DLL_EXPORT_API npBool xnOvrCommitFrame(xnOvrSession* session, int numberOfExtraLayers, xnOvrQuadLayer** extraLayers)
{
ovrLayerHeader* layers[1 + numberOfExtraLayers];
//add the default layer first
layers[0] = &session->Layer.Header;
//commit the default fov layer
ovr_CommitTextureSwapChain(session->Session, session->SwapChain);
for (auto i = 0; i < numberOfExtraLayers; i++)
{
//add further quad layers
layers[i + 1] = &extraLayers[i]->Layer.Header;
//also commit the quad layer
ovr_CommitTextureSwapChain(session->Session, extraLayers[i]->SwapChain);
}
if(!OVR_SUCCESS(ovr_SubmitFrame(session->Session, 0, NULL, layers, 1 + numberOfExtraLayers)))
{
return false;
}
ovrSessionStatus status;
if (!OVR_SUCCESS(ovr_GetSessionStatus(session->Session, &status)))
{
return false;
}
if(status.ShouldRecenter)
{
ovr_RecenterTrackingOrigin(session->Session);
}
return true;
}
void TextureStatic::createTexture()
{
ovrTextureSwapChainDesc desc = {};
desc.Type = ovrTexture_2D;
desc.Format = OVR_FORMAT_R8G8B8A8_UNORM_SRGB;
desc.ArraySize = 1;
desc.Width = width;
desc.Height = height;
desc.MipLevels = 1;
desc.SampleCount = 1;
desc.StaticImage = ovrTrue;
desc.MiscFlags = ovrTextureMisc_None;
desc.BindFlags = ovrTextureBind_None;
if (ovr_CreateTextureSwapChainGL(session, &desc, &textureSwapChain) != ovrSuccess) {
yFatal() << "Failed to create texture swap chain";
}
ovr_GetTextureSwapChainBufferGL(session, textureSwapChain, -1, &chainTexId);
checkGlErrorMacro;
glBindTexture(GL_TEXTURE_2D, chainTexId);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_REPEAT);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_REPEAT);
glTexSubImage2D(GL_TEXTURE_2D, 0, 0, 0, width, height, GL_RGBA, GL_UNSIGNED_BYTE, ptr);
checkGlErrorMacro;
glBindTexture(GL_TEXTURE_2D, 0);
ovr_CommitTextureSwapChain(session, textureSwapChain);
checkGlErrorMacro;
}
void OculusVR::OnRenderFinish()
{
if (m_msaaEnabled)
m_renderBuffer->OnRenderMSAAFinish();
else
m_renderBuffer->OnRenderFinish();
ovr_CommitTextureSwapChain(m_hmdSession, m_renderBuffer->m_swapTextureChain);
}
void OculusWindow::finish_frame() {
ovr_CommitTextureSwapChain(hmd_session_, texture_swap_chain_);
ovrLayerHeader* layers = &color_layer_.Header;
ovrResult result = ovr_SubmitFrame(hmd_session_, framecount_, nullptr, &layers, 1);
if (!OVR_SUCCESS(result)) {
gua::Logger::LOG_WARNING << "Failed to submit frame to the oculus rift.\n";
}
GlfwWindow::finish_frame();
}
void GuardianSystemDemo::Render()
{
// Get current eye pose for rendering
double eyePoseTime = 0;
ovrPosef eyePose[ovrEye_Count] = {};
ovr_GetEyePoses(mSession, mFrameIndex, ovrTrue, mHmdToEyeOffset, eyePose, &eyePoseTime);
// Render each eye
for (int i = 0; i < ovrEye_Count; ++i) {
int renderTargetIndex = 0;
ovr_GetTextureSwapChainCurrentIndex(mSession, mTextureChain[i], &renderTargetIndex);
ID3D11RenderTargetView* renderTargetView = mEyeRenderTargets[i][renderTargetIndex];
ID3D11DepthStencilView* depthTargetView = mEyeDepthTarget[i];
// Clear and set render/depth target and viewport
DIRECTX.SetAndClearRenderTarget(renderTargetView, depthTargetView, 0.2f, 0.2f, 0.2f, 1.0f);
DIRECTX.SetViewport((float)mEyeRenderViewport[i].Pos.x, (float)mEyeRenderViewport[i].Pos.y,
(float)mEyeRenderViewport[i].Size.w, (float)mEyeRenderViewport[i].Size.h);
// Eye
XMVECTOR eyeRot = XMVectorSet(eyePose[i].Orientation.x, eyePose[i].Orientation.y,
eyePose[i].Orientation.z, eyePose[i].Orientation.w);
XMVECTOR eyePos = XMVectorSet(eyePose[i].Position.x, eyePose[i].Position.y, eyePose[i].Position.z, 0);
XMVECTOR eyeForward = XMVector3Rotate(XMVectorSet(0, 0, -1, 0), eyeRot);
// Matrices
XMMATRIX viewMat = XMMatrixLookAtRH(eyePos, XMVectorAdd(eyePos, eyeForward),
XMVector3Rotate(XMVectorSet(0.0f, 1.0f, 0.0f, 0.0f), eyeRot));
ovrMatrix4f proj = ovrMatrix4f_Projection(mEyeRenderLayer.Fov[i], 0.001f, 1000.0f, ovrProjection_None);
XMMATRIX projMat = XMMatrixTranspose(XMMATRIX(&proj.M[0][0]));
XMMATRIX viewProjMat = XMMatrixMultiply(viewMat, projMat);
// Render and commit to swap chain
mDynamicScene.Render(&viewProjMat, 1.0f, 1.0f, 1.0f, 1.0f, true);
ovr_CommitTextureSwapChain(mSession, mTextureChain[i]);
// Update eye layer
mEyeRenderLayer.ColorTexture[i] = mTextureChain[i];
mEyeRenderLayer.RenderPose[i] = eyePose[i];
mEyeRenderLayer.SensorSampleTime = eyePoseTime;
}
// Submit frames
ovrLayerHeader* layers = &mEyeRenderLayer.Header;
ovrResult result = ovr_SubmitFrame(mSession, mFrameIndex++, nullptr, &layers, 1);
if (!OVR_SUCCESS(result)) {
printf("ovr_SubmitFrame failed"); exit(-1);
}
}
void VR::submitFrame()
{
int frameIndex = xapp->getCurrentBackBufferIndex();
// Increment to use next texture, just before writing
int currentIndex;
ovr_GetTextureSwapChainCurrentIndex(session, textureSwapChain, ¤tIndex);
assert(currentIndex == frameIndex);
xapp->lastPresentedFrame = frameIndex;
//xapp->d3d11On12Device->AcquireWrappedResources(xapp->wrappedBackBuffers[frameIndex].GetAddressOf(), 1);
//xapp->d3d11DeviceContext->CopyResource(xapp->wrappedTextures[currentIndex].Get(), xapp->wrappedBackBuffers[frameIndex].Get());
//xapp->d3d11On12Device->ReleaseWrappedResources(xapp->wrappedBackBuffers[frameIndex].GetAddressOf(), 1);
//xapp->d3d11DeviceContext->Flush();
//xapp->device->
//ovr_CommitTextureSwapChain(session, textureSwapChain);
ovr_CommitTextureSwapChain(session, textureSwapChain);
/* pTextureSet->CurrentIndex = (pTextureSet->CurrentIndex + 1) % pTextureSet->TextureCount;
*/
// Submit frame with one layer we have.
ovrLayerHeader* layers = &layer.Header;
ovrResult result = ovr_SubmitFrame(session, 0, nullptr, &layers, 1);
bool isVisible = (result == ovrSuccess);
//Log
}
void HudQuad::_FinalizeDrawToQuad()
{
ovr_CommitTextureSwapChain(m_session, m_swapChain);
}
int main(int argc, char **argv)
{
// Initialize SDL2's context
SDL_Init(SDL_INIT_VIDEO);
// Initialize Oculus' context
ovrResult result = ovr_Initialize(nullptr);
if (OVR_FAILURE(result))
{
std::cout << "ERROR: Failed to initialize libOVR" << std::endl;
SDL_Quit();
return -1;
}
ovrSession session;
ovrGraphicsLuid luid;
// Connect to the Oculus headset
result = ovr_Create(&session, &luid);
if (OVR_FAILURE(result))
{
std::cout << "ERROR: Oculus Rift not detected" << std::endl;
ovr_Shutdown();
SDL_Quit();
return -1;
}
int x = SDL_WINDOWPOS_CENTERED, y = SDL_WINDOWPOS_CENTERED;
int winWidth = 1280;
int winHeight = 720;
Uint32 flags = SDL_WINDOW_OPENGL | SDL_WINDOW_SHOWN;
// Create SDL2 Window
SDL_Window* window = SDL_CreateWindow("OVR ZED App", x, y, winWidth, winHeight, flags);
// Create OpenGL context
SDL_GLContext glContext = SDL_GL_CreateContext(window);
// Initialize GLEW
glewInit();
// Turn off vsync to let the compositor do its magic
SDL_GL_SetSwapInterval(0);
// Initialize the ZED Camera
sl::zed::Camera* zed = 0;
zed = new sl::zed::Camera(sl::zed::HD720);
sl::zed::ERRCODE zederr = zed->init(sl::zed::MODE::PERFORMANCE, 0);
int zedWidth = zed->getImageSize().width;
int zedHeight = zed->getImageSize().height;
if (zederr != sl::zed::SUCCESS)
{
std::cout << "ERROR: " << sl::zed::errcode2str(zederr) << std::endl;
ovr_Destroy(session);
ovr_Shutdown();
SDL_GL_DeleteContext(glContext);
SDL_DestroyWindow(window);
SDL_Quit();
delete zed;
return -1;
}
GLuint zedTextureID_L, zedTextureID_R;
// Generate OpenGL texture for left images of the ZED camera
glGenTextures(1, &zedTextureID_L);
glBindTexture(GL_TEXTURE_2D, zedTextureID_L);
glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, zedWidth, zedHeight, 0, GL_BGRA, GL_UNSIGNED_BYTE, NULL);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
// Generate OpenGL texture for right images of the ZED camera
glGenTextures(1, &zedTextureID_R);
glBindTexture(GL_TEXTURE_2D, zedTextureID_R);
glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, zedWidth, zedHeight, 0, GL_BGRA, GL_UNSIGNED_BYTE, NULL);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
glBindTexture(GL_TEXTURE_2D, 0);
#if OPENGL_GPU_INTEROP
cudaGraphicsResource* cimg_L;
cudaGraphicsResource* cimg_R;
cudaError_t errL, errR;
errL = cudaGraphicsGLRegisterImage(&cimg_L, zedTextureID_L, GL_TEXTURE_2D, cudaGraphicsMapFlagsNone);
errR = cudaGraphicsGLRegisterImage(&cimg_R, zedTextureID_R, GL_TEXTURE_2D, cudaGraphicsMapFlagsNone);
if (errL != cudaSuccess || errR != cudaSuccess)
{
std::cout << "ERROR: cannot create CUDA texture : " << errL << "|" << errR << std::endl;
}
#endif
ovrHmdDesc hmdDesc = ovr_GetHmdDesc(session);
// Get the texture sizes of Oculus eyes
ovrSizei textureSize0 = ovr_GetFovTextureSize(session, ovrEye_Left, hmdDesc.DefaultEyeFov[0], 1.0f);
ovrSizei textureSize1 = ovr_GetFovTextureSize(session, ovrEye_Right, hmdDesc.DefaultEyeFov[1], 1.0f);
// Compute the final size of the render buffer
ovrSizei bufferSize;
bufferSize.w = textureSize0.w + textureSize1.w;
bufferSize.h = std::max(textureSize0.h, textureSize1.h);
// Initialize OpenGL swap textures to render
ovrTextureSwapChain textureChain = nullptr;
// Description of the swap chain
ovrTextureSwapChainDesc descTextureSwap = {};
descTextureSwap.Type = ovrTexture_2D;
descTextureSwap.ArraySize = 1;
descTextureSwap.Width = bufferSize.w;
descTextureSwap.Height = bufferSize.h;
descTextureSwap.MipLevels = 1;
descTextureSwap.Format = OVR_FORMAT_R8G8B8A8_UNORM_SRGB;
descTextureSwap.SampleCount = 1;
descTextureSwap.StaticImage = ovrFalse;
// Create the OpenGL texture swap chain
result = ovr_CreateTextureSwapChainGL(session, &descTextureSwap, &textureChain);
int length = 0;
ovr_GetTextureSwapChainLength(session, textureChain, &length);
if (OVR_SUCCESS(result))
{
for (int i = 0; i < length; ++i)
{
GLuint chainTexId;
ovr_GetTextureSwapChainBufferGL(session, textureChain, i, &chainTexId);
glBindTexture(GL_TEXTURE_2D, chainTexId);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
}
}
else
{
std::cout << "ERROR: failed creating swap texture" << std::endl;
ovr_Destroy(session);
ovr_Shutdown();
SDL_GL_DeleteContext(glContext);
SDL_DestroyWindow(window);
SDL_Quit();
delete zed;
return -1;
}
// Generate frame buffer to render
GLuint fboID;
glGenFramebuffers(1, &fboID);
// Generate depth buffer of the frame buffer
GLuint depthBuffID;
glGenTextures(1, &depthBuffID);
glBindTexture(GL_TEXTURE_2D, depthBuffID);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
GLenum internalFormat = GL_DEPTH_COMPONENT24;
GLenum type = GL_UNSIGNED_INT;
glTexImage2D(GL_TEXTURE_2D, 0, internalFormat, bufferSize.w, bufferSize.h, 0, GL_DEPTH_COMPONENT, type, NULL);
// Create a mirror texture to display the render result in the SDL2 window
ovrMirrorTextureDesc descMirrorTexture;
memset(&descMirrorTexture, 0, sizeof(descMirrorTexture));
descMirrorTexture.Width = winWidth;
descMirrorTexture.Height = winHeight;
descMirrorTexture.Format = OVR_FORMAT_R8G8B8A8_UNORM_SRGB;
ovrMirrorTexture mirrorTexture = nullptr;
result = ovr_CreateMirrorTextureGL(session, &descMirrorTexture, &mirrorTexture);
if (!OVR_SUCCESS(result))
{
std::cout << "ERROR: Failed to create mirror texture" << std::endl;
}
GLuint mirrorTextureId;
ovr_GetMirrorTextureBufferGL(session, mirrorTexture, &mirrorTextureId);
GLuint mirrorFBOID;
glGenFramebuffers(1, &mirrorFBOID);
glBindFramebuffer(GL_READ_FRAMEBUFFER, mirrorFBOID);
glFramebufferTexture2D(GL_READ_FRAMEBUFFER, GL_COLOR_ATTACHMENT0, GL_TEXTURE_2D, mirrorTextureId, 0);
glFramebufferRenderbuffer(GL_READ_FRAMEBUFFER, GL_DEPTH_ATTACHMENT, GL_RENDERBUFFER, 0);
glBindFramebuffer(GL_READ_FRAMEBUFFER, 0);
// Frame index used by the compositor
// it needs to be updated each new frame
long long frameIndex = 0;
// FloorLevel will give tracking poses where the floor height is 0
ovr_SetTrackingOriginType(session, ovrTrackingOrigin_FloorLevel);
// Initialize a default Pose
ovrPosef eyeRenderPose[2];
// Get the render description of the left and right "eyes" of the Oculus headset
ovrEyeRenderDesc eyeRenderDesc[2];
eyeRenderDesc[0] = ovr_GetRenderDesc(session, ovrEye_Left, hmdDesc.DefaultEyeFov[0]);
eyeRenderDesc[1] = ovr_GetRenderDesc(session, ovrEye_Right, hmdDesc.DefaultEyeFov[1]);
// Get the Oculus view scale description
ovrVector3f hmdToEyeOffset[2];
double sensorSampleTime;
// Create and compile the shader's sources
Shader shader(OVR_ZED_VS, OVR_ZED_FS);
// Compute the ZED image field of view with the ZED parameters
float zedFovH = atanf(zed->getImageSize().width / (zed->getParameters()->LeftCam.fx *2.f)) * 2.f;
// Compute the Horizontal Oculus' field of view with its parameters
float ovrFovH = (atanf(hmdDesc.DefaultEyeFov[0].LeftTan) + atanf(hmdDesc.DefaultEyeFov[0].RightTan));
// Compute the useful part of the ZED image
unsigned int usefulWidth = zed->getImageSize().width * ovrFovH / zedFovH;
// Compute the size of the final image displayed in the headset with the ZED image's aspect-ratio kept
unsigned int widthFinal = bufferSize.w / 2;
float heightGL = 1.f;
float widthGL = 1.f;
if (usefulWidth > 0.f)
{
unsigned int heightFinal = zed->getImageSize().height * widthFinal / usefulWidth;
// Convert this size to OpenGL viewport's frame's coordinates
heightGL = (heightFinal) / (float)(bufferSize.h);
widthGL = ((zed->getImageSize().width * (heightFinal / (float)zed->getImageSize().height)) / (float)widthFinal);
}
else
{
std::cout << "WARNING: ZED parameters got wrong values."
"Default vertical and horizontal FOV are used.\n"
"Check your calibration file or check if your ZED is not too close to a surface or an object."
<< std::endl;
}
// Compute the Vertical Oculus' field of view with its parameters
float ovrFovV = (atanf(hmdDesc.DefaultEyeFov[0].UpTan) + atanf(hmdDesc.DefaultEyeFov[0].DownTan));
// Compute the center of the optical lenses of the headset
float offsetLensCenterX = ((atanf(hmdDesc.DefaultEyeFov[0].LeftTan)) / ovrFovH) * 2.f - 1.f;
float offsetLensCenterY = ((atanf(hmdDesc.DefaultEyeFov[0].UpTan)) / ovrFovV) * 2.f - 1.f;
// Create a rectangle with the computed coordinates and push it in GPU memory.
struct GLScreenCoordinates
{
float left, up, right, down;
} screenCoord;
screenCoord.up = heightGL + offsetLensCenterY;
screenCoord.down = heightGL - offsetLensCenterY;
screenCoord.right = widthGL + offsetLensCenterX;
screenCoord.left = widthGL - offsetLensCenterX;
float rectVertices[12] = { -screenCoord.left, -screenCoord.up, 0,
screenCoord.right, -screenCoord.up, 0,
screenCoord.right, screenCoord.down, 0,
-screenCoord.left, screenCoord.down, 0 };
GLuint rectVBO[3];
glGenBuffers(1, &rectVBO[0]);
glBindBuffer(GL_ARRAY_BUFFER, rectVBO[0]);
glBufferData(GL_ARRAY_BUFFER, sizeof(rectVertices), rectVertices, GL_STATIC_DRAW);
float rectTexCoord[8] = { 0, 1, 1, 1, 1, 0, 0, 0 };
glGenBuffers(1, &rectVBO[1]);
glBindBuffer(GL_ARRAY_BUFFER, rectVBO[1]);
glBufferData(GL_ARRAY_BUFFER, sizeof(rectTexCoord), rectTexCoord, GL_STATIC_DRAW);
unsigned int rectIndices[6] = { 0, 1, 2, 0, 2, 3 };
glGenBuffers(1, &rectVBO[2]);
glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, rectVBO[2]);
glBufferData(GL_ELEMENT_ARRAY_BUFFER, sizeof(rectIndices), rectIndices, GL_STATIC_DRAW);
glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0);
glBindBuffer(GL_ARRAY_BUFFER, 0);
// Initialize hit value
float hit = 0.02f;
// Initialize a boolean that will be used to stop the application’s loop and another one to pause/unpause rendering
bool end = false;
bool refresh = true;
// SDL variable that will be used to store input events
SDL_Event events;
// Initialize time variables. They will be used to limit the number of frames rendered per second.
// Frame counter
unsigned int riftc = 0, zedc = 1;
// Chronometer
unsigned int rifttime = 0, zedtime = 0, zedFPS = 0;
int time1 = 0, timePerFrame = 0;
int frameRate = (int)(1000 / MAX_FPS);
// This boolean is used to test if the application is focused
bool isVisible = true;
// Enable the shader
glUseProgram(shader.getProgramId());
// Bind the Vertex Buffer Objects of the rectangle that displays ZED images
// vertices
glEnableVertexAttribArray(Shader::ATTRIB_VERTICES_POS);
glBindBuffer(GL_ARRAY_BUFFER, rectVBO[0]);
glVertexAttribPointer(Shader::ATTRIB_VERTICES_POS, 3, GL_FLOAT, GL_FALSE, 0, 0);
// indices
glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, rectVBO[2]);
// texture coordinates
glEnableVertexAttribArray(Shader::ATTRIB_TEXTURE2D_POS);
glBindBuffer(GL_ARRAY_BUFFER, rectVBO[1]);
glVertexAttribPointer(Shader::ATTRIB_TEXTURE2D_POS, 2, GL_FLOAT, GL_FALSE, 0, 0);
// Main loop
while (!end)
{
// Compute the time used to render the previous frame
timePerFrame = SDL_GetTicks() - time1;
// If the previous frame has been rendered too fast
if (timePerFrame < frameRate)
{
// Pause the loop to have a max FPS equal to MAX_FPS
SDL_Delay(frameRate - timePerFrame);
timePerFrame = frameRate;
}
// Increment the ZED chronometer
zedtime += timePerFrame;
// If ZED chronometer reached 1 second
if (zedtime > 1000)
{
zedFPS = zedc;
zedc = 0;
zedtime = 0;
}
// Increment the Rift chronometer and the Rift frame counter
rifttime += timePerFrame;
riftc++;
// If Rift chronometer reached 200 milliseconds
if (rifttime > 200)
{
// Display FPS
std::cout << "\rRIFT FPS: " << 1000 / (rifttime / riftc) << " | ZED FPS: " << zedFPS;
// Reset Rift chronometer
rifttime = 0;
// Reset Rift frame counter
riftc = 0;
}
// Start frame chronometer
time1 = SDL_GetTicks();
// While there is an event catched and not tested
while (SDL_PollEvent(&events))
{
// If a key is released
if (events.type == SDL_KEYUP)
{
// If Q quit the application
if (events.key.keysym.scancode == SDL_SCANCODE_Q)
end = true;
// If R reset the hit value
else if (events.key.keysym.scancode == SDL_SCANCODE_R)
hit = 0.0f;
// If C pause/unpause rendering
else if (events.key.keysym.scancode == SDL_SCANCODE_C)
refresh = !refresh;
}
// If the mouse wheel is used
if (events.type == SDL_MOUSEWHEEL)
{
// Increase or decrease hit value
float s;
events.wheel.y > 0 ? s = 1.0f : s = -1.0f;
hit += 0.005f * s;
}
}
// Get texture swap index where we must draw our frame
GLuint curTexId;
int curIndex;
ovr_GetTextureSwapChainCurrentIndex(session, textureChain, &curIndex);
ovr_GetTextureSwapChainBufferGL(session, textureChain, curIndex, &curTexId);
// Call ovr_GetRenderDesc each frame to get the ovrEyeRenderDesc, as the returned values (e.g. HmdToEyeOffset) may change at runtime.
eyeRenderDesc[0] = ovr_GetRenderDesc(session, ovrEye_Left, hmdDesc.DefaultEyeFov[0]);
eyeRenderDesc[1] = ovr_GetRenderDesc(session, ovrEye_Right, hmdDesc.DefaultEyeFov[1]);
hmdToEyeOffset[0] = eyeRenderDesc[0].HmdToEyeOffset;
hmdToEyeOffset[1] = eyeRenderDesc[1].HmdToEyeOffset;
// Get eye poses, feeding in correct IPD offset
ovr_GetEyePoses(session, frameIndex, ovrTrue, hmdToEyeOffset, eyeRenderPose, &sensorSampleTime);
// If the application is focused
if (isVisible)
{
// If successful grab a new ZED image
if (!zed->grab(sl::zed::SENSING_MODE::RAW, false, false))
{
// Update the ZED frame counter
zedc++;
if (refresh)
{
#if OPENGL_GPU_INTEROP
sl::zed::Mat m = zed->retrieveImage_gpu(sl::zed::SIDE::LEFT);
cudaArray_t arrIm;
cudaGraphicsMapResources(1, &cimg_L, 0);
cudaGraphicsSubResourceGetMappedArray(&arrIm, cimg_L, 0, 0);
cudaMemcpy2DToArray(arrIm, 0, 0, m.data, m.step, zedWidth * 4, zedHeight, cudaMemcpyDeviceToDevice);
cudaGraphicsUnmapResources(1, &cimg_L, 0);
m = zed->retrieveImage_gpu(sl::zed::SIDE::RIGHT);
cudaGraphicsMapResources(1, &cimg_R, 0);
cudaGraphicsSubResourceGetMappedArray(&arrIm, cimg_R, 0, 0);
cudaMemcpy2DToArray(arrIm, 0, 0, m.data, m.step, zedWidth * 4, zedHeight, cudaMemcpyDeviceToDevice); // *4 = 4 channels * 1 bytes (uint)
cudaGraphicsUnmapResources(1, &cimg_R, 0);
#endif
// Bind the frame buffer
glBindFramebuffer(GL_FRAMEBUFFER, fboID);
// Set its color layer 0 as the current swap texture
glFramebufferTexture2D(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0, GL_TEXTURE_2D, curTexId, 0);
// Set its depth layer as our depth buffer
glFramebufferTexture2D(GL_FRAMEBUFFER, GL_DEPTH_ATTACHMENT, GL_TEXTURE_2D, depthBuffID, 0);
// Clear the frame buffer
glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT);
glClearColor(0, 0, 0, 1);
// Render for each Oculus eye the equivalent ZED image
for (int eye = 0; eye < 2; eye++)
{
// Set the left or right vertical half of the buffer as the viewport
glViewport(eye == ovrEye_Left ? 0 : bufferSize.w / 2, 0, bufferSize.w / 2, bufferSize.h);
// Bind the left or right ZED image
glBindTexture(GL_TEXTURE_2D, eye == ovrEye_Left ? zedTextureID_L : zedTextureID_R);
#if !OPENGL_GPU_INTEROP
glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA, zedWidth, zedHeight, 0, GL_BGRA, GL_UNSIGNED_BYTE, zed->retrieveImage(eye == ovrEye_Left ? sl::zed::SIDE::LEFT : sl::zed::SIDE::RIGHT).data);
#endif
// Bind the hit value
glUniform1f(glGetUniformLocation(shader.getProgramId(), "hit"), eye == ovrEye_Left ? hit : -hit);
// Bind the isLeft value
glUniform1ui(glGetUniformLocation(shader.getProgramId(), "isLeft"), eye == ovrEye_Left ? 1U : 0U);
// Draw the ZED image
glDrawElements(GL_TRIANGLES, 6, GL_UNSIGNED_INT, 0);
}
// Avoids an error when calling SetAndClearRenderSurface during next iteration.
// Without this, during the next while loop iteration SetAndClearRenderSurface
// would bind a framebuffer with an invalid COLOR_ATTACHMENT0 because the texture ID
// associated with COLOR_ATTACHMENT0 had been unlocked by calling wglDXUnlockObjectsNV.
glBindFramebuffer(GL_FRAMEBUFFER, fboID);
glFramebufferTexture2D(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0, GL_TEXTURE_2D, 0, 0);
glFramebufferTexture2D(GL_FRAMEBUFFER, GL_DEPTH_ATTACHMENT, GL_TEXTURE_2D, 0, 0);
// Commit changes to the textures so they get picked up frame
ovr_CommitTextureSwapChain(session, textureChain);
}
// Do not forget to increment the frameIndex!
frameIndex++;
}
}
/*
Note: Even if we don't ask to refresh the framebuffer or if the Camera::grab()
doesn't catch a new frame, we have to submit an image to the Rift; it
needs 75Hz refresh. Else there will be jumbs, black frames and/or glitches
in the headset.
*/
ovrLayerEyeFov ld;
ld.Header.Type = ovrLayerType_EyeFov;
// Tell to the Oculus compositor that our texture origin is at the bottom left
ld.Header.Flags = ovrLayerFlag_TextureOriginAtBottomLeft; // Because OpenGL | Disable head tracking
// Set the Oculus layer eye field of view for each view
for (int eye = 0; eye < 2; ++eye)
{
// Set the color texture as the current swap texture
ld.ColorTexture[eye] = textureChain;
// Set the viewport as the right or left vertical half part of the color texture
ld.Viewport[eye] = OVR::Recti(eye == ovrEye_Left ? 0 : bufferSize.w / 2, 0, bufferSize.w / 2, bufferSize.h);
// Set the field of view
ld.Fov[eye] = hmdDesc.DefaultEyeFov[eye];
// Set the pose matrix
ld.RenderPose[eye] = eyeRenderPose[eye];
}
ld.SensorSampleTime = sensorSampleTime;
ovrLayerHeader* layers = &ld.Header;
// Submit the frame to the Oculus compositor
// which will display the frame in the Oculus headset
result = ovr_SubmitFrame(session, frameIndex, nullptr, &layers, 1);
if (!OVR_SUCCESS(result))
{
std::cout << "ERROR: failed to submit frame" << std::endl;
glDeleteBuffers(3, rectVBO);
ovr_DestroyTextureSwapChain(session, textureChain);
ovr_DestroyMirrorTexture(session, mirrorTexture);
ovr_Destroy(session);
ovr_Shutdown();
SDL_GL_DeleteContext(glContext);
SDL_DestroyWindow(window);
SDL_Quit();
delete zed;
return -1;
}
if (result == ovrSuccess && !isVisible)
{
std::cout << "The application is now shown in the headset." << std::endl;
}
isVisible = (result == ovrSuccess);
// This is not really needed for this application but it may be usefull for an more advanced application
ovrSessionStatus sessionStatus;
ovr_GetSessionStatus(session, &sessionStatus);
if (sessionStatus.ShouldRecenter)
{
std::cout << "Recenter Tracking asked by Session" << std::endl;
ovr_RecenterTrackingOrigin(session);
}
// Copy the frame to the mirror buffer
// which will be drawn in the SDL2 image
glBindFramebuffer(GL_READ_FRAMEBUFFER, mirrorFBOID);
glBindFramebuffer(GL_DRAW_FRAMEBUFFER, 0);
GLint w = winWidth;
GLint h = winHeight;
glBlitFramebuffer(0, h, w, 0,
0, 0, w, h,
GL_COLOR_BUFFER_BIT, GL_NEAREST);
glBindFramebuffer(GL_READ_FRAMEBUFFER, 0);
// Swap the SDL2 window
SDL_GL_SwapWindow(window);
}
// Disable all OpenGL buffer
glDisableVertexAttribArray(Shader::ATTRIB_TEXTURE2D_POS);
glDisableVertexAttribArray(Shader::ATTRIB_VERTICES_POS);
glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0);
glBindBuffer(GL_ARRAY_BUFFER, 0);
glBindTexture(GL_TEXTURE_2D, 0);
glUseProgram(0);
glBindVertexArray(0);
// Delete the Vertex Buffer Objects of the rectangle
glDeleteBuffers(3, rectVBO);
// Delete SDL, OpenGL, Oculus and ZED context
ovr_DestroyTextureSwapChain(session, textureChain);
ovr_DestroyMirrorTexture(session, mirrorTexture);
ovr_Destroy(session);
ovr_Shutdown();
SDL_GL_DeleteContext(glContext);
SDL_DestroyWindow(window);
SDL_Quit();
delete zed;
// quit
return 0;
}
// Commit changes
void Commit()
{
ovr_CommitTextureSwapChain(Session, TextureChain);
}
// Display to an HMD with OVR SDK backend.
void displayHMD()
{
ovrSessionStatus sessionStatus;
ovr_GetSessionStatus(g_session, &sessionStatus);
if (sessionStatus.HmdPresent == false)
{
displayMonitor();
return;
}
const ovrHmdDesc& hmdDesc = m_Hmd;
double sensorSampleTime; // sensorSampleTime is fed into the layer later
if (g_hmdVisible)
{
// Call ovr_GetRenderDesc each frame to get the ovrEyeRenderDesc, as the returned values (e.g. HmdToEyeOffset) may change at runtime.
ovrEyeRenderDesc eyeRenderDesc[2];
eyeRenderDesc[0] = ovr_GetRenderDesc(g_session, ovrEye_Left, hmdDesc.DefaultEyeFov[0]);
eyeRenderDesc[1] = ovr_GetRenderDesc(g_session, ovrEye_Right, hmdDesc.DefaultEyeFov[1]);
// Get eye poses, feeding in correct IPD offset
ovrVector3f HmdToEyeOffset[2] = {
eyeRenderDesc[0].HmdToEyeOffset,
eyeRenderDesc[1].HmdToEyeOffset };
#if 0
// Get both eye poses simultaneously, with IPD offset already included.
double displayMidpointSeconds = ovr_GetPredictedDisplayTime(g_session, 0);
ovrTrackingState hmdState = ovr_GetTrackingState(g_session, displayMidpointSeconds, ovrTrue);
ovr_CalcEyePoses(hmdState.HeadPose.ThePose, HmdToEyeOffset, m_eyePoses);
#else
ovr_GetEyePoses(g_session, g_frameIndex, ovrTrue, HmdToEyeOffset, m_eyePoses, &sensorSampleTime);
#endif
storeHmdPose(m_eyePoses[0]);
for (int eye = 0; eye < 2; ++eye)
{
const FBO& swapfbo = m_swapFBO[eye];
const ovrTextureSwapChain& chain = g_textureSwapChain[eye];
int curIndex;
ovr_GetTextureSwapChainCurrentIndex(g_session, chain, &curIndex);
GLuint curTexId;
ovr_GetTextureSwapChainBufferGL(g_session, chain, curIndex, &curTexId);
glBindFramebuffer(GL_FRAMEBUFFER, swapfbo.id);
glFramebufferTexture2D(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0, GL_TEXTURE_2D, curTexId, 0);
glViewport(0, 0, swapfbo.w, swapfbo.h);
glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT);
glEnable(GL_FRAMEBUFFER_SRGB);
{
glClearColor(0.3f, 0.3f, 0.3f, 0.f);
glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT);
const ovrSizei& downSize = ovr_GetFovTextureSize(g_session, ovrEyeType(eye), hmdDesc.DefaultEyeFov[eye], m_fboScale);
ovrRecti vp = { 0, 0, downSize.w, downSize.h };
const int texh = swapfbo.h;
vp.Pos.y = (texh - vp.Size.h) / 2;
glViewport(vp.Pos.x, vp.Pos.y, vp.Size.w, vp.Size.h);
// Cinemascope - letterbox bars scissoring off pixels above and below vp center
const float hc = .5f * m_cinemaScope;
const int scisPx = static_cast<int>(hc * static_cast<float>(vp.Size.h));
ovrRecti sp = vp;
sp.Pos.y += scisPx;
sp.Size.h -= 2 * scisPx;
glScissor(sp.Pos.x, sp.Pos.y, sp.Size.w, sp.Size.h);
glEnable(GL_SCISSOR_TEST);
glEnable(GL_DEPTH_TEST);
// Render the scene for the current eye
const ovrPosef& eyePose = m_eyePoses[eye];
const glm::mat4 mview =
makeWorldToChassisMatrix() *
makeMatrixFromPose(eyePose, m_headSize);
const ovrMatrix4f ovrproj = ovrMatrix4f_Projection(hmdDesc.DefaultEyeFov[eye], 0.2f, 1000.0f, ovrProjection_None);
const glm::mat4 proj = makeGlmMatrixFromOvrMatrix(ovrproj);
g_pScene->RenderForOneEye(glm::value_ptr(glm::inverse(mview)), glm::value_ptr(proj));
const ovrTextureSwapChain& chain = g_textureSwapChain[eye];
const ovrResult commitres = ovr_CommitTextureSwapChain(g_session, chain);
if (!OVR_SUCCESS(commitres))
{
LOG_ERROR("ovr_CommitTextureSwapChain returned %d", commitres);
return;
}
}
glDisable(GL_SCISSOR_TEST);
// Grab a copy of the left eye's undistorted render output for presentation
// to the desktop window instead of the barrel distorted mirror texture.
// This blit, while cheap, could cost some framerate to the HMD.
// An over-the-shoulder view is another option, at a greater performance cost.
if (0)
{
if (eye == ovrEyeType::ovrEye_Left)
{
BlitLeftEyeRenderToUndistortedMirrorTexture();
}
}
glFramebufferTexture2D(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0, GL_TEXTURE_2D, 0, 0);
glBindFramebuffer(GL_FRAMEBUFFER, 0);
}
}
std::vector<const ovrLayerHeader*> layerHeaders;
{
// Do distortion rendering, Present and flush/sync
ovrLayerEyeFov ld;
ld.Header.Type = ovrLayerType_EyeFov;
ld.Header.Flags = ovrLayerFlag_TextureOriginAtBottomLeft; // Because OpenGL.
for (int eye = 0; eye < 2; ++eye)
{
const FBO& swapfbo = m_swapFBO[eye];
const ovrTextureSwapChain& chain = g_textureSwapChain[eye];
ld.ColorTexture[eye] = chain;
const ovrSizei& downSize = ovr_GetFovTextureSize(g_session, ovrEyeType(eye), hmdDesc.DefaultEyeFov[eye], m_fboScale);
ovrRecti vp = { 0, 0, downSize.w, downSize.h };
const int texh = swapfbo.h;
vp.Pos.y = (texh - vp.Size.h) / 2;
ld.Viewport[eye] = vp;
ld.Fov[eye] = hmdDesc.DefaultEyeFov[eye];
ld.RenderPose[eye] = m_eyePoses[eye];
ld.SensorSampleTime = sensorSampleTime;
}
layerHeaders.push_back(&ld.Header);
// Submit layers to HMD for display
ovrLayerQuad ql;
if (g_tweakbarQuad.m_showQuadInWorld)
{
ql.Header.Type = ovrLayerType_Quad;
ql.Header.Flags = ovrLayerFlag_TextureOriginAtBottomLeft; // Because OpenGL.
ql.ColorTexture = g_tweakbarQuad.m_swapChain;
ovrRecti vp;
vp.Pos.x = 0;
vp.Pos.y = 0;
vp.Size.w = 600; ///@todo
vp.Size.h = 600; ///@todo
ql.Viewport = vp;
ql.QuadPoseCenter = g_tweakbarQuad.m_QuadPoseCenter;
ql.QuadSize = { 1.f, 1.f }; ///@todo Pass in
g_tweakbarQuad.SetHmdEyeRay(m_eyePoses[ovrEyeType::ovrEye_Left]); // Writes to m_layerQuad.QuadPoseCenter
g_tweakbarQuad.DrawToQuad();
layerHeaders.push_back(&ql.Header);
}
}
#if 0
ovrViewScaleDesc viewScaleDesc;
viewScaleDesc.HmdToEyeOffset[0] = m_eyeOffsets[0];
viewScaleDesc.HmdToEyeOffset[1] = m_eyeOffsets[1];
viewScaleDesc.HmdSpaceToWorldScaleInMeters = 1.f;
#endif
const ovrResult result = ovr_SubmitFrame(g_session, g_frameIndex, nullptr, &layerHeaders[0], layerHeaders.size());
if (result == ovrSuccess)
{
g_hmdVisible = true;
}
else if (result == ovrSuccess_NotVisible)
{
g_hmdVisible = false;
///@todo Enter a lower-power, polling "no focus/HMD not worn" mode
}
else if (result == ovrError_DisplayLost)
{
LOG_INFO("ovr_SubmitFrame returned ovrError_DisplayLost");
g_hmdVisible = false;
///@todo Tear down textures and session and re-create
}
else
{
LOG_INFO("ovr_SubmitFrame returned %d", result);
//g_hmdVisible = false;
}
// Handle OVR session events
ovr_GetSessionStatus(g_session, &sessionStatus);
if (sessionStatus.ShouldQuit)
{
glfwSetWindowShouldClose(g_pMirrorWindow, 1);
}
if (sessionStatus.ShouldRecenter)
{
ovr_RecenterTrackingOrigin(g_session);
}
// Blit mirror texture to monitor window
if (g_hmdVisible)
{
glViewport(0, 0, g_mirrorWindowSz.x, g_mirrorWindowSz.y);
const FBO& srcFBO = m_mirrorFBO;
glBindFramebuffer(GL_READ_FRAMEBUFFER, srcFBO.id);
glBlitFramebuffer(
0, srcFBO.h, srcFBO.w, 0,
0, 0, g_mirrorWindowSz.x, g_mirrorWindowSz.y,
GL_COLOR_BUFFER_BIT, GL_NEAREST);
glBindFramebuffer(GL_READ_FRAMEBUFFER, 0);
}
else
{
displayMonitor();
}
++g_frameIndex;
#ifdef USE_ANTTWEAKBAR
if (g_tweakbarQuad.m_showQuadInWorld)
{
TwDraw();
}
#endif
}
