353 lines
9.9 KiB
C
353 lines
9.9 KiB
C
#include <stdio.h>
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#include <assert.h>
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#include "private.h"
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#include "../include/glkos.h"
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#include "../include/glext.h"
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typedef struct {
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GLuint index;
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GLuint texture_id;
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GLboolean is_complete;
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/* FIXME: Add OP, TR and PT lists per framebuffer */
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} FrameBuffer;
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static FrameBuffer* ACTIVE_FRAMEBUFFER = NULL;
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static NamedArray FRAMEBUFFERS;
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void _glInitFramebuffers() {
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named_array_init(&FRAMEBUFFERS, sizeof(FrameBuffer), 32);
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// Reserve zero so that it is never given to anyone as an ID!
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named_array_reserve(&FRAMEBUFFERS, 0);
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}
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void _glWipeTextureOnFramebuffers(GLuint texture) {
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/* Spec says we don't update inactive framebuffers, they'll presumably just cause
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* a GL_INVALID_OPERATION if we try to render to them */
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if(ACTIVE_FRAMEBUFFER && ACTIVE_FRAMEBUFFER->texture_id == texture) {
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ACTIVE_FRAMEBUFFER->texture_id = 0;
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}
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}
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void APIENTRY glGenFramebuffersEXT(GLsizei n, GLuint* framebuffers) {
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TRACE();
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while(n--) {
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GLuint id = 0;
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FrameBuffer* fb = (FrameBuffer*) named_array_alloc(&FRAMEBUFFERS, &id);
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fb->index = id;
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fb->is_complete = GL_FALSE;
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fb->texture_id = 0;
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*framebuffers = id;
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framebuffers++;
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}
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}
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void APIENTRY glDeleteFramebuffersEXT(GLsizei n, const GLuint* framebuffers) {
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TRACE();
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while(n--) {
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FrameBuffer* fb = (FrameBuffer*) named_array_get(&FRAMEBUFFERS, *framebuffers);
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if(fb == ACTIVE_FRAMEBUFFER) {
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ACTIVE_FRAMEBUFFER = NULL;
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}
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named_array_release(&FRAMEBUFFERS, *framebuffers++);
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}
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}
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void APIENTRY glBindFramebufferEXT(GLenum target, GLuint framebuffer) {
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_GL_UNUSED(target);
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TRACE();
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if(framebuffer) {
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ACTIVE_FRAMEBUFFER = (FrameBuffer*) named_array_get(&FRAMEBUFFERS, framebuffer);
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} else {
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ACTIVE_FRAMEBUFFER = NULL;
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/* FIXME: This is where we need to submit the lists and then clear them. Binding zero means returning to the
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* default framebuffer so we need to render a frame to the texture at that point */
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}
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}
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void APIENTRY glFramebufferTexture2DEXT(GLenum target, GLenum attachment, GLenum textarget, GLuint texture, GLint level) {
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_GL_UNUSED(target);
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_GL_UNUSED(attachment);
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_GL_UNUSED(textarget);
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_GL_UNUSED(level);
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if(texture != 0 && !glIsTexture(texture)) {
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_glKosThrowError(GL_INVALID_OPERATION, __func__);
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_glKosPrintError();
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return;
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}
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if(!ACTIVE_FRAMEBUFFER) {
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_glKosThrowError(GL_INVALID_OPERATION, __func__);
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_glKosPrintError();
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return;
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}
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ACTIVE_FRAMEBUFFER->texture_id = texture;
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}
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GL_FORCE_INLINE GLuint A1555(GLuint v) {
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const GLuint MASK = (1 << 15);
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return (v & MASK) >> 8;
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}
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GL_FORCE_INLINE GLuint R1555(GLuint v) {
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const GLuint MASK = (31 << 10);
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return (v & MASK) >> 7;
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}
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GL_FORCE_INLINE GLuint G1555(GLuint v) {
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const GLuint MASK = (31 << 5);
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return (v & MASK) >> 2;
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}
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GL_FORCE_INLINE GLuint B1555(GLuint v) {
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const GLuint MASK = (31 << 0);
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return (v & MASK) << 3;
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}
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GL_FORCE_INLINE GLuint A4444(GLuint v) {
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const GLuint MASK = (0xF << 12);
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return (v & MASK) >> 12;
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}
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GL_FORCE_INLINE GLuint R4444(GLuint v) {
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const GLuint MASK = (0xF << 8);
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return (v & MASK) >> 8;
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}
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GL_FORCE_INLINE GLuint G4444(GLuint v) {
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const GLuint MASK = (0xF << 4);
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return (v & MASK) >> 4;
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}
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GL_FORCE_INLINE GLuint B4444(GLuint v) {
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const GLuint MASK = (0xF << 0);
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return (v & MASK) >> 0;
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}
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GL_FORCE_INLINE GLuint R565(GLuint v) {
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const GLuint MASK = (31 << 11);
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return (v & MASK) >> 8;
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}
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GL_FORCE_INLINE GLuint G565(GLuint v) {
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const GLuint MASK = (63 << 5);
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return (v & MASK) >> 3;
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}
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GL_FORCE_INLINE GLuint B565(GLuint v) {
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const GLuint MASK = (31 << 0);
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return (v & MASK) << 3;
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}
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static GL_NO_INSTRUMENT GLboolean _glCalculateAverageTexel(GLuint pvrFormat, const GLubyte* src1, const GLubyte* src2, const GLubyte* src3, const GLubyte* src4, GLubyte* t) {
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GLuint a, r, g, b;
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GLubyte format = ((pvrFormat & (1 << 27)) | (pvrFormat & (1 << 26))) >> 26;
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const GLubyte ARGB1555 = 0;
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const GLubyte ARGB4444 = 1;
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const GLubyte RGB565 = 2;
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if((pvrFormat & PVR_TXRFMT_PAL8BPP) == PVR_TXRFMT_PAL8BPP) {
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/* Paletted... all we can do really is just pick one of the
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* 4 texels.. unless we want to change the palette (bad) or
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* pick the closest available colour (slow, and probably bad)
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*/
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*t = *src1;
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} else if(format == RGB565) {
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GLushort* s1 = (GLushort*) src1;
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GLushort* s2 = (GLushort*) src2;
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GLushort* s3 = (GLushort*) src3;
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GLushort* s4 = (GLushort*) src4;
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GLushort* d1 = (GLushort*) t;
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r = R565(*s1) + R565(*s2) + R565(*s3) + R565(*s4);
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g = G565(*s1) + G565(*s2) + G565(*s3) + G565(*s4);
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b = B565(*s1) + B565(*s2) + B565(*s3) + B565(*s4);
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r /= 4;
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g /= 4;
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b /= 4;
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*d1 = PACK_RGB565(r, g, b);
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} else if(format == ARGB4444) {
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GLushort* s1 = (GLushort*) src1;
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GLushort* s2 = (GLushort*) src2;
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GLushort* s3 = (GLushort*) src3;
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GLushort* s4 = (GLushort*) src4;
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GLushort* d1 = (GLushort*) t;
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a = A4444(*s1) + A4444(*s2) + A4444(*s3) + A4444(*s4);
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r = R4444(*s1) + R4444(*s2) + R4444(*s3) + R4444(*s4);
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g = G4444(*s1) + G4444(*s2) + G4444(*s3) + G4444(*s4);
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b = B4444(*s1) + B4444(*s2) + B4444(*s3) + B4444(*s4);
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a /= 4;
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r /= 4;
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g /= 4;
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b /= 4;
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*d1 = PACK_ARGB4444(a, r, g, b);
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} else {
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assert(format == ARGB1555);
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GLushort* s1 = (GLushort*) src1;
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GLushort* s2 = (GLushort*) src2;
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GLushort* s3 = (GLushort*) src3;
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GLushort* s4 = (GLushort*) src4;
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GLushort* d1 = (GLushort*) t;
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a = A1555(*s1) + A1555(*s2) + A1555(*s3) + A1555(*s4);
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r = R1555(*s1) + R1555(*s2) + R1555(*s3) + R1555(*s4);
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g = G1555(*s1) + G1555(*s2) + G1555(*s3) + G1555(*s4);
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b = B1555(*s1) + B1555(*s2) + B1555(*s3) + B1555(*s4);
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a /= 4;
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r /= 4;
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g /= 4;
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b /= 4;
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*d1 = PACK_ARGB1555((GLubyte) a, (GLubyte) r, (GLubyte) g, (GLubyte) b);
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}
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return GL_TRUE;
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}
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GLboolean _glGenerateMipmapTwiddled(const GLuint pvrFormat, const GLubyte* prevData, GLuint thisWidth, GLuint thisHeight, GLubyte* thisData) {
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uint32_t lastWidth = thisWidth * 2;
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uint32_t lastHeight = thisHeight * 2;
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uint32_t i, j;
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uint32_t stride = 0;
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if((pvrFormat & PVR_TXRFMT_PAL8BPP) == PVR_TXRFMT_PAL8BPP) {
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stride = 1;
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} else {
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stride = 2;
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}
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for(i = 0, j = 0; i < lastWidth * lastHeight; i += 4, j++) {
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/* In a twiddled texture, the neighbouring texels
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* are next to each other. By averaging them we just basically shrink
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* the reverse Ns so each reverse N becomes the next level down... if that makes sense!? */
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const GLubyte* s1 = &prevData[i * stride];
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const GLubyte* s2 = s1 + stride;
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const GLubyte* s3 = s2 + stride;
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const GLubyte* s4 = s3 + stride;
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GLubyte* t = &thisData[j * stride];
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assert(s4 < prevData + (lastHeight * lastWidth * stride));
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assert(t < thisData + (thisHeight * thisWidth * stride));
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_glCalculateAverageTexel(pvrFormat, s1, s2, s3, s4, t);
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}
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return GL_TRUE;
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}
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void APIENTRY glGenerateMipmapEXT(GLenum target) {
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if(target != GL_TEXTURE_2D) {
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_glKosThrowError(GL_INVALID_OPERATION, __func__);
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_glKosPrintError();
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return;
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}
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TextureObject* tex = _glGetBoundTexture();
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if(!tex || !tex->data || !tex->mipmapCount) {
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_glKosThrowError(GL_INVALID_OPERATION, __func__);
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_glKosPrintError();
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return;
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}
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if(tex->width != tex->height) {
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fprintf(stderr, "[GL ERROR] Mipmaps cannot be supported on non-square textures\n");
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_glKosThrowError(GL_INVALID_OPERATION, __func__);
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_glKosPrintError();
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return;
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}
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if((tex->color & PVR_TXRFMT_NONTWIDDLED) == PVR_TXRFMT_NONTWIDDLED) {
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/* glTexImage2D should twiddle internally textures in nearly all cases
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* so this error is unlikely */
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fprintf(stderr, "[GL ERROR] Mipmaps are only supported on twiddled textures\n");
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_glKosThrowError(GL_INVALID_OPERATION, __func__);
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_glKosPrintError();
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return;
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}
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GLboolean complete = _glIsMipmapComplete(tex);
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if(!complete && tex->isCompressed) {
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fprintf(stderr, "[GL ERROR] Generating mipmaps for compressed textures is not yet supported\n");
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_glKosThrowError(GL_INVALID_OPERATION, __func__);
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_glKosPrintError();
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return;
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}
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if(complete) {
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/* Nothing to do */
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return;
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}
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GLuint i;
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GLuint prevWidth = tex->width;
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GLuint prevHeight = tex->height;
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/* Make sure there is room for the mipmap data on the texture object */
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_glAllocateSpaceForMipmaps(tex);
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for(i = 1; i < _glGetMipmapLevelCount(tex); ++i) {
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GLubyte* prevData = _glGetMipmapLocation(tex, i - 1);
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GLubyte* thisData = _glGetMipmapLocation(tex, i);
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GLuint thisWidth = (prevWidth > 1) ? prevWidth / 2 : 1;
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GLuint thisHeight = (prevHeight > 1) ? prevHeight / 2 : 1;
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_glGenerateMipmapTwiddled(tex->color, prevData, thisWidth, thisHeight, thisData);
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tex->mipmap |= (1 << i);
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prevWidth = thisWidth;
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prevHeight = thisHeight;
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}
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assert(_glIsMipmapComplete(tex));
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}
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GLenum APIENTRY glCheckFramebufferStatusEXT(GLenum target) {
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if(target != GL_FRAMEBUFFER_EXT) {
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_glKosThrowError(GL_INVALID_ENUM, __func__);
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_glKosPrintError();
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return 0;
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}
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if(!ACTIVE_FRAMEBUFFER) {
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return GL_FRAMEBUFFER_COMPLETE_EXT;
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}
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if(!ACTIVE_FRAMEBUFFER->texture_id) {
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return GL_FRAMEBUFFER_INCOMPLETE_MISSING_ATTACHMENT_EXT;
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}
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return GL_FRAMEBUFFER_COMPLETE_EXT;
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}
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GLboolean APIENTRY glIsFramebufferEXT(GLuint framebuffer) {
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return (named_array_used(&FRAMEBUFFERS, framebuffer)) ? GL_TRUE : GL_FALSE;
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}
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