vmware-svga/examples/screen-cursor/main.c

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/*
* This is a test app for virtual hardware cursor overlays. It
* provides a number of test cases which exercise and demonstrate the
* various cursor modes.
*
* This example requires SVGA Screen Object support. (The cursor
* functionality we're testing has nothing to do with Screen Object,
* but Screen Object is required by our text drawing code...)
*/
#include "svga.h"
#include "gmr.h"
#include "screen.h"
#include "intr.h"
#include "screendraw.h"
#include "keyboard.h"
#include "vmbackdoor.h"
#include "timer.h"
#include "mt19937ar.h"
#include "math.h"
/*
* Constants
*/
#define GMRID_SCREEN_DRAW 0
#define GMRID_NOISE 1
#define FRAME_RATE 60
/*
* Global data
*/
int currentTest = -1;
const int testListX = 150;
const int testListY = 70;
const int testListItemHeight = 22;
SVGAScreenObject myScreen = {
.structSize = sizeof(SVGAScreenObject),
.id = 0,
.flags = SVGA_SCREEN_HAS_ROOT | SVGA_SCREEN_IS_PRIMARY,
.size = { 800, 600 },
.root = { 150000, -0x20000000 },
};
/*
* Test Cases
*/
void
testAlphaArrow(void)
{
static const SVGAFifoCmdDefineAlphaCursor cursor = {
.id = 0,
.hotspotX = 1,
.hotspotY = 1,
.width = 36,
.height = 51,
};
static const uint32 data[] = {
# include "rgba_arrow.h"
};
void *fifoData;
/*
* Switch to 8-bit mode. Alpha cursors should work even if the
* legacy framebuffer is in a low color depth.
*/
SVGA_WriteReg(SVGA_REG_BITS_PER_PIXEL, 8);
SVGA_BeginDefineAlphaCursor(&cursor, &fifoData);
memcpy(fifoData, data, sizeof data);
SVGA_FIFOCommitAll();
}
void
testGradient(int size)
{
const SVGAFifoCmdDefineAlphaCursor cursor = {
.id = 0,
.hotspotX = size / 2,
.hotspotY = size / 2,
.width = size,
.height = size,
};
uint32 *data;
int x, y;
SVGA_WriteReg(SVGA_REG_BITS_PER_PIXEL, 8);
SVGA_BeginDefineAlphaCursor(&cursor, (void**) &data);
for (y = 0; y < cursor.height; y++) {
for (x = 0; x < cursor.width; x++) {
uint8 alpha = y * 255 / cursor.height;
/* Solid white, with pre-multiplied alpha: L = 255 * alpha / 255 */
uint8 luma = alpha;
*(data++) = (alpha << 24) | (luma << 16) | (luma << 8) | luma;
}
}
SVGA_FIFOCommitAll();
}
void
testGradient64(void)
{
testGradient(64);
}
void
testGradient180(void)
{
testGradient(180);
}
void
testGradient256(void)
{
testGradient(256);
}
void
testMonochrome(void)
{
static const SVGAFifoCmdDefineCursor cursor = {
.id = 0,
.hotspotX = 24,
.hotspotY = 24,
.width = 48,
.height = 48,
.andMaskDepth = 1,
.xorMaskDepth = 1,
};
static const uint8 data[] = {
# include "beachball_mono.h"
};
void *andData, *xorData;
/*
* Switch to 32bpp mode, just because we can. Monochrome cursors
* work in any framebuffer depth.
*/
SVGA_WriteReg(SVGA_REG_BITS_PER_PIXEL, 32);
SVGA_BeginDefineCursor(&cursor, &andData, &xorData);
memcpy(andData, data, sizeof data);
SVGA_FIFOCommitAll();
}
void
testMonochromeXOR(void)
{
static const SVGAFifoCmdDefineCursor cursor = {
.id = 0,
.hotspotX = 24,
.hotspotY = 24,
.width = 48,
.height = 48,
.andMaskDepth = 1,
.xorMaskDepth = 1,
};
static const uint8 data[] = {
# include "beachball_mono_xor.h"
};
void *andData, *xorData;
SVGA_WriteReg(SVGA_REG_BITS_PER_PIXEL, 32);
SVGA_BeginDefineCursor(&cursor, &andData, &xorData);
memcpy(andData, data, sizeof data);
SVGA_FIFOCommitAll();
}
void
testMonochromeLarge(void)
{
static const SVGAFifoCmdDefineCursor cursor = {
.id = 0,
.hotspotX = 50,
.hotspotY = 50,
.width = 100,
.height = 98,
.andMaskDepth = 1,
.xorMaskDepth = 1,
};
static const uint8 data[] = {
# include "chip_mono.h"
};
void *andData, *xorData;
/*
* Switch to 32bpp mode, just because we can. Monochrome cursors
* work in any framebuffer depth.
*/
SVGA_WriteReg(SVGA_REG_BITS_PER_PIXEL, 32);
SVGA_BeginDefineCursor(&cursor, &andData, &xorData);
memcpy(andData, data, sizeof data);
SVGA_FIFOCommitAll();
}
void
testANDXOR32(void)
{
static const SVGAFifoCmdDefineCursor cursor = {
.id = 0,
.hotspotX = 16,
.hotspotY = 16,
.width = 32,
.height = 32,
.andMaskDepth = 32,
.xorMaskDepth = 32
};
uint32 *andData, *xorData;
int x, y;
SVGA_WriteReg(SVGA_REG_BITS_PER_PIXEL, 32);
SVGA_BeginDefineCursor(&cursor, (void**) &andData, (void**) &xorData);
for (y = 0; y < cursor.height; y++) {
for (x = 0; x < cursor.width; x++) {
*(andData++) = 0x808080;
*(xorData++) = y * 127 / cursor.height;
}
}
SVGA_FIFOCommitAll();
}
static const uint32 yellowCrabData[] = {
# include "yellow_crab_rgba.h"
};
void
buildCrabANDMask(uint8 *andData)
{
const uint32 *rgba = yellowCrabData;
const int width = 48;
const int height = 50;
uint32 andPitch = ((width + 31) / 32) * 4;
uint8 *andLine;
int x, y;
for (y = 0; y < height; y++) {
andLine = andData;
andData += andPitch;
memset(andLine, 0, andPitch);
for (x = 0; x < width; x++) {
uint32 color = *(rgba++);
*andLine <<= 1;
if ((color & 0xFF000000) == 0) {
/*
* Transparent pixel
*/
*andLine |= 1;
}
if ((x & 7) == 7) {
andLine++;
}
}
}
}
void
testCrabAlpha(void)
{
static const SVGAFifoCmdDefineAlphaCursor cursor = {
.id = 0,
.hotspotX = 24,
.hotspotY = 25,
.width = 48,
.height = 50,
};
void *fifoData;
SVGA_WriteReg(SVGA_REG_BITS_PER_PIXEL, 32);
SVGA_BeginDefineAlphaCursor(&cursor, &fifoData);
memcpy(fifoData, yellowCrabData, sizeof yellowCrabData);
SVGA_FIFOCommitAll();
}
void
testCrabANDXOR32(void)
{
static const SVGAFifoCmdDefineCursor cursor = {
.id = 0,
.hotspotX = 24,
.hotspotY = 25,
.width = 48,
.height = 50,
.andMaskDepth = 1,
.xorMaskDepth = 32
};
uint8 *andData;
uint32 *xorData;
SVGA_WriteReg(SVGA_REG_BITS_PER_PIXEL, 32);
SVGA_BeginDefineCursor(&cursor, (void**) &andData, (void**) &xorData);
buildCrabANDMask(andData);
memcpy(xorData, yellowCrabData, sizeof yellowCrabData);
SVGA_FIFOCommitAll();
}
void
testCrabANDXOR16(void)
{
static const SVGAFifoCmdDefineCursor cursor = {
.id = 0,
.hotspotX = 24,
.hotspotY = 25,
.width = 48,
.height = 50,
.andMaskDepth = 1,
.xorMaskDepth = 16
};
const uint32 *rgba = yellowCrabData;
uint8 *andData;
uint16 *xorData;
int x, y;
SVGA_WriteReg(SVGA_REG_BITS_PER_PIXEL, 16);
if (SVGA_ReadReg(SVGA_REG_DEPTH) != 16) {
Console_Panic("Expected SVGA_REG_DEPTH == 16 for 16bpp mode");
}
SVGA_BeginDefineCursor(&cursor, (void**) &andData, (void**) &xorData);
buildCrabANDMask(andData);
for (y = 0; y < cursor.height; y++) {
for (x = 0; x < cursor.width; x++) {
uint32 color = *(rgba++);
/*
* Convert to RGB 5-6-5
*/
uint8 r = (color >> 19) & 0x1F;
uint8 g = (color >> 10) & 0x3F;
uint8 b = (color >> 3) & 0x1F;
*(xorData++) = (r << 11) | (g << 5) | b;
}
}
SVGA_FIFOCommitAll();
}
void
testCrabANDXOR8(void)
{
static const SVGAFifoCmdDefineCursor cursor = {
.id = 0,
.hotspotX = 24,
.hotspotY = 25,
.width = 48,
.height = 50,
.andMaskDepth = 1,
.xorMaskDepth = 8
};
static const uint8 crabPixels[] = {
# include "yellow_crab_256_pixels.h"
};
static const uint8 crabColormap[] = {
# include "yellow_crab_256_colormap.h"
};
uint8 *andData, *xorData;
int i;
SVGA_WriteReg(SVGA_REG_BITS_PER_PIXEL, 8);
if (SVGA_ReadReg(SVGA_REG_PSEUDOCOLOR) != TRUE) {
Console_Panic("Expected SVGA_REG_PSUEDOCOLOR == TRUE for 8bpp mode");
}
/*
* Load the crab's colormap into the SVGA palette registers.
*/
for (i = 0; i < arraysize(crabColormap); i++) {
SVGA_WriteReg(SVGA_PALETTE_BASE + i, crabColormap[i]);
}
SVGA_BeginDefineCursor(&cursor, (void**) &andData, (void**) &xorData);
buildCrabANDMask(andData);
memcpy(xorData, crabPixels, sizeof crabPixels);
SVGA_FIFOCommitAll();
}
void
createPaletteCursor(void)
{
/*
* Set up a cursor which shows every color in the palette. It has
* a 1-pixel border of color 255, but every other color forms a
* 16x16 grid in which each square is a different color. Each grid
* square is 3x3 pixels.
*
* We also take this opportunity to use an 8-bit AND mask, but it's
* fully opaque (all zeroes).
*
* This does mean that to function correctly, this cursor needs
* color 0 to be black. The SVGA device doesn't specify whether
* AND/XOR masks are applied before or after pseudocolor emulation,
* so we need to be okay with either.
*/
static const SVGAFifoCmdDefineCursor cursor = {
.id = 0,
.hotspotX = 24,
.hotspotY = 24,
.width = 49,
.height = 49,
.andMaskDepth = 8,
.xorMaskDepth = 8
};
uint8 *andData, *xorData;
uint8 *line;
int x, y;
uint32 pitch = roundup(cursor.width, sizeof(uint32)) * sizeof(uint32);
SVGA_WriteReg(SVGA_REG_BITS_PER_PIXEL, 8);
if (SVGA_ReadReg(SVGA_REG_PSEUDOCOLOR) != TRUE) {
Console_Panic("Expected SVGA_REG_PSUEDOCOLOR == TRUE for 8bpp mode");
}
SVGA_BeginDefineCursor(&cursor, (void**) &andData, (void**) &xorData);
memset(andData, 0, pitch * cursor.height);
for (y = 0; y < cursor.height; y++) {
line = xorData;
xorData += pitch;
for (x = 0; x < cursor.width; x++) {
uint8 color;
if (y == 0 || x == 0 || y == cursor.height - 1 || x == cursor.width - 1) {
/* Border color */
color = 0xFF;
} else {
int row = (y - 1) / 3;
int column = (x - 1) / 3;
color = row * 16 + column;
}
*(line++) = color;
}
}
SVGA_FIFOCommitAll();
}
void
animatePalette(void)
{
/*
* Animate the palette. This is stolen from the vbe-palette test...
*/
static int tick = 0;
int i;
/*
* Let the phase of each color channel slowly drift around.
*/
const float rPhase = tick * 0.001;
const float gPhase = tick * 0.002;
const float bPhase = tick * 0.003;
/*
* Animate every color except 0 (used for the AND mask) and 255
* (for the border).
*/
for (i = 1; i < 255; i++) {
const int x = (i & 0x0F) - 3;
const int y = (i >> 4) - 3;
const float t = (x*x + y*y) * 0.05 + tick * 0.02;
const uint8 r = sinf(t + rPhase) * 0x7f + 0x80;
const uint8 g = sinf(t + gPhase) * 0x7f + 0x80;
const uint8 b = sinf(t + bPhase) * 0x7f + 0x80;
SVGA_WriteReg(SVGA_PALETTE_BASE + i * 3 + 0, r);
SVGA_WriteReg(SVGA_PALETTE_BASE + i * 3 + 1, g);
SVGA_WriteReg(SVGA_PALETTE_BASE + i * 3 + 2, b);
}
tick++;
}
void
blit32(const uint32 *src, int srcX, int srcY, int srcWidth,
uint32 *dest, int destX, int destY, int destWidth,
int copyWidth, int copyHeight)
{
src += srcX + srcY * srcWidth;
dest += destX + destY * destWidth;
while (copyHeight--) {
memcpy32(dest, src, copyWidth);
src += srcWidth;
dest += destWidth;
}
}
void
testCursorAnim(void)
{
/*
* Animate a cursor image of a moon orbiting a planet. The cursor
* hotspot is always centered on the planet, but we dynamically
* size the cursor according to the bounding box around the planet
* and moon, and we dynamically adjust the hotspot to keep it
* centered on the moon.
*/
const int moonWidth = 10;
const int planetWidth = 20;
static int tick = 0;
float angle = tick * 0.03;
tick++;
const int orbitRadius = 40;
int orbitX = cosf(angle) * orbitRadius;
int orbitY = sinf(angle) * orbitRadius;
int width, height, planetX, planetY, moonX, moonY;
if (orbitX >= 0) {
width = planetWidth + orbitX;
planetX = planetWidth/2;
moonX = planetX + orbitX;
} else {
width = planetWidth - orbitX;
moonX = planetWidth/2;
planetX = moonX - orbitX;
}
if (orbitY >= 0) {
height = planetWidth + orbitY;
planetY = planetWidth/2;
moonY = planetY + orbitY;
} else {
height = planetWidth - orbitY;
moonY = planetWidth/2;
planetY = moonY - orbitY;
}
const SVGAFifoCmdDefineAlphaCursor cursor = {
.id = 0,
.hotspotX = planetX,
.hotspotY = planetY,
.width = width,
.height = height,
};
uint32 *image;
static const uint32 planet[] = {
# include "planet_rgba.h"
};
static const uint32 moon[] = {
# include "moon_rgba.h"
};
SVGA_WriteReg(SVGA_REG_BITS_PER_PIXEL, 8);
SVGA_BeginDefineAlphaCursor(&cursor, (void**) &image);
memset32(image, 0, width * height);
blit32(planet, 0, 0, planetWidth,
image, planetX - planetWidth/2, planetY - planetWidth/2, width,
planetWidth, planetWidth);
blit32(moon, 0, 0, moonWidth,
image, moonX - moonWidth/2, moonY - moonWidth/2, width,
moonWidth, moonWidth);
SVGA_FIFOCommitAll();
}
/*
* gTestCases --
*
* Master array of cursor test cases. Each one has a title and a
* function pointer. The function is run once when a test mode is
* selected.
*/
struct {
void (*fn)(void);
const char *title;
void (*animateFn)(void);
} gTestCases[] = {
{ testAlphaArrow, "Translucent arrow cursor (36x51)" },
{ testGradient64, "Gradient from transparent white to opaque white (64x64)" },
{ testGradient180, "Gradient from transparent white to opaque white (180x180)" },
{ testGradient256, "Gradient from transparent white to opaque white (256x256)" },
{ testMonochrome, "Monochrome beachball cursor (48x48)" },
{ testMonochromeXOR, "Monochrome beachball cursor with XOR pixels (48x48)" },
{ testMonochromeLarge, "Monochrome chip cursor (100x96)" },
{ testANDXOR32, "AND masks off 7 LSBs, XOR draws blue gradient (32x32)" },
{ testCrabAlpha, "Yellow crab, alpha blended (48x50)" },
{ testCrabANDXOR32, "Yellow crab, 1-bit AND, 32-bit XOR (48x50)" },
{ testCrabANDXOR16, "Yellow crab, 1-bit AND, 16-bit XOR (48x50)" },
{ testCrabANDXOR8, "Yellow crab, 1-bit AND, 8-bit XOR (48x50)" },
{ createPaletteCursor, "Palette animation, 8-bit AND/XOR (49x49)", animatePalette },
{ testCursorAnim, "Animated cursor (variable size and hotspot)", testCursorAnim }
};
/*
* selectTest --
*
* Switch to a new current test case. Hilight the new test, un-hilight
* the old one, and call the new test's function.
*/
void
selectTest(int newTest)
{
if (newTest < 0) {
newTest += arraysize(gTestCases);
} else if (newTest >= arraysize(gTestCases)) {
newTest -= arraysize(gTestCases);
}
if (currentTest != newTest) {
if (currentTest >= 0) {
ScreenDraw_Border(testListX,
testListY + testListItemHeight * currentTest,
myScreen.size.width - testListX,
testListY + testListItemHeight * (currentTest + 1),
0x000000, 2);
}
currentTest = newTest;
ScreenDraw_Border(testListX,
testListY + testListItemHeight * currentTest,
myScreen.size.width - testListX,
testListY + testListItemHeight * (currentTest + 1),
0xFFFF00, 2);
gTestCases[newTest].fn();
}
}
/*
* allocNoise --
*
* Allocates a new GMR, and fills it with random noise.
*/
static void
allocNoise(void)
{
const uint32 numPages = 500;
const uint32 numWords = numPages * PAGE_SIZE / sizeof(uint32);
PPN pages = GMR_DefineContiguous(GMRID_NOISE, numPages);
uint32 *ptr = PPN_POINTER(pages);
int i;
init_genrand(0);
for (i = 0; i < numWords; i++) {
ptr[i] = genrand_int32();
}
}
/*
* prepareNoiseRect --
*
* Prepare some noise as the source for a blit.
* This defines the GMRFB, and generates a random source origin.
*/
static void
prepareNoiseRect(SVGASignedPoint *origin) // OUT
{
const uint32 bytesPerLine = 512;
static const SVGAGMRImageFormat format = {{{ 32, 24 }}};
const SVGAGuestPtr gPtr = { GMRID_NOISE, 0 };
const uint32 rand = genrand_int32();
Screen_DefineGMRFB(gPtr, bytesPerLine, format);
origin->x = rand & 0x7F;
origin->y = (rand >> 8) & 0x7F;
}
/*
* main --
*
* Initialization and main loop. This reads a global array of test
* cases, and presents a menu which cycles through them. The main
* loop services keyboard and mouse input, and draws an animated test
* pattern for testing cursor interaction with the base layer.
*/
int
main(void)
{
Intr_Init();
Intr_SetFaultHandlers(SVGA_DefaultFaultHandler);
Timer_InitPIT(PIT_HZ / FRAME_RATE);
Intr_SetMask(PIT_IRQ, TRUE);
SVGA_Init();
GMR_Init();
Keyboard_Init();
VMBackdoor_MouseInit(TRUE);
Heap_Reset();
SVGA_SetMode(0, 0, 32);
Screen_Init();
ScreenDraw_Init(GMRID_SCREEN_DRAW);
allocNoise();
2011-09-19 08:21:29 -05:00
Screen_Create(&myScreen);
/*
* Draw the menu of test modes.
*/
ScreenDraw_SetScreen(myScreen.id, myScreen.size.width, myScreen.size.height);
Console_Clear();
ScreenDraw_Border(0, 0, myScreen.size.width, myScreen.size.height, 0x808080, 1);
Console_WriteString("Cursor tests:\n"
"Select with up/down arrows. "
"Move cursor with mouse or WASD keys.\n");
for (currentTest = 0; currentTest < arraysize(gTestCases); currentTest++) {
Console_MoveTo(testListX + 2, testListY + testListItemHeight * currentTest + 2);
Console_Format("%d. %s", currentTest + 1, gTestCases[currentTest].title);
}
/*
* Draw a white square on the right side of the menu, so we can see
* what the cursors look like on a solid white background.
*/
ScreenDraw_Rectangle(myScreen.size.width - testListX + 10,
testListY,
myScreen.size.width - 10,
myScreen.size.height - 10,
0xFFFFFF);
/*
* Main loop.
*/
selectTest(0);
while (1) {
int prevTest = currentTest - 1;
int nextTest = currentTest + 1;
static VMMousePacket mouseState;
const int kbdMouseSpeed = 100;
Bool needCursorUpdate = FALSE;
while (Keyboard_IsKeyPressed(KEY_UP)) {
selectTest(prevTest);
}
while (Keyboard_IsKeyPressed(KEY_DOWN)) {
selectTest(nextTest);
}
while (VMBackdoor_MouseGetPacket(&mouseState)) {
needCursorUpdate = TRUE;
}
if (Keyboard_IsKeyPressed('w')) {
mouseState.y -= kbdMouseSpeed;
needCursorUpdate = TRUE;
}
if (Keyboard_IsKeyPressed('s')) {
mouseState.y += kbdMouseSpeed;
needCursorUpdate = TRUE;
}
if (Keyboard_IsKeyPressed('a')) {
mouseState.x -= kbdMouseSpeed;
needCursorUpdate = TRUE;
}
if (Keyboard_IsKeyPressed('d')) {
mouseState.x += kbdMouseSpeed;
needCursorUpdate = TRUE;
}
if (needCursorUpdate) {
/*
* Send a cursor position update. In order to test the SVGA
* device's cursor screen ID support, we alternate between
* sending cursor updates in virtual coordinates and in
* screen-relative coordinates.
*
* If all is well, cursor movement should still be smooth. If
* there's a bug in decoding, the cursor will jitter as it's
* moved, or the cursor may flicker if it's moved over an
* animated region like the static bar on the left side of
* the screen.
*/
/*
* Fixed-point to pixels.
*/
SVGASignedPoint pixelLocation = {
mouseState.x * myScreen.size.width / 65535,
mouseState.y * myScreen.size.height / 65535
};
uint32 screenId;
static Bool toggle;
if (toggle) {
screenId = SVGA_ID_INVALID;
pixelLocation.x += myScreen.root.x;
pixelLocation.y += myScreen.root.y;
toggle = FALSE;
} else {
screenId = myScreen.id;
toggle = TRUE;
}
SVGA_MoveCursor(TRUE, pixelLocation.x, pixelLocation.y, screenId);
}
/*
* Draw some noise on the side of the screen, for testing overlay compositing.
*/
SVGASignedPoint srcOrigin;
SVGASignedRect noiseRect = {
10, testListY, testListX - 10, myScreen.size.height - 10,
};
prepareNoiseRect(&srcOrigin);
Screen_BlitFromGMRFB(&srcOrigin, &noiseRect, myScreen.id);
/*
* Some tests are animated...
*/
if (gTestCases[currentTest].animateFn) {
gTestCases[currentTest].animateFn();
}
/*
* Wait for the next frame.
*/
Intr_Halt();
}
return 0;
}