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/*++
Copyright (c) 1990-2000 Microsoft Corporation
Module Name:
boot.c
Abstract:
This is the device dependent portion of the graphical boot dll.
Author:
Erick Smith (ericks) Oct. 1997
Environment:
kernel mode only
Revision History:
--*/
//
// vga routines
//
#include <ntddk.h>
#include <bootvid.h>
#include "vga.h"
extern PUCHAR VgaBase;extern PUCHAR VgaRegisterBase;extern UCHAR FontData[];
#define FONT_HEIGHT (13)
#define STRING_HEIGHT (14)
typedef struct _RECT{ ULONG x1; ULONG y1; ULONG x2; ULONG y2;} RECT, *PRECT;
//
// globals to track screen position
//
ULONG curr_x=0;ULONG curr_y=0;RECT ScrollRegion = {0, 0, 639, 479}; // 53 lines of 9 pixel height text.
ULONG TextColor = 15;
#define DELTA 80L
UCHAR lMaskTable[8] = {0xff, 0x7f, 0x3f, 0x1f, 0x0f, 0x07, 0x03, 0x01};UCHAR rMaskTable[8] = {0x80, 0xc0, 0xe0, 0xf0, 0xf8, 0xfc, 0xfe, 0xff};UCHAR PixelMask[8] = {0x80, 0x40, 0x20, 0x10, 0x08, 0x04, 0x02, 0x01};
ULONG lookup[16] ={ 0x00000000, 0x00000100, 0x00001000, 0x00001100, 0x00000001, 0x00000101, 0x00001001, 0x00001101, 0x00000010, 0x00000110, 0x00001010, 0x00001110, 0x00000011, 0x00000111, 0x00001011, 0x00001111};
void __outpw(int p, int v){ WRITE_PORT_USHORT((PUSHORT)(p+VgaRegisterBase), (USHORT)v);}
void __outpb(int p, int v){ WRITE_PORT_UCHAR((PUCHAR)(p+VgaRegisterBase), (UCHAR)v);}
VOIDReadWriteMode( ULONG mode ){ UCHAR value;
WRITE_PORT_UCHAR((PUCHAR)(VgaRegisterBase+0x3ce), 5); value = READ_PORT_UCHAR((PUCHAR)(VgaRegisterBase+0x3cf));
value &= 0xf4; value |= mode;
WRITE_PORT_UCHAR((PUCHAR)(VgaRegisterBase+0x3cf), value);}
VOIDSetPixel( ULONG x, ULONG y, ULONG color ){ PUCHAR pDst; ULONG bank;
bank = x >> 3;
pDst = (char *)(VgaBase + y * DELTA + bank);
ReadWriteMode(0x8 | 0x2); __outpw(0x3c4, 0x0f02); // enable all write planes
__outpw(0x3ce, 0x0007); // set color don't care register to zero
__outpw(0x3ce, (PixelMask[x & 0x7] << 8) | 8);
WRITE_REGISTER_UCHAR(pDst, (UCHAR)(READ_REGISTER_UCHAR(pDst) & ((UCHAR)color)));}
VOIDVidSolidColorFill( ULONG x1, ULONG y1, ULONG x2, ULONG y2, ULONG color ){ PUCHAR pDst; ULONG x, y; ULONG bank1, bank2, count; ULONG lMask, rMask;
lMask = (lMaskTable[x1 & 0x7] << 8) | 8; rMask = (rMaskTable[x2 & 0x7] << 8) | 8;
bank1 = x1 >> 3; bank2 = x2 >> 3; count = bank2 - bank1;
if (!count) { lMask = lMask & rMask; }
ReadWriteMode(0x8 | 0x2);
__outpw(0x3c4, 0x0f02); // enable writing to all color planes
__outpw(0x3ce, 0x0007); // set color don't care register to zero
//
// Do the left edge
//
pDst = (char *)(VgaBase + y1 * DELTA + bank1);
__outpw(0x3ce, lMask);
for (y=y1; y<=y2; y++) {
WRITE_REGISTER_UCHAR(pDst, (UCHAR)(READ_REGISTER_UCHAR(pDst) & (UCHAR) color)); pDst += DELTA; }
if (count) {
//
// Do the right edge
//
pDst = (char *)(VgaBase + y1 * DELTA + bank2); count--; __outpw(0x3ce, rMask);
for (y=y1; y<=y2; y++) { WRITE_REGISTER_UCHAR(pDst, (UCHAR)(READ_REGISTER_UCHAR(pDst) & (UCHAR) color)); pDst += DELTA; }
//
// Do the center section
//
if (count) {
pDst = (char *)(VgaBase + y1 * DELTA + bank1 + 1); __outpw(0x3ce, 0xff08);
for (y=y1; y<=y2; y++) {
for (x=0; x<count; x++) { WRITE_REGISTER_UCHAR(pDst++, (unsigned char) color); } pDst += DELTA - count; }
} }}
VOIDDisplayCharacter( UCHAR c, ULONG x, ULONG y, ULONG fore_color, ULONG back_color ){ ULONG i, j; ULONG xx, yy;
UCHAR *BitPattern = &FontData[(int)c * FONT_HEIGHT];
yy = y; for (j=0; j<FONT_HEIGHT; j++) {
xx = x; for (i=128; i>0; i >>= 1) {
if (i & *BitPattern) {
SetPixel(xx, yy, fore_color);
} else if (back_color < 16) {
SetPixel(xx, yy, back_color); }
xx++; }
BitPattern++; yy++; }
//
// That is 8x8. But we will want to put a blank line
// such that the font is 8x9. This will allow some room
// between characters, and still allow for 53 lines of text.
//
// We only draw this blank line if not transparent text.
}
ULONGVidSetTextColor( ULONG Color )
/*++
Routine Description:
Modifies the text drawing color.
Arguments:
Color - Palette index of new text color.
Returns:
Previous text color.
--*/
{ ULONG ulRet = TextColor; TextColor = Color; return ulRet;}
VOIDVidDisplayString( PUCHAR str ){ static BOOLEAN bRestore = FALSE;
while (*str) {
switch(*str) { case '\n':
curr_y += STRING_HEIGHT;
if (curr_y >= ScrollRegion.y2) {
VgaScroll(STRING_HEIGHT); curr_y = curr_y - STRING_HEIGHT; PreserveRow(curr_y, STRING_HEIGHT, TRUE); // restore the row
}
curr_x = ScrollRegion.x1; PreserveRow(curr_y, STRING_HEIGHT, FALSE); break;
case '\r':
curr_x = ScrollRegion.x1;
//
// If we are doing a CR, but not a LF also, then
// we must be returing to the beginning of a row
// to display text again. So we'll need to
// restore the original contents of the row.
//
if (*(str+1) != '\n') { bRestore = TRUE; } break;
default:
if (bRestore) { PreserveRow(curr_y, STRING_HEIGHT, TRUE); bRestore = FALSE; }
DisplayCharacter(*str, curr_x, curr_y, TextColor, 16); curr_x += 8;
if (curr_x > ScrollRegion.x2) { curr_y += STRING_HEIGHT;
if (curr_y > ScrollRegion.y2) {
VgaScroll(STRING_HEIGHT); curr_y = curr_y - STRING_HEIGHT; PreserveRow(curr_y, STRING_HEIGHT, TRUE); } curr_x = ScrollRegion.x1; } }
str++; }}
VOIDVidDisplayStringXY( PUCHAR s, ULONG x, ULONG y, BOOLEAN Transparent ){ DisplayStringXY(s, x, y, 12, Transparent ? 16 : 14);}
VOIDDisplayStringXY( PUCHAR s, ULONG x, ULONG y, ULONG fore_color, ULONG back_color ){ while (*s) {
DisplayCharacter(*s, x, y, fore_color, back_color); s++; x += 8; }}
VOIDRleBitBlt( ULONG x, ULONG y, ULONG width, ULONG height, PUCHAR Buffer )
/*++
Routine Description:
This routine displays an RLE 4 bitmap.
Arguments:
x, y - location at which to display the bitmap.
width, height - height of the bitmap
Buffer - Pointer to the compressed bitmap data.
--*/
{ BOOLEAN Done = FALSE; PUCHAR p = Buffer; ULONG RunLength; LONG RunExtra; ULONG curr_x, curr_y; ULONG Color1, Color2;
curr_x = x; curr_y = y + height - 1;
while (!Done) {
if (*p) {
RunLength = (ULONG) *p++;
//
// Make sure we don't draw past end of scan.
//
if ((curr_x + RunLength) > (x + width)) RunLength -= (curr_x + RunLength) - (width + x);
Color1 = (*p & 0xf0) >> 4; Color2 = (*p++ & 0x0f);
if (Color1 == Color2) {
ULONG end_x = curr_x + RunLength - 1;
VidSolidColorFill(curr_x, curr_y, end_x, curr_y, Color1);
curr_x += RunLength;
} else {
while (RunLength > 1) { SetPixel(curr_x++, curr_y, Color1); SetPixel(curr_x++, curr_y, Color2); RunLength -= 2; }
if (RunLength) { SetPixel(curr_x, curr_y, Color1); curr_x++; } }
} else {
p++;
switch (*p) {
case 0: curr_x = x; curr_y--; p++; break;
case 1: Done = TRUE; p++; break;
case 2: p++; curr_x += (ULONG) *p++; curr_y -= (ULONG) *p++; break;
default: RunLength = (ULONG) *p++;
//
// Make sure we don't draw past end of scan.
//
if ((curr_x + RunLength) > (x + width)) { RunExtra = (curr_x + RunLength) - (width + x); RunLength -= RunExtra; } else { RunExtra = 0; }
while (RunLength > 1) {
Color1 = (*p & 0xf0) >> 4; Color2 = (*p++ & 0x0f);
SetPixel(curr_x++, curr_y, Color1); SetPixel(curr_x++, curr_y, Color2);
RunLength -= 2; }
if (RunLength) { Color1 = (*p++ & 0xf0) >> 4; SetPixel(curr_x++, curr_y, Color1); RunExtra--; }
//
// Read any remaining "extra" run data.
//
while (RunExtra > 0) { p++; RunExtra -= 2; }
if ((ULONG_PTR)p & 1) p++; // make sure we are word aligned
break; } } }}
VOIDBitBlt( ULONG x, ULONG y, ULONG width, ULONG height, PUCHAR Buffer, ULONG bpp, LONG ScanWidth ){ ULONG i, j; ULONG color=8;
if (bpp == 4) {
UCHAR Plane[81]; ULONG lMask, rMask, count; ULONG bank1, bank2, bank; ULONG bRightEdge = FALSE, bCenterSection = FALSE; UCHAR value; ULONG plane; UCHAR Mask; ULONG toggle; PUCHAR pSrc, pSrcTemp; PUCHAR pDst, pDstTemp; UCHAR PlaneMask;
lMask = lMaskTable[x & 0x7]; rMask = rMaskTable[(x + width - 1) & 0x7];
bank1 = x >> 3; bank2 = (x + width - 1) >> 3;
count = bank2 - bank1;
if (bank1 == bank2) {
lMask = lMask & rMask;
}
if (count) {
bRightEdge = TRUE;
count--;
if (count) {
bCenterSection = TRUE; } }
pDst = (PUCHAR)(VgaBase + (y * DELTA) + (x / 8)); pSrc = Buffer;
ReadWriteMode(0x0 | 0x0);
for (j=0; j<height; j++) {
for (plane=0; plane<4; plane++) {
pSrcTemp = pSrc; pDstTemp = pDst;
PlaneMask = 1 << plane;
//
// Convert the packed bitmap data into planar data
// for this plane.
//
bank = bank1; Plane[bank] = 0; Mask = PixelMask[x & 0x7]; toggle = 0;
for (i=0; i<width; i++) {
if (toggle++ & 0x1) {
if (*pSrcTemp & PlaneMask) { Plane[bank] |= Mask; }
pSrcTemp++;
} else {
if (((*pSrcTemp) >> 4) & PlaneMask) { Plane[bank] |= Mask; } }
Mask >>= 1;
if (!Mask) {
bank++; Plane[bank] = 0; Mask = 0x80; } }
//
// Set up the vga so that we see the correct bit plane.
//
__outpw(0x3c4, (1 << (plane + 8)) | 2);
//
// bank will go from bank1 to bank2
//
bank = bank1; pDstTemp = pDst;
//
// Set Bitmask for left edge.
//
__outpw(0x3ce, (lMask << 8) | 8);
value = READ_REGISTER_UCHAR(pDstTemp);
value &= ~lMask; value |= Plane[bank++];
WRITE_REGISTER_UCHAR(pDstTemp++, value);
if (bCenterSection) {
__outpw(0x3ce, 0xff08); // enable writing to all bits
for (i=0; i<count; i++) {
WRITE_REGISTER_UCHAR(pDstTemp++, Plane[bank++]); } }
if (bRightEdge) {
//
// Set bitmask for right edge.
//
__outpw(0x3ce, (rMask << 8) | 8);
value = READ_REGISTER_UCHAR(pDstTemp);
value &= ~rMask; value |= Plane[bank];
WRITE_REGISTER_UCHAR(pDstTemp, value); } }
pDst += DELTA; pSrc += ScanWidth; }
} else {
PUCHAR pDst, pDstTemp; PUCHAR pSrc, pSrcTemp; ULONG count; UCHAR Value; ULONG lMask, rMask; ULONG bank1, bank2; ULONG plane; UCHAR colorMask;
bank1 = x >> 8; bank2 = (x + width - 1) >> 8;
lMask = lMaskTable[x & 7]; rMask = rMaskTable[(x + width - 1) & 7];
if (bank1 == bank2) {
lMask &= rMask; }
lMask = ~lMask; rMask = ~rMask;
pSrc = Buffer; pDst = (PUCHAR)(VgaBase + (y * DELTA) + (x / 8));
ReadWriteMode(0x0 | 0x0);
for (j=0; j<height; j++) {
plane = 1; for (i=0; i<4; i++) {
pDstTemp = pDst; pSrcTemp = pSrc;
__outpw(0x3c4, (plane << 8) | 2);
colorMask = (UCHAR)((color & plane) ? 0xff : 0x00);
plane <<= 1; // bump up each time through loop
count = width;
//
// non aligned case
//
if (x & 7) {
//
// Left Edge.
//
Value = READ_REGISTER_UCHAR(pDstTemp);
Value &= lMask; Value |= (*pSrcTemp >> x) & colorMask;
WRITE_REGISTER_UCHAR(pDstTemp++, Value);
count -= (8 - x);
//
// Now do center section
//
while (count > 7) {
Value = (*pSrcTemp << (8 - x)) | (*(pSrcTemp+1) >> x); Value &= colorMask;
WRITE_REGISTER_UCHAR(pDstTemp++, Value);
pSrcTemp++; count -= 8; }
//
// Now do the right edge.
//
if (count) {
Value = READ_REGISTER_UCHAR(pDstTemp);
Value &= rMask; Value |= *pSrcTemp << (8 - x) & colorMask;
WRITE_REGISTER_UCHAR(pDstTemp++, Value); }
} else {
//
// Aligned case.
//
ULONG ulColorMask = colorMask ? 0xffffffff : 0x00000000; USHORT usColorMask = colorMask ? 0xffff : 0x0000;
while (count > 31) {
WRITE_REGISTER_ULONG(((PULONG)pDstTemp)++, (ULONG)((*((PULONG)pSrcTemp)++) & ulColorMask)); count -= 32; }
while (count > 15) {
WRITE_REGISTER_USHORT(((PUSHORT)pDstTemp)++, (USHORT)((*((PUSHORT)pSrcTemp)++) & usColorMask)); count -= 16; }
if (count > 7) {
WRITE_REGISTER_UCHAR(pDstTemp++, (UCHAR)(*pSrcTemp++ & colorMask)); count -= 8; }
//
// Now do any remaining bits.
//
if (count) {
Value = READ_REGISTER_UCHAR(pDstTemp);
Value &= rMask; Value |= *pSrcTemp & colorMask;
WRITE_REGISTER_UCHAR(pDstTemp++, Value); } } }
pSrc += ScanWidth; pDst += DELTA; } }}
VOIDVidBitBlt( PUCHAR Buffer, ULONG x, ULONG y )
/*++
Routine Description:
This routine takes a bitmap resource and displays it at a given location.
Arguments:
Buffer - Pointer to the bitmap resource.
x, y - The position at which to display the bitmap.
--*/
{ PBITMAPINFOHEADER bih; PRGBQUAD Palette;
LONG lDelta; PUCHAR pBuffer; LONG cbScanLine;
bih = (PBITMAPINFOHEADER) Buffer;
Palette = (PRGBQUAD)(((PUCHAR)bih) + bih->biSize); InitPaletteWithTable(Palette, bih->biClrUsed ? bih->biClrUsed : 16);
//
// Make sure this is a 1bpp or 4bpp bitmap.
//
if ((bih->biBitCount * bih->biPlanes) <= 4) {
cbScanLine = (((bih->biWidth * bih->biBitCount) + 31) & ~31) >> 3;
pBuffer = (PUCHAR)(Buffer + sizeof(BITMAPINFOHEADER) + 64);
if (bih->biCompression == BI_RLE4) {
if (bih->biWidth && bih->biHeight) { RleBitBlt(x, y, bih->biWidth, bih->biHeight, pBuffer); }
} else {
if (bih->biHeight < 0) {
// top down bitmap
lDelta = cbScanLine; bih->biHeight = -bih->biHeight;
} else {
// bottom up bitmap
pBuffer += cbScanLine * (bih->biHeight - 1); lDelta = -cbScanLine; }
if (bih->biWidth && bih->biHeight) { BitBlt(x, y, bih->biWidth, bih->biHeight, pBuffer, bih->biBitCount, lDelta); } }
} else {
//
// We don't support this type of bitmap.
//
ASSERT((bih->biBitCount * bih->biPlanes) <= 4); }}
VOIDVgaScroll( ULONG CharHeight ){ ULONG i, j; PUCHAR pDst, pSrc; PUCHAR pDstTemp, pSrcTemp;
pDst = (PUCHAR)(VgaBase + ScrollRegion.y1 * DELTA + (ScrollRegion.x1 >> 3)); pSrc = (PUCHAR)(pDst + DELTA * CharHeight);
__outpw(0x3c4, 0x0f02); // enable write to all planes
__outpw(0x3ce, 0xff08); // enable write to all bits in plane
ReadWriteMode(0x0 | 0x1); // set read mode = 0, write mode = 1
for (i=ScrollRegion.y1; i<=ScrollRegion.y2; i++) {
pDstTemp = pDst; pSrcTemp = pSrc;
for (j=(ScrollRegion.x1 >> 3); j<=(ScrollRegion.x2 >> 3); j++) { WRITE_REGISTER_UCHAR(pDstTemp++, READ_REGISTER_UCHAR(pSrcTemp++)); }
pDst += DELTA; pSrc += DELTA; }}
VOIDPreserveRow( ULONG y, ULONG CharHeight, BOOLEAN bRestore ){ PUCHAR pDst, pSrc; ULONG count;
__outpw(0x3c4, 0x0f02); // enable write to all planes
__outpw(0x3ce, 0xff08); // enable write to all bits in plane
ReadWriteMode(0x0 | 0x1); // set read mode = 0, write mode = 1
if (bRestore) { pDst = (PUCHAR)(VgaBase + DELTA * y); pSrc = (PUCHAR)(VgaBase + DELTA * 480); } else { pDst = (PUCHAR)(VgaBase + DELTA * 480); pSrc = (PUCHAR)(VgaBase + DELTA * y); }
count = CharHeight * DELTA;
while (count--) { WRITE_REGISTER_UCHAR(pDst++, READ_REGISTER_UCHAR(pSrc++)); }}
VOIDVidScreenToBufferBlt( PUCHAR Buffer, ULONG x, ULONG y, ULONG width, ULONG height, ULONG lDelta )
/*++
Routine Description:
This routine allows you to copy a portion of video memory into system memory.
Arguments:
Buffer - Points to system memory where the video image should be copied.
x, y - X,Y coordinates in video memory of top-left portion of image.
width, height - width and height of the image in pixels.
lDelta - width of the buffer in bytes.
Notes:
Upon completion, the video memory image will be in system memory. Each plane of the image are stored seperately, so the first scan line of plane 0 will be followed by the first scan line of plane 1, etc. Then the second scan of plane 0, plane 1, and so on.
--*/
{ ULONG Plane, i, j, BankStart, BankEnd; PUCHAR pSrc, pSrcTemp, pDst; PULONG pulDstTemp; UCHAR Val1, Val2; ULONG Shift1, Shift2; UCHAR ucCombined; ULONG ulCombined;
BankStart = x >> 3; BankEnd = (x + width - 1) >> 3; Shift1 = x & 7; Shift2 = 8 - Shift1;
//
// Zero initialize the buffer so we can or in the bits later!
//
pDst = Buffer; memset(pDst, 0, lDelta * height);
for (Plane=0; Plane<4; Plane++) {
pSrc = (PUCHAR)(VgaBase + (DELTA * y) + BankStart); pDst = Buffer;
ReadWriteMode(0x0 | 0x0); // set read mode 0
__outpw(0x3ce, (Plane << 8) | 0x04); // read from given plane
for (j=0; j<height; j++) {
pSrcTemp = pSrc; pulDstTemp = (PULONG)pDst;
Val1 = READ_REGISTER_UCHAR(pSrcTemp++);
for (i=BankStart; i<=BankEnd; i++) {
Val2 = READ_REGISTER_UCHAR(pSrcTemp++);
ucCombined = (Val1 << Shift1) | (Val2 >> Shift2); ulCombined = ((lookup[(ucCombined & 0x0f) >> 0] << 16) | lookup[(ucCombined & 0xf0) >> 4]) << Plane;
*pulDstTemp++ |= ulCombined;
Val1 = Val2; }
pSrc += DELTA; // go to next video memory scan line
pDst += lDelta; // go to next scan for this plane in buffer
} }}
void VidBufferToScreenBlt( PUCHAR Buffer, ULONG x, ULONG y, ULONG width, ULONG height, ULONG lDelta )
/*++
Routine Description:
This routine allows you to copy a portion of video memory into system memory.
Arguments:
Buffer - Points to system memory where the video image should be copied from.
x, y - X,Y coordinates in video memory of top-left portion of image.
width, height - width and height of the image in pixels.
lDelta - width of the buffer in bytes.
Notes:
This routine will allow you to blt from a buffer filled by VidScreenToBufferBlt.
--*/
{ if (width && height) { BitBlt(x, y, width, height, Buffer, 4, lDelta); }}
VOIDSetPaletteEntry( ULONG index, ULONG RGB ){ __outpb(0x3c8, index);
__outpb(0x3c9, RGB & 0xff); RGB >>= 8; __outpb(0x3c9, RGB & 0xff); RGB >>= 8; __outpb(0x3c9, RGB & 0xff);}
VOIDSetPaletteEntryRGB( ULONG index, RGBQUAD rgb ){ __outpb(0x3c8, index); __outpb(0x3c9, rgb.rgbRed >> 2); __outpb(0x3c9, rgb.rgbGreen >> 2); __outpb(0x3c9, rgb.rgbBlue >> 2);}
VOIDInitPaletteWithTable( PRGBQUAD Palette, ULONG count ){ ULONG i;
for (i=0; i<count; i++) {
SetPaletteEntryRGB(i, *Palette++); }}
VOIDInitializePalette( VOID ){ ULONG Palette[] = { 0x00000000, 0x00000020, 0x00002000, 0x00002020, 0x00200000, 0x00200020, 0x00202000, 0x00202020, 0x00303030, 0x0000003f, 0x00003f00, 0x00003f3f, 0x003f0000, 0x003f003f, 0x003f3f00, 0x003f3f3f, }; ULONG i;
for (i=0; i<16; i++) {
SetPaletteEntry(i, Palette[i]); }
}
VOIDWaitForVsync( VOID )
/*++
Routine Description:
Wait for a v-sync
--*/
{ //
// Check to see if vsync's are being generated.
//
WRITE_PORT_UCHAR((VgaRegisterBase+0x3c4), 00);
if (READ_PORT_UCHAR(VgaRegisterBase+0x3c5) & 0x2) {
ULONG MaxDelay;
//
// Slight delay. Wait for one vsync.
//
MaxDelay = 100000; while (((READ_PORT_UCHAR(VgaRegisterBase+0x3da) & 0x08) == 0x08) && MaxDelay--); MaxDelay = 100000; while (((READ_PORT_UCHAR(VgaRegisterBase+0x3da) & 0x08) == 0x00) && MaxDelay--); }}
VOIDVidSetScrollRegion( ULONG x1, ULONG y1, ULONG x2, ULONG y2 )
/*++
Routine Description:
Controls the portion of the screen which is used for text.
Arguments:
x1, y1, x2, y2 - coordinates of scroll rectangle.
Notes:
x1 and x2 must be multiples of 8.
--*/
{ ASSERT((x1 & 0x7) == 0); ASSERT((x2 & 0x7) == 7);
ScrollRegion.x1 = x1; ScrollRegion.y1 = y1; ScrollRegion.x2 = x2; ScrollRegion.y2 = y2;
curr_x = ScrollRegion.x1; curr_y = ScrollRegion.y1;}
VOIDVidCleanUp( VOID )
/*++
Routine Description:
This routine is called when the boot driver has lost ownership of the display. This gives us to restore any vga registers which may need to be put back into a known state.
--*/
{ //
// Set the bit mask register to its default state.
//
WRITE_PORT_UCHAR((VgaRegisterBase+0x3ce), 0x08); WRITE_PORT_UCHAR((VgaRegisterBase+0x3cf), 0xff);}
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