/*
* Carga un programa a partir de un fichero binario (ya compilado), o, si este
* no existe, compila y construye un programa a partir de un fichero con el
* código fuente.
* > ctx : Contexto en el cual crear el programa.
* > ds : Array con los dispostivos seleccionados.
* > src : Ruta del código fuente.
* > bin : Ruta del fichero binario.
*/
cl_program loadProgramFromArgs (cl_context ctx, cl_device_id *ds,
cl_uint ds_size, char *src, char *bin) {
FILE *f;
char *data;
cl_program prg;
size_t size;
if ((f = fopen(bin, "rb")) != NULL)
return loadBinaryProgram(ctx, ds, ds_size, bin);
if ((f = fopen(src, "r")) != NULL) {
printf("Compiling %s... ", src);
fflush(stdout);
data = (char*) malloc(PRG_BUFFER_SIZE * sizeof(char));
size = fread(data, 1, PRG_BUFFER_SIZE, f);
fclose(f);
data[size] = '\0';
prg = clCreateProgramWithSource(ctx, 1, (const char**)&data, NULL,
NULL);
if(clBuildProgram(prg, ds_size, ds, NULL, NULL, NULL) != CL_SUCCESS) {
fprintf(stderr, "FAIL\n");
showProgramBuildLog(ds, ds_size, prg);
return NULL;
}
printf("OK\n");
saveBinaryProgram(prg, ds, ds_size, bin);
return prg;
}
return NULL;
}
/*!****************************************************************************
@Function InitView
@Return bool true if no error occured
@Description Code in InitView() will be called by PVRShell upon
initialization or after a change in the rendering context.
Used to initialize variables that are dependant on the rendering
context (e.g. textures, vertex buffers, etc.)
******************************************************************************/
bool OGLES2BinaryShader::InitView()
{
// Initialise a colour to draw our triangle
// (For this training course, binary loaded shaders use a different colour
// To show which is being used. Red means it had to compile the shaders,
// green shows that it retrieved the binary from memory.
float afColour[]={0.0,0.0,0.0};
// Filename and path strings.
char* pWritePath = (char*)PVRShellGet(prefWritePath);
char* shaderPath = new char[strlen(pWritePath) + 13];
sprintf(shaderPath, "%sShaderBinary", pWritePath);
//Checks if the program binary handling extension is supported.
m_bBinaryShaderSupported=IsGLExtensionSupported("GL_OES_get_program_binary");
#if !defined (TARGET_OS_IPHONE)
glGetProgramBinaryOES=0;
glProgramBinaryOES=0;
// Retrieves the functions needed to use the extension.
if (m_bBinaryShaderSupported)
{
glGetProgramBinaryOES = (PFNGLGETPROGRAMBINARYOESPROC) PVRGetProcAddress(glGetProgramBinaryOES);
glProgramBinaryOES = (PFNGLPROGRAMBINARYOESPROC) PVRGetProcAddress(glProgramBinaryOES);
}
#endif
// If binary shaders are not supported or there isn't a valid binary shader stored, recompile the shaders.
if (!m_bBinaryShaderSupported || !loadBinaryProgram(shaderPath,m_uiProgramObject))
{
{
// Fragment shader code
const char* pszFragShader = "\
uniform lowp vec3 myColour;\
void main (void)\
{\
gl_FragColor = vec4(myColour, 1.0);\
}";
// Create the fragment shader object
m_uiFragShader = glCreateShader(GL_FRAGMENT_SHADER);
// Load the source code into it
glShaderSource(m_uiFragShader, 1, (const char**)&pszFragShader, NULL);
// Compile the source code
glCompileShader(m_uiFragShader);
// Check if compilation succeeded
GLint bShaderCompiled;
glGetShaderiv(m_uiFragShader, GL_COMPILE_STATUS, &bShaderCompiled);
if (!bShaderCompiled)
{
// An error happened, first retrieve the length of the log message
int i32InfoLogLength, i32CharsWritten;
glGetShaderiv(m_uiFragShader, GL_INFO_LOG_LENGTH, &i32InfoLogLength);
// Allocate enough space for the message and retrieve it
char* pszInfoLog = new char[i32InfoLogLength];
glGetShaderInfoLog(m_uiFragShader, i32InfoLogLength, &i32CharsWritten, pszInfoLog);
/*
Displays the message in a dialog box when the application quits
using the shell PVRShellSet function with first parameter prefExitMessage.
*/
char* pszMsg = new char[i32InfoLogLength+256];
strcpy(pszMsg, "Failed to compile fragment shader: ");
strcat(pszMsg, pszInfoLog);
PVRShellSet(prefExitMessage, pszMsg);
delete [] pszMsg;
delete [] pszInfoLog;
delete [] shaderPath;
return false;
}
}
/*!****************************************************************************
@Function InitView
@Return bool true if no error occured
@Description Code in InitView() will be called by PVRShell upon
initialization or after a change in the rendering context.
Used to initialize variables that are dependant on the rendering
context (e.g. textures, vertex buffers, etc.)
******************************************************************************/
bool OGLES3BinaryShader::InitView()
{
// Initialise a colour to draw our triangle
// (For this training course, binary loaded shaders use a different colour
// To show which is being used. Red means it had to compile the shaders,
// green shows that it retrieved the binary from memory.
float afColour[]={0.0,0.0,0.0};
// Filename and path strings.
char* pWritePath = (char*)PVRShellGet(prefWritePath);
char* shaderPath = new char[strlen(pWritePath) + 13];
sprintf(shaderPath, "%sShaderBinary", pWritePath);
// If binary shaders are not supported or there isn't a valid binary shader stored, recompile the shaders.
if(!loadBinaryProgram(shaderPath,m_uiProgramObject))
{
{
// Fragment shader code
const char* pszFragShader = "\
#version 300 es\n\
uniform lowp vec3 myColour;\
layout (location = 0) out lowp vec4 oColour;\
void main (void)\
{\
oColour = vec4(myColour, 1.0);\
}";
// Create the fragment shader object
m_uiFragShader = glCreateShader(GL_FRAGMENT_SHADER);
// Load the source code into it
glShaderSource(m_uiFragShader, 1, (const char**)&pszFragShader, NULL);
// Compile the source code
glCompileShader(m_uiFragShader);
// Check if compilation succeeded
GLint bShaderCompiled;
glGetShaderiv(m_uiFragShader, GL_COMPILE_STATUS, &bShaderCompiled);
if (!bShaderCompiled)
{
// An error happened, first retrieve the length of the log message
int i32InfoLogLength, i32CharsWritten;
glGetShaderiv(m_uiFragShader, GL_INFO_LOG_LENGTH, &i32InfoLogLength);
// Allocate enough space for the message and retrieve it
char* pszInfoLog = new char[i32InfoLogLength];
glGetShaderInfoLog(m_uiFragShader, i32InfoLogLength, &i32CharsWritten, pszInfoLog);
/*
Displays the message in a dialog box when the application quits
using the shell PVRShellSet function with first parameter prefExitMessage.
*/
char* pszMsg = new char[i32InfoLogLength+256];
strcpy(pszMsg, "Failed to compile fragment shader: ");
strcat(pszMsg, pszInfoLog);
PVRShellSet(prefExitMessage, pszMsg);
delete [] pszMsg;
delete [] pszInfoLog;
delete [] shaderPath;
return false;
}
}
{
// Vertex shader code.
const char* pszVertShader = "\
#version 300 es\n\
layout (location = 0) in highp vec4 myVertex;\
uniform mediump mat4 myPMVMatrix;\
void main(void)\
{\
gl_Position = myPMVMatrix * myVertex;\
}";
// Loads the vertex shader in the same way
m_uiVertexShader = glCreateShader(GL_VERTEX_SHADER);
glShaderSource(m_uiVertexShader, 1, (const char**)&pszVertShader, NULL);
glCompileShader(m_uiVertexShader);
// Checks if the shader has compiled.
GLint bShaderCompiled;
glGetShaderiv(m_uiVertexShader, GL_COMPILE_STATUS, &bShaderCompiled);
if (!bShaderCompiled)
{
int i32InfoLogLength, i32CharsWritten;
glGetShaderiv(m_uiVertexShader, GL_INFO_LOG_LENGTH, &i32InfoLogLength);
char* pszInfoLog = new char[i32InfoLogLength];
glGetShaderInfoLog(m_uiVertexShader, i32InfoLogLength, &i32CharsWritten, pszInfoLog);
char* pszMsg = new char[i32InfoLogLength+256];
strcpy(pszMsg, "Failed to compile vertex shader: ");
strcat(pszMsg, pszInfoLog);
PVRShellSet(prefExitMessage, pszMsg);
delete [] pszMsg;
delete [] pszInfoLog;
delete [] shaderPath;
return false;
}
}
// Create the shader program
m_uiProgramObject = glCreateProgram();
// Attach the fragment and vertex shaders to the shader program.
glAttachShader(m_uiProgramObject, m_uiFragShader);
glAttachShader(m_uiProgramObject, m_uiVertexShader);
// Bind the custom vertex attribute "myVertex" to location VERTEX_ARRAY
glBindAttribLocation(m_uiProgramObject, VERTEX_ARRAY, "myVertex");
// Link the program
glLinkProgram(m_uiProgramObject);
// Check if linking succeeded in the same way we checked for compilation success
GLint bLinked;
glGetProgramiv(m_uiProgramObject, GL_LINK_STATUS, &bLinked);
if (!bLinked)
{
int i32InfoLogLength, i32CharsWritten;
glGetProgramiv(m_uiProgramObject, GL_INFO_LOG_LENGTH, &i32InfoLogLength);
char* pszInfoLog = new char[i32InfoLogLength];
glGetProgramInfoLog(m_uiProgramObject, i32InfoLogLength, &i32CharsWritten, pszInfoLog);
char* pszMsg = new char[i32InfoLogLength+256];
strcpy(pszMsg, "Failed to link program: ");
strcat(pszMsg, pszInfoLog);
PVRShellSet(prefExitMessage, pszMsg);
delete [] pszMsg;
delete [] pszInfoLog;
delete [] shaderPath;
return false;
}
// As there is no stored binary, save the current binary out for use later.
// Note that this is done after both binding attributes and linking -
// none of these can be performed after
saveBinaryProgram(shaderPath,m_uiProgramObject);
//Set red channel of the colour to maximum - red shows that the shaders had to be compiled.
afColour[0]=1.0f;
}
else
{
//Set green channel of the colour to maximum - green shows that the shaders were loaded from binary files.
afColour[1]=1.0f;
}
delete[] shaderPath;
// Uses the program.
glUseProgram(m_uiProgramObject);
// Bind the colour to the fragment shader.
GLint i32ColourLocation = glGetUniformLocation(m_uiProgramObject, "myColour");
// Then passes the colour to that variable
glUniform3fv(i32ColourLocation, 1, afColour);
// Sets the clear color
glClearColor(0.6f, 0.8f, 1.0f, 1.0f);
// Create VBO for the triangle from our data
// Vertex data
GLfloat afVertices[] = {-0.4f,-0.4f,0.0f, 0.4f,-0.4f,0.0f, 0.0f,0.4f,0.0f};
// Gen VBO
glGenBuffers(1, &m_ui32Vbo);
// Bind the VBO
glBindBuffer(GL_ARRAY_BUFFER, m_ui32Vbo);
// Set the buffer's data
glBufferData(GL_ARRAY_BUFFER, 3 * (3 * sizeof(GLfloat)) /* 3 Vertices of 3 floats in size */, afVertices, GL_STATIC_DRAW);
// Unbind the VBO
glBindBuffer(GL_ARRAY_BUFFER, 0);
// Enable culling
glEnable(GL_CULL_FACE);
return true;
}
