vmware-svga/examples/dynamic-vertex/main.c

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2009-04-13 02:05:42 -05:00
/*
* SVGA3D example: Dynamic vertex buffers.
*
* This example shows how to efficiently stream vertex data to the
* GPU, using multiple DMA buffers but a single vertex buffer. We
* allocate DMA buffers from a pool every time we want to draw a new
* dynamic mesh, then we asynchronously recycle those buffers after
* the DMA transfer has completed.
*
* Copyright (C) 2008-2009 VMware, Inc. Licensed under the MIT
* License, please see the README.txt. All rights reserved.
*/
#include "svga3dutil.h"
#include "svga3dtext.h"
#include "matrix.h"
#include "math.h"
#define MESH_WIDTH 128
#define MESH_HEIGHT 128
#define MESH_NUM_VERTICES (MESH_WIDTH * MESH_HEIGHT)
#define MESH_NUM_QUADS ((MESH_WIDTH-1) * (MESH_HEIGHT-1))
#define MESH_NUM_TRIANGLES (MESH_NUM_QUADS * 2)
#define MESH_NUM_INDICES (MESH_NUM_TRIANGLES * 3)
#define MESH_ELEMENT(x, y) (MESH_WIDTH * (y) + (x))
typedef struct {
float position[3];
float color[3];
} MyVertex;
typedef uint16 IndexType;
DMAPool vertexDMA;
uint32 vertexSid, indexSid;
Matrix perspectiveMat;
FPSCounterState gFPS;
/*
* setupFrame --
*
* Set up render state that we load once per frame (because
* SVGA3DText clobbered it) and perform matrix calculations that we
* only need once per frame.
*/
void
setupFrame(void)
{
static Matrix world;
SVGA3dTextureState *ts;
SVGA3dRenderState *rs;
Matrix_Copy(world, gIdentityMatrix);
Matrix_RotateX(world, -60.0 * PI_OVER_180);
Matrix_RotateY(world, gFPS.frame * 0.001f);
SVGA3D_SetTransform(CID, SVGA3D_TRANSFORM_WORLD, world);
SVGA3D_SetTransform(CID, SVGA3D_TRANSFORM_PROJECTION, perspectiveMat);
SVGA3D_BeginSetRenderState(CID, &rs, 4);
{
rs[0].state = SVGA3D_RS_BLENDENABLE;
rs[0].uintValue = FALSE;
rs[1].state = SVGA3D_RS_ZENABLE;
rs[1].uintValue = TRUE;
rs[2].state = SVGA3D_RS_ZWRITEENABLE;
rs[2].uintValue = TRUE;
rs[3].state = SVGA3D_RS_ZFUNC;
rs[3].uintValue = SVGA3D_CMP_LESS;
}
SVGA_FIFOCommitAll();
SVGA3D_BeginSetTextureState(CID, &ts, 4);
{
ts[0].stage = 0;
ts[0].name = SVGA3D_TS_BIND_TEXTURE;
ts[0].value = SVGA3D_INVALID_ID;
ts[1].stage = 0;
ts[1].name = SVGA3D_TS_COLOROP;
ts[1].value = SVGA3D_TC_SELECTARG1;
ts[2].stage = 0;
ts[2].name = SVGA3D_TS_COLORARG1;
ts[2].value = SVGA3D_TA_DIFFUSE;
ts[3].stage = 0;
ts[3].name = SVGA3D_TS_ALPHAARG1;
ts[3].value = SVGA3D_TA_DIFFUSE;
}
SVGA_FIFOCommitAll();
}
/*
* updateVertices --
*
* Calculate new vertices, writing them directly into an available
* DMA buffer. Asynchronously begin DMA and recycle the buffer.
*/
void
updateVertices(float red, float green, float blue, float phase, float offset)
{
DMAPoolBuffer *dma;
MyVertex *vert;
int x, y;
float t = gFPS.frame * 0.01f + phase;
dma = SVGA3DUtil_DMAPoolGetBuffer(&vertexDMA);
vert = (MyVertex*) dma->buffer;
for (y = 0; y < MESH_HEIGHT; y++) {
for (x = 0; x < MESH_WIDTH; x++) {
float fx = x * (2.0 / MESH_WIDTH) - 1.0;
float fy = y * (2.0 / MESH_HEIGHT) - 1.0;
float fxo = fx + offset;
float dist = fxo * fxo + fy * fy;
float z = sinf(dist * 8.0 + t) / (1 + dist * 10.0);
vert->position[0] = fx;
vert->position[1] = fy;
vert->position[2] = z;
vert->color[0] = red - z;
vert->color[1] = green - z;
vert->color[2] = blue - z;
vert++;
}
}
SVGA3DUtil_SurfaceDMA2D(vertexSid, &dma->ptr, SVGA3D_WRITE_HOST_VRAM,
MESH_NUM_VERTICES * sizeof(MyVertex), 1);
SVGA3DUtil_AsyncCall((AsyncCallFn) SVGA3DUtil_DMAPoolFreeBuffer, dma);
}
/*
* drawMesh --
*
* Draw our mesh at a particular position. This uses the index and
* vertex data which is resident in the host VRAM buffers at the
* time the drawing command is executed asynchronously.
*/
void
drawMesh(float posX, float posY, float posZ)
{
SVGA3dVertexDecl *decls;
SVGA3dPrimitiveRange *ranges;
static Matrix view;
Matrix_Copy(view, gIdentityMatrix);
Matrix_Translate(view, posX, posY, posZ);
SVGA3D_SetTransform(CID, SVGA3D_TRANSFORM_VIEW, view);
SVGA3D_BeginDrawPrimitives(CID, &decls, 2, &ranges, 1);
{
decls[0].identity.type = SVGA3D_DECLTYPE_FLOAT3;
decls[0].identity.usage = SVGA3D_DECLUSAGE_POSITION;
decls[0].array.surfaceId = vertexSid;
decls[0].array.stride = sizeof(MyVertex);
decls[0].array.offset = offsetof(MyVertex, position);
decls[1].identity.type = SVGA3D_DECLTYPE_FLOAT3;
decls[1].identity.usage = SVGA3D_DECLUSAGE_COLOR;
decls[1].array.surfaceId = vertexSid;
decls[1].array.stride = sizeof(MyVertex);
decls[1].array.offset = offsetof(MyVertex, color);
ranges[0].primType = SVGA3D_PRIMITIVE_TRIANGLELIST;
ranges[0].primitiveCount = MESH_NUM_TRIANGLES;
ranges[0].indexArray.surfaceId = indexSid;
ranges[0].indexArray.stride = sizeof(IndexType);
ranges[0].indexWidth = sizeof(IndexType);
}
SVGA_FIFOCommitAll();
}
/*
* createIndexBuffer --
*
* Create a static index buffer that renders our vertices as a 2D
* mesh. For simplicity, we use a triangle list rather than a
* triangle strip.
*/
uint32
createIndexBuffer(void)
{
IndexType *indexBuffer;
const uint32 bufferSize = MESH_NUM_INDICES * sizeof *indexBuffer;
SVGAGuestPtr gPtr;
uint32 sid;
int x, y;
sid = SVGA3DUtil_DefineSurface2D(bufferSize, 1, SVGA3D_BUFFER);
indexBuffer = SVGA3DUtil_AllocDMABuffer(bufferSize, &gPtr);
for (y = 0; y < (MESH_HEIGHT - 1); y++) {
for (x = 0; x < (MESH_WIDTH - 1); x++) {
indexBuffer[0] = MESH_ELEMENT(x, y );
indexBuffer[1] = MESH_ELEMENT(x+1, y );
indexBuffer[2] = MESH_ELEMENT(x+1, y+1);
indexBuffer[3] = MESH_ELEMENT(x+1, y+1);
indexBuffer[4] = MESH_ELEMENT(x, y+1);
indexBuffer[5] = MESH_ELEMENT(x, y );
indexBuffer += 6;
}
}
SVGA3DUtil_SurfaceDMA2D(sid, &gPtr, SVGA3D_WRITE_HOST_VRAM, bufferSize, 1);
return sid;
}
/*
* main --
*
* Our example's entry point, invoked directly by the bootloader.
*/
int
main(void)
{
SVGA3DUtil_InitFullscreen(CID, 800, 600);
SVGA3DText_Init();
vertexSid = SVGA3DUtil_DefineSurface2D(MESH_NUM_VERTICES * sizeof(MyVertex),
1, SVGA3D_BUFFER);
indexSid = createIndexBuffer();
SVGA3DUtil_AllocDMAPool(&vertexDMA, MESH_NUM_VERTICES * sizeof(MyVertex), 16);
Matrix_Perspective(perspectiveMat, 45.0f,
gSVGA.width / (float)gSVGA.height, 0.1f, 100.0f);
while (1) {
if (SVGA3DUtil_UpdateFPSCounter(&gFPS)) {
Console_Clear();
Console_Format("VMware SVGA3D Example:\n"
"Dynamic vertex buffers.\n\n%s",
gFPS.text);
SVGA3DText_Update();
}
SVGA3DUtil_ClearFullscreen(CID, SVGA3D_CLEAR_COLOR | SVGA3D_CLEAR_DEPTH,
0x113366, 1.0f, 0);
setupFrame();
updateVertices(1, 0.5, 0.5, M_PI, 0);
drawMesh(-1.5, -1, 6);
updateVertices(0.5, 1.0, 0.5, 0, 0);
drawMesh(0, 1, 6);
updateVertices(0.5, 0.5, 1.0, 0, 1.5);
drawMesh(1.5, -1, 6);
SVGA3DText_Draw();
SVGA3DUtil_PresentFullscreen();
}
return 0;
}