Merge vk-gl-cts/vulkan-cts-1.2.6 into vk-gl-cts/vulkan-cts-1.2.7

[platform/upstream/VK-GL-CTS.git] / executor / xeTestResultParser.cpp

/*-------------------------------------------------------------------------
 * drawElements Quality Program Test Executor
 * ------------------------------------------
 *
 * Copyright 2014 The Android Open Source Project
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 *
 *//*!
 * \file
 * \brief Test case result parser.
 *//*--------------------------------------------------------------------*/

#include "xeTestResultParser.hpp"
#include "xeTestCaseResult.hpp"
#include "xeBatchResult.hpp"
#include "deString.h"
#include "deInt32.h"

#include <sstream>
#include <stdlib.h>

using std::string;
using std::vector;

namespace xe
{

static inline int toInt (const char* str)
{
        return atoi(str);
}

static inline double toDouble (const char* str)
{
        return atof(str);
}

static inline deInt64 toInt64 (const char* str)
{
        std::istringstream      s       (str);
        deInt64                         val;

        s >> val;

        return val;
}

static inline bool toBool (const char* str)
{
        return deStringEqual(str, "OK") || deStringEqual(str, "True");
}

static const char* stripLeadingWhitespace (const char* str)
{
        int whitespaceCount = 0;

        while (str[whitespaceCount]     != 0    &&
                   (str[whitespaceCount] == ' '         ||
                        str[whitespaceCount] == '\t'    ||
                        str[whitespaceCount] == '\r'    ||
                        str[whitespaceCount] == '\n'))
                whitespaceCount += 1;

        return str + whitespaceCount;
}

struct EnumMapEntry
{
        deUint32                hash;
        const char*             name;
        int                             value;
};

static const EnumMapEntry s_statusCodeMap[] =
{
        { 0x7c8a99bc,   "Pass",                                 TESTSTATUSCODE_PASS                                             },
        { 0x7c851ca1,   "Fail",                                 TESTSTATUSCODE_FAIL                                             },
        { 0x10ecd324,   "QualityWarning",               TESTSTATUSCODE_QUALITY_WARNING                  },
        { 0x341ae835,   "CompatibilityWarning", TESTSTATUSCODE_COMPATIBILITY_WARNING    },
        { 0x058acbca,   "Pending",                              TESTSTATUSCODE_PENDING                                  },
        { 0xc4d74b26,   "Running",                              TESTSTATUSCODE_RUNNING                                  },
        { 0x6409f93c,   "NotSupported",                 TESTSTATUSCODE_NOT_SUPPORTED                    },
        { 0xfa5a9ab7,   "ResourceError",                TESTSTATUSCODE_RESOURCE_ERROR                   },
        { 0xad6793ec,   "InternalError",                TESTSTATUSCODE_INTERNAL_ERROR                   },
        { 0x838f3034,   "Canceled",                             TESTSTATUSCODE_CANCELED                                 },
        { 0x42b6efac,   "Timeout",                              TESTSTATUSCODE_TIMEOUT                                  },
        { 0x0cfb98f6,   "Crash",                                TESTSTATUSCODE_CRASH                                    },
        { 0xe326e01d,   "Disabled",                             TESTSTATUSCODE_DISABLED                                 },
        { 0x77061af2,   "Terminated",                   TESTSTATUSCODE_TERMINATED                               },
        { 0xd9e6b393,   "Waiver",                           TESTSTATUSCODE_WAIVER                                   }
};

static const EnumMapEntry s_resultItemMap[] =
{
        { 0xce8ac2e4,   "Result",                               ri::TYPE_RESULT                 },
        { 0x7c8cdcea,   "Text",                                 ri::TYPE_TEXT                   },
        { 0xc6540c6e,   "Number",                               ri::TYPE_NUMBER                 },
        { 0x0d656c88,   "Image",                                ri::TYPE_IMAGE                  },
        { 0x8ac9ee14,   "ImageSet",                             ri::TYPE_IMAGESET               },
        { 0x1181fa5a,   "VertexShader",                 ri::TYPE_SHADER                 },
        { 0xa93daef0,   "FragmentShader",               ri::TYPE_SHADER                 },
        { 0x8f066128,   "GeometryShader",               ri::TYPE_SHADER                 },
        { 0x235a931c,   "TessControlShader",    ri::TYPE_SHADER                 },
        { 0xa1bf7153,   "TessEvaluationShader", ri::TYPE_SHADER                 },
        { 0x6c1415d9,   "ComputeShader",                ri::TYPE_SHADER                 },
        { 0x68738b22,   "RaygenShader",                 ri::TYPE_SHADER                 },
        { 0x51d29ce9,   "AnyHitShader",                 ri::TYPE_SHADER                 },
        { 0x8c64a6be,   "ClosestHitShader",             ri::TYPE_SHADER                 },
        { 0xb30ed398,   "MissShader",                   ri::TYPE_SHADER                 },
        { 0x26150e53,   "IntersectionShader",   ri::TYPE_SHADER                 },
        { 0x7e50944c,   "CallableShader",               ri::TYPE_SHADER                 },
        { 0x72863a54,   "ShaderProgram",                ri::TYPE_SHADERPROGRAM  },
        { 0xb4efc08d,   "ShaderSource",                 ri::TYPE_SHADERSOURCE   },
        { 0xaee4380a,   "SpirVAssemblySource",  ri::TYPE_SPIRVSOURCE    },
        { 0xff265913,   "InfoLog",                              ri::TYPE_INFOLOG                },
        { 0x84159b73,   "EglConfig",                    ri::TYPE_EGLCONFIG              },
        { 0xdd34391f,   "EglConfigSet",                 ri::TYPE_EGLCONFIGSET   },
        { 0xebbb3aba,   "Section",                              ri::TYPE_SECTION                },
        { 0xa0f15677,   "KernelSource",                 ri::TYPE_KERNELSOURCE   },
        { 0x1ee9083a,   "CompileInfo",                  ri::TYPE_COMPILEINFO    },
        { 0xf1004023,   "SampleList",                   ri::TYPE_SAMPLELIST             },
        { 0xf0feae93,   "SampleInfo",                   ri::TYPE_SAMPLEINFO             },
        { 0x2aa6f14e,   "ValueInfo",                    ri::TYPE_VALUEINFO              },
        { 0xd09429e7,   "Sample",                               ri::TYPE_SAMPLE                 },
        { 0x0e4a4722,   "Value",                                ri::TYPE_SAMPLEVALUE    }
};

static const EnumMapEntry s_imageFormatMap[] =
{
        { 0xcc4ffac8,   "RGB888",               ri::Image::FORMAT_RGB888        },
        { 0x20dcb0c1,   "RGBA8888",             ri::Image::FORMAT_RGBA8888      }
};

static const EnumMapEntry s_compressionMap[] =
{
        { 0x7c89bbd5,   "None",                 ri::Image::COMPRESSION_NONE     },
        { 0x0b88118a,   "PNG",                  ri::Image::COMPRESSION_PNG      }
};

static const EnumMapEntry s_shaderTypeFromTagMap[] =
{
        { 0x1181fa5a,   "VertexShader",                 ri::Shader::SHADERTYPE_VERTEX                   },
        { 0xa93daef0,   "FragmentShader",               ri::Shader::SHADERTYPE_FRAGMENT                 },
        { 0x8f066128,   "GeometryShader",               ri::Shader::SHADERTYPE_GEOMETRY                 },
        { 0x235a931c,   "TessControlShader",    ri::Shader::SHADERTYPE_TESS_CONTROL             },
        { 0xa1bf7153,   "TessEvaluationShader", ri::Shader::SHADERTYPE_TESS_EVALUATION  },
        { 0x6c1415d9,   "ComputeShader",                ri::Shader::SHADERTYPE_COMPUTE                  },
        { 0x68738b22,   "RaygenShader",                 ri::Shader::SHADERTYPE_RAYGEN                   },
        { 0x51d29ce9,   "AnyHitShader",                 ri::Shader::SHADERTYPE_ANY_HIT                  },
        { 0x8c64a6be,   "ClosestHitShader",             ri::Shader::SHADERTYPE_CLOSEST_HIT              },
        { 0xb30ed398,   "MissShader",                   ri::Shader::SHADERTYPE_MISS                             },
        { 0x26150e53,   "IntersectionShader",   ri::Shader::SHADERTYPE_INTERSECTION             },
        { 0x7e50944c,   "CallableShader",               ri::Shader::SHADERTYPE_CALLABLE                 }
};

static const EnumMapEntry s_testTypeMap[] =
{
        { 0x7fa80959,   "SelfValidate", TESTCASETYPE_SELF_VALIDATE      },
        { 0xdb797567,   "Capability",   TESTCASETYPE_CAPABILITY         },
        { 0x2ca3ec10,   "Accuracy",             TESTCASETYPE_ACCURACY           },
        { 0xa48ac277,   "Performance",  TESTCASETYPE_PERFORMANCE        }
};

static const EnumMapEntry s_logVersionMap[] =
{
        { 0x0b7dac93,   "0.2.0",                TESTLOGVERSION_0_2_0    },
        { 0x0b7db0d4,   "0.3.0",                TESTLOGVERSION_0_3_0    },
        { 0x0b7db0d5,   "0.3.1",                TESTLOGVERSION_0_3_1    },
        { 0x0b7db0d6,   "0.3.2",                TESTLOGVERSION_0_3_2    },
        { 0x0b7db0d7,   "0.3.3",                TESTLOGVERSION_0_3_3    },
        { 0x0b7db0d8,   "0.3.4",                TESTLOGVERSION_0_3_4    }
};

static const EnumMapEntry s_sampleValueTagMap[] =
{
        { 0xddf2d0d1,   "Predictor",    ri::ValueInfo::VALUETAG_PREDICTOR       },
        { 0x9bee2c34,   "Response",             ri::ValueInfo::VALUETAG_RESPONSE        },
};

#if defined(DE_DEBUG)
static void printHashes (const char* name, const EnumMapEntry* entries, int numEntries)
{
        printf("%s:\n", name);

        for (int ndx = 0; ndx < numEntries; ndx++)
                printf("0x%08x\t%s\n", deStringHash(entries[ndx].name), entries[ndx].name);

        printf("\n");
}

#define PRINT_HASHES(MAP) printHashes(#MAP, MAP, DE_LENGTH_OF_ARRAY(MAP))

void TestResultParser_printHashes (void)
{
        PRINT_HASHES(s_statusCodeMap);
        PRINT_HASHES(s_resultItemMap);
        PRINT_HASHES(s_imageFormatMap);
        PRINT_HASHES(s_compressionMap);
        PRINT_HASHES(s_shaderTypeFromTagMap);
        PRINT_HASHES(s_testTypeMap);
        PRINT_HASHES(s_logVersionMap);
        PRINT_HASHES(s_sampleValueTagMap);
}
#endif

static inline int getEnumValue (const char* enumName, const EnumMapEntry* entries, int numEntries, const char* name)
{
        deUint32 hash = deStringHash(name);

        for (int ndx = 0; ndx < numEntries; ndx++)
        {
                if (entries[ndx].hash == hash && deStringEqual(entries[ndx].name, name))
                        return entries[ndx].value;
        }

        throw TestResultParseError(string("Could not map '") + name + "' to " + enumName);
}

TestStatusCode getTestStatusCode (const char* statusCode)
{
        return (TestStatusCode)getEnumValue("status code", s_statusCodeMap, DE_LENGTH_OF_ARRAY(s_statusCodeMap), statusCode);
}

static ri::Type getResultItemType (const char* elemName)
{
        return (ri::Type)getEnumValue("result item type", s_resultItemMap, DE_LENGTH_OF_ARRAY(s_resultItemMap), elemName);
}

static ri::Image::Format getImageFormat (const char* imageFormat)
{
        return (ri::Image::Format)getEnumValue("image format", s_imageFormatMap, DE_LENGTH_OF_ARRAY(s_imageFormatMap), imageFormat);
}

static ri::Image::Compression getImageCompression (const char* compression)
{
        return (ri::Image::Compression)getEnumValue("image compression", s_compressionMap, DE_LENGTH_OF_ARRAY(s_compressionMap), compression);
}

static ri::Shader::ShaderType getShaderTypeFromTagName (const char* shaderType)
{
        return (ri::Shader::ShaderType)getEnumValue("shader type", s_shaderTypeFromTagMap, DE_LENGTH_OF_ARRAY(s_shaderTypeFromTagMap), shaderType);
}

static TestCaseType getTestCaseType (const char* caseType)
{
        return (TestCaseType)getEnumValue("test case type", s_testTypeMap, DE_LENGTH_OF_ARRAY(s_testTypeMap), caseType);
}

static TestLogVersion getTestLogVersion (const char* logVersion)
{
        return (TestLogVersion)getEnumValue("test log version", s_logVersionMap, DE_LENGTH_OF_ARRAY(s_logVersionMap), logVersion);
}

static ri::ValueInfo::ValueTag getSampleValueTag (const char* tag)
{
        return (ri::ValueInfo::ValueTag)getEnumValue("sample value tag", s_sampleValueTagMap, DE_LENGTH_OF_ARRAY(s_sampleValueTagMap), tag);
}

static TestCaseType getTestCaseTypeFromPath (const char* casePath)
{
        if (deStringBeginsWith(casePath, "dEQP-GLES2."))
        {
                const char* group = casePath+11;
                if (deStringBeginsWith(group, "capability."))
                        return TESTCASETYPE_CAPABILITY;
                else if (deStringBeginsWith(group, "accuracy."))
                        return TESTCASETYPE_ACCURACY;
                else if (deStringBeginsWith(group, "performance."))
                        return TESTCASETYPE_PERFORMANCE;
        }

        return TESTCASETYPE_SELF_VALIDATE;
}

static ri::NumericValue getNumericValue (const std::string& value)
{
        const bool      isFloat         = value.find('.') != std::string::npos || value.find('e') != std::string::npos;

        if (isFloat)
        {
                const double num = toDouble(stripLeadingWhitespace(value.c_str()));
                return ri::NumericValue(num);
        }
        else
        {
                const deInt64 num = toInt64(stripLeadingWhitespace(value.c_str()));
                return ri::NumericValue(num);
        }
}

TestResultParser::TestResultParser (void)
        : m_result                              (DE_NULL)
        , m_state                               (STATE_NOT_INITIALIZED)
        , m_logVersion                  (TESTLOGVERSION_LAST)
        , m_curItemList                 (DE_NULL)
        , m_base64DecodeOffset  (0)
{
}

TestResultParser::~TestResultParser (void)
{
}

void TestResultParser::clear (void)
{
        m_xmlParser.clear();
        m_itemStack.clear();

        m_result                                = DE_NULL;
        m_state                                 = STATE_NOT_INITIALIZED;
        m_logVersion                    = TESTLOGVERSION_LAST;
        m_curItemList                   = DE_NULL;
        m_base64DecodeOffset    = 0;
        m_curNumValue.clear();
}

void TestResultParser::init (TestCaseResult* dstResult)
{
        clear();
        m_result                = dstResult;
        m_state                 = STATE_INITIALIZED;
        m_curItemList   = &dstResult->resultItems;
}

TestResultParser::ParseResult TestResultParser::parse (const deUint8* bytes, int numBytes)
{
        DE_ASSERT(m_result && m_state != STATE_NOT_INITIALIZED);

        try
        {
                bool resultChanged = false;

                m_xmlParser.feed(bytes, numBytes);

                for (;;)
                {
                        xml::Element curElement = m_xmlParser.getElement();

                        if (curElement == xml::ELEMENT_INCOMPLETE       ||
                                curElement == xml::ELEMENT_END_OF_STRING)
                                break;

                        switch (curElement)
                        {
                                case xml::ELEMENT_START:        handleElementStart();           break;
                                case xml::ELEMENT_END:          handleElementEnd();                     break;
                                case xml::ELEMENT_DATA:         handleData();                           break;

                                default:
                                        DE_ASSERT(false);
                        }

                        resultChanged = true;
                        m_xmlParser.advance();
                }

                if (m_xmlParser.getElement() == xml::ELEMENT_END_OF_STRING)
                {
                        if (m_state != STATE_TEST_CASE_RESULT_ENDED)
                                throw TestResultParseError("Unexpected end of log data");

                        return PARSERESULT_COMPLETE;
                }
                else
                        return resultChanged ? PARSERESULT_CHANGED
                                                                 : PARSERESULT_NOT_CHANGED;
        }
        catch (const TestResultParseError& e)
        {
                // Set error code to result.
                m_result->statusCode    = TESTSTATUSCODE_INTERNAL_ERROR;
                m_result->statusDetails = e.what();

                return PARSERESULT_ERROR;
        }
        catch (const xml::ParseError& e)
        {
                // Set error code to result.
                m_result->statusCode    = TESTSTATUSCODE_INTERNAL_ERROR;
                m_result->statusDetails = e.what();

                return PARSERESULT_ERROR;
        }
}

const char* TestResultParser::getAttribute (const char* name)
{
        if (!m_xmlParser.hasAttribute(name))
                throw TestResultParseError(string("Missing attribute '") + name + "' in <" + m_xmlParser.getElementName() + ">");

        return m_xmlParser.getAttribute(name);
}

ri::Item* TestResultParser::getCurrentItem (void)
{
        return !m_itemStack.empty() ? m_itemStack.back() : DE_NULL;
}

ri::List* TestResultParser::getCurrentItemList (void)
{
        DE_ASSERT(m_curItemList);
        return m_curItemList;
}

void TestResultParser::updateCurrentItemList (void)
{
        m_curItemList = DE_NULL;

        for (vector<ri::Item*>::reverse_iterator i = m_itemStack.rbegin(); i != m_itemStack.rend(); i++)
        {
                ri::Item*       item    = *i;
                ri::Type        type    = item->getType();

                if (type == ri::TYPE_IMAGESET)
                        m_curItemList = &static_cast<ri::ImageSet*>(item)->images;
                else if (type == ri::TYPE_SECTION)
                        m_curItemList = &static_cast<ri::Section*>(item)->items;
                else if (type == ri::TYPE_EGLCONFIGSET)
                        m_curItemList = &static_cast<ri::EglConfigSet*>(item)->configs;
                else if (type == ri::TYPE_SHADERPROGRAM)
                        m_curItemList = &static_cast<ri::ShaderProgram*>(item)->shaders;

                if (m_curItemList)
                        break;
        }

        if (!m_curItemList)
                m_curItemList = &m_result->resultItems;
}

void TestResultParser::pushItem (ri::Item* item)
{
        m_itemStack.push_back(item);
        updateCurrentItemList();
}

void TestResultParser::popItem (void)
{
        m_itemStack.pop_back();
        updateCurrentItemList();
}

void TestResultParser::handleElementStart (void)
{
        const char* elemName = m_xmlParser.getElementName();

        if (m_state == STATE_INITIALIZED)
        {
                // Expect TestCaseResult.
                if (!deStringEqual(elemName, "TestCaseResult"))
                        throw TestResultParseError(string("Expected <TestCaseResult>, got <") + elemName + ">");

                const char* version = getAttribute("Version");
                m_logVersion = getTestLogVersion(version);
                // \note Currently assumed that all known log versions are supported.

                m_result->caseVersion   = version;
                m_result->casePath              = getAttribute("CasePath");
                m_result->caseType              = TESTCASETYPE_SELF_VALIDATE;

                if (m_xmlParser.hasAttribute("CaseType"))
                        m_result->caseType = getTestCaseType(m_xmlParser.getAttribute("CaseType"));
                else
                {
                        // Do guess based on path for legacy log files.
                        if (m_logVersion >= TESTLOGVERSION_0_3_2)
                                throw TestResultParseError("Missing CaseType attribute in <TestCaseResult>");
                        m_result->caseType = getTestCaseTypeFromPath(m_result->casePath.c_str());
                }

                m_state = STATE_IN_TEST_CASE_RESULT;
        }
        else
        {
                ri::List*       curList         = getCurrentItemList();
                ri::Type        itemType        = getResultItemType(elemName);
                ri::Item*       item            = DE_NULL;
                ri::Item*       parentItem      = getCurrentItem();
                ri::Type        parentType      = parentItem ? parentItem->getType() : ri::TYPE_LAST;

                switch (itemType)
                {
                        case ri::TYPE_RESULT:
                        {
                                ri::Result* result = curList->allocItem<ri::Result>();
                                result->statusCode = getTestStatusCode(getAttribute("StatusCode"));
                                item = result;
                                break;
                        }

                        case ri::TYPE_TEXT:
                                item = curList->allocItem<ri::Text>();
                                break;

                        case ri::TYPE_SECTION:
                        {
                                ri::Section* section = curList->allocItem<ri::Section>();
                                section->name                   = getAttribute("Name");
                                section->description    = getAttribute("Description");
                                item = section;
                                break;
                        }

                        case ri::TYPE_NUMBER:
                        {
                                ri::Number* number = curList->allocItem<ri::Number>();
                                number->name            = getAttribute("Name");
                                number->description     = getAttribute("Description");
                                number->unit            = getAttribute("Unit");

                                if (m_xmlParser.hasAttribute("Tag"))
                                        number->tag = m_xmlParser.getAttribute("Tag");

                                item = number;

                                m_curNumValue.clear();
                                break;
                        }

                        case ri::TYPE_IMAGESET:
                        {
                                ri::ImageSet* imageSet = curList->allocItem<ri::ImageSet>();
                                imageSet->name                  = getAttribute("Name");
                                imageSet->description   = getAttribute("Description");
                                item = imageSet;
                                break;
                        }

                        case ri::TYPE_IMAGE:
                        {
                                ri::Image* image = curList->allocItem<ri::Image>();
                                image->name                     = getAttribute("Name");
                                image->description      = getAttribute("Description");
                                image->width            = toInt(getAttribute("Width"));
                                image->height           = toInt(getAttribute("Height"));
                                image->format           = getImageFormat(getAttribute("Format"));
                                image->compression      = getImageCompression(getAttribute("CompressionMode"));
                                item = image;
                                break;
                        }

                        case ri::TYPE_SHADERPROGRAM:
                        {
                                ri::ShaderProgram* shaderProgram = curList->allocItem<ri::ShaderProgram>();
                                shaderProgram->linkStatus = toBool(getAttribute("LinkStatus"));
                                item = shaderProgram;
                                break;
                        }

                        case ri::TYPE_SHADER:
                        {
                                if (parentType != ri::TYPE_SHADERPROGRAM)
                                        throw TestResultParseError(string("<") + elemName + "> outside of <ShaderProgram>");

                                ri::Shader* shader = curList->allocItem<ri::Shader>();

                                shader->shaderType              = getShaderTypeFromTagName(elemName);
                                shader->compileStatus   = toBool(getAttribute("CompileStatus"));

                                item = shader;
                                break;
                        }

                        case ri::TYPE_SPIRVSOURCE:
                        {
                                if (parentType != ri::TYPE_SHADERPROGRAM)
                                        throw TestResultParseError(string("<") + elemName + "> outside of <ShaderProgram>");
                                item = curList->allocItem<ri::SpirVSource>();
                                break;
                        }

                        case ri::TYPE_SHADERSOURCE:
                                if (parentType == ri::TYPE_SHADER)
                                        item = &static_cast<ri::Shader*>(parentItem)->source;
                                else
                                        throw TestResultParseError("Unexpected <ShaderSource>");
                                break;

                        case ri::TYPE_INFOLOG:
                                if (parentType == ri::TYPE_SHADERPROGRAM)
                                        item = &static_cast<ri::ShaderProgram*>(parentItem)->linkInfoLog;
                                else if (parentType == ri::TYPE_SHADER)
                                        item = &static_cast<ri::Shader*>(parentItem)->infoLog;
                                else if (parentType == ri::TYPE_COMPILEINFO)
                                        item = &static_cast<ri::CompileInfo*>(parentItem)->infoLog;
                                else
                                        throw TestResultParseError("Unexpected <InfoLog>");
                                break;

                        case ri::TYPE_KERNELSOURCE:
                                item = curList->allocItem<ri::KernelSource>();
                                break;

                        case ri::TYPE_COMPILEINFO:
                        {
                                ri::CompileInfo* info = curList->allocItem<ri::CompileInfo>();
                                info->name                      = getAttribute("Name");
                                info->description       = getAttribute("Description");
                                info->compileStatus     = toBool(getAttribute("CompileStatus"));
                                item = info;
                                break;
                        }

                        case ri::TYPE_EGLCONFIGSET:
                        {
                                ri::EglConfigSet* set = curList->allocItem<ri::EglConfigSet>();
                                set->name                       = getAttribute("Name");
                                set->description        = m_xmlParser.hasAttribute("Description") ? m_xmlParser.getAttribute("Description") : "";
                                item = set;
                                break;
                        }

                        case ri::TYPE_EGLCONFIG:
                        {
                                ri::EglConfig* config = curList->allocItem<ri::EglConfig>();
                                config->bufferSize                              = toInt(getAttribute("BufferSize"));
                                config->redSize                                 = toInt(getAttribute("RedSize"));
                                config->greenSize                               = toInt(getAttribute("GreenSize"));
                                config->blueSize                                = toInt(getAttribute("BlueSize"));
                                config->luminanceSize                   = toInt(getAttribute("LuminanceSize"));
                                config->alphaSize                               = toInt(getAttribute("AlphaSize"));
                                config->alphaMaskSize                   = toInt(getAttribute("AlphaMaskSize"));
                                config->bindToTextureRGB                = toBool(getAttribute("BindToTextureRGB"));
                                config->bindToTextureRGBA               = toBool(getAttribute("BindToTextureRGBA"));
                                config->colorBufferType                 = getAttribute("ColorBufferType");
                                config->configCaveat                    = getAttribute("ConfigCaveat");
                                config->configID                                = toInt(getAttribute("ConfigID"));
                                config->conformant                              = getAttribute("Conformant");
                                config->depthSize                               = toInt(getAttribute("DepthSize"));
                                config->level                                   = toInt(getAttribute("Level"));
                                config->maxPBufferWidth                 = toInt(getAttribute("MaxPBufferWidth"));
                                config->maxPBufferHeight                = toInt(getAttribute("MaxPBufferHeight"));
                                config->maxPBufferPixels                = toInt(getAttribute("MaxPBufferPixels"));
                                config->maxSwapInterval                 = toInt(getAttribute("MaxSwapInterval"));
                                config->minSwapInterval                 = toInt(getAttribute("MinSwapInterval"));
                                config->nativeRenderable                = toBool(getAttribute("NativeRenderable"));
                                config->renderableType                  = getAttribute("RenderableType");
                                config->sampleBuffers                   = toInt(getAttribute("SampleBuffers"));
                                config->samples                                 = toInt(getAttribute("Samples"));
                                config->stencilSize                             = toInt(getAttribute("StencilSize"));
                                config->surfaceTypes                    = getAttribute("SurfaceTypes");
                                config->transparentType                 = getAttribute("TransparentType");
                                config->transparentRedValue             = toInt(getAttribute("TransparentRedValue"));
                                config->transparentGreenValue   = toInt(getAttribute("TransparentGreenValue"));
                                config->transparentBlueValue    = toInt(getAttribute("TransparentBlueValue"));
                                item = config;
                                break;
                        }

                        case ri::TYPE_SAMPLELIST:
                        {
                                ri::SampleList* list = curList->allocItem<ri::SampleList>();
                                list->name                      = getAttribute("Name");
                                list->description       = getAttribute("Description");
                                item = list;
                                break;
                        }

                        case ri::TYPE_SAMPLEINFO:
                        {
                                if (parentType != ri::TYPE_SAMPLELIST)
                                        throw TestResultParseError("<SampleInfo> outside of <SampleList>");

                                ri::SampleList* list    = static_cast<ri::SampleList*>(parentItem);
                                ri::SampleInfo* info    = &list->sampleInfo;

                                item = info;
                                break;
                        }

                        case ri::TYPE_VALUEINFO:
                        {
                                if (parentType != ri::TYPE_SAMPLEINFO)
                                        throw TestResultParseError("<ValueInfo> outside of <SampleInfo>");

                                ri::SampleInfo* sampleInfo      = static_cast<ri::SampleInfo*>(parentItem);
                                ri::ValueInfo*  valueInfo       = sampleInfo->valueInfos.allocItem<ri::ValueInfo>();

                                valueInfo->name                 = getAttribute("Name");
                                valueInfo->description  = getAttribute("Description");
                                valueInfo->tag                  = getSampleValueTag(getAttribute("Tag"));

                                if (m_xmlParser.hasAttribute("Unit"))
                                        valueInfo->unit = getAttribute("Unit");

                                item = valueInfo;
                                break;
                        }

                        case ri::TYPE_SAMPLE:
                        {
                                if (parentType != ri::TYPE_SAMPLELIST)
                                        throw TestResultParseError("<Sample> outside of <SampleList>");

                                ri::SampleList* list    = static_cast<ri::SampleList*>(parentItem);
                                ri::Sample*             sample  = list->samples.allocItem<ri::Sample>();

                                item = sample;
                                break;
                        }

                        case ri::TYPE_SAMPLEVALUE:
                        {
                                if (parentType != ri::TYPE_SAMPLE)
                                        throw TestResultParseError("<Value> outside of <Sample>");

                                ri::Sample*                     sample  = static_cast<ri::Sample*>(parentItem);
                                ri::SampleValue*        value   = sample->values.allocItem<ri::SampleValue>();

                                item = value;
                                break;
                        }

                        default:
                                throw TestResultParseError(string("Unsupported element '") + elemName + ("'"));
                }

                DE_ASSERT(item);
                pushItem(item);

                // Reset base64 decoding offset.
                m_base64DecodeOffset = 0;
        }
}

void TestResultParser::handleElementEnd (void)
{
        const char* elemName = m_xmlParser.getElementName();

        if (m_state != STATE_IN_TEST_CASE_RESULT)
                throw TestResultParseError(string("Unexpected </") + elemName + "> outside of <TestCaseResult>");

        if (deStringEqual(elemName, "TestCaseResult"))
        {
                // Logs from buggy test cases may contain invalid XML.
                // DE_ASSERT(getCurrentItem() == DE_NULL);
                // \todo [2012-11-22 pyry] Log warning.

                m_state = STATE_TEST_CASE_RESULT_ENDED;
        }
        else
        {
                ri::Type        itemType        = getResultItemType(elemName);
                ri::Item*       curItem         = getCurrentItem();

                if (!curItem || itemType != curItem->getType())
                        throw TestResultParseError(string("Unexpected </") + elemName + ">");

                if (itemType == ri::TYPE_RESULT)
                {
                        ri::Result* result = static_cast<ri::Result*>(curItem);
                        m_result->statusCode    = result->statusCode;
                        m_result->statusDetails = result->details;
                }
                else if (itemType == ri::TYPE_NUMBER)
                {
                        // Parse value for number.
                        ri::Number*     number  = static_cast<ri::Number*>(curItem);
                        number->value = getNumericValue(m_curNumValue);
                        m_curNumValue.clear();
                }
                else if (itemType == ri::TYPE_SAMPLEVALUE)
                {
                        ri::SampleValue* value = static_cast<ri::SampleValue*>(curItem);
                        value->value = getNumericValue(m_curNumValue);
                        m_curNumValue.clear();
                }

                popItem();
        }
}

void TestResultParser::handleData (void)
{
        ri::Item*       curItem         = getCurrentItem();
        ri::Type        type            = curItem ? curItem->getType() : ri::TYPE_LAST;

        switch (type)
        {
                case ri::TYPE_RESULT:
                        m_xmlParser.appendDataStr(static_cast<ri::Result*>(curItem)->details);
                        break;

                case ri::TYPE_TEXT:
                        m_xmlParser.appendDataStr(static_cast<ri::Text*>(curItem)->text);
                        break;

                case ri::TYPE_SHADERSOURCE:
                        m_xmlParser.appendDataStr(static_cast<ri::ShaderSource*>(curItem)->source);
                        break;

                case ri::TYPE_SPIRVSOURCE:
                        m_xmlParser.appendDataStr(static_cast<ri::SpirVSource*>(curItem)->source);
                        break;

                case ri::TYPE_INFOLOG:
                        m_xmlParser.appendDataStr(static_cast<ri::InfoLog*>(curItem)->log);
                        break;

                case ri::TYPE_KERNELSOURCE:
                        m_xmlParser.appendDataStr(static_cast<ri::KernelSource*>(curItem)->source);
                        break;

                case ri::TYPE_NUMBER:
                case ri::TYPE_SAMPLEVALUE:
                        m_xmlParser.appendDataStr(m_curNumValue);
                        break;

                case ri::TYPE_IMAGE:
                {
                        ri::Image* image = static_cast<ri::Image*>(curItem);

                        // Base64 decode.
                        int numBytesIn = m_xmlParser.getDataSize();

                        for (int inNdx = 0; inNdx < numBytesIn; inNdx++)
                        {
                                deUint8         byte            = m_xmlParser.getDataByte(inNdx);
                                deUint8         decodedBits     = 0;

                                if (de::inRange<deInt8>(byte, 'A', 'Z'))
                                        decodedBits = (deUint8)(byte - 'A');
                                else if (de::inRange<deInt8>(byte, 'a', 'z'))
                                        decodedBits = (deUint8)(('Z'-'A'+1) + (byte-'a'));
                                else if (de::inRange<deInt8>(byte, '0', '9'))
                                        decodedBits = (deUint8)(('Z'-'A'+1) + ('z'-'a'+1) + (byte-'0'));
                                else if (byte == '+')
                                        decodedBits = ('Z'-'A'+1) + ('z'-'a'+1) + ('9'-'0'+1);
                                else if (byte == '/')
                                        decodedBits = ('Z'-'A'+1) + ('z'-'a'+1) + ('9'-'0'+2);
                                else if (byte == '=')
                                {
                                        // Padding at end - remove last byte.
                                        if (image->data.empty())
                                                throw TestResultParseError("Malformed base64 data");
                                        image->data.pop_back();
                                        continue;
                                }
                                else
                                        continue; // Not an B64 input character.

                                int phase = m_base64DecodeOffset % 4;

                                if (phase == 0)
                                        image->data.resize(image->data.size()+3, 0);

                                if ((int)image->data.size() < (m_base64DecodeOffset>>2)*3 + 3)
                                        throw TestResultParseError("Malformed base64 data");
                                deUint8* outPtr = &image->data[(m_base64DecodeOffset>>2)*3];

                                switch (phase)
                                {
                                        case 0: outPtr[0] |= (deUint8)(decodedBits<<2);                                                                                                                                                                                         break;
                                        case 1: outPtr[0] = (deUint8)(outPtr[0] | (deUint8)(decodedBits>>4));   outPtr[1] = (deUint8)(outPtr[1] | (deUint8)((decodedBits&0xF)<<4));     break;
                                        case 2: outPtr[1] = (deUint8)(outPtr[1] | (deUint8)(decodedBits>>2));   outPtr[2] = (deUint8)(outPtr[2] | (deUint8)((decodedBits&0x3)<<6));     break;
                                        case 3: outPtr[2] |= decodedBits;                                                                                                                                                                                                                       break;
                                        default:
                                                DE_ASSERT(false);
                                }

                                m_base64DecodeOffset += 1;
                        }

                        break;
                }

                default:
                        // Just ignore data.
                        break;
        }
}

//! Helper for parsing TestCaseResult from TestCaseResultData.
void parseTestCaseResultFromData (TestResultParser* parser, TestCaseResult* result, const TestCaseResultData& data)
{
        DE_ASSERT(result->resultItems.getNumItems() == 0);

        // Initialize status codes etc. from data.
        result->casePath                = data.getTestCasePath();
        result->caseType                = TESTCASETYPE_SELF_VALIDATE;
        result->statusCode              = data.getStatusCode();
        result->statusDetails   = data.getStatusDetails();

        if (data.getDataSize() > 0)
        {
                parser->init(result);

                const TestResultParser::ParseResult parseResult = parser->parse(data.getData(), data.getDataSize());

                if (result->statusCode == TESTSTATUSCODE_LAST)
                {
                        result->statusCode = TESTSTATUSCODE_INTERNAL_ERROR;

                        if (parseResult == TestResultParser::PARSERESULT_ERROR)
                                result->statusDetails = "Test case result parsing failed";
                        else if (parseResult != TestResultParser::PARSERESULT_COMPLETE)
                                result->statusDetails = "Incomplete test case result";
                        else
                                result->statusDetails = "Test case result is missing <Result> item";
                }
        }
        else if (result->statusCode == TESTSTATUSCODE_LAST)
        {
                result->statusCode              = TESTSTATUSCODE_TERMINATED;
                result->statusDetails   = "Empty test case result";
        }

        if (result->casePath.empty())
                throw Error("Empty test case path in result");

        if (result->caseType == TESTCASETYPE_LAST)
                throw Error("Invalid test case type in result");

        DE_ASSERT(result->statusCode != TESTSTATUSCODE_LAST);
}

} // xe