blob: a1e1ae53e115469d9a05d7088716b50f100c5197 [file] [log] [blame]
// Copyright (c) 2013 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "gpu/config/gpu_control_list.h"
#include <stddef.h>
#include <stdint.h>
#include <utility>
#include "base/cpu.h"
#include "base/json/json_reader.h"
#include "base/logging.h"
#include "base/strings/string_number_conversions.h"
#include "base/strings/string_split.h"
#include "base/strings/string_util.h"
#include "base/strings/stringprintf.h"
#include "base/sys_info.h"
#include "gpu/config/gpu_info.h"
#include "gpu/config/gpu_util.h"
#include "third_party/re2/src/re2/re2.h"
namespace gpu {
namespace {
// Break a version string into segments. Return true if each segment is
// a valid number, and not all segment is 0.
bool ProcessVersionString(const std::string& version_string,
char splitter,
std::vector<std::string>* version) {
DCHECK(version);
*version = base::SplitString(
version_string, std::string(1, splitter),
base::TRIM_WHITESPACE, base::SPLIT_WANT_ALL);
if (version->size() == 0)
return false;
// If the splitter is '-', we assume it's a date with format "mm-dd-yyyy";
// we split it into the order of "yyyy", "mm", "dd".
if (splitter == '-') {
std::string year = version->back();
for (int i = version->size() - 1; i > 0; --i) {
(*version)[i] = (*version)[i - 1];
}
(*version)[0] = year;
}
bool all_zero = true;
for (size_t i = 0; i < version->size(); ++i) {
unsigned num = 0;
if (!base::StringToUint((*version)[i], &num))
return false;
if (num)
all_zero = false;
}
return !all_zero;
}
// Compare two number strings using numerical ordering.
// Return 0 if number = number_ref,
// 1 if number > number_ref,
// -1 if number < number_ref.
int CompareNumericalNumberStrings(
const std::string& number, const std::string& number_ref) {
unsigned value1 = 0;
unsigned value2 = 0;
bool valid = base::StringToUint(number, &value1);
DCHECK(valid);
valid = base::StringToUint(number_ref, &value2);
DCHECK(valid);
if (value1 == value2)
return 0;
if (value1 > value2)
return 1;
return -1;
}
// Compare two number strings using lexical ordering.
// Return 0 if number = number_ref,
// 1 if number > number_ref,
// -1 if number < number_ref.
// We only compare as many digits as number_ref contains.
// If number_ref is xxx, it's considered as xxx*
// For example: CompareLexicalNumberStrings("121", "12") returns 0,
// CompareLexicalNumberStrings("12", "121") returns -1.
int CompareLexicalNumberStrings(
const std::string& number, const std::string& number_ref) {
for (size_t i = 0; i < number_ref.length(); ++i) {
unsigned value1 = 0;
if (i < number.length())
value1 = number[i] - '0';
unsigned value2 = number_ref[i] - '0';
if (value1 > value2)
return 1;
if (value1 < value2)
return -1;
}
return 0;
}
// A mismatch is identified only if both |input| and |pattern| are not empty.
bool StringMismatch(const std::string& input, const std::string& pattern) {
if (input.empty() || pattern.empty())
return false;
return !RE2::FullMatch(input, pattern);
}
const char kMultiGpuStyleStringAMDSwitchable[] = "amd_switchable";
const char kMultiGpuStyleStringAMDSwitchableDiscrete[] =
"amd_switchable_discrete";
const char kMultiGpuStyleStringAMDSwitchableIntegrated[] =
"amd_switchable_integrated";
const char kMultiGpuStyleStringOptimus[] = "optimus";
const char kMultiGpuCategoryStringPrimary[] = "primary";
const char kMultiGpuCategoryStringSecondary[] = "secondary";
const char kMultiGpuCategoryStringActive[] = "active";
const char kMultiGpuCategoryStringAny[] = "any";
const char kGLTypeStringGL[] = "gl";
const char kGLTypeStringGLES[] = "gles";
const char kGLTypeStringANGLE[] = "angle";
const char kVersionStyleStringNumerical[] = "numerical";
const char kVersionStyleStringLexical[] = "lexical";
const char kOp[] = "op";
} // namespace
GpuControlList::VersionInfo::VersionInfo(
const std::string& version_op,
const std::string& version_style,
const std::string& version_string,
const std::string& version_string2)
: version_style_(kVersionStyleNumerical) {
op_ = StringToNumericOp(version_op);
if (op_ == kUnknown || op_ == kAny)
return;
version_style_ = StringToVersionStyle(version_style);
if (!ProcessVersionString(version_string, '.', &version_)) {
op_ = kUnknown;
return;
}
if (op_ == kBetween) {
if (!ProcessVersionString(version_string2, '.', &version2_))
op_ = kUnknown;
}
}
GpuControlList::VersionInfo::~VersionInfo() {
}
bool GpuControlList::VersionInfo::Contains(
const std::string& version_string) const {
return Contains(version_string, '.');
}
bool GpuControlList::VersionInfo::Contains(
const std::string& version_string, char splitter) const {
if (op_ == kUnknown)
return false;
if (op_ == kAny)
return true;
std::vector<std::string> version;
if (!ProcessVersionString(version_string, splitter, &version))
return false;
int relation = Compare(version, version_, version_style_);
if (op_ == kEQ)
return (relation == 0);
else if (op_ == kLT)
return (relation < 0);
else if (op_ == kLE)
return (relation <= 0);
else if (op_ == kGT)
return (relation > 0);
else if (op_ == kGE)
return (relation >= 0);
// op_ == kBetween
if (relation < 0)
return false;
return Compare(version, version2_, version_style_) <= 0;
}
bool GpuControlList::VersionInfo::IsValid() const {
return (op_ != kUnknown && version_style_ != kVersionStyleUnknown);
}
bool GpuControlList::VersionInfo::IsLexical() const {
return version_style_ == kVersionStyleLexical;
}
// static
int GpuControlList::VersionInfo::Compare(
const std::vector<std::string>& version,
const std::vector<std::string>& version_ref,
VersionStyle version_style) {
DCHECK(version.size() > 0 && version_ref.size() > 0);
DCHECK(version_style != kVersionStyleUnknown);
for (size_t i = 0; i < version_ref.size(); ++i) {
if (i >= version.size())
return 0;
int ret = 0;
// We assume both versions are checked by ProcessVersionString().
if (i > 0 && version_style == kVersionStyleLexical)
ret = CompareLexicalNumberStrings(version[i], version_ref[i]);
else
ret = CompareNumericalNumberStrings(version[i], version_ref[i]);
if (ret != 0)
return ret;
}
return 0;
}
// static
GpuControlList::VersionInfo::VersionStyle
GpuControlList::VersionInfo::StringToVersionStyle(
const std::string& version_style) {
if (version_style.empty() || version_style == kVersionStyleStringNumerical)
return kVersionStyleNumerical;
if (version_style == kVersionStyleStringLexical)
return kVersionStyleLexical;
return kVersionStyleUnknown;
}
GpuControlList::OsInfo::OsInfo(const std::string& os,
const std::string& version_op,
const std::string& version_string,
const std::string& version_string2) {
type_ = StringToOsType(os);
if (type_ != kOsUnknown) {
version_info_.reset(new VersionInfo(
version_op, std::string(), version_string, version_string2));
}
}
GpuControlList::OsInfo::~OsInfo() {}
bool GpuControlList::OsInfo::Contains(
OsType type, const std::string& version) const {
if (!IsValid())
return false;
if (type_ != type && type_ != kOsAny)
return false;
std::string processed_version;
size_t pos = version.find_first_not_of("0123456789.");
if (pos != std::string::npos)
processed_version = version.substr(0, pos);
else
processed_version = version;
return version_info_->Contains(processed_version);
}
bool GpuControlList::OsInfo::IsValid() const {
return type_ != kOsUnknown && version_info_->IsValid();
}
GpuControlList::OsType GpuControlList::OsInfo::type() const {
return type_;
}
GpuControlList::OsType GpuControlList::OsInfo::StringToOsType(
const std::string& os) {
if (os == "win")
return kOsWin;
else if (os == "macosx")
return kOsMacosx;
else if (os == "android")
return kOsAndroid;
else if (os == "linux")
return kOsLinux;
else if (os == "chromeos")
return kOsChromeOS;
else if (os == "any")
return kOsAny;
return kOsUnknown;
}
GpuControlList::FloatInfo::FloatInfo(const std::string& float_op,
const std::string& float_value,
const std::string& float_value2)
: op_(kUnknown),
value_(0.f),
value2_(0.f) {
op_ = StringToNumericOp(float_op);
if (op_ == kAny)
return;
double dvalue = 0;
if (!base::StringToDouble(float_value, &dvalue)) {
op_ = kUnknown;
return;
}
value_ = static_cast<float>(dvalue);
if (op_ == kBetween) {
if (!base::StringToDouble(float_value2, &dvalue)) {
op_ = kUnknown;
return;
}
value2_ = static_cast<float>(dvalue);
}
}
bool GpuControlList::FloatInfo::Contains(float value) const {
if (op_ == kUnknown)
return false;
if (op_ == kAny)
return true;
if (op_ == kEQ)
return (value == value_);
if (op_ == kLT)
return (value < value_);
if (op_ == kLE)
return (value <= value_);
if (op_ == kGT)
return (value > value_);
if (op_ == kGE)
return (value >= value_);
DCHECK(op_ == kBetween);
return ((value_ <= value && value <= value2_) ||
(value2_ <= value && value <= value_));
}
bool GpuControlList::FloatInfo::IsValid() const {
return op_ != kUnknown;
}
GpuControlList::IntInfo::IntInfo(const std::string& int_op,
const std::string& int_value,
const std::string& int_value2)
: op_(kUnknown),
value_(0),
value2_(0) {
op_ = StringToNumericOp(int_op);
if (op_ == kAny)
return;
if (!base::StringToInt(int_value, &value_)) {
op_ = kUnknown;
return;
}
if (op_ == kBetween &&
!base::StringToInt(int_value2, &value2_))
op_ = kUnknown;
}
bool GpuControlList::IntInfo::Contains(int value) const {
if (op_ == kUnknown)
return false;
if (op_ == kAny)
return true;
if (op_ == kEQ)
return (value == value_);
if (op_ == kLT)
return (value < value_);
if (op_ == kLE)
return (value <= value_);
if (op_ == kGT)
return (value > value_);
if (op_ == kGE)
return (value >= value_);
DCHECK(op_ == kBetween);
return ((value_ <= value && value <= value2_) ||
(value2_ <= value && value <= value_));
}
bool GpuControlList::IntInfo::IsValid() const {
return op_ != kUnknown;
}
GpuControlList::BoolInfo::BoolInfo(bool value) : value_(value) {}
bool GpuControlList::BoolInfo::Contains(bool value) const {
return value_ == value;
}
// static
GpuControlList::ScopedGpuControlListEntry
GpuControlList::GpuControlListEntry::GetEntryFromValue(
const base::DictionaryValue* value, bool top_level,
const FeatureMap& feature_map,
bool supports_feature_type_all) {
DCHECK(value);
ScopedGpuControlListEntry entry(new GpuControlListEntry());
size_t dictionary_entry_count = 0;
if (top_level) {
uint32_t id;
if (!value->GetInteger("id", reinterpret_cast<int*>(&id)) ||
!entry->SetId(id)) {
LOG(WARNING) << "Malformed id entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
bool disabled;
if (value->GetBoolean("disabled", &disabled)) {
entry->SetDisabled(disabled);
dictionary_entry_count++;
}
}
std::string description;
if (value->GetString("description", &description)) {
entry->description_ = description;
dictionary_entry_count++;
} else {
entry->description_ = "The GPU is unavailable for an unexplained reason.";
}
const base::ListValue* cr_bugs;
if (value->GetList("cr_bugs", &cr_bugs)) {
for (size_t i = 0; i < cr_bugs->GetSize(); ++i) {
int bug_id;
if (cr_bugs->GetInteger(i, &bug_id)) {
entry->cr_bugs_.push_back(bug_id);
} else {
LOG(WARNING) << "Malformed cr_bugs entry " << entry->id();
return NULL;
}
}
dictionary_entry_count++;
}
const base::ListValue* webkit_bugs;
if (value->GetList("webkit_bugs", &webkit_bugs)) {
for (size_t i = 0; i < webkit_bugs->GetSize(); ++i) {
int bug_id;
if (webkit_bugs->GetInteger(i, &bug_id)) {
entry->webkit_bugs_.push_back(bug_id);
} else {
LOG(WARNING) << "Malformed webkit_bugs entry " << entry->id();
return NULL;
}
}
dictionary_entry_count++;
}
const base::ListValue* disabled_extensions;
if (value->GetList("disabled_extensions", &disabled_extensions)) {
for (size_t i = 0; i < disabled_extensions->GetSize(); ++i) {
std::string disabled_extension;
if (disabled_extensions->GetString(i, &disabled_extension)) {
entry->disabled_extensions_.push_back(disabled_extension);
} else {
LOG(WARNING) << "Malformed disabled_extensions entry " << entry->id();
return NULL;
}
}
dictionary_entry_count++;
}
const base::DictionaryValue* os_value = NULL;
if (value->GetDictionary("os", &os_value)) {
std::string os_type;
std::string os_version_op = "any";
std::string os_version_string;
std::string os_version_string2;
os_value->GetString("type", &os_type);
const base::DictionaryValue* os_version_value = NULL;
if (os_value->GetDictionary("version", &os_version_value)) {
os_version_value->GetString(kOp, &os_version_op);
os_version_value->GetString("value", &os_version_string);
os_version_value->GetString("value2", &os_version_string2);
}
if (!entry->SetOsInfo(os_type, os_version_op, os_version_string,
os_version_string2)) {
LOG(WARNING) << "Malformed os entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
std::string vendor_id;
if (value->GetString("vendor_id", &vendor_id)) {
if (!entry->SetVendorId(vendor_id)) {
LOG(WARNING) << "Malformed vendor_id entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
const base::ListValue* device_id_list;
if (value->GetList("device_id", &device_id_list)) {
for (size_t i = 0; i < device_id_list->GetSize(); ++i) {
std::string device_id;
if (!device_id_list->GetString(i, &device_id) ||
!entry->AddDeviceId(device_id)) {
LOG(WARNING) << "Malformed device_id entry " << entry->id();
return NULL;
}
}
dictionary_entry_count++;
}
std::string multi_gpu_style;
if (value->GetString("multi_gpu_style", &multi_gpu_style)) {
if (!entry->SetMultiGpuStyle(multi_gpu_style)) {
LOG(WARNING) << "Malformed multi_gpu_style entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
std::string multi_gpu_category;
if (value->GetString("multi_gpu_category", &multi_gpu_category)) {
if (!entry->SetMultiGpuCategory(multi_gpu_category)) {
LOG(WARNING) << "Malformed multi_gpu_category entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
std::string driver_vendor_value;
if (value->GetString("driver_vendor", &driver_vendor_value)) {
if (!entry->SetDriverVendorInfo(driver_vendor_value)) {
LOG(WARNING) << "Malformed driver_vendor entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
const base::DictionaryValue* driver_version_value = NULL;
if (value->GetDictionary("driver_version", &driver_version_value)) {
std::string driver_version_op = "any";
std::string driver_version_style;
std::string driver_version_string;
std::string driver_version_string2;
driver_version_value->GetString(kOp, &driver_version_op);
driver_version_value->GetString("style", &driver_version_style);
driver_version_value->GetString("value", &driver_version_string);
driver_version_value->GetString("value2", &driver_version_string2);
if (!entry->SetDriverVersionInfo(driver_version_op,
driver_version_style,
driver_version_string,
driver_version_string2)) {
LOG(WARNING) << "Malformed driver_version entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
const base::DictionaryValue* driver_date_value = NULL;
if (value->GetDictionary("driver_date", &driver_date_value)) {
std::string driver_date_op = "any";
std::string driver_date_string;
std::string driver_date_string2;
driver_date_value->GetString(kOp, &driver_date_op);
driver_date_value->GetString("value", &driver_date_string);
driver_date_value->GetString("value2", &driver_date_string2);
if (!entry->SetDriverDateInfo(driver_date_op, driver_date_string,
driver_date_string2)) {
LOG(WARNING) << "Malformed driver_date entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
std::string gl_type;
if (value->GetString("gl_type", &gl_type)) {
if (!entry->SetGLType(gl_type)) {
LOG(WARNING) << "Malformed gl_type entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
const base::DictionaryValue* gl_version_value = NULL;
if (value->GetDictionary("gl_version", &gl_version_value)) {
std::string version_op = "any";
std::string version_string;
std::string version_string2;
gl_version_value->GetString(kOp, &version_op);
gl_version_value->GetString("value", &version_string);
gl_version_value->GetString("value2", &version_string2);
if (!entry->SetGLVersionInfo(
version_op, version_string, version_string2)) {
LOG(WARNING) << "Malformed gl_version entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
std::string gl_vendor_value;
if (value->GetString("gl_vendor", &gl_vendor_value)) {
if (!entry->SetGLVendorInfo(gl_vendor_value)) {
LOG(WARNING) << "Malformed gl_vendor entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
std::string gl_renderer_value;
if (value->GetString("gl_renderer", &gl_renderer_value)) {
if (!entry->SetGLRendererInfo(gl_renderer_value)) {
LOG(WARNING) << "Malformed gl_renderer entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
std::string gl_extensions_value;
if (value->GetString("gl_extensions", &gl_extensions_value)) {
if (!entry->SetGLExtensionsInfo(gl_extensions_value)) {
LOG(WARNING) << "Malformed gl_extensions entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
const base::DictionaryValue* gl_reset_notification_strategy_value = NULL;
if (value->GetDictionary("gl_reset_notification_strategy",
&gl_reset_notification_strategy_value)) {
std::string op;
std::string int_value;
std::string int_value2;
gl_reset_notification_strategy_value->GetString(kOp, &op);
gl_reset_notification_strategy_value->GetString("value", &int_value);
gl_reset_notification_strategy_value->GetString("value2", &int_value2);
if (!entry->SetGLResetNotificationStrategyInfo(
op, int_value, int_value2)) {
LOG(WARNING) << "Malformed gl_reset_notification_strategy entry "
<< entry->id();
return NULL;
}
dictionary_entry_count++;
}
std::string cpu_brand_value;
if (value->GetString("cpu_info", &cpu_brand_value)) {
if (!entry->SetCpuBrand(cpu_brand_value)) {
LOG(WARNING) << "Malformed cpu_brand entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
const base::DictionaryValue* perf_graphics_value = NULL;
if (value->GetDictionary("perf_graphics", &perf_graphics_value)) {
std::string op;
std::string float_value;
std::string float_value2;
perf_graphics_value->GetString(kOp, &op);
perf_graphics_value->GetString("value", &float_value);
perf_graphics_value->GetString("value2", &float_value2);
if (!entry->SetPerfGraphicsInfo(op, float_value, float_value2)) {
LOG(WARNING) << "Malformed perf_graphics entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
const base::DictionaryValue* perf_gaming_value = NULL;
if (value->GetDictionary("perf_gaming", &perf_gaming_value)) {
std::string op;
std::string float_value;
std::string float_value2;
perf_gaming_value->GetString(kOp, &op);
perf_gaming_value->GetString("value", &float_value);
perf_gaming_value->GetString("value2", &float_value2);
if (!entry->SetPerfGamingInfo(op, float_value, float_value2)) {
LOG(WARNING) << "Malformed perf_gaming entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
const base::DictionaryValue* perf_overall_value = NULL;
if (value->GetDictionary("perf_overall", &perf_overall_value)) {
std::string op;
std::string float_value;
std::string float_value2;
perf_overall_value->GetString(kOp, &op);
perf_overall_value->GetString("value", &float_value);
perf_overall_value->GetString("value2", &float_value2);
if (!entry->SetPerfOverallInfo(op, float_value, float_value2)) {
LOG(WARNING) << "Malformed perf_overall entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
const base::ListValue* machine_model_name_list;
if (value->GetList("machine_model_name", &machine_model_name_list)) {
for (size_t i = 0; i < machine_model_name_list->GetSize(); ++i) {
std::string model_name;
if (!machine_model_name_list->GetString(i, &model_name) ||
!entry->AddMachineModelName(model_name)) {
LOG(WARNING) << "Malformed machine_model_name entry " << entry->id();
return NULL;
}
}
dictionary_entry_count++;
}
const base::DictionaryValue* machine_model_version_value = NULL;
if (value->GetDictionary(
"machine_model_version", &machine_model_version_value)) {
std::string version_op = "any";
std::string version_string;
std::string version_string2;
machine_model_version_value->GetString(kOp, &version_op);
machine_model_version_value->GetString("value", &version_string);
machine_model_version_value->GetString("value2", &version_string2);
if (!entry->SetMachineModelVersionInfo(
version_op, version_string, version_string2)) {
LOG(WARNING) << "Malformed machine_model_version entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
const base::DictionaryValue* gpu_count_value = NULL;
if (value->GetDictionary("gpu_count", &gpu_count_value)) {
std::string op;
std::string int_value;
std::string int_value2;
gpu_count_value->GetString(kOp, &op);
gpu_count_value->GetString("value", &int_value);
gpu_count_value->GetString("value2", &int_value2);
if (!entry->SetGpuCountInfo(op, int_value, int_value2)) {
LOG(WARNING) << "Malformed gpu_count entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
bool direct_rendering;
if (value->GetBoolean("direct_rendering", &direct_rendering)) {
entry->SetDirectRenderingInfo(direct_rendering);
dictionary_entry_count++;
}
bool in_process_gpu;
if (value->GetBoolean("in_process_gpu", &in_process_gpu)) {
entry->SetInProcessGPUInfo(in_process_gpu);
dictionary_entry_count++;
}
if (top_level) {
const base::ListValue* feature_value = NULL;
if (value->GetList("features", &feature_value)) {
std::vector<std::string> feature_list;
std::vector<std::string> feature_exception_list;
for (size_t i = 0; i < feature_value->GetSize(); ++i) {
std::string feature;
const base::DictionaryValue* features_info_value = NULL;
if (feature_value->GetString(i, &feature)) {
feature_list.push_back(feature);
} else if (feature_value->GetDictionary(i, &features_info_value)) {
const base::ListValue* exception_list_value = NULL;
if (features_info_value->size() > 1) {
LOG(WARNING) << "Malformed feature entry " << entry->id();
return NULL;
}
if (features_info_value->GetList("exceptions",
&exception_list_value)) {
for (size_t i = 0; i < exception_list_value->GetSize(); ++i) {
std::string exception_feature;
if (exception_list_value->GetString(i, &exception_feature)) {
feature_exception_list.push_back(exception_feature);
} else {
LOG(WARNING) << "Malformed feature entry " << entry->id();
return NULL;
}
}
} else {
LOG(WARNING) << "Malformed feature entry " << entry->id();
return NULL;
}
} else {
LOG(WARNING) << "Malformed feature entry " << entry->id();
return NULL;
}
}
if (!entry->SetFeatures(feature_list, feature_exception_list, feature_map,
supports_feature_type_all)) {
LOG(WARNING) << "Malformed feature entry " << entry->id();
return NULL;
}
dictionary_entry_count++;
}
}
if (top_level) {
const base::ListValue* exception_list_value = NULL;
if (value->GetList("exceptions", &exception_list_value)) {
for (size_t i = 0; i < exception_list_value->GetSize(); ++i) {
const base::DictionaryValue* exception_value = NULL;
if (!exception_list_value->GetDictionary(i, &exception_value)) {
LOG(WARNING) << "Malformed exceptions entry " << entry->id();
return NULL;
}
ScopedGpuControlListEntry exception(GetEntryFromValue(
exception_value, false, feature_map, supports_feature_type_all));
if (exception.get() == NULL) {
LOG(WARNING) << "Malformed exceptions entry " << entry->id();
return NULL;
}
// Exception should inherit vendor_id from parent, otherwise if only
// device_ids are specified in Exception, the info will be incomplete.
if (exception->vendor_id_ == 0 && entry->vendor_id_ != 0)
exception->vendor_id_ = entry->vendor_id_;
entry->AddException(exception);
}
dictionary_entry_count++;
}
}
if (value->size() != dictionary_entry_count) {
LOG(WARNING) << "Entry with unknown fields " << entry->id();
return NULL;
}
// If GL_VERSION is specified, but no info about whether it's GL or GLES,
// we use the default for the platform. See GLType enum declaration.
if (entry->gl_version_info_.get() != NULL && entry->gl_type_ == kGLTypeNone)
entry->gl_type_ = GetDefaultGLType();
return entry;
}
GpuControlList::GpuControlListEntry::GpuControlListEntry()
: id_(0),
disabled_(false),
vendor_id_(0),
multi_gpu_style_(kMultiGpuStyleNone),
multi_gpu_category_(kMultiGpuCategoryActive),
gl_type_(kGLTypeNone) {
}
GpuControlList::GpuControlListEntry::~GpuControlListEntry() { }
bool GpuControlList::GpuControlListEntry::SetId(uint32_t id) {
if (id != 0) {
id_ = id;
return true;
}
return false;
}
void GpuControlList::GpuControlListEntry::SetDisabled(bool disabled) {
disabled_ = disabled;
}
bool GpuControlList::GpuControlListEntry::SetOsInfo(
const std::string& os,
const std::string& version_op,
const std::string& version_string,
const std::string& version_string2) {
os_info_.reset(new OsInfo(os, version_op, version_string, version_string2));
return os_info_->IsValid();
}
bool GpuControlList::GpuControlListEntry::SetVendorId(
const std::string& vendor_id_string) {
vendor_id_ = 0;
return base::HexStringToUInt(vendor_id_string, &vendor_id_) &&
vendor_id_ != 0;
}
bool GpuControlList::GpuControlListEntry::AddDeviceId(
const std::string& device_id_string) {
uint32_t device_id = 0;
if (base::HexStringToUInt(device_id_string, &device_id) && device_id != 0) {
device_id_list_.push_back(device_id);
return true;
}
return false;
}
bool GpuControlList::GpuControlListEntry::SetMultiGpuStyle(
const std::string& multi_gpu_style_string) {
MultiGpuStyle style = StringToMultiGpuStyle(multi_gpu_style_string);
if (style == kMultiGpuStyleNone)
return false;
multi_gpu_style_ = style;
return true;
}
bool GpuControlList::GpuControlListEntry::SetMultiGpuCategory(
const std::string& multi_gpu_category_string) {
MultiGpuCategory category =
StringToMultiGpuCategory(multi_gpu_category_string);
if (category == kMultiGpuCategoryNone)
return false;
multi_gpu_category_ = category;
return true;
}
bool GpuControlList::GpuControlListEntry::SetGLType(
const std::string& gl_type_string) {
GLType gl_type = StringToGLType(gl_type_string);
if (gl_type == kGLTypeNone)
return false;
gl_type_ = gl_type;
return true;
}
bool GpuControlList::GpuControlListEntry::SetDriverVendorInfo(
const std::string& vendor_value) {
driver_vendor_info_ = vendor_value;
return !driver_vendor_info_.empty();
}
bool GpuControlList::GpuControlListEntry::SetDriverVersionInfo(
const std::string& version_op,
const std::string& version_style,
const std::string& version_string,
const std::string& version_string2) {
driver_version_info_.reset(new VersionInfo(
version_op, version_style, version_string, version_string2));
return driver_version_info_->IsValid();
}
bool GpuControlList::GpuControlListEntry::SetDriverDateInfo(
const std::string& date_op,
const std::string& date_string,
const std::string& date_string2) {
driver_date_info_.reset(
new VersionInfo(date_op, std::string(), date_string, date_string2));
return driver_date_info_->IsValid();
}
bool GpuControlList::GpuControlListEntry::SetGLVersionInfo(
const std::string& version_op,
const std::string& version_string,
const std::string& version_string2) {
gl_version_info_.reset(new VersionInfo(
version_op, std::string(), version_string, version_string2));
return gl_version_info_->IsValid();
}
bool GpuControlList::GpuControlListEntry::SetGLVendorInfo(
const std::string& vendor_value) {
gl_vendor_info_ = vendor_value;
return !gl_vendor_info_.empty();
}
bool GpuControlList::GpuControlListEntry::SetGLRendererInfo(
const std::string& renderer_value) {
gl_renderer_info_ = renderer_value;
return !gl_renderer_info_.empty();
}
bool GpuControlList::GpuControlListEntry::SetGLExtensionsInfo(
const std::string& extensions_value) {
gl_extensions_info_ = extensions_value;
return !gl_extensions_info_.empty();
}
bool GpuControlList::GpuControlListEntry::SetGLResetNotificationStrategyInfo(
const std::string& op,
const std::string& int_string,
const std::string& int_string2) {
gl_reset_notification_strategy_info_.reset(
new IntInfo(op, int_string, int_string2));
return gl_reset_notification_strategy_info_->IsValid();
}
bool GpuControlList::GpuControlListEntry::SetCpuBrand(
const std::string& cpu_value) {
cpu_brand_ = cpu_value;
return !cpu_brand_.empty();
}
bool GpuControlList::GpuControlListEntry::SetPerfGraphicsInfo(
const std::string& op,
const std::string& float_string,
const std::string& float_string2) {
perf_graphics_info_.reset(new FloatInfo(op, float_string, float_string2));
return perf_graphics_info_->IsValid();
}
bool GpuControlList::GpuControlListEntry::SetPerfGamingInfo(
const std::string& op,
const std::string& float_string,
const std::string& float_string2) {
perf_gaming_info_.reset(new FloatInfo(op, float_string, float_string2));
return perf_gaming_info_->IsValid();
}
bool GpuControlList::GpuControlListEntry::SetPerfOverallInfo(
const std::string& op,
const std::string& float_string,
const std::string& float_string2) {
perf_overall_info_.reset(new FloatInfo(op, float_string, float_string2));
return perf_overall_info_->IsValid();
}
bool GpuControlList::GpuControlListEntry::AddMachineModelName(
const std::string& model_name) {
if (model_name.empty())
return false;
machine_model_name_list_.push_back(model_name);
return true;
}
bool GpuControlList::GpuControlListEntry::SetMachineModelVersionInfo(
const std::string& version_op,
const std::string& version_string,
const std::string& version_string2) {
machine_model_version_info_.reset(new VersionInfo(
version_op, std::string(), version_string, version_string2));
return machine_model_version_info_->IsValid();
}
bool GpuControlList::GpuControlListEntry::SetGpuCountInfo(
const std::string& op,
const std::string& int_string,
const std::string& int_string2) {
gpu_count_info_.reset(new IntInfo(op, int_string, int_string2));
return gpu_count_info_->IsValid();
}
void GpuControlList::GpuControlListEntry::SetDirectRenderingInfo(bool value) {
direct_rendering_info_.reset(new BoolInfo(value));
}
void GpuControlList::GpuControlListEntry::SetInProcessGPUInfo(bool value) {
in_process_gpu_info_.reset(new BoolInfo(value));
}
bool GpuControlList::GpuControlListEntry::SetFeatures(
const std::vector<std::string>& feature_strings,
const std::vector<std::string>& exception_strings,
const FeatureMap& feature_map,
bool supports_feature_type_all) {
size_t size = feature_strings.size();
if (size == 0)
return false;
features_.clear();
for (size_t i = 0; i < size; ++i) {
int feature = 0;
if (supports_feature_type_all && feature_strings[i] == "all") {
for (FeatureMap::const_iterator iter = feature_map.begin();
iter != feature_map.end(); ++iter) {
if (std::find(exception_strings.begin(), exception_strings.end(),
iter->first) == exception_strings.end())
features_.insert(iter->second);
}
continue;
}
if (!StringToFeature(feature_strings[i], &feature, feature_map)) {
features_.clear();
return false;
}
if (std::find(exception_strings.begin(), exception_strings.end(),
feature_strings[i]) == exception_strings.end())
features_.insert(feature);
}
return true;
}
void GpuControlList::GpuControlListEntry::AddException(
ScopedGpuControlListEntry exception) {
exceptions_.push_back(exception);
}
bool GpuControlList::GpuControlListEntry::GLVersionInfoMismatch(
const std::string& gl_version) const {
if (gl_version.empty())
return false;
if (gl_version_info_.get() == NULL && gl_type_ == kGLTypeNone)
return false;
std::vector<std::string> segments = base::SplitString(
gl_version, " ", base::TRIM_WHITESPACE, base::SPLIT_WANT_ALL);
std::string number;
GLType gl_type = kGLTypeNone;
if (segments.size() > 2 &&
segments[0] == "OpenGL" && segments[1] == "ES") {
bool full_match = RE2::FullMatch(segments[2], "([\\d.]+).*", &number);
DCHECK(full_match);
gl_type = kGLTypeGLES;
if (segments.size() > 3 &&
base::StartsWith(segments[3], "(ANGLE",
base::CompareCase::INSENSITIVE_ASCII)) {
gl_type = kGLTypeANGLE;
}
} else {
number = segments[0];
gl_type = kGLTypeGL;
}
if (gl_type_ != kGLTypeNone && gl_type_ != gl_type)
return true;
if (gl_version_info_.get() != NULL && !gl_version_info_->Contains(number))
return true;
return false;
}
// static
GpuControlList::GpuControlListEntry::MultiGpuStyle
GpuControlList::GpuControlListEntry::StringToMultiGpuStyle(
const std::string& style) {
if (style == kMultiGpuStyleStringOptimus)
return kMultiGpuStyleOptimus;
if (style == kMultiGpuStyleStringAMDSwitchable)
return kMultiGpuStyleAMDSwitchable;
if (style == kMultiGpuStyleStringAMDSwitchableIntegrated)
return kMultiGpuStyleAMDSwitchableIntegrated;
if (style == kMultiGpuStyleStringAMDSwitchableDiscrete)
return kMultiGpuStyleAMDSwitchableDiscrete;
return kMultiGpuStyleNone;
}
// static
GpuControlList::GpuControlListEntry::MultiGpuCategory
GpuControlList::GpuControlListEntry::StringToMultiGpuCategory(
const std::string& category) {
if (category == kMultiGpuCategoryStringPrimary)
return kMultiGpuCategoryPrimary;
if (category == kMultiGpuCategoryStringSecondary)
return kMultiGpuCategorySecondary;
if (category == kMultiGpuCategoryStringActive)
return kMultiGpuCategoryActive;
if (category == kMultiGpuCategoryStringAny)
return kMultiGpuCategoryAny;
return kMultiGpuCategoryNone;
}
// static
GpuControlList::GpuControlListEntry::GLType
GpuControlList::GpuControlListEntry::StringToGLType(
const std::string& gl_type) {
if (gl_type == kGLTypeStringGL)
return kGLTypeGL;
if (gl_type == kGLTypeStringGLES)
return kGLTypeGLES;
if (gl_type == kGLTypeStringANGLE)
return kGLTypeANGLE;
return kGLTypeNone;
}
// static
GpuControlList::GpuControlListEntry::GLType
GpuControlList::GpuControlListEntry::GetDefaultGLType() {
#if defined(OS_CHROMEOS)
return kGLTypeGL;
#elif defined(OS_LINUX) || defined(OS_OPENBSD)
return kGLTypeGL;
#elif defined(OS_MACOSX)
return kGLTypeGL;
#elif defined(OS_WIN)
return kGLTypeANGLE;
#elif defined(OS_ANDROID)
return kGLTypeGLES;
#else
return kGLTypeNone;
#endif
}
void GpuControlList::GpuControlListEntry::LogControlListMatch(
const std::string& control_list_logging_name) const {
static const char kControlListMatchMessage[] =
"Control list match for rule #%u in %s.";
VLOG(1) << base::StringPrintf(kControlListMatchMessage, id_,
control_list_logging_name.c_str());
}
bool GpuControlList::GpuControlListEntry::Contains(
OsType os_type, const std::string& os_version,
const GPUInfo& gpu_info) const {
DCHECK(os_type != kOsAny);
if (os_info_.get() != NULL && !os_info_->Contains(os_type, os_version))
return false;
if (vendor_id_ != 0) {
std::vector<GPUInfo::GPUDevice> candidates;
switch (multi_gpu_category_) {
case kMultiGpuCategoryPrimary:
candidates.push_back(gpu_info.gpu);
break;
case kMultiGpuCategorySecondary:
candidates = gpu_info.secondary_gpus;
break;
case kMultiGpuCategoryAny:
candidates = gpu_info.secondary_gpus;
candidates.push_back(gpu_info.gpu);
break;
case kMultiGpuCategoryActive:
if (gpu_info.gpu.active || gpu_info.secondary_gpus.empty())
candidates.push_back(gpu_info.gpu);
for (size_t ii = 0; ii < gpu_info.secondary_gpus.size(); ++ii) {
if (gpu_info.secondary_gpus[ii].active)
candidates.push_back(gpu_info.secondary_gpus[ii]);
}
if (candidates.empty())
candidates.push_back(gpu_info.gpu);
default:
break;
}
GPUInfo::GPUDevice gpu;
gpu.vendor_id = vendor_id_;
bool found = false;
if (device_id_list_.empty()) {
for (size_t ii = 0; ii < candidates.size(); ++ii) {
if (gpu.vendor_id == candidates[ii].vendor_id) {
found = true;
break;
}
}
} else {
for (size_t ii = 0; ii < device_id_list_.size(); ++ii) {
gpu.device_id = device_id_list_[ii];
for (size_t jj = 0; jj < candidates.size(); ++jj) {
if (gpu.vendor_id == candidates[jj].vendor_id &&
gpu.device_id == candidates[jj].device_id) {
found = true;
break;
}
}
}
}
if (!found)
return false;
}
switch (multi_gpu_style_) {
case kMultiGpuStyleOptimus:
if (!gpu_info.optimus)
return false;
break;
case kMultiGpuStyleAMDSwitchable:
if (!gpu_info.amd_switchable)
return false;
break;
case kMultiGpuStyleAMDSwitchableDiscrete:
if (!gpu_info.amd_switchable)
return false;
// The discrete GPU is always the primary GPU.
// This is guaranteed by GpuInfoCollector.
if (!gpu_info.gpu.active)
return false;
break;
case kMultiGpuStyleAMDSwitchableIntegrated:
if (!gpu_info.amd_switchable)
return false;
// Assume the integrated GPU is the first in the secondary GPU list.
if (gpu_info.secondary_gpus.size() == 0 ||
!gpu_info.secondary_gpus[0].active)
return false;
break;
case kMultiGpuStyleNone:
break;
}
if (StringMismatch(gpu_info.driver_vendor, driver_vendor_info_))
return false;
if (driver_version_info_.get() != NULL && !gpu_info.driver_version.empty()) {
if (!driver_version_info_->Contains(gpu_info.driver_version))
return false;
}
if (driver_date_info_.get() != NULL && !gpu_info.driver_date.empty()) {
if (!driver_date_info_->Contains(gpu_info.driver_date, '-'))
return false;
}
if (GLVersionInfoMismatch(gpu_info.gl_version))
return false;
if (StringMismatch(gpu_info.gl_vendor, gl_vendor_info_))
return false;
if (StringMismatch(gpu_info.gl_renderer, gl_renderer_info_))
return false;
if (StringMismatch(gpu_info.gl_extensions, gl_extensions_info_))
return false;
if (gl_reset_notification_strategy_info_.get() != NULL &&
!gl_reset_notification_strategy_info_->Contains(
gpu_info.gl_reset_notification_strategy))
return false;
if (!machine_model_name_list_.empty()) {
if (gpu_info.machine_model_name.empty())
return false;
bool found_match = false;
for (size_t ii = 0; ii < machine_model_name_list_.size(); ++ii) {
if (RE2::FullMatch(gpu_info.machine_model_name,
machine_model_name_list_[ii])) {
found_match = true;
break;
}
}
if (!found_match)
return false;
}
if (machine_model_version_info_.get() != NULL &&
(gpu_info.machine_model_version.empty() ||
!machine_model_version_info_->Contains(gpu_info.machine_model_version)))
return false;
if (gpu_count_info_.get() != NULL &&
!gpu_count_info_->Contains(gpu_info.secondary_gpus.size() + 1))
return false;
if (direct_rendering_info_.get() != NULL &&
!direct_rendering_info_->Contains(gpu_info.direct_rendering))
return false;
if (in_process_gpu_info_.get() != NULL &&
!in_process_gpu_info_->Contains(gpu_info.in_process_gpu))
return false;
if (!cpu_brand_.empty()) {
base::CPU cpu_info;
if (StringMismatch(cpu_info.cpu_brand(), cpu_brand_))
return false;
}
for (size_t i = 0; i < exceptions_.size(); ++i) {
if (exceptions_[i]->Contains(os_type, os_version, gpu_info) &&
!exceptions_[i]->NeedsMoreInfo(gpu_info, true))
return false;
}
return true;
}
bool GpuControlList::GpuControlListEntry::NeedsMoreInfo(
const GPUInfo& gpu_info,
bool consider_exceptions) const {
// We only check for missing info that might be collected with a gl context.
// If certain info is missing due to some error, say, we fail to collect
// vendor_id/device_id, then even if we launch GPU process and create a gl
// context, we won't gather such missing info, so we still return false.
if (!driver_vendor_info_.empty() && gpu_info.driver_vendor.empty())
return true;
if (driver_version_info_.get() && gpu_info.driver_version.empty())
return true;
if (!gl_vendor_info_.empty() && gpu_info.gl_vendor.empty())
return true;
if (!gl_renderer_info_.empty() && gpu_info.gl_renderer.empty())
return true;
if (consider_exceptions) {
for (size_t i = 0; i < exceptions_.size(); ++i) {
if (exceptions_[i]->NeedsMoreInfo(gpu_info, consider_exceptions))
return true;
}
}
return false;
}
GpuControlList::OsType GpuControlList::GpuControlListEntry::GetOsType() const {
if (os_info_.get() == NULL)
return kOsAny;
return os_info_->type();
}
uint32_t GpuControlList::GpuControlListEntry::id() const {
return id_;
}
bool GpuControlList::GpuControlListEntry::disabled() const {
return disabled_;
}
const std::set<int>& GpuControlList::GpuControlListEntry::features() const {
return features_;
}
void GpuControlList::GpuControlListEntry::GetFeatureNames(
base::ListValue* feature_names,
const FeatureMap& feature_map,
bool supports_feature_type_all) const {
DCHECK(feature_names);
if (supports_feature_type_all && features_.size() == feature_map.size()) {
feature_names->AppendString("all");
return;
}
for (FeatureMap::const_iterator iter = feature_map.begin();
iter != feature_map.end(); ++iter) {
if (features_.count(iter->second) > 0)
feature_names->AppendString(iter->first);
}
}
// static
bool GpuControlList::GpuControlListEntry::StringToFeature(
const std::string& feature_name, int* feature_id,
const FeatureMap& feature_map) {
FeatureMap::const_iterator iter = feature_map.find(feature_name);
if (iter != feature_map.end()) {
*feature_id = iter->second;
return true;
}
return false;
}
GpuControlList::GpuControlList()
: max_entry_id_(0),
needs_more_info_(false),
supports_feature_type_all_(false),
control_list_logging_enabled_(false) {
}
GpuControlList::~GpuControlList() {
Clear();
}
bool GpuControlList::LoadList(
const std::string& json_context,
GpuControlList::OsFilter os_filter) {
std::unique_ptr<base::DictionaryValue> root =
base::DictionaryValue::From(base::JSONReader::Read(json_context));
if (!root)
return false;
return LoadList(*root, os_filter);
}
bool GpuControlList::LoadList(const base::DictionaryValue& parsed_json,
GpuControlList::OsFilter os_filter) {
std::vector<ScopedGpuControlListEntry> entries;
parsed_json.GetString("version", &version_);
std::vector<std::string> pieces;
if (!ProcessVersionString(version_, '.', &pieces))
return false;
const base::ListValue* list = NULL;
if (!parsed_json.GetList("entries", &list))
return false;
uint32_t max_entry_id = 0;
for (size_t i = 0; i < list->GetSize(); ++i) {
const base::DictionaryValue* list_item = NULL;
bool valid = list->GetDictionary(i, &list_item);
if (!valid || list_item == NULL)
return false;
ScopedGpuControlListEntry entry(GpuControlListEntry::GetEntryFromValue(
list_item, true, feature_map_, supports_feature_type_all_));
if (entry.get() == NULL)
return false;
if (entry->id() > max_entry_id)
max_entry_id = entry->id();
entries.push_back(entry);
}
Clear();
OsType my_os = GetOsType();
for (size_t i = 0; i < entries.size(); ++i) {
OsType entry_os = entries[i]->GetOsType();
if (os_filter == GpuControlList::kAllOs ||
entry_os == kOsAny || entry_os == my_os)
entries_.push_back(entries[i]);
}
max_entry_id_ = max_entry_id;
return true;
}
std::set<int> GpuControlList::MakeDecision(
GpuControlList::OsType os,
std::string os_version,
const GPUInfo& gpu_info) {
active_entries_.clear();
std::set<int> features;
needs_more_info_ = false;
// Has all features permanently in the list without any possibility of
// removal in the future (subset of "features" set).
std::set<int> permanent_features;
// Has all features absent from "features" set that could potentially be
// included later with more information.
std::set<int> potential_features;
if (os == kOsAny)
os = GetOsType();
if (os_version.empty())
os_version = base::SysInfo::OperatingSystemVersion();
for (size_t i = 0; i < entries_.size(); ++i) {
ScopedGpuControlListEntry entry = entries_[i];
if (entry->Contains(os, os_version, gpu_info)) {
bool needs_more_info_main = entry->NeedsMoreInfo(gpu_info, false);
bool needs_more_info_exception = entry->NeedsMoreInfo(gpu_info, true);
if (!entry->disabled()) {
if (control_list_logging_enabled_)
entry->LogControlListMatch(control_list_logging_name_);
// Only look at main entry info when deciding what to add to "features"
// set. If we don't have enough info for an exception, it's safer if we
// just ignore the exception and assume the exception doesn't apply.
for (std::set<int>::const_iterator iter = entry->features().begin();
iter != entry->features().end(); ++iter) {
if (needs_more_info_main) {
if (!features.count(*iter))
potential_features.insert(*iter);
} else {
features.insert(*iter);
potential_features.erase(*iter);
if (!needs_more_info_exception)
permanent_features.insert(*iter);
}
}
}
if (!needs_more_info_main)
active_entries_.push_back(entry);
}
}
needs_more_info_ = permanent_features.size() < features.size() ||
!potential_features.empty();
return features;
}
void GpuControlList::GetDecisionEntries(std::vector<uint32_t>* entry_ids,
bool disabled) const {
DCHECK(entry_ids);
entry_ids->clear();
for (size_t i = 0; i < active_entries_.size(); ++i) {
if (disabled == active_entries_[i]->disabled())
entry_ids->push_back(active_entries_[i]->id());
}
}
std::vector<std::string> GpuControlList::GetDisabledExtensions() {
std::set<std::string> disabled_extensions;
for (size_t i = 0; i < active_entries_.size(); ++i) {
GpuControlListEntry* entry = active_entries_[i].get();
if (entry->disabled())
continue;
disabled_extensions.insert(entry->disabled_extensions().begin(),
entry->disabled_extensions().end());
}
return std::vector<std::string>(disabled_extensions.begin(),
disabled_extensions.end());
}
void GpuControlList::GetReasons(base::ListValue* problem_list,
const std::string& tag) const {
DCHECK(problem_list);
for (size_t i = 0; i < active_entries_.size(); ++i) {
GpuControlListEntry* entry = active_entries_[i].get();
if (entry->disabled())
continue;
std::unique_ptr<base::DictionaryValue> problem(new base::DictionaryValue());
problem->SetString("description", entry->description());
base::ListValue* cr_bugs = new base::ListValue();
for (size_t j = 0; j < entry->cr_bugs().size(); ++j)
cr_bugs->AppendInteger(entry->cr_bugs()[j]);
problem->Set("crBugs", cr_bugs);
base::ListValue* webkit_bugs = new base::ListValue();
for (size_t j = 0; j < entry->webkit_bugs().size(); ++j) {
webkit_bugs->AppendInteger(entry->webkit_bugs()[j]);
}
problem->Set("webkitBugs", webkit_bugs);
base::ListValue* features = new base::ListValue();
entry->GetFeatureNames(features, feature_map_, supports_feature_type_all_);
problem->Set("affectedGpuSettings", features);
DCHECK(tag == "workarounds" || tag == "disabledFeatures");
problem->SetString("tag", tag);
problem_list->Append(std::move(problem));
}
}
size_t GpuControlList::num_entries() const {
return entries_.size();
}
uint32_t GpuControlList::max_entry_id() const {
return max_entry_id_;
}
std::string GpuControlList::version() const {
return version_;
}
GpuControlList::OsType GpuControlList::GetOsType() {
#if defined(OS_CHROMEOS)
return kOsChromeOS;
#elif defined(OS_WIN)
return kOsWin;
#elif defined(OS_ANDROID)
return kOsAndroid;
#elif defined(OS_LINUX) || defined(OS_OPENBSD)
return kOsLinux;
#elif defined(OS_MACOSX)
return kOsMacosx;
#else
return kOsUnknown;
#endif
}
void GpuControlList::Clear() {
entries_.clear();
active_entries_.clear();
max_entry_id_ = 0;
}
// static
GpuControlList::NumericOp GpuControlList::StringToNumericOp(
const std::string& op) {
if (op == "=")
return kEQ;
if (op == "<")
return kLT;
if (op == "<=")
return kLE;
if (op == ">")
return kGT;
if (op == ">=")
return kGE;
if (op == "any")
return kAny;
if (op == "between")
return kBetween;
return kUnknown;
}
void GpuControlList::AddSupportedFeature(
const std::string& feature_name, int feature_id) {
feature_map_[feature_name] = feature_id;
}
void GpuControlList::set_supports_feature_type_all(bool supported) {
supports_feature_type_all_ = supported;
}
} // namespace gpu