path: root/Source/MemCard.c

/* *************************************
 * 	Includes
 * *************************************/

#include "MemCard.h"
#include "System.h"
#include "Pad.h"
#include "Font.h"

/* *************************************
 * 	Defines
 * *************************************/

#define MEMCARD_SECTOR_SIZE 128
#define MEMCARD_SECTORS_PER_BLOCK 64
#define MEMCARD_SECTORS_PER_BLOCK_BITSHIFT 6
#define MEMCARD_BLOCK_MAX_ICONS 3
#define MEMCARD_ICON_INDEX_TIME 4

#define MEMCARD_MAXIMUM_SECTOR (1024 - 1)

#define MEMCARD_INVALID_CHECKSUM 	0x4E
#define MEMCARD_CORRECT_RW			0x47
#define MEMCARD_BAD_SECTOR			0xFF

/* *************************************
 * 	Structs and enums
 * *************************************/

typedef enum t_Sectors
{
	TITLE_FRAME = 0,
	ICON_FRAME_1,
	ICON_FRAME_2,
	ICON_FRAME_3,
	DATA_FRAME,
}MEMCARD_FILE_SECTORS;

enum
{
	MEMCARD_BLOCK_IMAGE_X = 768	,
	MEMCARD_BLOCK_IMAGE_Y = 352	,
	MEMCARD_BLOCK_CLUT_X = 960	,
	MEMCARD_BLOCK_CLUT_Y = 352	,
	MEMCARD_BLOCK_CLUT_W = 16	,
	MEMCARD_BLOCK_CLUT_H = 1	,
	MEMCARD_BLOCK_IMAGE_W = 16	,
	MEMCARD_BLOCK_IMAGE_H = 16	,
	MEMCARD_BLOCK_IMAGE_W_BITSHIFT = 2,
	MEMCARD_LOAD_DATA_TEXT_X = 96,
	MEMCARD_LOAD_DATA_TEXT_Y = 192,
};

enum
{
	MEMCARD_DIALOG_X = 64,
	MEMCARD_DIALOG_Y = 28,
	MEMCARD_DIALOG_W = 256,
	MEMCARD_DIALOG_H = 184,

	MEMCARD_DIALOG_R = 0,
	MEMCARD_DIALOG_G = 128,
	MEMCARD_DIALOG_B = 64,

	MEMCARD_DIALOG_GAP_X = 24,
	MEMCARD_DIALOG_GAP_SLOT = 128
};

enum
{
	MEMCARD_BG_X = 64,
	MEMCARD_BG_Y = 28,
	MEMCARD_BG_W = 256,
	MEMCARD_BG_H = 184,

	MEMCARD_BG_R0 = 0,
	MEMCARD_BG_R1 = MEMCARD_BG_R0,
	MEMCARD_BG_R2 = MEMCARD_BG_R0,
	MEMCARD_BG_R3 = MEMCARD_BG_R0,

	MEMCARD_BG_G0 = 0,
	MEMCARD_BG_G1 = MEMCARD_BG_G0,
	MEMCARD_BG_G2 = NORMAL_LUMINANCE,
	MEMCARD_BG_G3 = MEMCARD_BG_G2,

	MEMCARD_BG_B0 = 0,
	MEMCARD_BG_B1 = MEMCARD_BG_B0,
	MEMCARD_BG_B2 = NORMAL_LUMINANCE >> 1,
	MEMCARD_BG_B3 = MEMCARD_BG_B2
};

enum
{
	MEMCARD_PROGRESS_BAR_X = 86,
	MEMCARD_PROGRESS_BAR_Y = 148,
	MEMCARD_PROGRESS_BAR_W = 226,
	MEMCARD_PROGRESS_BAR_H = 16,

	MEMCARD_PROGRESS_BAR_N_LINES = 4,

	MEMCARD_PROGRESS_BAR_R = NORMAL_LUMINANCE,
	MEMCARD_PROGRESS_BAR_G = NORMAL_LUMINANCE,
	MEMCARD_PROGRESS_BAR_B = NORMAL_LUMINANCE
};

typedef enum t_MemcardProcess
{
	MEMCARD_PROCESS_GET_FILENAME = 0,
	MEMCARD_PROCESS_GET_INITIAL_FRAME,
	MEMCARD_PROCESS_GET_ICON_FRAME,
	MEMCARD_PROCESS_UPLOAD_TO_GPU
}MEMCARD_PROCESS;

typedef struct t_MemCardErrors
{
	unsigned char ErrorByte;
	MEMCARD_SLOTS Slot;
	MEMCARD_BLOCKS Block;
	MEMCARD_PROCESS Process;
}TYPE_MEMCARD_ERRORS;

/* *************************************
 * 	Local Prototypes
 * *************************************/

static bool MemCardGetInitialFrameInfo(TYPE_BLOCK_DATA * ptrBlockData);
static bool MemCardGetIconFrameInfo(TYPE_BLOCK_DATA * ptrBlockData);
static bool MemCardGetBlockStateFileName(TYPE_BLOCK_DATA * ptrBlockData);
static void ISR_MemCardDataHandling(void);
static bool MemCardReadSector(TYPE_BLOCK_DATA * ptrBlockData, int sector);
static void MemCardIconIndexHandler(void);

/* *************************************
 * 	Local Variables
 * *************************************/

static uint8_t DataBuffer[MEMCARD_SECTOR_SIZE];
static TYPE_MEMCARD_ERRORS MemCardErrors;
static GsSprite SecondDisplay;
static GsGPoly4 MemCardRect;
static GsRectangle MemCardProgressBar;
static GsLine MemCardProgressBarLines[MEMCARD_PROGRESS_BAR_N_LINES];
static uint8_t IconIndex;
static enum memcard_status MemCardStatus[MEMCARD_NUMBER_OF_SLOTS];

// Local variables used to communicate between functions and ISR.
// Names are pretty self-explanatory.
static volatile uint8_t TotalBlocks;
static volatile uint8_t CurrentReadBlock;
static volatile short ProgressBarXOffset;

/* *************************************
 * 	Global Variables
 * *************************************/

TYPE_BLOCK_DATA MemCardData[MEMCARD_BLOCKS_PER_CARD][MEMCARD_NUMBER_OF_SLOTS];

void MemCardInit(void)
{
	TYPE_BLOCK_DATA * ptrBlockData;
	uint8_t i;
	uint8_t j;

	for (j = SLOT_ONE; j <= SLOT_TWO; j++)
	{
		for (i = BLOCK_1; i <= BLOCK_15; i++)
		{
			ptrBlockData = &MemCardData[i - BLOCK_1][j];

			ptrBlockData->IconTPoly.r = NORMAL_LUMINANCE;
			ptrBlockData->IconTPoly.g = NORMAL_LUMINANCE;
			ptrBlockData->IconTPoly.b = NORMAL_LUMINANCE;
		}
	}

	bzero((TYPE_MEMCARD_ERRORS*)&MemCardErrors, sizeof (TYPE_MEMCARD_ERRORS) );
}

void ISR_MemCardDataHandling(void)
{

	uint8_t i;

	if (	(GfxIsGPUBusy()) || (SystemIsBusy()) )
	{
		return;
	}

	// Dim background
	SecondDisplay.r = NORMAL_LUMINANCE >> 1;
	SecondDisplay.g = NORMAL_LUMINANCE >> 1;
	SecondDisplay.b = NORMAL_LUMINANCE >> 1;

	MemCardRect.x[0] = MEMCARD_BG_X;
	MemCardRect.x[1] = MEMCARD_BG_X + MEMCARD_BG_W;
	MemCardRect.x[2] = MEMCARD_BG_X;
	MemCardRect.x[3] = MEMCARD_BG_X + MEMCARD_BG_W;

	MemCardRect.y[0] = MEMCARD_BG_Y;
	MemCardRect.y[1] = MEMCARD_BG_Y;
	MemCardRect.y[2] = MEMCARD_BG_Y + MEMCARD_BG_H;
	MemCardRect.y[3] = MEMCARD_BG_Y + MEMCARD_BG_H;

	MemCardRect.r[0] = MEMCARD_BG_R0;
	MemCardRect.r[1] = MEMCARD_BG_R1;
	MemCardRect.r[2] = MEMCARD_BG_R2;
	MemCardRect.r[3] = MEMCARD_BG_R3;

	MemCardRect.g[0] = MEMCARD_BG_G0;
	MemCardRect.g[1] = MEMCARD_BG_G1;
	MemCardRect.g[2] = MEMCARD_BG_G2;
	MemCardRect.g[3] = MEMCARD_BG_G3;

	MemCardRect.b[0] = MEMCARD_BG_B0;
	MemCardRect.b[1] = MEMCARD_BG_B1;
	MemCardRect.b[2] = MEMCARD_BG_B2;
	MemCardRect.b[3] = MEMCARD_BG_B3;

	MemCardRect.attribute |= ENABLE_TRANS | TRANS_MODE(0);

	// "Loading" bar line 0 (up left - up right)

	MemCardProgressBarLines[0].x[0] = MEMCARD_PROGRESS_BAR_X;
	MemCardProgressBarLines[0].x[1] = MEMCARD_PROGRESS_BAR_X + MEMCARD_PROGRESS_BAR_W;

	MemCardProgressBarLines[0].y[0] = MEMCARD_PROGRESS_BAR_Y;
	MemCardProgressBarLines[0].y[1] = MEMCARD_PROGRESS_BAR_Y;

	// "Loading" bar line 1 (up left - down left)

	MemCardProgressBarLines[1].x[0] = MEMCARD_PROGRESS_BAR_X;
	MemCardProgressBarLines[1].x[1] = MEMCARD_PROGRESS_BAR_X;

	MemCardProgressBarLines[1].y[0] = MEMCARD_PROGRESS_BAR_Y;
	MemCardProgressBarLines[1].y[1] = MEMCARD_PROGRESS_BAR_Y + MEMCARD_PROGRESS_BAR_H;

	// "Loading" bar line 2 (down left - down right)

	MemCardProgressBarLines[2].x[0] = MEMCARD_PROGRESS_BAR_X;
	MemCardProgressBarLines[2].x[1] = MEMCARD_PROGRESS_BAR_X + MEMCARD_PROGRESS_BAR_W;

	MemCardProgressBarLines[2].y[0] = MEMCARD_PROGRESS_BAR_Y + MEMCARD_PROGRESS_BAR_H;
	MemCardProgressBarLines[2].y[1] = MEMCARD_PROGRESS_BAR_Y + MEMCARD_PROGRESS_BAR_H;

	// "Loading" bar line 3 (up right - down right)

	MemCardProgressBarLines[3].x[0] = MEMCARD_PROGRESS_BAR_X + MEMCARD_PROGRESS_BAR_W;
	MemCardProgressBarLines[3].x[1] = MEMCARD_PROGRESS_BAR_X + MEMCARD_PROGRESS_BAR_W;

	MemCardProgressBarLines[3].y[0] = MEMCARD_PROGRESS_BAR_Y;
	MemCardProgressBarLines[3].y[1] = MEMCARD_PROGRESS_BAR_Y + MEMCARD_PROGRESS_BAR_H;

	for (i = 0; i < MEMCARD_PROGRESS_BAR_N_LINES; i++)
	{
		MemCardProgressBarLines[i].r = NORMAL_LUMINANCE;
		MemCardProgressBarLines[i].g = NORMAL_LUMINANCE;
		MemCardProgressBarLines[i].b = NORMAL_LUMINANCE;
	}

	// Set progress bar attributes

	MemCardProgressBar.x = MEMCARD_PROGRESS_BAR_X;
	MemCardProgressBar.y = MEMCARD_PROGRESS_BAR_Y;

	MemCardProgressBar.w = ProgressBarXOffset;
	MemCardProgressBar.h = MEMCARD_PROGRESS_BAR_H;

	MemCardProgressBar.r = MEMCARD_PROGRESS_BAR_R;
	MemCardProgressBar.g = MEMCARD_PROGRESS_BAR_G;
	MemCardProgressBar.b = MEMCARD_PROGRESS_BAR_B;

	GfxSortSprite(&SecondDisplay);
	GsSortGPoly4(&MemCardRect);
	GsSortRectangle(&MemCardProgressBar);

	for (i = 0; i < MEMCARD_PROGRESS_BAR_N_LINES; i++)
	{
		GsSortLine(&MemCardProgressBarLines[i]);
	}

	FontSetFlags(&SmallFont, FONT_BLEND_EFFECT);

	FontPrintText(&SmallFont, MEMCARD_LOAD_DATA_TEXT_X, MEMCARD_LOAD_DATA_TEXT_Y, "Loading memory card data...");

	FontSetFlags(&SmallFont, FONT_NOFLAGS);

	GfxDrawScene_Fast();

}

void MemCardResetBlockData(TYPE_BLOCK_DATA * ptrBlockData)
{
	bzero((TYPE_BLOCK_DATA*)ptrBlockData, sizeof (TYPE_BLOCK_DATA));

	ptrBlockData->BlockCount = FIRST_OR_ONLY_BLOCK;

	IconIndex = 0;
}

bool MemCardGetBlockInfo(	TYPE_BLOCK_DATA * ptrBlockData,
							MEMCARD_SLOTS slot,
							MEMCARD_BLOCKS blockNumber	)
{
	MemCardResetBlockData(ptrBlockData);

	ptrBlockData->Slot = slot;
	ptrBlockData->Block = blockNumber;

	Serial_printf("MemCardGetBlockStateFileName...\n");

	if (MemCardGetBlockStateFileName(ptrBlockData) == false)
	{
		return false;
	}

	if (ptrBlockData->BlockCount == EMPTY_BLOCK)
	{
		// Stop looking for any other data.
		return true;
	}

	Serial_printf("MemCardGetInitialFrameInfo...\n");

	if (MemCardGetInitialFrameInfo(ptrBlockData) == false)
	{
		return false;
	}

	Serial_printf("MemCardGetIconFrameInfo...\n");

	if (MemCardGetIconFrameInfo(ptrBlockData) == false)
	{
		return false;
	}

	// We will not get any block data information, we are only interested
	// in basic info.

	Serial_printf("MemCardUploadToGPU...\n");

	if (MemCardUploadToGPU(ptrBlockData) == false)
	{
		return false;
	}

	return true;
}

bool MemCardGetBlockStateFileName(TYPE_BLOCK_DATA * ptrBlockData)
{
	int sector = ptrBlockData->Block;

	MemCardErrors.Block = ptrBlockData->Block;
	MemCardErrors.Slot = ptrBlockData->Slot;
	MemCardErrors.Process = MEMCARD_PROCESS_GET_FILENAME;

	memset(DataBuffer, 0, MEMCARD_SECTOR_SIZE);

	if (MemCardReadSector(ptrBlockData, sector) == false)
	{
		return false;
	}

	// 00h-03h Block Allocation State
	Serial_printf("Block %d, slot %d, allocation state: 0x%02X.\n",
			ptrBlockData->Block,
			ptrBlockData->Slot,
			DataBuffer[0]	);

	/*	00000051h - In use ;first-or-only block of a file
	*	00000052h - In use ;middle block of a file (if 3 or more blocks)
	*	00000053h - In use ;last block of a file   (if 2 or more blocks)
	* 	000000A0h - Free   ;freshly formatted
	*	000000A1h - Free   ;deleted (first-or-only block of file)
	*	000000A2h - Free   ;deleted (middle block of file)
	*	000000A3h - Free   ;deleted (last block of file)		*/

	// Always take into account memory card data is little-endian,
	// so if using a hex editor, you will read 51000000h.

	switch(DataBuffer[0])
	{
		case 0x51:
			ptrBlockData->BlockCount = FIRST_OR_ONLY_BLOCK;
		break;

		case 0x52:
			ptrBlockData->BlockCount = INTERMEDIATE_BLOCK;
		break;

		case 0x53:
			ptrBlockData->BlockCount = LAST_BLOCK;
		break;
		case 0xA0:
		case 0xA1:
		case 0xA2:
		case 0xA3:
			ptrBlockData->BlockCount = EMPTY_BLOCK;
			return true;
		default:
			printf("Invalid block allocation state!\n");
			return false;
	}

	// 0Ah-1Eh Filename in ASCII, terminated by 00h (max 20 chars, plus ending 00h)
	// File name is only defined on first block of group (allocation state == 0x51)

	if (ptrBlockData->BlockCount == FIRST_OR_ONLY_BLOCK)
	{
		memset(ptrBlockData->FileName, 0 , MEMCARD_FILENAME_SIZE);

		memmove(ptrBlockData->FileName, &DataBuffer[0x0A], MEMCARD_FILENAME_SIZE);

		Serial_printf("File name: %s\n", ptrBlockData->FileName);
	}

	return true;
}

bool MemCardGetInitialFrameInfo(TYPE_BLOCK_DATA * ptrBlockData)
{
	unsigned int i;
	int sector = ptrBlockData->Block << MEMCARD_SECTORS_PER_BLOCK_BITSHIFT;

	MemCardErrors.Block = ptrBlockData->Block;
	MemCardErrors.Slot = ptrBlockData->Slot;
	MemCardErrors.Process = MEMCARD_PROCESS_GET_FILENAME;

	if (ptrBlockData->BlockCount != FIRST_OR_ONLY_BLOCK)
	{
		// Icon data is only stored on first block (if game takes more
		// than one block. Skip this step otherwise.

		// When dealing with intermediate or last blocks of a file,
		// we use a static pointer which points to first block of a file,
		// and then image data is copied into other blocks.
		return true;
	}

	// Pretty silly operation (TITLE_FRAME = 0), but used for
	// conceptual purposes and better understanding.
	sector += TITLE_FRAME;

	memset(DataBuffer, 0, MEMCARD_SECTOR_SIZE);

	if (MemCardReadSector(ptrBlockData, sector) == false)
	{
		return false;
	}

	Serial_printf("Magic number: '%c' '%c'\n",DataBuffer[0], DataBuffer[1]);

	if (DataBuffer[0] != 'S' || DataBuffer[1] != 'C')
	{
		// Invalid magic number.
		Serial_printf("Invalid magic number extracted from slot %d, block %d.\n",
				ptrBlockData->Slot,
				ptrBlockData->Block);

		return false;
	}

	/* 02h	Icon Display Flag
				11h...Icon has 1 frame  (static) (same image shown forever)
				12h...Icon has 2 frames (animated) (changes every 16 PAL frames)
				13h...Icon has 3 frames (animated) (changes every 11 PAL frames)
	* */

	switch(DataBuffer[2])
	{
		case 0x11:
			ptrBlockData->IconNumber = 1;
		break;

		case 0x12:
			ptrBlockData->IconNumber = 2;
		break;

		case 0x13:
			ptrBlockData->IconNumber = 3;
		break;

		default:
			// Invalid icon display flag! We can't know how many icons
			// are used.
			return false;
	}

	Serial_printf("Number of icons: %d\n", ptrBlockData->IconNumber);

	// 60h-7Fh  Icon 16 Color Palette Data (each entry is 16bit CLUT)

	for (i = 0; i < ptrBlockData->IconNumber; i++)
	{
		memmove(ptrBlockData->CLUT[i],&DataBuffer[0x60], MEMCARD_CLUT_SIZE);
	}

	return true;
}

bool MemCardGetIconFrameInfo(TYPE_BLOCK_DATA * ptrBlockData)
{
	int initial_sector = ptrBlockData->Block << MEMCARD_SECTORS_PER_BLOCK_BITSHIFT;
	int sector;
	unsigned int i;
	unsigned int j;
	uint8_t buffer_contents;
	static TYPE_BLOCK_DATA * ptrReferenceBlock = NULL;

	switch(ptrBlockData->BlockCount)
	{
		case EMPTY_BLOCK:
		// Empty blocks are not of interest. Skip.
		return true;

		case INTERMEDIATE_BLOCK:
		case LAST_BLOCK:

			if (ptrReferenceBlock == NULL)
			{
				Serial_printf("No reference memory card block found yet!\n");
				return false;
			}

			ptrBlockData->IconNumber = ptrReferenceBlock->IconNumber;

			for (i = 0; i < MEMCARD_NUMBER_OF_ICONS; i++)
			{
				memmove(ptrBlockData->CLUT[i], ptrReferenceBlock->CLUT[i], MEMCARD_CLUT_SIZE);
				memmove(ptrBlockData->Icons[i], ptrReferenceBlock->Icons[i], MEMCARD_ICON_SIZE);
			}

			if (ptrBlockData->BlockCount == LAST_BLOCK)
			{
				// Dereference pointer
				ptrReferenceBlock = NULL;
			}

		return true;
		case FIRST_OR_ONLY_BLOCK:

			// Icon Frame(s) (Block 1..15, Frame 1..3) (in first block of file only)
			for (i = ICON_FRAME_1; i <= ptrBlockData->IconNumber; i++)
			{
				Serial_printf("\tIcon %d out of %d\n",i, ptrBlockData->IconNumber);
				buffer_contents = 0;
				sector = initial_sector + i;
				memset(DataBuffer, 0, MEMCARD_SECTOR_SIZE * sizeof (uint8_t) );

				if (MemCardReadSector(ptrBlockData, sector) == false)
				{
					Serial_printf("Could not read memory sector!\n");
					return false;
				}

				memmove(ptrBlockData->Icons[i - 1 /* ICON_FRAME_# - 1 */], DataBuffer, MEMCARD_SECTOR_SIZE);

				for (j = 0; j < MEMCARD_SECTOR_SIZE; j++)
				{
					buffer_contents |= ptrBlockData->Icons[i - 1][j];
				}

				if (buffer_contents == 0)
				{
					// Icon buffer is empty!
					Serial_printf("Invalid icon buffer for slot %d, block %d.\n",
							ptrBlockData->Slot,
							ptrBlockData->Block);

					return false;
				}
			}

		// Use current block as reference if file contains more than one block.
		ptrReferenceBlock = ptrBlockData;

		return true;
	}

	Serial_printf("Unknown error from MemCardGetIconFrameInfo()!\n");

	return false;
}

bool MemCardUploadToGPU(TYPE_BLOCK_DATA * ptrBlockData)
{
	uint8_t i;
	short x_clut_offset;
	short y_clut_offset;
	short x_block_offset;
	GsImage gs;

	if (	(ptrBlockData->IconNumber < 1)
					||
		(ptrBlockData->IconNumber > MEMCARD_NUMBER_OF_ICONS) )
	{
		Serial_printf("Invalid number of icons.\n");
		return false;
	}

	for (i = 0; i < ptrBlockData->IconNumber; i++)
	{
		gs.pmode = COLORMODE_4BPP;
		gs.has_clut = 1;

		x_clut_offset = i << 4;
		y_clut_offset = ptrBlockData->Block - 1;

		gs.clut_x = MEMCARD_BLOCK_CLUT_X + x_clut_offset;
		gs.clut_y = MEMCARD_BLOCK_CLUT_Y + y_clut_offset + (ptrBlockData->Slot << 4);
		gs.clut_w = MEMCARD_BLOCK_CLUT_W;
		gs.clut_h = MEMCARD_BLOCK_CLUT_H;

		Serial_printf("Gs Clut = {%d,%d,%d,%d}\n",
				gs.clut_x,
				gs.clut_y,
				gs.clut_w,
				gs.clut_h	);

		x_block_offset = MEMCARD_BLOCK_IMAGE_W * (ptrBlockData->Block - 1);
		x_block_offset *= MEMCARD_BLOCK_MAX_ICONS;
		x_block_offset >>= MEMCARD_BLOCK_IMAGE_W_BITSHIFT;
		x_block_offset += i<<MEMCARD_BLOCK_IMAGE_W_BITSHIFT;

		gs.x = MEMCARD_BLOCK_IMAGE_X + x_block_offset;
		gs.y = MEMCARD_BLOCK_IMAGE_Y + (MEMCARD_BLOCK_IMAGE_H * ptrBlockData->Slot);

		// Dimensions are 16x16 px, but since 4bpp is used, it actually
		// takes 4x16 px on the framebuffer.
		gs.w = MEMCARD_BLOCK_IMAGE_W >> MEMCARD_BLOCK_IMAGE_W_BITSHIFT;
		gs.h = MEMCARD_BLOCK_IMAGE_H;

		gs.clut_data = (uint8_t*)ptrBlockData->CLUT[i];
		gs.data = (uint8_t*)ptrBlockData->Icons[i];

		GsUploadImage(&gs);

		if (i == 0)
		{
			ptrBlockData->IconTPoly.attribute = COLORMODE(COLORMODE_4BPP);
			ptrBlockData->IconTPoly.tpage = (gs.x / 64) + ((gs.y/256)*16);

			Serial_printf("\tTPAGE = %d\n", ptrBlockData->IconTPoly.tpage);

			x_block_offset = MEMCARD_BLOCK_IMAGE_W * (ptrBlockData->Block - 1);
			x_block_offset *= MEMCARD_BLOCK_MAX_ICONS;

			ptrBlockData->IconTPoly.u[0] = MEMCARD_BLOCK_IMAGE_X + x_block_offset;
			ptrBlockData->IconTPoly.u[1] = ptrBlockData->IconTPoly.u[0] + (gs.w << 2);
			ptrBlockData->IconTPoly.u[2] = ptrBlockData->IconTPoly.u[0];
			ptrBlockData->IconTPoly.u[3] = ptrBlockData->IconTPoly.u[1];

			Serial_printf("\tu = {%d, %d, %d, %d}\n",
					ptrBlockData->IconTPoly.u[0],
					ptrBlockData->IconTPoly.u[1],
					ptrBlockData->IconTPoly.u[2],
					ptrBlockData->IconTPoly.u[3]);

			ptrBlockData->IconTPoly.v[0] = gs.y % 256;
			ptrBlockData->IconTPoly.v[1] = ptrBlockData->IconTPoly.v[0];
			ptrBlockData->IconTPoly.v[2] = (gs.y % 256) + (gs.h);
			ptrBlockData->IconTPoly.v[3] = ptrBlockData->IconTPoly.v[2];

			Serial_printf("\tu = {%d, %d, %d, %d}\n",
					ptrBlockData->IconTPoly.v[0],
					ptrBlockData->IconTPoly.v[1],
					ptrBlockData->IconTPoly.v[2],
					ptrBlockData->IconTPoly.v[3]);

			ptrBlockData->IconTPoly.r = NORMAL_LUMINANCE;
			ptrBlockData->IconTPoly.g = NORMAL_LUMINANCE;
			ptrBlockData->IconTPoly.b = NORMAL_LUMINANCE;

			ptrBlockData->IconTPoly.cx = gs.clut_x;
			ptrBlockData->IconTPoly.cy = gs.clut_y;

			Serial_printf("\tclut = {%d, %d}\n",
					ptrBlockData->IconTPoly.cx,
					ptrBlockData->IconTPoly.cy);
		}
	}

	return true;
}

bool MemCardReadSector(TYPE_BLOCK_DATA * ptrBlockData, int sector)
{
	uint8_t result;

	MemCardErrors.Block = ptrBlockData->Block;
	MemCardErrors.Slot = ptrBlockData->Slot;

	if (	(ptrBlockData->Slot != 0)
				&&
		(ptrBlockData->Slot != 1)	)
	{
		MemCardErrors.ErrorByte = 'S';

		Serial_printf("Incorrect slot %d! Block %d?\n",
				ptrBlockData->Slot,
				ptrBlockData->Block);

		return false;
	}

	if ((sector < 0) || (sector > MEMCARD_MAXIMUM_SECTOR))
	{
		MemCardErrors.ErrorByte = 'T';

		Serial_printf("Invalid memory card sector %d. Only values between"
				" 0 and %d are allowed!\n", sector, MEMCARD_MAXIMUM_SECTOR);
		return false;
	}

	while (GfxIsGPUBusy());

	result = McReadSector(ptrBlockData->Slot, sector, DataBuffer);

	// Fill char "MemCardErrors" for further error description.
	MemCardErrors.ErrorByte = result;

	switch(result)
	{
		case '1':
		case '2':
		case 'L':
		case 'M':
			return false;

		case MEMCARD_INVALID_CHECKSUM:
			Serial_printf("Invalid checksum for memory card sector %d"
					" from block %d, slot %d",
					sector,
					ptrBlockData->Block,
					ptrBlockData->Slot		);
			return false;

		case MEMCARD_BAD_SECTOR:
			Serial_printf("Invalid memory card sector %d. Only values between"
				" 0 and 511 are allowed!\n", sector);
			return false;

		case MEMCARD_CORRECT_RW:
			return true;

		default:
		return false;
	}

	return true;
}

bool MemCardGetAllData(void)
{
	uint8_t i;
	uint8_t j;

	PadClearData();

	CurrentReadBlock = 0;

	TotalBlocks = MEMCARD_BLOCKS_PER_CARD * MEMCARD_NUMBER_OF_SLOTS;

	SmallFont.spr.r = 0;
	SmallFont.spr.g = 0;
	SmallFont.spr.b = 0;

	GfxSaveDisplayData(&SecondDisplay);

	GfxSetGlobalLuminance(NORMAL_LUMINANCE);

	// ISR_MemCardDataHandling draws a rectangle on top to show
	// memory card loading progress.

	SetVBlankHandler(&ISR_MemCardDataHandling);

	for (j = SLOT_ONE; j <= SLOT_TWO; j++)
	{
		MemCardStatus[j] = McGetStatus(j);

		if (MemCardStatus[j] == MEMCARD_STATUS_UNKNOWN)
		{
			// Memcard not connected and/or formatted.
			continue;
		}

		for (i = BLOCK_1; i <= BLOCK_15; i++)
		{
			ProgressBarXOffset = (short)(CurrentReadBlock *
								(MEMCARD_PROGRESS_BAR_W /
								(MEMCARD_BLOCKS_PER_CARD * MEMCARD_NUMBER_OF_SLOTS) ) );

			if (MemCardGetBlockInfo(&MemCardData[i - BLOCK_1][j], j, i) == false)
			{
				// Return to normal behaviour if anything fails
				SetVBlankHandler(&ISR_SystemDefaultVBlank);
				return false;
			}

			CurrentReadBlock++;
		}
	}

	SetVBlankHandler(&ISR_SystemDefaultVBlank);

	CurrentReadBlock = 0;

	return true;
}

void MemCardHandler(void)
{
	MemCardIconIndexHandler();
}

void MemCardIconIndexHandler(void)
{
	static uint8_t iconTimer = 0;

	if (System100msTick())
	{
		if (++iconTimer >= MEMCARD_ICON_INDEX_TIME)
		{
			iconTimer = 0;

			if (++IconIndex >= MEMCARD_NUMBER_OF_ICONS)
			{
				IconIndex = 0;
			}
		}
	}
}

void MemCardDrawIcon(TYPE_BLOCK_DATA * ptrBlockData, short x, short y)
{
	uint8_t i;
	// Auxiliar variable to keep original data
	short orig_u[4];
	short orig_clut_x;
	static bool first_access = true;

	if (ptrBlockData->BlockCount == EMPTY_BLOCK)
	{
		return;
	}

	ptrBlockData->IconTPoly.x[0] = x;
	ptrBlockData->IconTPoly.x[1] = x + MEMCARD_BLOCK_IMAGE_W;
	ptrBlockData->IconTPoly.x[2] = x;
	ptrBlockData->IconTPoly.x[3] = ptrBlockData->IconTPoly.x[1];

	ptrBlockData->IconTPoly.y[0] = y;
	ptrBlockData->IconTPoly.y[1] = ptrBlockData->IconTPoly.y[0];
	ptrBlockData->IconTPoly.y[2] = y + MEMCARD_BLOCK_IMAGE_H;
	ptrBlockData->IconTPoly.y[3] = ptrBlockData->IconTPoly.y[2];

	for (i = 0; i < 4; i++)
	{
		orig_u[i] = ptrBlockData->IconTPoly.u[i];
	}

	orig_clut_x = ptrBlockData->IconTPoly.cx;

	if (ptrBlockData->IconNumber > IconIndex)
	{
		ptrBlockData->IconTPoly.u[0] += MEMCARD_BLOCK_IMAGE_W * IconIndex;
		ptrBlockData->IconTPoly.u[1] = ptrBlockData->IconTPoly.u[0] + MEMCARD_BLOCK_IMAGE_W;
		ptrBlockData->IconTPoly.u[2] = ptrBlockData->IconTPoly.u[0];
		ptrBlockData->IconTPoly.u[3] = ptrBlockData->IconTPoly.u[1];

		ptrBlockData->IconTPoly.cx += IconIndex * MEMCARD_BLOCK_CLUT_W;
	}


	if (first_access)
	{
		if (IconIndex == 0)
		{
			first_access = false;

			Serial_printf("Icon index: %d\n",IconIndex);

			Serial_printf("\tU = {%d,%d,%d,%d}\n",
					ptrBlockData->IconTPoly.u[0],
					ptrBlockData->IconTPoly.u[1],
					ptrBlockData->IconTPoly.u[2],
					ptrBlockData->IconTPoly.u[3]);


			Serial_printf("\tV = {%d,%d,%d,%d}\n",
					ptrBlockData->IconTPoly.v[0],
					ptrBlockData->IconTPoly.v[1],
					ptrBlockData->IconTPoly.v[2],
					ptrBlockData->IconTPoly.v[3]);

			Serial_printf("\tBlock number: %d\n",ptrBlockData->Block);

			Serial_printf("\tBlock count: %d\n",ptrBlockData->BlockCount);

			Serial_printf("\tX = {%d,%d,%d,%d}\n",
					ptrBlockData->IconTPoly.x[0],
					ptrBlockData->IconTPoly.x[1],
					ptrBlockData->IconTPoly.x[2],
					ptrBlockData->IconTPoly.x[3]);

			Serial_printf("\tY = {%d,%d,%d,%d}\n",
					ptrBlockData->IconTPoly.y[0],
					ptrBlockData->IconTPoly.y[1],
					ptrBlockData->IconTPoly.y[2],
					ptrBlockData->IconTPoly.y[3]);

			Serial_printf("\tTPAGE = %d\n", ptrBlockData->IconTPoly.tpage);
			Serial_printf("\tCLUT = {%d, %d}\n",
					ptrBlockData->IconTPoly.cx,
					ptrBlockData->IconTPoly.cy);
		}
	}

	GsSortTPoly4(&ptrBlockData->IconTPoly);

	for (i = 0; i < 4; i++)
	{
		ptrBlockData->IconTPoly.u[i] = orig_u[i]; // Restore data
	}

	ptrBlockData->IconTPoly.cx = orig_clut_x;
}

TYPE_BLOCK_DATA * MemCardShowMap(void)
{
	uint8_t i;
	uint8_t j;
	uint8_t selectedBlock = BLOCK_1;
	uint8_t selectedSlot = SLOT_ONE;
	TYPE_BLOCK_DATA * ptrBlockData;
	GsRectangle emptyBlockRect;
	short x;
	short y;
	unsigned char orig_r;
	unsigned char orig_g;
	unsigned char orig_b;
	GsRectangle MemCardMapDialog;

	if (MemCardGetAllData() == false)
	{
		return false;
	}

	bzero((GsRectangle*)&MemCardMapDialog, sizeof (GsRectangle));
	bzero((GsRectangle*)&emptyBlockRect, sizeof (GsRectangle));

	emptyBlockRect.attribute |= ENABLE_TRANS | TRANS_MODE(1);

	MemCardMapDialog.x = MEMCARD_DIALOG_X;
	MemCardMapDialog.y = MEMCARD_DIALOG_Y;
	MemCardMapDialog.w = MEMCARD_DIALOG_W;
	MemCardMapDialog.h = MEMCARD_DIALOG_H;

	MemCardMapDialog.r = MEMCARD_DIALOG_R;
	MemCardMapDialog.g = MEMCARD_DIALOG_G;
	MemCardMapDialog.b = MEMCARD_DIALOG_B;

	MemCardMapDialog.attribute |= ENABLE_TRANS | TRANS_MODE(0);

	GfxSetGlobalLuminance(NORMAL_LUMINANCE);

	while (1)
	{
		if (PadOneKeyReleased(PAD_TRIANGLE))
		{
			break;
		}
		else if (PadOneKeyReleased(PAD_CROSS))
		{
			return &MemCardData[selectedBlock - BLOCK_1][selectedSlot];
		}
		else if (PadOneKeyReleased(PAD_LEFT))
		{
			if (selectedSlot == SLOT_TWO)
			{
				selectedSlot = SLOT_ONE;
			}
		}
		else if (PadOneKeyReleased(PAD_RIGHT))
		{
			if (selectedSlot == SLOT_ONE)
			{
				selectedSlot = SLOT_TWO;
			}
		}
		else if (PadOneKeyReleased(PAD_UP))
		{
			if (selectedBlock > BLOCK_1)
			{
				selectedBlock--;
			}
		}
		else if (PadOneKeyReleased(PAD_DOWN))
		{
			if (selectedBlock < BLOCK_15)
			{
				selectedBlock++;
			}
		}

		// Dim background
		SecondDisplay.r = NORMAL_LUMINANCE >> 1;
		SecondDisplay.g = NORMAL_LUMINANCE >> 1;
		SecondDisplay.b = NORMAL_LUMINANCE >> 1;

		GfxSortSprite(&SecondDisplay);

		GsSortRectangle(&MemCardMapDialog);

		for (j = SLOT_ONE; j <= SLOT_TWO; j++)
		{
			if (MemCardStatus[j] == MEMCARD_STATUS_UNKNOWN)
			{
				FontSetFlags(&SmallFont, FONT_NOFLAGS);

				x = MEMCARD_DIALOG_X;
				x += MEMCARD_DIALOG_GAP_SLOT * j;

				y = MEMCARD_DIALOG_Y;
				y += (short)(MEMCARD_DIALOG_GAP_X << 1);
				y += MEMCARD_DIALOG_GAP_X;

				x += MEMCARD_DIALOG_GAP_X;

				FontPrintText(	&SmallFont,
								x,
								y,
								"Disconnected"			);
				continue;
			}

			for (i = BLOCK_1; i <= BLOCK_15; i++)
			{
				ptrBlockData = &MemCardData[i - BLOCK_1][j];

				x = MEMCARD_DIALOG_X;
				x += MEMCARD_DIALOG_GAP_SLOT * j;
				x += ( (i - BLOCK_1) % 3) * MEMCARD_DIALOG_GAP_X;
				x += MEMCARD_DIALOG_GAP_X;

				y = MEMCARD_DIALOG_Y;
				y += (short)(MEMCARD_DIALOG_GAP_X * ((i - BLOCK_1) / 3));
				y += MEMCARD_DIALOG_GAP_X;

				if (ptrBlockData->BlockCount == EMPTY_BLOCK)
				{
					emptyBlockRect.x = x;
					emptyBlockRect.y = y;
					emptyBlockRect.w = MEMCARD_BLOCK_IMAGE_W;
					emptyBlockRect.h = MEMCARD_BLOCK_IMAGE_H;

					if (	(i == selectedBlock) && (j == selectedSlot) )
					{
						emptyBlockRect.r = FULL_LUMINANCE;
						emptyBlockRect.g = FULL_LUMINANCE;
						emptyBlockRect.b = FULL_LUMINANCE;

						FontSetFlags(&SmallFont, FONT_NOFLAGS);

						FontPrintText(	&SmallFont,
										MEMCARD_LOAD_DATA_TEXT_X,
										MEMCARD_LOAD_DATA_TEXT_Y,
										"Empty block"			);
					}
					else
					{
						emptyBlockRect.r = NORMAL_LUMINANCE >> 1;
						emptyBlockRect.g = NORMAL_LUMINANCE >> 1;
						emptyBlockRect.b = NORMAL_LUMINANCE >> 1;
					}

					GsSortRectangle(&emptyBlockRect);

					continue;
				}

				orig_r = ptrBlockData->IconTPoly.r;
				orig_g = ptrBlockData->IconTPoly.g;
				orig_b = ptrBlockData->IconTPoly.b;

				if (	(i == selectedBlock) && (j == selectedSlot) )
				{
					ptrBlockData->IconTPoly.r = FULL_LUMINANCE;
					ptrBlockData->IconTPoly.g = FULL_LUMINANCE;
					ptrBlockData->IconTPoly.b = FULL_LUMINANCE;

					if (ptrBlockData->BlockCount == FIRST_OR_ONLY_BLOCK)
					{
						FontPrintText(	&SmallFont,
										MEMCARD_LOAD_DATA_TEXT_X,
										MEMCARD_LOAD_DATA_TEXT_Y,
										(char*)ptrBlockData->FileName	);
					}
					else if (ptrBlockData->BlockCount == INTERMEDIATE_BLOCK)
					{
						FontPrintText(	&SmallFont,
										MEMCARD_LOAD_DATA_TEXT_X,
										MEMCARD_LOAD_DATA_TEXT_Y,
										"Intermediate block"	);
					}
					else if (ptrBlockData->BlockCount == LAST_BLOCK)
					{
						FontPrintText(	&SmallFont,
										MEMCARD_LOAD_DATA_TEXT_X,
										MEMCARD_LOAD_DATA_TEXT_Y,
										"Last block"			);
					}
				}
				else
				{
					ptrBlockData->IconTPoly.r = NORMAL_LUMINANCE >> 1;
					ptrBlockData->IconTPoly.g = NORMAL_LUMINANCE >> 1;
					ptrBlockData->IconTPoly.b = NORMAL_LUMINANCE >> 1;
				}

				MemCardDrawIcon(ptrBlockData, x, y);

				ptrBlockData->IconTPoly.r = orig_r;
				ptrBlockData->IconTPoly.g = orig_g;
				ptrBlockData->IconTPoly.b = orig_b;
			}
		}

		GfxDrawScene_Slow();
	}

	return NULL;
}

bool MemCardSaveData(TYPE_BLOCK_DATA * ptrBlockData)
{
	uint32_t i;
	uint32_t sz;
	int sector = (ptrBlockData->Block << MEMCARD_SECTORS_PER_BLOCK_BITSHIFT) + DATA_FRAME;

	// Always check whether current block is empty or not

	if (ptrBlockData->BlockCount != EMPTY_BLOCK)
	{
		if (strncmp((char*)ptrBlockData->FileName, MEMCARD_GAME_FILENAME, MEMCARD_FILENAME_SIZE) != 0)
		{
			// Only our own blocks can be overwritten. NEVER overwrite other game blocks!
			Serial_printf("I cannot erase blocks from other games!\n");
			return false;
		}
	}
	else if (ptrBlockData->BlockCount != FIRST_OR_ONLY_BLOCK)
	{
		Serial_printf("Please select first block of block array.\n");
		return false;
	}
	else if (ptrBlockData->Data == NULL)
	{
		Serial_printf("No data on current block!\n");
		return false;
	}
	else if (ptrBlockData->Block == DIRECTORY_BLOCK)
	{
		Serial_printf("Invalid block selected!\n");
		return false;
	}

	// After all these checks, now we can save data!

	sz = MEMCARD_FIRST_OR_LAST_DATA_SIZE;

	for (i = 0; i < sz; i++)
	{
		McWriteSector(ptrBlockData->Slot, sector + i, &ptrBlockData->Data[i << 7 /* 128 */]);
	}

	return true;
}