axmol/extensions/fairygui/display/FUISprite.cpp

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#include "FUISprite.h"
NS_FGUI_BEGIN
USING_NS_CC;
#define kProgressTextureCoordsCount 4
// kProgressTextureCoords holds points {0,1} {0,0} {1,0} {1,1} we can represent it as bits
const char kProgressTextureCoords = 0x4b;
Texture2D* FUISprite::_empty = nullptr;
FUISprite::FUISprite()
: _fillMethod(FillMethod::None),
_fillOrigin(FillOrigin::Left),
_fillAmount(0),
_fillClockwise(false),
_vertexDataCount(0),
_vertexData(nullptr),
_vertexIndex(nullptr),
_scaleByTile(false)
{
}
FUISprite::~FUISprite()
{
CC_SAFE_FREE(_vertexData);
CC_SAFE_FREE(_vertexIndex);
}
void FUISprite::clearContent()
{
setTexture(nullptr);
CC_SAFE_RELEASE_NULL(_spriteFrame);
setCenterRectNormalized(Rect(0, 0, 1, 1));
_empty = _texture;
}
void FUISprite::setScale9Grid(Rect* value)
{
if (value == nullptr)
{
setCenterRectNormalized(Rect(0, 0, 1, 1));
return;
}
Rect insets = *value;
// When Insets == Zero --> we should use a 1/3 of its untrimmed size
if (insets.equals(Rect::ZERO))
{
insets = Rect(_originalContentSize.width / 3.0f,
_originalContentSize.height / 3.0f,
_originalContentSize.width / 3.0f,
_originalContentSize.height / 3.0f);
}
// emulate invalid insets. shouldn't be supported, but the original code supported it.
if (insets.origin.x > _originalContentSize.width)
insets.origin.x = 0;
if (insets.origin.y > _originalContentSize.height)
insets.origin.y = 0;
if (insets.size.width > _originalContentSize.width)
insets.size.width = 1;
if (insets.size.height > _originalContentSize.height)
insets.size.height = 1;
// we have to convert from untrimmed to trimmed
// Sprite::setCenterRect is using trimmed values (to be compatible with Cocos Creator)
// Scale9Sprite::setCapInsects uses untrimmed values (which makes more sense)
// use _rect coordinates. recenter origin to calculate the
// intersecting rectangle
// can't use _offsetPosition since it is calculated using bottom-left as origin,
// and the center rect is calculated using top-left
insets.origin.x -= (_originalContentSize.width - _rect.size.width) / 2 + _unflippedOffsetPositionFromCenter.x;
insets.origin.y -= (_originalContentSize.height - _rect.size.height) / 2 - _unflippedOffsetPositionFromCenter.y;
// intersecting rectangle
const float x1 = std::max(insets.origin.x, 0.0f);
const float y1 = std::max(insets.origin.y, 0.0f);
const float x2 = std::min(insets.origin.x + insets.size.width, 0.0f + _rect.size.width);
const float y2 = std::min(insets.origin.y + insets.size.height, 0.0f + _rect.size.height);
// centerRect uses the trimmed frame origin as 0,0.
// so, recenter inset rect
insets.setRect(x1,
y1,
x2 - x1,
y2 - y1);
// Only update center rect while in slice mode.
setCenterRect(insets);
}
void FUISprite::setScaleByTile(bool value)
{
_scaleByTile = value;
}
void FUISprite::setGrayed(bool value)
{
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#if defined(ADXE_VERSION)
Sprite::setProgramState(value ? backend::ProgramType::GRAY_SCALE : backend::ProgramType::POSITION_TEXTURE_COLOR);
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#elif COCOS2D_VERSION >= 0x00040000
auto isETC1 = getTexture() && getTexture()->getAlphaTextureName();
if (value) {
Sprite::updateShaders(positionTextureColor_vert, (isETC1)?etc1Gray_frag:grayScale_frag);
} else {
Sprite::updateShaders(positionTextureColor_vert, (isETC1)?etc1_frag:positionTextureColor_frag);
}
#else
GLProgramState* glState = nullptr;
if (value)
glState = GLProgramState::getOrCreateWithGLProgramName(GLProgram::SHADER_NAME_POSITION_GRAYSCALE, getTexture());
else
glState = GLProgramState::getOrCreateWithGLProgramName(GLProgram::SHADER_NAME_POSITION_TEXTURE_COLOR_NO_MVP, getTexture());
setGLProgramState(glState);
#endif
}
void FUISprite::setFillMethod(FillMethod value)
{
if (_fillMethod != value)
{
_fillMethod = value;
if (_fillMethod != FillMethod::None)
setupFill();
else
{
CC_SAFE_FREE(_vertexData);
CC_SAFE_FREE(_vertexIndex);
}
}
}
void FUISprite::setFillOrigin(FillOrigin value)
{
if (_fillOrigin != value)
{
_fillOrigin = value;
if (_fillMethod != FillMethod::None)
setupFill();
}
}
void FUISprite::setFillClockwise(bool value)
{
if (_fillClockwise != value)
{
_fillClockwise = value;
if (_fillMethod != FillMethod::None)
setupFill();
}
}
void FUISprite::setFillAmount(float value)
{
if (_fillAmount != value)
{
_fillAmount = value;
if (_fillMethod != FillMethod::None)
setupFill();
}
}
void FUISprite::setContentSize(const Size& size)
{
if (_scaleByTile)
setTextureRect(Rect(Vec2::ZERO, size));
else
Sprite::setContentSize(size);
}
void FUISprite::setupFill()
{
if (_fillMethod == FillMethod::Horizontal || _fillMethod == FillMethod::Vertical)
updateBar();
else
updateRadial();
}
//from CCFUISprite.h
///
// @returns the vertex position from the texture coordinate
///
Tex2F FUISprite::textureCoordFromAlphaPoint(Vec2 alpha)
{
Tex2F ret(0.0f, 0.0f);
V3F_C4B_T2F_Quad quad = getQuad();
Vec2 min(quad.bl.texCoords.u, quad.bl.texCoords.v);
Vec2 max(quad.tr.texCoords.u, quad.tr.texCoords.v);
// Fix bug #1303 so that progress timer handles sprite frame texture rotation
if (isTextureRectRotated())
{
std::swap(alpha.x, alpha.y);
}
return Tex2F(min.x * (1.f - alpha.x) + max.x * alpha.x, min.y * (1.f - alpha.y) + max.y * alpha.y);
}
Vec3 FUISprite::vertexFromAlphaPoint(Vec2 alpha)
{
Vec3 ret(0.0f, 0.0f, 0.0f);
V3F_C4B_T2F_Quad quad = getQuad();
Vec2 min(quad.bl.vertices.x, quad.bl.vertices.y);
Vec2 max(quad.tr.vertices.x, quad.tr.vertices.y);
ret.x = min.x * (1.f - alpha.x) + max.x * alpha.x;
ret.y = min.y * (1.f - alpha.y) + max.y * alpha.y;
return ret;
}
void FUISprite::updateColor(void)
{
Sprite::updateColor();
if (_vertexData)
{
Color4B sc = getQuad().tl.colors;
for (int i = 0; i < _vertexDataCount; ++i)
{
_vertexData[i].colors = sc;
}
}
}
///
// Update does the work of mapping the texture onto the triangles
// It now doesn't occur the cost of free/alloc data every update cycle.
// It also only changes the percentage point but no other points if they have not
// been modified.
//
// It now deals with flipped texture. If you run into this problem, just use the
// sprite property and enable the methods flipX, flipY.
///
void FUISprite::updateRadial(void)
{
float angle = 2.f * ((float)M_PI) * (_fillClockwise ? (1.0f - _fillAmount) : _fillAmount);
// We find the vector to do a hit detection based on the percentage
// We know the first vector is the one @ 12 o'clock (top,mid) so we rotate
// from that by the progress angle around the _midpoint pivot
Vec2 midpoint(0.5f, 0.5f);
Vec2 topMid(0.5f, 1.f);
Vec2 percentagePt = topMid.rotateByAngle(midpoint, angle);
int index = 0;
Vec2 hit;
if (_fillAmount == 0.f)
{
// More efficient since we don't always need to check intersection
// If the alpha is zero then the hit point is top mid and the index is 0.
hit = topMid;
index = 0;
}
else if (_fillAmount == 1.f)
{
// More efficient since we don't always need to check intersection
// If the alpha is one then the hit point is top mid and the index is 4.
hit = topMid;
index = 4;
}
else
{
// We run a for loop checking the edges of the texture to find the
// intersection point
// We loop through five points since the top is split in half
float min_t = FLT_MAX;
for (int i = 0; i <= kProgressTextureCoordsCount; ++i)
{
int pIndex = (i + (kProgressTextureCoordsCount - 1)) % kProgressTextureCoordsCount;
Vec2 edgePtA = boundaryTexCoord(i % kProgressTextureCoordsCount);
Vec2 edgePtB = boundaryTexCoord(pIndex);
// Remember that the top edge is split in half for the 12 o'clock position
// Let's deal with that here by finding the correct endpoints
if (i == 0)
{
edgePtB = edgePtA.lerp(edgePtB, 1 - midpoint.x);
}
else if (i == 4)
{
edgePtA = edgePtA.lerp(edgePtB, 1 - midpoint.x);
}
// s and t are returned by ccpLineIntersect
float s = 0, t = 0;
if (Vec2::isLineIntersect(edgePtA, edgePtB, midpoint, percentagePt, &s, &t))
{
// Since our hit test is on rays we have to deal with the top edge
// being in split in half so we have to test as a segment
if ((i == 0 || i == 4))
{
// s represents the point between edgePtA--edgePtB
if (!(0.f <= s && s <= 1.f))
{
continue;
}
}
// As long as our t isn't negative we are at least finding a
// correct hitpoint from _midpoint to percentagePt.
if (t >= 0.f)
{
// Because the percentage line and all the texture edges are
// rays we should only account for the shortest intersection
if (t < min_t)
{
min_t = t;
index = i;
}
}
}
}
// Now that we have the minimum magnitude we can use that to find our intersection
hit = midpoint + ((percentagePt - midpoint) * min_t);
}
// The size of the vertex data is the index from the hitpoint
// the 3 is for the _midpoint, 12 o'clock point and hitpoint position.
bool sameIndexCount = true;
int triangleCount = 0;
if (_vertexDataCount != index + 3)
{
sameIndexCount = false;
CC_SAFE_FREE(_vertexData);
CC_SAFE_FREE(_vertexIndex);
_vertexDataCount = 0;
}
if (!_vertexData)
{
_vertexDataCount = index + 3;
triangleCount = _vertexDataCount - 2;
_vertexData = (V3F_C4B_T2F*)malloc(_vertexDataCount * sizeof(*_vertexData));
_vertexIndex = (unsigned short *)malloc(triangleCount * 3 * sizeof(*_vertexIndex));
CCASSERT(_vertexData, "FUISprite. Not enough memory");
}
else
{
triangleCount = _vertexDataCount - 2;
}
updateColor();
if (!sameIndexCount)
{
// First we populate the array with the _midpoint, then all
// vertices/texcoords/colors of the 12 'o clock start and edges and the hitpoint
_vertexData[0].texCoords = textureCoordFromAlphaPoint(midpoint);
_vertexData[0].vertices = vertexFromAlphaPoint(midpoint);
_vertexData[1].texCoords = textureCoordFromAlphaPoint(topMid);
_vertexData[1].vertices = vertexFromAlphaPoint(topMid);
for (int i = 0; i < index; ++i)
{
Vec2 alphaPoint = boundaryTexCoord(i);
_vertexData[i + 2].texCoords = textureCoordFromAlphaPoint(alphaPoint);
_vertexData[i + 2].vertices = vertexFromAlphaPoint(alphaPoint);
}
}
// hitpoint will go last
_vertexData[_vertexDataCount - 1].texCoords = textureCoordFromAlphaPoint(hit);
_vertexData[_vertexDataCount - 1].vertices = vertexFromAlphaPoint(hit);
for (int i = 0; i < triangleCount; i++) {
_vertexIndex[i * 3] = 0;
_vertexIndex[i * 3 + 1] = i + 1;
_vertexIndex[i * 3 + 2] = i + 2;
}
_fillTriangles.verts = _vertexData;
_fillTriangles.vertCount = _vertexDataCount;
_fillTriangles.indices = _vertexIndex;
_fillTriangles.indexCount = triangleCount * 3;
}
///
// Update does the work of mapping the texture onto the triangles for the bar
// It now doesn't occur the cost of free/alloc data every update cycle.
// It also only changes the percentage point but no other points if they have not
// been modified.
//
// It now deals with flipped texture. If you run into this problem, just use the
// sprite property and enable the methods flipX, flipY.
///
void FUISprite::updateBar(void)
{
Vec2 min, max;
if (_fillMethod == FillMethod::Horizontal)
{
if (_fillOrigin == FillOrigin::Left || _fillOrigin == FillOrigin::Top)
{
min = Vec2(0, 0);
max = Vec2(_fillAmount, 1);
}
else
{
min = Vec2(1 - _fillAmount, 0);
max = Vec2(1, 1);
}
}
else
{
if (_fillOrigin == FillOrigin::Left || _fillOrigin == FillOrigin::Top)
{
min = Vec2(0, 1 - _fillAmount);
max = Vec2(1, 1);
}
else
{
min = Vec2(0, 0);
max = Vec2(1, _fillAmount);
}
}
if (!_vertexData)
{
_vertexDataCount = 4;
_vertexData = (V3F_C4B_T2F*)malloc(_vertexDataCount * sizeof(*_vertexData));
_vertexIndex = (unsigned short*)malloc(6 * sizeof(*_vertexIndex));
CCASSERT(_vertexData, "FUISprite. Not enough memory");
}
// TOPLEFT
_vertexData[0].texCoords = textureCoordFromAlphaPoint(Vec2(min.x, max.y));
_vertexData[0].vertices = vertexFromAlphaPoint(Vec2(min.x, max.y));
// BOTLEFT
_vertexData[1].texCoords = textureCoordFromAlphaPoint(Vec2(min.x, min.y));
_vertexData[1].vertices = vertexFromAlphaPoint(Vec2(min.x, min.y));
// TOPRIGHT
_vertexData[2].texCoords = textureCoordFromAlphaPoint(Vec2(max.x, max.y));
_vertexData[2].vertices = vertexFromAlphaPoint(Vec2(max.x, max.y));
// BOTRIGHT
_vertexData[3].texCoords = textureCoordFromAlphaPoint(Vec2(max.x, min.y));
_vertexData[3].vertices = vertexFromAlphaPoint(Vec2(max.x, min.y));
_vertexIndex[0] = 0;
_vertexIndex[1] = 1;
_vertexIndex[2] = 2;
_vertexIndex[3] = 2;
_vertexIndex[4] = 1;
_vertexIndex[5] = 3;
_fillTriangles.verts = _vertexData;
_fillTriangles.vertCount = 4;
_fillTriangles.indices = _vertexIndex;
_fillTriangles.indexCount = 6;
updateColor();
}
Vec2 FUISprite::boundaryTexCoord(char index)
{
if (index < kProgressTextureCoordsCount)
{
if (!_fillClockwise)
{
return Vec2((kProgressTextureCoords >> (7 - (index << 1))) & 1, (kProgressTextureCoords >> (7 - ((index << 1) + 1))) & 1);
}
else
{
return Vec2((kProgressTextureCoords >> ((index << 1) + 1)) & 1, (kProgressTextureCoords >> (index << 1)) & 1);
}
}
return Vec2::ZERO;
}
void FUISprite::draw(cocos2d::Renderer* renderer, const cocos2d::Mat4& transform, uint32_t flags)
{
if (_texture == _empty)
return;
if (_fillMethod == FillMethod::None)
Sprite::draw(renderer, transform, flags);
else
{
#if COCOS2D_VERSION >= 0x00040000
setMVPMatrixUniform();
#endif
#if CC_USE_CULLING
// Don't calculate the culling if the transform was not updated
auto visitingCamera = Camera::getVisitingCamera();
auto defaultCamera = Camera::getDefaultCamera();
if (visitingCamera == nullptr) {
_insideBounds = true;
}
else if (visitingCamera == defaultCamera) {
_insideBounds = ((flags & FLAGS_TRANSFORM_DIRTY) || visitingCamera->isViewProjectionUpdated()) ? renderer->checkVisibility(transform, _contentSize) : _insideBounds;
}
else
{
// XXX: this always return true since
_insideBounds = renderer->checkVisibility(transform, _contentSize);
}
if(_insideBounds)
#endif
{
_trianglesCommand.init(_globalZOrder,
_texture,
#if COCOS2D_VERSION < 0x00040000
getGLProgramState(),
#endif
_blendFunc,
_fillTriangles,
transform,
flags);
renderer->addCommand(&_trianglesCommand);
}
}
}
NS_FGUI_END