#include "translateshaderclass.h" TranslateShaderClass::TranslateShaderClass() { m_vertexShader = 0; m_pixelShader = 0; m_layout = 0; m_matrixBuffer = 0; m_sampleState = 0; m_translateBuffer = 0; } TranslateShaderClass::TranslateShaderClass(const TranslateShaderClass& other) { } TranslateShaderClass::~TranslateShaderClass() { } bool TranslateShaderClass::Initialize(ID3D11Device* device, HWND hwnd) { Logger::Get().Log("Initilaizing TranslateShaderClass", __FILE__, __LINE__, Logger::LogLevel::Initialize); bool result; wchar_t vsFilename[128]; wchar_t psFilename[128]; int error; // Set the filename of the vertex shader. error = wcscpy_s(vsFilename, 128, L"translate.vs"); if (error != 0) { Logger::Get().Log("Failed to copy vsFilename", __FILE__, __LINE__, Logger::LogLevel::Error); return false; } // Set the filename of the pixel shader. error = wcscpy_s(psFilename, 128, L"translate.ps"); if (error != 0) { Logger::Get().Log("Failed to copy psFilename", __FILE__, __LINE__, Logger::LogLevel::Error); return false; } // Initialize the vertex and pixel shaders. result = InitializeShader(device, hwnd, vsFilename, psFilename); if (!result) { Logger::Get().Log("Failed to initialize shader", __FILE__, __LINE__, Logger::LogLevel::Error); return false; } Logger::Get().Log("TranslateShaderClass initialized", __FILE__, __LINE__, Logger::LogLevel::Initialize); return true; } void TranslateShaderClass::Shutdown() { // Shutdown the vertex and pixel shaders as well as the related objects. ShutdownShader(); return; } bool TranslateShaderClass::Render(ID3D11DeviceContext * deviceContext, int indexCount, XMMATRIX worldMatrix, XMMATRIX viewMatrix, XMMATRIX projectionMatrix, ID3D11ShaderResourceView * texture, float translation) { bool result; // Set the shader parameters that it will use for rendering. result = SetShaderParameters(deviceContext, worldMatrix, viewMatrix, projectionMatrix, texture, translation); if (!result) { Logger::Get().Log("Failed to set shader parameters", __FILE__, __LINE__, Logger::LogLevel::Error); return false; } // Now render the prepared buffers with the shader. RenderShader(deviceContext, indexCount); return true; } bool TranslateShaderClass::InitializeShader(ID3D11Device * device, HWND hwnd, WCHAR * vsFilename, WCHAR * psFilename) { Logger::Get().Log("Initializing translate shader", __FILE__, __LINE__, Logger::LogLevel::Initialize); HRESULT result; ID3D10Blob* errorMessage; ID3D10Blob* vertexShaderBuffer; ID3D10Blob* pixelShaderBuffer; D3D11_INPUT_ELEMENT_DESC polygonLayout[2]; unsigned int numElements; D3D11_BUFFER_DESC matrixBufferDesc; D3D11_SAMPLER_DESC samplerDesc; D3D11_BUFFER_DESC translateBufferDesc; // Initialize the pointers this function will use to null. errorMessage = 0; vertexShaderBuffer = 0; pixelShaderBuffer = 0; // Compile the vertex shader code. result = D3DCompileFromFile(vsFilename, NULL, NULL, "TranslateVertexShader", "vs_5_0", D3D10_SHADER_ENABLE_STRICTNESS, 0, &vertexShaderBuffer, &errorMessage); if (FAILED(result)) { // If the shader failed to compile it should have writen something to the error message. if (errorMessage) { OutputShaderErrorMessage(errorMessage, hwnd, vsFilename); } // If there was nothing in the error message then it simply could not find the shader file itself. else { Logger::Get().Log("Failed to compile shader", __FILE__, __LINE__, Logger::LogLevel::Error); } return false; } // Compile the pixel shader code. result = D3DCompileFromFile(psFilename, NULL, NULL, "TranslatePixelShader", "ps_5_0", D3D10_SHADER_ENABLE_STRICTNESS, 0, &pixelShaderBuffer, &errorMessage); if (FAILED(result)) { // If the shader failed to compile it should have writen something to the error message. if (errorMessage) { OutputShaderErrorMessage(errorMessage, hwnd, psFilename); } // If there was nothing in the error message then it simply could not find the file itself. else { Logger::Get().Log("Failed to compile shader", __FILE__, __LINE__, Logger::LogLevel::Error); } return false; } // Create the vertex shader from the buffer. result = device->CreateVertexShader(vertexShaderBuffer->GetBufferPointer(), vertexShaderBuffer->GetBufferSize(), NULL, &m_vertexShader); if (FAILED(result)) { Logger::Get().Log("Failed to create vertex shader", __FILE__, __LINE__, Logger::LogLevel::Error); return false; } // Create the pixel shader from the buffer. result = device->CreatePixelShader(pixelShaderBuffer->GetBufferPointer(), pixelShaderBuffer->GetBufferSize(), NULL, &m_pixelShader); if (FAILED(result)) { Logger::Get().Log("Failed to create pixel shader", __FILE__, __LINE__, Logger::LogLevel::Error); return false; } // Create the vertex input layout description. polygonLayout[0].SemanticName = "POSITION"; polygonLayout[0].SemanticIndex = 0; polygonLayout[0].Format = DXGI_FORMAT_R32G32B32_FLOAT; polygonLayout[0].InputSlot = 0; polygonLayout[0].AlignedByteOffset = 0; polygonLayout[0].InputSlotClass = D3D11_INPUT_PER_VERTEX_DATA; polygonLayout[0].InstanceDataStepRate = 0; polygonLayout[1].SemanticName = "TEXCOORD"; polygonLayout[1].SemanticIndex = 0; polygonLayout[1].Format = DXGI_FORMAT_R32G32_FLOAT; polygonLayout[1].InputSlot = 0; polygonLayout[1].AlignedByteOffset = D3D11_APPEND_ALIGNED_ELEMENT; polygonLayout[1].InputSlotClass = D3D11_INPUT_PER_VERTEX_DATA; polygonLayout[1].InstanceDataStepRate = 0; // Get a count of the elements in the layout. numElements = sizeof(polygonLayout) / sizeof(polygonLayout[0]); // Create the vertex input layout. result = device->CreateInputLayout(polygonLayout, numElements, vertexShaderBuffer->GetBufferPointer(), vertexShaderBuffer->GetBufferSize(), &m_layout); if (FAILED(result)) { Logger::Get().Log("Failed to create input layout", __FILE__, __LINE__, Logger::LogLevel::Error); return false; } // Release the vertex shader buffer and pixel shader buffer since they are no longer needed. vertexShaderBuffer->Release(); vertexShaderBuffer = 0; pixelShaderBuffer->Release(); pixelShaderBuffer = 0; // Setup the description of the dynamic matrix constant buffer that is in the vertex shader. matrixBufferDesc.Usage = D3D11_USAGE_DYNAMIC; matrixBufferDesc.ByteWidth = sizeof(MatrixBufferType); matrixBufferDesc.BindFlags = D3D11_BIND_CONSTANT_BUFFER; matrixBufferDesc.CPUAccessFlags = D3D11_CPU_ACCESS_WRITE; matrixBufferDesc.MiscFlags = 0; matrixBufferDesc.StructureByteStride = 0; // Create the constant buffer pointer so we can access the vertex shader constant buffer from within this class. result = device->CreateBuffer(&matrixBufferDesc, NULL, &m_matrixBuffer); if (FAILED(result)) { Logger::Get().Log("Failed to create matrix buffer", __FILE__, __LINE__, Logger::LogLevel::Error); return false; } // Create a texture sampler state description. samplerDesc.Filter = D3D11_FILTER_MIN_MAG_MIP_LINEAR; samplerDesc.AddressU = D3D11_TEXTURE_ADDRESS_WRAP; samplerDesc.AddressV = D3D11_TEXTURE_ADDRESS_WRAP; samplerDesc.AddressW = D3D11_TEXTURE_ADDRESS_WRAP; samplerDesc.MipLODBias = 0.0f; samplerDesc.MaxAnisotropy = 1; samplerDesc.ComparisonFunc = D3D11_COMPARISON_ALWAYS; samplerDesc.BorderColor[0] = 0; samplerDesc.BorderColor[1] = 0; samplerDesc.BorderColor[2] = 0; samplerDesc.BorderColor[3] = 0; samplerDesc.MinLOD = 0; samplerDesc.MaxLOD = D3D11_FLOAT32_MAX; // Create the texture sampler state. result = device->CreateSamplerState(&samplerDesc, &m_sampleState); if (FAILED(result)) { Logger::Get().Log("Failed to create sampler state", __FILE__, __LINE__, Logger::LogLevel::Error); return false; } // Setup the description of the texture translation dynamic constant buffer that is in the pixel shader. translateBufferDesc.Usage = D3D11_USAGE_DYNAMIC; translateBufferDesc.ByteWidth = sizeof(TranslateBufferType); translateBufferDesc.BindFlags = D3D11_BIND_CONSTANT_BUFFER; translateBufferDesc.CPUAccessFlags = D3D11_CPU_ACCESS_WRITE; translateBufferDesc.MiscFlags = 0; translateBufferDesc.StructureByteStride = 0; // Create the constant buffer pointer so we can access the pixel shader constant buffer from within this class. result = device->CreateBuffer(&translateBufferDesc, NULL, &m_translateBuffer); if (FAILED(result)) { Logger::Get().Log("Failed to create translate buffer", __FILE__, __LINE__, Logger::LogLevel::Error); return false; } Logger::Get().Log("Translate shader initialized", __FILE__, __LINE__, Logger::LogLevel::Initialize); return true; } void TranslateShaderClass::ShutdownShader() { Logger::Get().Log("Shutting down translate shader", __FILE__, __LINE__, Logger::LogLevel::Shutdown); // Release the texture translation constant buffer. if (m_translateBuffer) { m_translateBuffer->Release(); m_translateBuffer = 0; } // Release the sampler state. if (m_sampleState) { m_sampleState->Release(); m_sampleState = 0; } // Release the matrix constant buffer. if (m_matrixBuffer) { m_matrixBuffer->Release(); m_matrixBuffer = 0; } // Release the layout. if (m_layout) { m_layout->Release(); m_layout = 0; } // Release the pixel shader. if (m_pixelShader) { m_pixelShader->Release(); m_pixelShader = 0; } // Release the vertex shader. if (m_vertexShader) { m_vertexShader->Release(); m_vertexShader = 0; } Logger::Get().Log("Translate shader shut down", __FILE__, __LINE__, Logger::LogLevel::Shutdown); return; } void TranslateShaderClass::OutputShaderErrorMessage(ID3D10Blob * errorMessage, HWND hwnd, WCHAR * shaderFilename) { char* compileErrors; unsigned long long bufferSize, i; ofstream fout; // Get a pointer to the error message text buffer. compileErrors = (char*)(errorMessage->GetBufferPointer()); // Get the length of the message. bufferSize = errorMessage->GetBufferSize(); // Open a file to write the error message to. fout.open("shader-error.txt"); // Write out the error message. for (i = 0; i < bufferSize; i++) { fout << compileErrors[i]; } // Close the file. fout.close(); // Release the error message. errorMessage->Release(); errorMessage = 0; // Pop a message up on the screen to notify the user to check the text file for compile errors. MessageBox(hwnd, L"Error compiling shader. Check shader-error.txt for message.", shaderFilename, MB_OK); return; } bool TranslateShaderClass::SetShaderParameters(ID3D11DeviceContext * deviceContext, XMMATRIX worldMatrix, XMMATRIX viewMatrix, XMMATRIX projectionMatrix, ID3D11ShaderResourceView * texture, float translation) { HRESULT result; D3D11_MAPPED_SUBRESOURCE mappedResource; MatrixBufferType* dataPtr; unsigned int bufferNumber; TranslateBufferType* dataPtr2; // Transpose the matrices to prepare them for the shader. worldMatrix = XMMatrixTranspose(worldMatrix); viewMatrix = XMMatrixTranspose(viewMatrix); projectionMatrix = XMMatrixTranspose(projectionMatrix); // Lock the constant buffer so it can be written to. result = deviceContext->Map(m_matrixBuffer, 0, D3D11_MAP_WRITE_DISCARD, 0, &mappedResource); if (FAILED(result)) { Logger::Get().Log("Failed to map matrix buffer", __FILE__, __LINE__, Logger::LogLevel::Error); return false; } // Get a pointer to the data in the constant buffer. dataPtr = (MatrixBufferType*)mappedResource.pData; // Copy the matrices into the constant buffer. dataPtr->world = worldMatrix; dataPtr->view = viewMatrix; dataPtr->projection = projectionMatrix; // Unlock the constant buffer. deviceContext->Unmap(m_matrixBuffer, 0); // Set the position of the constant buffer in the vertex shader. bufferNumber = 0; // Finally set the constant buffer in the vertex shader with the updated values. deviceContext->VSSetConstantBuffers(bufferNumber, 1, &m_matrixBuffer); // Set shader texture resource in the pixel shader. deviceContext->PSSetShaderResources(0, 1, &texture); // Lock the texture translation constant buffer so it can be written to. result = deviceContext->Map(m_translateBuffer, 0, D3D11_MAP_WRITE_DISCARD, 0, &mappedResource); if (FAILED(result)) { Logger::Get().Log("Failed to map translate buffer", __FILE__, __LINE__, Logger::LogLevel::Error); return false; } // Get a pointer to the data in the texture translation constant buffer. dataPtr2 = (TranslateBufferType*)mappedResource.pData; // Copy the translation value into the texture translation constant buffer. dataPtr2->translation = translation; // Unlock the buffer. deviceContext->Unmap(m_translateBuffer, 0); // Set the position of the texture translation constant buffer in the pixel shader. bufferNumber = 0; // Now set the texture translation constant buffer in the pixel shader with the updated values. deviceContext->PSSetConstantBuffers(bufferNumber, 1, &m_translateBuffer); return true; } void TranslateShaderClass::RenderShader(ID3D11DeviceContext * deviceContext, int indexCount) { // Set the vertex input layout. deviceContext->IASetInputLayout(m_layout); // Set the vertex and pixel shaders that will be used to render this triangle. deviceContext->VSSetShader(m_vertexShader, NULL, 0); deviceContext->PSSetShader(m_pixelShader, NULL, 0); // Set the sampler state in the pixel shader. deviceContext->PSSetSamplers(0, 1, &m_sampleState); // Render the geometry. deviceContext->DrawIndexed(indexCount, 0, 0); return; }