object. Part of P0067, funded by Splashman. 2020-01-10 20:25:29 +00:00			`#include "th01/hardware/graph.h"`
[Decompilation] [th01] master.lib resident palette function reimplementations Which store colors as GRB, as suggested by the structure's ID string. Even master.lib's own functions add an additional XCHG AH, AL instruction to get colors into and out of this format. MASTER.MAN suggests that it's some sort of standard on PC-98. It does match the order of ths hardware's palette register ports, after all. (0AAh = green, 0ACh = red, 0AEh = blue) Now we also know why __seg* wasn't used more commonly, as lamented in c8e8e98. Turbo C++ simply doesn't support a lot of arithmetic on segment pointers. And then that undecompilable far call to a function within the same segment, but inside a different translation unit… Also, thanks again to Egor for the SCOPY@ hack that debuted in 0460072. Would have probably struggled with this a lot more without that. And then you realize that TH01 effectively doesn't even use the resident palette. 😐 And yes, we're procrastinating the whole issue of potentially using a single translation unit for all three binaries by using a common segment name, because it really isn't that easy. Completes P0066, funded by Keyblade Wiedling Neko and Splashman. 2020-01-05 15:10:00 +00:00			`#include "th01/hardware/palette.hpp"`

[Decompilation] [th01] Inter-page rectangle moves Semi-unused, that is, the one use of this function doesn't actually move the rectangle to a different position. Ironically, the non-moving back-to-front function immediately above is unused… Also, too bad that stack order is the only reason we can't use structs to combine all plane variables into a single object. Part of P0067, funded by Splashman. 2020-01-10 20:25:29 +00:00			`/// VRAM plane "structures"`
			`/// -----------------------`
			`#define Planes_declare(var) \`
			`planar8_t var##_B = reinterpret_cast<planar8_t >(MK_FP(SEG_PLANE_B, 0)); \`
			`planar8_t var##_R = reinterpret_cast<planar8_t >(MK_FP(SEG_PLANE_R, 0)); \`
			`planar8_t var##_G = reinterpret_cast<planar8_t >(MK_FP(SEG_PLANE_G, 0)); \`
			`planar8_t var##_E = reinterpret_cast<planar8_t >(MK_FP(SEG_PLANE_E, 0));`

			`#define Planes_next_row(var) \`
			`var##_B += ROW_SIZE; \`
			`var##_R += ROW_SIZE; \`
			`var##_G += ROW_SIZE; \`
			`var##_E += ROW_SIZE;`

			`#define Planes_offset(var, x, y) \`
			`var##_B += (x / 8) + (y * ROW_SIZE); \`
			`var##_R += (x / 8) + (y * ROW_SIZE); \`
			`var##_G += (x / 8) + (y * ROW_SIZE); \`
			`var##_E += (x / 8) + (y * ROW_SIZE);`

			`#define PlanarRow_declare(var) \`
			`planar8_t var##_B[ROW_SIZE]; \`
			`planar8_t var##_R[ROW_SIZE]; \`
			`planar8_t var##_G[ROW_SIZE]; \`
			`planar8_t var##_E[ROW_SIZE]; \`

			`#define PlanarRow_blit(dst, src, bytes) \`
			`memcpy(dst##_B, src##_B, bytes); \`
			`memcpy(dst##_R, src##_R, bytes); \`
			`memcpy(dst##_G, src##_G, bytes); \`
			`memcpy(dst##_E, src##_E, bytes);`
			`/// -----------------------`

[Reverse-engineering] [th01] Current back page Previously sloppily mis-RE'd as "some page variable, idk", back in 2015… Now also with a page number typedef. And yeah, restricting bool to C++ has now proven to be stupid after all. Part of P0067, funded by Splashman. 2020-01-06 13:40:42 +00:00			`/// Pages`
			`/// -----`
			`extern page_t page_back;`
			`/// -----`

[Reverse-engineering] [th01] Restorable line and box drawing Including the longest function present in more than one game among all of PC-98 Touhou, and #23 on the list of longest functions overall, which draws a 1-pixel line between two arbitrary pixels. Completes P0067, funded by Splashman. 2020-01-11 14:12:23 +00:00			`/// Restorable line drawing`
			`/// -----------------------`
			`// Never read from, so it's supposedly only there for debugging purposes?`
			`extern Point graph_r_last_line_end;`
			// `true` copies the pixels to be drawn from the same position on page 1, thus
			// restoring them with the background image. `false` (the default) draws them
			`// regularly the given [col].`
			`extern bool graph_r_restore_from_1;`
			`// Not used for purely horizontal lines.`
			`extern planar16_t graph_r_pattern;`
			`/// -----------------------`

[Decompilation] [th01] Inter-page rectangle moves Semi-unused, that is, the one use of this function doesn't actually move the rectangle to a different position. Ironically, the non-moving back-to-front function immediately above is unused… Also, too bad that stack order is the only reason we can't use structs to combine all plane variables into a single object. Part of P0067, funded by Splashman. 2020-01-10 20:25:29 +00:00			`void graph_copy_byterect_back_to_front(`
			`int left, int top, int right, int bottom`
			`)`
			`{`
			`int w = (right - left) / 8;`
			`int h = (bottom - top);`
			`Planes_declare(p);`
			`page_t page_front = page_back ^ 1;`
			`int row;`
			`PlanarRow_declare(tmp);`

			`Planes_offset(p, left, top);`
			`for(row = 0; row < h; row++) {`
			`PlanarRow_blit(tmp, p, w);`
			`graph_accesspage(page_front);`
			`PlanarRow_blit(p, tmp, w);`
			`graph_accesspage(page_back);`
			`Planes_next_row(p);`
			`}`
			`}`

			`void graph_move_byterect_interpage(`
			`int src_left, int src_top, int src_right, int src_bottom,`
			`int dst_left, int dst_top,`
			`page_t src, page_t dst`
			`)`
			`{`
			`int w = (src_right - src_left) / 8;`
			`int h = (src_bottom - src_top);`
			`Planes_declare(src);`
			`Planes_declare(dst);`
			`int row;`
			`PlanarRow_declare(tmp);`

			`Planes_offset(src, src_left, src_top);`
			`Planes_offset(dst, dst_left, dst_top);`
			`for(row = 0; row < h; row++) {`
			`PlanarRow_blit(tmp, src, w);`
			`graph_accesspage(dst);`
			`PlanarRow_blit(dst, tmp, w);`
			`graph_accesspage(src);`
			`Planes_next_row(src);`
			`Planes_next_row(dst);`
			`}`
			`graph_accesspage(page_back);`
			`}`

[Decompilation] [th01] Blocking palette fade-ins from a custom start color ❎ Unused… Part of P0067, funded by Splashman. 2020-01-06 11:07:53 +00:00			`void z_palette_fade_from(`
			`uint4_t from_r, uint4_t from_g, uint4_t from_b,`
			`int keep[COLOR_COUNT],`
			`unsigned int step_ms`
			`)`
			`{`
			`RGB4 fadepal[COLOR_COUNT];`
			`int i;`
			`int col;`
			`int comp;`

			`memset(&fadepal, 0x0, sizeof(fadepal));`
			`for(i = 0; i < COLOR_COUNT; i++) {`
			`if(!keep[i]) {`
			`fadepal[i].c.r = from_r;`
			`fadepal[i].c.g = from_g;`
			`fadepal[i].c.b = from_b;`
			`} else {`
			`fadepal[i].c.r = z_Palettes.colors[i].c.r;`
			`fadepal[i].c.g = z_Palettes.colors[i].c.g;`
			`fadepal[i].c.b = z_Palettes.colors[i].c.b;`
			`}`
			`}`
			`for(i = 0; i < 16; i++) {`
			`z_vsync_wait();`
			`for(col = 0; col < COLOR_COUNT; col++) {`
			`for(comp = 0; comp < sizeof(RGB4); comp++) {`
			`if(fadepal[col].v[comp] != z_Palettes.colors[col].v[comp]) {`
			`fadepal[col].v[comp] +=`
			`(fadepal[col].v[comp] < z_Palettes.colors[col].v[comp])`
			`? 1`
			`: -1;`
			`}`
			`}`
			`/* TODO: Replace with the decompiled call`
			`* z_palette_show_single_col(col, fadepal[col]);`
			`* once that function is part of this translation unit */`
			`__asm {`
			`#define push_comp(comp) \`
			`mov bx, col; \`
			`db 0x6B, 0xDB, 0x03; /* IMUL BX, 3, which Turbo C++ can't into? */ \`
			`lea ax, fadepal[comp]; \`
			`db 0x03, 0xD8; /* Turbo C++'s preferred opcode for ADD BX, AX */ \`
			`mov al, ss:[bx]; \`
			`cbw; \`
			`push ax;`
			`push_comp(2)`
			`push_comp(1)`
			`push_comp(0)`
			`push col`
			`push cs`
			`call near ptr z_palette_show_single`
			`add sp, 8`
			`}`
			`}`
			`delay(step_ms);`
			`}`
			`}`

[Decompilation] [th01] master.lib resident palette function reimplementations Which store colors as GRB, as suggested by the structure's ID string. Even master.lib's own functions add an additional XCHG AH, AL instruction to get colors into and out of this format. MASTER.MAN suggests that it's some sort of standard on PC-98. It does match the order of ths hardware's palette register ports, after all. (0AAh = green, 0ACh = red, 0AEh = blue) Now we also know why __seg* wasn't used more commonly, as lamented in c8e8e98. Turbo C++ simply doesn't support a lot of arithmetic on segment pointers. And then that undecompilable far call to a function within the same segment, but inside a different translation unit… Also, thanks again to Egor for the SCOPY@ hack that debuted in 0460072. Would have probably struggled with this a lot more without that. And then you realize that TH01 effectively doesn't even use the resident palette. 😐 And yes, we're procrastinating the whole issue of potentially using a single translation unit for all three binaries by using a common segment name, because it really isn't that easy. Completes P0066, funded by Keyblade Wiedling Neko and Splashman. 2020-01-05 15:10:00 +00:00			`// Resident palette`
			`// ----------------`
			`#define RESPAL_ID "pal98 grb"`
			`struct hack { char x[sizeof(RESPAL_ID)]; }; // XXX`
			`extern const hack PAL98_GRB;`

			`#pragma option -a1`
			`// MASTER.MAN suggests that GBR ordering is some sort of standard on PC-98.`
			`// It does match the order of the hardware's palette register ports, after`
			`// all. (0AAh = green, 0ACh = red, 0AEh = blue)`
			`struct grb_t {`
			`uint4_t g, r, b;`
			`};`

			`struct respal_t {`
			`char id[sizeof(RESPAL_ID)];`
			`unsigned char tone;`
			`int8_t padding[5];`
			`grb_t pal[COLOR_COUNT];`
			`};`
			`// ----------------`

			`// Memory Control Block`
			`// Adapted from FreeDOS' kernel/hdr/mcb.h`
			`// --------------------`
			`#define MCB_NORMAL 0x4d`
			`#define MCB_LAST 0x5a`

			`struct mcb_t {`
			`uint8_t m_type; // mcb type - chain or end`
			`uint16_t __seg* m_psp; // owner id via psp segment`
			`uint16_t m_size; // size of segment in paragraphs`
			`uint8_t m_fill[3];`
			`uint8_t m_name[8];`
			`};`
			`#pragma option -a.`

			`respal_t __seg* z_respal_exist(void)`
			`{`
			`union REGS regs;`
			`struct SREGS sregs;`
			`const hack ID = PAL98_GRB;`
			`seg_t mcb;`
			`int i;`

			`#define MCB reinterpret_cast<mcb_t __seg >(mcb) / For easy derefencing */`
			`#define MCB_PARAS (sizeof(mcb_t) / 16) /* For segment pointer arithmetic */`

			`// "Get list of lists"`
			`segread(&sregs);`
			`regs.h.ah = 0x52;`
			`intdosx(&regs, &regs, &sregs);`

			`mcb = reinterpret_cast<seg_t >(MK_FP(sregs.es, regs.w.bx - 2));`
			`while(1) {`
			`if(MCB->m_psp != 0) {`
			`for(i = 0; i < sizeof(ID); i++) {`
			`if(reinterpret_cast<respal_t *>(MCB + 1)->id[i] != ID.x[i]) {`
			`break;`
			`}`
			`}`
			`if(i == sizeof(ID)) {`
			`return reinterpret_cast<respal_t __seg *>(mcb + MCB_PARAS);`
			`}`
			`}`
			`if(MCB->m_type != MCB_NORMAL) {`
			`return 0;`
			`}`
			`mcb += MCB_PARAS + MCB->m_size;`
			`};`

			`#undef MCB_PARAS`
			`#undef MCB`
			`}`

			`int z_respal_get_show(void)`
			`{`
			`int i;`
			`respal_t __seg *respal_seg = z_respal_exist();`
			`if(respal_seg) {`
			`grb_t *respal = respal_seg->pal;`
			`for(i = 0; i < COLOR_COUNT; i++) {`
			`/* TODO: Replace with the decompiled call`
			`* z_palette_set_show(i, respal->r, respal->g, respal->b);`
			`* once that function is part of this translation unit */`
			`__asm {`
			`les bx, respal`
			`mov al, es:[bx+2]`
			`cbw`
			`push ax`
			`mov al, es:[bx+0]`
			`cbw`
			`push ax`
			`mov al, es:[bx+1]`
			`cbw`
			`push ax`
			`// Spelling out PUSH SI causes Turbo C++ to interpret SI as`
			`// reserved, and it then moves [i] to DI rather than SI`
			`db 0x56`
			`push cs`
			`call near ptr z_palette_set_show`
			`add sp, 8`
			`}`
			`respal++;`
			`}`
			`return 0;`
			`}`
			`return 1;`
			`}`

			`int z_respal_set(void)`
			`{`
			`int i;`
			`respal_t __seg *respal_seg = z_respal_exist();`
			`if(respal_seg) {`
			`grb_t *respal = respal_seg->pal;`
			`for(i = 0; i < COLOR_COUNT; i++) {`
			`respal->g = z_Palettes.colors[i].c.g;`
			`respal->r = z_Palettes.colors[i].c.r;`
			`respal->b = z_Palettes.colors[i].c.b;`
			`respal++;`
			`}`
			`return 0;`
			`}`
			`return 1;`
			`}`

			`}`