void GLRender::drawTexture(GLfloat x1, GLfloat y1, GLfloat x2, GLfloat y2, const CString& key, GLCamera* camera) {
GLCamera* cam = (camera != NULL) ? camera : this->cameras->gui;
cam->update();
GLfloat* projection16fv = cam->projection16fv.v;
if (shaderSquareTexture == NULL)
return;
enableBlend();
glUseProgram(shaderSquareTexture->program);
glUniformMatrix4fv(shaderSquareTexture->uLayerProjectionMatrix, 1, GL_FALSE, projection16fv);
glBindBuffer(GL_ARRAY_BUFFER, m_squareBuffer);
glBufferData(GL_ARRAY_BUFFER, 8 * sizeof(GLfloat), makeRect(x1, y1, x2, y2), GL_DYNAMIC_DRAW);
glVertexAttribPointer(shaderSquareTexture->aVertexPosition, 2, GL_FLOAT, GL_FALSE, 0, NULL);
glEnableVertexAttribArray(shaderSquareTexture->aVertexPosition);
glBindBuffer(GL_ARRAY_BUFFER, m_textureBuffer);
glBufferData(GL_ARRAY_BUFFER, 8 * sizeof(GLfloat), makeRect(0, 0, 1, 1), GL_DYNAMIC_DRAW);
glVertexAttribPointer(shaderSquareTexture->aTextureCoord, 2, GL_FLOAT, GL_FALSE, 0, NULL);
glEnableVertexAttribArray(shaderSquareTexture->aTextureCoord);
GLuint index = textures->get((wchar_t*)key)->bind(0, shaderSquareTexture->uTexture);
glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
glDisableVertexAttribArray(shaderSquareTexture->aVertexPosition);
glDisableVertexAttribArray(shaderSquareTexture->aTextureCoord);
cleanup(index);
}
void GLRender::drawRect(GLfloat x1, GLfloat y1, GLfloat x2, GLfloat y2, const GLPaint& paint, GLCamera* camera) {
GLCamera* cam = (camera != NULL) ? camera : this->cameras->gui;
cam->update();
GLfloat* projection16fv = cam->projection16fv.v;
if (((paint.m_color & 0xFF000000) != 0) && (shaderSquareFill != NULL)) {
if ((paint.m_color & 0xFF000000) != 0xFF000000)
enableBlend();
else
disableBlend();
glUseProgram(shaderSquareFill->program);
glUniformMatrix4fv(shaderSquareFill->uLayerProjectionMatrix, 1, GL_FALSE, projection16fv);
GLfloat* c = makeColor(&paint.m_color, 1);
glUniform4fv(shaderSquareFill->uColor, 1, c);
glBindBuffer(GL_ARRAY_BUFFER, m_squareBuffer);
glBufferData(GL_ARRAY_BUFFER, 8 * sizeof(GLfloat), makeRect(x1, y1, x2, y2), GL_DYNAMIC_DRAW);
glVertexAttribPointer(shaderSquareFill->aVertexPosition, 2, GL_FLOAT, GL_FALSE, 0, NULL);
glEnableVertexAttribArray(shaderSquareFill->aVertexPosition);
glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
glDisableVertexAttribArray(shaderSquareFill->aVertexPosition);
glUseProgram(0);
}
if (((paint.m_strokeColor & 0xFF000000) != 0) && (shaderSquareStroke != NULL)) {
enableBlend();
glUseProgram(shaderSquareStroke->program);
glUniformMatrix4fv(shaderSquareStroke->uLayerProjectionMatrix, 1, GL_FALSE, projection16fv);
GLfloat half = floorf((GLfloat)(paint.m_strokeWidth) / 2.0f);
GLfloat corners[4] = { x1 - half, y1 - half, x2 + half, y2 + half };
glUniform2fv(shaderSquareStroke->uCorners, 2, corners);
glUniform1f(shaderSquareStroke->uBorder, paint.m_strokeWidth);
GLfloat* c = makeColor(&paint.m_strokeColor, 1);
glUniform4fv(shaderSquareStroke->uColor, 1, c);
glBindBuffer(GL_ARRAY_BUFFER, m_squareBuffer);
glBufferData(GL_ARRAY_BUFFER, 8 * sizeof(GLfloat), makeRect(x1-half, y1-half, x2+half, y2+half), GL_DYNAMIC_DRAW);
glVertexAttribPointer(shaderSquareStroke->aVertexPosition, 2, GL_FLOAT, GL_FALSE, 0, NULL);
glEnableVertexAttribArray(shaderSquareStroke->aVertexPosition);
glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
glDisableVertexAttribArray(shaderSquareStroke->aVertexPosition);
glUseProgram(0);
}
}
void Surface::box(Uint32 color, SDL_Rect *rect, int thickness){
if (!rect)
return;
SDL_Rect &r = *rect;
int half = thickness/2;
SDL_FillRect(surface_, &makeRect(r.x - half, r.y - half, r.w + thickness, thickness), color); //u
SDL_FillRect(surface_, &makeRect(r.x - half, r.y + r.h - half, r.w + thickness, thickness), color); //d
SDL_FillRect(surface_, &makeRect(r.x - half, r.y - half, thickness, r.h + thickness), color); //l
SDL_FillRect(surface_, &makeRect(r.x + r.w - half, r.y - half, thickness, r.h + thickness), color); //r
}
node *readNode(int address){
++reads;
FILE *f;
node *n;
int child,size,leaf,i;
float x1,x2,y1,y2;
char filename[20];
sprintf(filename,"%s/%d",path,address);
errno = 0;
f=fopen(filename,"rb");
if(f == NULL){
fprintf(stderr, "Error al leer el archivo %s: %s\n", filename, strerror(errno));
exit(1);
}
n=new(node);
n->address=address;
for(i = 0; i < 2*b+1; i++)
n->values[i]=NULL;
//size,leaf
fread(&size,4, 1, f);
fread(&leaf,4, 1, f);
n->leaf = leaf;
n->size = size;
//mbr
fread(&x1, 4, 1, f);
fread(&y1, 4, 1, f);
fread(&x2, 4, 1 ,f);
fread(&y2, 4, 1, f);
n->MBR = makeRect(x1,y1,x2,y2);
int a;
for(i=0;i<size;i++){
fread(&x1, 4, 1, f);
fread(&y1, 4, 1, f);
fread(&x2, 4, 1 ,f);
fread(&y2, 4, 1, f);
fread(&child, 4, 1, f);
n->values[i] = new(nodeVal);
n->values[i]->r = makeRect(x1,y1,x2,y2);
n->values[i]->child = child;
}
fclose(f);
return n;
}
GXRect operator-(const GXRect& lhs, const GXPoint& rhs)
{
return makeRect(lhs.origin.x - rhs.x,
lhs.origin.y - rhs.y,
lhs.size.width ,
lhs.size.height);
}
GXRect operator+(const GXRect& lhs, const GXPoint& rhs)
{
return makeRect(lhs.origin.x + rhs.x,
lhs.origin.y + rhs.y,
lhs.size.width ,
lhs.size.height );// GXRect { lhs.origin + rhs , lhs.size + rhs };
}
void GLRender::drawEffectMobile(GLfloat x1, GLfloat y1, GLfloat x2, GLfloat y2, const CString& key, GLfloat localTime, GLfloat worldTime) {
GLCamera* cam = this->cameras->gui;
cam->update();
GLfloat* projection16fv = cam->projection16fv.v;
GLShader* shader;
try {
shader = shaders->get(key);
} catch (...) {
return;
}
GLuint program = shader->program;
GLuint uLayerProjectionMatrix = (GLuint)glGetUniformLocation(program, "uLayerProjectionMatrix");
GLuint aVertexPosition = (GLuint)glGetAttribLocation(program, "aVertexPosition");
GLuint aTextureCoord = (GLuint)glGetAttribLocation(program, "aTextureCoord");
GLuint uTime = (GLuint)glGetUniformLocation(program, "uTime");
GLuint uTexture0 = (GLuint)glGetUniformLocation(program, "uTexture0");
GLuint uTexture1 = (GLuint)glGetUniformLocation(program, "uTexture1");
static Vector<GLint> effectTexturesVector = Vector<GLint>(2);
static GLint* effectTextures = effectTexturesVector.items();
effectTextures[0] = uTexture0;
effectTextures[1] = uTexture1;
enableBlend();
GLuint index = shader->bind(0, effectTexturesVector);
glUniform2f(uTime, localTime - floorf(localTime), worldTime - floorf(worldTime));
glUniformMatrix4fv(uLayerProjectionMatrix, 1, GL_FALSE, projection16fv);
glBindBuffer(GL_ARRAY_BUFFER, m_squareBuffer);
glBufferData(GL_ARRAY_BUFFER, 8 * sizeof(GLfloat), makeRect(x1, y1, x2, y2), GL_DYNAMIC_DRAW);
glVertexAttribPointer(aVertexPosition, 2, GL_FLOAT, GL_FALSE, 0, NULL);
glEnableVertexAttribArray(aVertexPosition);
glBindBuffer(GL_ARRAY_BUFFER, m_textureBuffer);
glBufferData(GL_ARRAY_BUFFER, 8 * sizeof(GLfloat), makeRect(0, 0, 1, 1), GL_DYNAMIC_DRAW);
glVertexAttribPointer(aTextureCoord, 2, GL_FLOAT, GL_FALSE, 0, NULL);
glEnableVertexAttribArray(aTextureCoord);
glDrawArrays(GL_TRIANGLE_STRIP, 0, 4);
glDisableVertexAttribArray(aVertexPosition);
glDisableVertexAttribArray(aTextureCoord);
cleanup(index);
}
SkRRect makeRRect() {
SkRRect rrect;
RandomSetRRect rrectType = makeSetRRectType();
if (fPrintName) {
SkDebugf("%.*s%s\n", fPathDepth * 3, fTab, gRandomSetRRectNames[rrectType]);
}
switch (rrectType) {
case kSetEmpty:
rrect.setEmpty();
break;
case kSetRect: {
SkRect rect = makeRect();
rrect.setRect(rect);
}
break;
case kSetOval: {
SkRect oval = makeRect();
rrect.setOval(oval);
}
break;
case kSetRectXY: {
SkRect rect = makeRect();
SkScalar xRad = makeScalar();
SkScalar yRad = makeScalar();
rrect.setRectXY(rect, xRad, yRad);
}
break;
case kSetNinePatch: {
SkRect rect = makeRect();
SkScalar leftRad = makeScalar();
SkScalar topRad = makeScalar();
SkScalar rightRad = makeScalar();
SkScalar bottomRad = makeScalar();
rrect.setNinePatch(rect, leftRad, topRad, rightRad, bottomRad);
SkDebugf(""); // keep locals in scope
}
break;
case kSetRectRadii: {
SkRect rect = makeRect();
SkVector radii[4];
makeVectorArray(SK_ARRAY_COUNT(radii), radii);
rrect.setRectRadii(rect, radii);
}
break;
}
return rrect;
}
GXRect operator-=(const GXRect& lhs, const GXPoint& rhs)
{
// return GXRect { lhs.origin - rhs , lhs.size - rhs };
return makeRect(lhs.origin.x - rhs.x,
lhs.origin.y - rhs.y,
lhs.size.width ,
lhs.size.height );
}
void refreshMBR(node *n){
int i;
freeRect(n->MBR);
if(n->size==0){
n->MBR=makeRect(0,0,0,0);
return;
}
n->MBR = dupRect(n->values[0]->r);
for(i=1; i < n->size; ++i)
increaseMBR(n->MBR, n->values[i]->r);
}
void MessageBox::draw() const{
if (visible_)
if (message_ != ""){
assert (screenBuf);
//message surface
Surface text(font_, message_, color_);
pixels_t width = text->clip_rect.w + margin_;
//background
if (background_) {
SDL_Rect rect1 = makeRect(x_ - margin_, y_ - margin_);
SDL_Rect rect2 = makeRect(0, 0, width, height_);
background_.draw(screenBuf,
&rect1,
&rect2);
}
//message
SDL_Rect rect = makeRect(x_ + margin_, y_ + margin_);
text.draw(screenBuf, &rect);
}
}
void RenderQueue::addText(int16 x, int16 y, byte color, uint fontResIndex, byte *text, int len) {
Font font(_vm->_res->load(fontResIndex)->data);
RenderQueueItem item;
item.type = kText;
item.flags = kRefresh;
item.rect = makeRect(x, y, font.getTextWidth(text), font.getHeight());
item.priority = 1000;
item.text.color = color;
item.text.fontResIndex = fontResIndex;
item.text.text = text;
item.text.len = len;
_currQueue->push_back(item);
}
void RenderQueue::addMask(SegmapMaskRect &mask) {
RenderQueueItem item;
item.type = kMask;
item.flags = kRefresh;
item.rect = makeRect(mask.x - _vm->_cameraX, mask.y - _vm->_cameraY, mask.width, mask.height);
item.priority = mask.priority;
item.mask = mask;
// Only add the mask if a sprite intersects its rect
if (rectIntersectsItem(item.rect)) {
RenderQueueArray::iterator iter = _currQueue->begin();
while (iter != _currQueue->end() && (*iter).priority <= item.priority) {
iter++;
}
_currQueue->insert(iter, item);
}
}
void RenderQueue::addSprite(SpriteDrawItem &sprite) {
RenderQueueItem item;
item.type = kSprite;
item.flags = kRefresh;
item.rect = makeRect(sprite.x - _vm->_cameraX, sprite.y - _vm->_cameraY, sprite.width, sprite.height);
item.priority = sprite.priority;
item.sprite = sprite;
item.sprite.x -= _vm->_cameraX;
item.sprite.y -= _vm->_cameraY;
// Add sprite sorted by priority
RenderQueueArray::iterator iter = _currQueue->begin();
while (iter != _currQueue->end() && (*iter).priority <= item.priority) {
iter++;
}
_currQueue->insert(iter, item);
}
void MapperRoomRender::fillWhite(int x, int y, int dx, int dy)
{
RECT p; makeRect(x,y,dx,dy,&p);
m_hdc.FillRect(&p, m_whiteBkg);
}
SDL_Rect Vampire::drawRect() const{
return makeRect(-64, -120, 128, 128);
}
SDL_Rect Vampire::collisionRect() const{
return makeRect(-20, -20, 40, 40);
}
SkPath makePath() {
SkPath path;
for (uint32_t cIndex = 0; cIndex < fPathContourCount; ++cIndex) {
uint32_t segments = makeSegmentCount();
for (uint32_t sIndex = 0; sIndex < segments; ++sIndex) {
RandomAddPath addPathType = makeAddPathType();
++fAddCount;
if (fPrintName) {
SkDebugf("%.*s%s\n", fPathDepth * 3, fTab,
gRandomAddPathNames[addPathType]);
}
switch (addPathType) {
case kAddArc: {
SkRect oval = makeRect();
SkScalar startAngle = makeAngle();
SkScalar sweepAngle = makeAngle();
path.addArc(oval, startAngle, sweepAngle);
validate(path);
} break;
case kAddRoundRect1: {
SkRect rect = makeRect();
SkScalar rx = makeScalar(), ry = makeScalar();
SkPath::Direction dir = makeDirection();
path.addRoundRect(rect, rx, ry, dir);
validate(path);
} break;
case kAddRoundRect2: {
SkRect rect = makeRect();
SkScalar radii[8];
makeScalarArray(SK_ARRAY_COUNT(radii), radii);
SkPath::Direction dir = makeDirection();
path.addRoundRect(rect, radii, dir);
validate(path);
} break;
case kAddRRect: {
SkRRect rrect = makeRRect();
SkPath::Direction dir = makeDirection();
path.addRRect(rrect, dir);
validate(path);
} break;
case kAddPoly: {
SkTDArray<SkPoint> points;
makePointArray(&points);
bool close = makeBool();
path.addPoly(&points[0], points.count(), close);
validate(path);
} break;
case kAddPath1:
if (fPathDepth < fPathDepthLimit) {
++fPathDepth;
SkPath src = makePath();
validate(src);
SkScalar dx = makeScalar();
SkScalar dy = makeScalar();
SkPath::AddPathMode mode = makeAddPathMode();
path.addPath(src, dx, dy, mode);
--fPathDepth;
validate(path);
}
break;
case kAddPath2:
if (fPathDepth < fPathDepthLimit) {
++fPathDepth;
SkPath src = makePath();
validate(src);
SkPath::AddPathMode mode = makeAddPathMode();
path.addPath(src, mode);
--fPathDepth;
validate(path);
}
break;
case kAddPath3:
if (fPathDepth < fPathDepthLimit) {
++fPathDepth;
SkPath src = makePath();
validate(src);
SkMatrix matrix = makeMatrix();
SkPath::AddPathMode mode = makeAddPathMode();
path.addPath(src, matrix, mode);
--fPathDepth;
validate(path);
}
break;
case kReverseAddPath:
if (fPathDepth < fPathDepthLimit) {
++fPathDepth;
SkPath src = makePath();
validate(src);
path.reverseAddPath(src);
--fPathDepth;
validate(path);
}
break;
case kMoveToPath: {
SkScalar x = makeScalar();
SkScalar y = makeScalar();
path.moveTo(x, y);
validate(path);
} break;
case kRMoveToPath: {
SkScalar x = makeScalar();
SkScalar y = makeScalar();
path.rMoveTo(x, y);
validate(path);
} break;
case kLineToPath: {
SkScalar x = makeScalar();
SkScalar y = makeScalar();
path.lineTo(x, y);
validate(path);
} break;
case kRLineToPath: {
SkScalar x = makeScalar();
SkScalar y = makeScalar();
path.rLineTo(x, y);
validate(path);
} break;
case kQuadToPath: {
SkPoint pt[2];
makePointArray(SK_ARRAY_COUNT(pt), pt);
path.quadTo(pt[0], pt[1]);
validate(path);
} break;
case kRQuadToPath: {
SkPoint pt[2];
makePointArray(SK_ARRAY_COUNT(pt), pt);
path.rQuadTo(pt[0].fX, pt[0].fY, pt[1].fX, pt[1].fY);
validate(path);
} break;
case kConicToPath: {
SkPoint pt[2];
makePointArray(SK_ARRAY_COUNT(pt), pt);
SkScalar weight = makeScalar();
path.conicTo(pt[0], pt[1], weight);
validate(path);
} break;
case kRConicToPath: {
SkPoint pt[2];
makePointArray(SK_ARRAY_COUNT(pt), pt);
SkScalar weight = makeScalar();
path.rConicTo(pt[0].fX, pt[0].fY, pt[1].fX, pt[1].fY, weight);
validate(path);
} break;
case kCubicToPath: {
SkPoint pt[3];
makePointArray(SK_ARRAY_COUNT(pt), pt);
path.cubicTo(pt[0], pt[1], pt[2]);
validate(path);
} break;
case kRCubicToPath: {
SkPoint pt[3];
makePointArray(SK_ARRAY_COUNT(pt), pt);
path.rCubicTo(pt[0].fX, pt[0].fY, pt[1].fX, pt[1].fY, pt[2].fX, pt[2].fY);
validate(path);
} break;
case kArcToPath: {
SkPoint pt[2];
makePointArray(SK_ARRAY_COUNT(pt), pt);
SkScalar radius = makeScalar();
path.arcTo(pt[0], pt[1], radius);
validate(path);
} break;
case kArcTo2Path: {
SkRect oval = makeRect();
SkScalar startAngle = makeAngle();
SkScalar sweepAngle = makeAngle();
bool forceMoveTo = makeBool();
path.arcTo(oval, startAngle, sweepAngle, forceMoveTo);
validate(path);
} break;
case kClosePath:
path.close();
validate(path);
break;
}
}
}
return path;
}
void Vampire::draw(Point offset, Surface &surface) const{
if (!visible)
return;
// Draw attack under vampire sprite
smallAttack.draw(offset, surface);
batAttack.draw(offset, surface);
// Vampire sprite
const Surface *image = 0;
switch (dir){
case DIR_E:
switch (state){
case IDLE:
image = idleE; break;
case MOVING:
image = movingE; break;
case ATTACKING:
image = attackingE; break;
case BURNING:
image = burningR; break;
}
break;
case DIR_F:
switch (state){
case IDLE:
image = idleF; break;
case MOVING:
image = movingF; break;
case ATTACKING:
image = attackingF; break;
case BURNING:
image = burningR; break;
}
break;
case DIR_G:
switch (state){
case IDLE:
image = idleG; break;
case MOVING:
image = movingG; break;
case ATTACKING:
image = attackingG; break;
case BURNING:
image = burningL; break;
}
break;
case DIR_H:
switch (state){
case IDLE:
image = idleH; break;
case MOVING:
image = movingH; break;
case ATTACKING:
image = attackingH; break;
case BURNING:
image = burningL; break;
}
break;
default:
// Should not happen
assert(false);
break;
}
assert(image);
size_t col = 0, row = 0;
switch (state){
case IDLE:
row = frame / idleColumns;
col = frame % idleColumns;
break;
case MOVING:
row = frame / movingColumns;
col = frame % movingColumns;
break;
case ATTACKING:
row = frame / attackingColumns;
col = frame % attackingColumns;
break;
case BURNING:
row = frame / burningColumns;
col = frame % burningColumns;
debug("Burning; frame=", frame);
break;
default:
// Should not happen
assert(false);
break;
}
SDL_Rect srcRect;
srcRect.w = srcRect.h = 128;
image->draw(screenBuf, &getDrawRect(offset), &makeRect(col * 128, row * 128, 128, 128));
// Entity debug
Entity::draw(offset, surface);
}
/**
Retrieves the actual dimensions of text.
@param text text.
@return dimensions.
*/
Rect<int> getDimensions(const char *text) const {
int x, y, w, h;
al_get_text_dimensions(get(), text, &x, &y, &w, &h);
return makeRect(makePoint(x, y), makeSize(w, h));
}
/**
Retrieves the actual dimensions of text.
@param text text.
@return dimensions.
*/
Rect<int> getDimensions(const String &text) const {
int x, y, w, h;
al_get_ustr_dimensions(get(), text.get(), &x, &y, &w, &h);
return makeRect(makePoint(x, y), makeSize(w, h));
}
//! constructor
CGUIPlot::CGUIPlot(
scene::ISceneManager* smgr,
IGUIEnvironment* env,
IGUIElement* parent,
s32 id,
const core::rect<s32>& rectangle)
: IGUIElement( EGUIET_ELEMENT, env, parent, id, rectangle)
//, Viewport(0,0,0,0)
, ZoomRect(-1,-4,10,5)
, Plotrect(0,0,0,0)
, IsDrawBackground(false)
, BackgroundColor(video::SColor(255,255,255,255))
, TextColor(video::SColor(255,0,0,0))
, IsDrawGrid(true)
, GridColor(video::SColor(255,200,200,200))
, SubGridColor(video::SColor(255,235,235,235))
, SceneManager(smgr)
, Root(0)
, Camera(0)
{
#ifdef _DEBUG
setDebugName("CGUIPlot");
#endif
// this element can be tabbed to
setTabStop(false);
setTabOrder(-1);
IGUISkin *skin = 0;
if (Environment)
skin = Environment->getSkin();
//FrameRect.UpperLeftCorner.X += skin->getSize(EGDS_TEXT_DISTANCE_X)+1;
//FrameRect.UpperLeftCorner.Y += skin->getSize(EGDS_TEXT_DISTANCE_Y)+1;
//FrameRect.LowerRightCorner.X -= skin->getSize(EGDS_TEXT_DISTANCE_X)+1;
//FrameRect.LowerRightCorner.Y -= skin->getSize(EGDS_TEXT_DISTANCE_Y)+1;
// TextColor=skin->getColor(EGDC_HIGH_LIGHT_TEXT);
s32 w = rectangle.getWidth(); // in pixels
s32 h = rectangle.getHeight(); // in pixels
s32 sb_size = 16; // in pixels
core::recti r_canvas = makeRect(0,0, (u32)(w-sb_size-1), (u32)(h-sb_size-1) );
core::recti r_scrollH = makeRect(1,h-sb_size, (u32)(w-sb_size-1), (u32)sb_size );
core::recti r_scrollV = makeRect( w-sb_size, 1, (u32)sb_size, (u32)(h-sb_size-1) );
core::recti r_reset = makeRect( w-sb_size, h-sb_size, (u32)sb_size, (u32)sb_size );
Plotrect = r_canvas; //! visible ContentRect, Viewport is projected to this rect
ScrollbarH = Environment->addScrollBar(true,r_scrollH,this,-1);
ScrollbarH->setVisible(true);
ScrollbarH->setSubElement(false);
ScrollbarH->setTabStop(false);
ScrollbarH->setAlignment(EGUIA_LOWERRIGHT, EGUIA_LOWERRIGHT, EGUIA_UPPERLEFT, EGUIA_LOWERRIGHT);
ScrollbarH->setSmallStep(3);
ScrollbarH->setMin(0);
ScrollbarH->setMax(100);
ScrollbarH->setPos(0);
ScrollbarV = Environment->addScrollBar(false,r_scrollV,this,-1);
ScrollbarV->setVisible(true);
ScrollbarV->setSubElement(false);
ScrollbarV->setTabStop(false);
ScrollbarV->setAlignment(EGUIA_LOWERRIGHT, EGUIA_LOWERRIGHT, EGUIA_UPPERLEFT, EGUIA_LOWERRIGHT);
ScrollbarV->setMin(0);
ScrollbarV->setMax(100);
ScrollbarV->setSmallStep(3);
ScrollbarV->setPos(0);
Environment->addButton( r_reset, this, -1, L"R", L"Reset Zoom Button");
BackgroundColor=skin->getColor(EGDC_WINDOW);
ContentPane = 0;
Environment->setFocus(this);
//
// SceneManager = new scene::CSceneManager(
// Environment->getVideoDriver(), Environment->getFileSystem(), 0, 0, Environment);
_IRR_DEBUG_BREAK_IF( !SceneManager )
// if (!SceneManager)
// {
// printf("CGUIPlot::Could not create SceneManager\n");
// return;
// }
Root = SceneManager->addEmptySceneNode( SceneManager->getRootSceneNode(), -1);
_IRR_DEBUG_BREAK_IF( !Root )
Camera = SceneManager->addCameraSceneNode( Root, core::vector3df(0,0,-100), core::vector3df(0,0,100), -1, false);
_IRR_DEBUG_BREAK_IF( !Camera )
Root->setVisible( false );
/// Prepare some SceneNodes for x,y Axis and Grid
//scene::ISceneManager* SceneManager = SceneManager;
gui::IGUIFont* font = Environment->getBuiltInFont();
scene::ITextSceneNode* textNode00 = SceneManager->addTextSceneNode(
font, L"(0,0)", TextColor, SceneManager->getRootSceneNode(), core::vector3df(0,0,0) );
scene::ITextSceneNode* textNodeX = SceneManager->addTextSceneNode(
font, L"X", TextColor, SceneManager->getRootSceneNode(), core::vector3df(ZoomRect.LowerRightCorner.X,0,0) );
scene::ITextSceneNode* textNodeY = SceneManager->addTextSceneNode(
font, L"Y", TextColor, SceneManager->getRootSceneNode(), core::vector3df(0, ZoomRect.UpperLeftCorner.Y,0) );
addShape( textNode00, L"Ursprung" );
addShape( textNodeX, L"X-Axis" );
addShape( textNodeY, L"Y-Axis" );
}
void MapperRoomRender::fillExit(int x, int y, int dx, int dy)
{
RECT p; makeRect(x,y,dx,dy,&p);
m_hdc.FillRect(&p, m_exitBkg);
}
sm501alpha_t::sm501alpha_t(
mode_t mode,
unsigned x,
unsigned y,
unsigned w,
unsigned h )
: mode_( mode )
, fd_( open( "/dev/" SM501ALPHA_CLASS, O_RDWR ) )
, pos_( makeRect(0,0,0,0) )
, ram_( 0 )
, ramOffs_( 0 )
{
if( isOpen() ){
fcntl( fd_, F_SETFD, FD_CLOEXEC);
fbDevice_t &fb = getFB();
if( 0 == w ){
w = fb.getWidth();
if( 0 != x )
w -= x ;
}
if( 0 == h ){
h = fb.getHeight();
if( 0 != y )
h -= y ;
}
struct sm501_alphaPlane_t plane ;
plane.xLeft_ = pos_.xLeft_ = x ;
plane.yTop_ = pos_.yTop_ = y ;
plane.width_ = pos_.width_ = w ;
plane.height_ = pos_.height_ = h ;
plane.mode_ = mode ;
plane.planeOffset_ = 0 ;
unsigned short const adder = (2<<11)|(4<<5)|2 ;
unsigned short *outWords = (unsigned short *)plane.palette_ ;
unsigned short palVal = 0 ;
// printf( "color palette:\n" );
for( unsigned i = 0 ; i < 16 ; i++ ){
// printf( " %04x\n", palVal );
*outWords++ = palVal ;
palVal += adder ;
}
outWords[-1] = 0xFFFF ; // make it truly white
int rval = ioctl( fd_, SM501ALPHA_SETPLANE, &plane );
if( 0 == rval ){
unsigned bytes = plane.width_*plane.height_*2 ;
printf( "mapping %u bytes of RAM\n", bytes );
ram_ = (unsigned char *)mmap( 0, bytes, PROT_READ|PROT_WRITE, MAP_SHARED, fd_, 0 );
if( MAP_FAILED == ram_ ){
perror( "mmap sm501alpha" );
ram_ = 0 ;
}
ramOffs_ = plane.planeOffset_ ;
return ;
}
else
perror( "SM501ALPHA_SETPLANE" );
close( fd_ );
fd_ = 0 ;
}
}
void MapperRoomRender::fillBlack(int x, int y, int dx, int dy)
{
RECT p; makeRect(x,y,dx,dy,&p);
m_hdc.FillRect(&p, m_blackBkg);
}
void MapperRoomRender::fillColor(int x, int y, int dx, int dy, COLORREF color)
{
RECT p; makeRect(x, y, dx, dy, &p);
m_hdc.FillSolidRect(&p, color);
}
