Merge pull request #50 from DanielSWolf/feature/cleanup

Code cleanup
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Daniel Wolf 2019-01-03 08:50:10 +01:00 committed by GitHub
commit 59f2993174
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94 changed files with 1700 additions and 1060 deletions

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@ -1,7 +1,50 @@
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<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppBadAngleBracketsSpaces/@EntryIndexedValue">WARNING</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppBadBracesSpaces/@EntryIndexedValue">WARNING</s:String>
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<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppBadColonSpaces/@EntryIndexedValue">WARNING</s:String>
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<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppBadEmptyBracesLineBreaks/@EntryIndexedValue">WARNING</s:String>
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<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppBadListLineBreaks/@EntryIndexedValue">WARNING</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppBadMemberAccessSpaces/@EntryIndexedValue">WARNING</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppBadNamespaceBracesIndent/@EntryIndexedValue">WARNING</s:String>
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<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppBadSwitchBracesIndent/@EntryIndexedValue">WARNING</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppBadSymbolSpaces/@EntryIndexedValue">WARNING</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClangTidyHicppUseAuto/@EntryIndexedValue">HINT</s:String>
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<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClangTidyModernizePassByValue/@EntryIndexedValue">HINT</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClangTidyModernizeRawStringLiteral/@EntryIndexedValue">HINT</s:String> <s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppClangTidyModernizeRawStringLiteral/@EntryIndexedValue">HINT</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppFunctionDoesntReturnValue/@EntryIndexedValue">ERROR</s:String> <s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppFunctionDoesntReturnValue/@EntryIndexedValue">ERROR</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppIncorrectBlankLinesNearBraces/@EntryIndexedValue">WARNING</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppLocalVariableMayBeConst/@EntryIndexedValue">WARNING</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppMissingBlankLines/@EntryIndexedValue">WARNING</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppMissingIndent/@EntryIndexedValue">DO_NOT_SHOW</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppMissingLinebreak/@EntryIndexedValue">WARNING</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppMissingSpace/@EntryIndexedValue">WARNING</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppMultipleSpaces/@EntryIndexedValue">WARNING</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppOutdentIsOffPrevLevel/@EntryIndexedValue">DO_NOT_SHOW</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppRedundantBlankLines/@EntryIndexedValue">WARNING</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppRedundantLinebreak/@EntryIndexedValue">WARNING</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppRedundantSpace/@EntryIndexedValue">WARNING</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=CppTabsAndSpacesMismatch/@EntryIndexedValue">WARNING</s:String>
<s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=LocalizableElement/@EntryIndexedValue">DO_NOT_SHOW</s:String> <s:String x:Key="/Default/CodeInspection/Highlighting/InspectionSeverities/=LocalizableElement/@EntryIndexedValue">DO_NOT_SHOW</s:String>
@ -29,9 +72,12 @@
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<s:String x:Key="/Default/CodeStyle/CodeFormatting/CppFormatting/SIMPLE_EMBEDDED_STATEMENT_STYLE/@EntryValue">ON_SINGLE_LINE</s:String> <s:String x:Key="/Default/CodeStyle/CodeFormatting/CppFormatting/SIMPLE_EMBEDDED_STATEMENT_STYLE/@EntryValue">ON_SINGLE_LINE</s:String>
<s:Boolean x:Key="/Default/CodeStyle/CodeFormatting/CppFormatting/SPACE_AFTER_CAST_EXPRESSION_PARENTHESES/@EntryValue">True</s:Boolean> <s:Boolean x:Key="/Default/CodeStyle/CodeFormatting/CppFormatting/SPACE_AFTER_CAST_EXPRESSION_PARENTHESES/@EntryValue">True</s:Boolean>
<s:Boolean x:Key="/Default/CodeStyle/CodeFormatting/CppFormatting/SPACE_BEFORE_INITIALIZER_BRACES/@EntryValue">True</s:Boolean>
<s:Boolean x:Key="/Default/CodeStyle/CodeFormatting/CppFormatting/SPACE_BEFORE_TEMPLATE_PARAMS/@EntryValue">False</s:Boolean> <s:Boolean x:Key="/Default/CodeStyle/CodeFormatting/CppFormatting/SPACE_BEFORE_TEMPLATE_PARAMS/@EntryValue">False</s:Boolean>
<s:Boolean x:Key="/Default/CodeStyle/CodeFormatting/CppFormatting/SPACE_WITHIN_INITIALIZER_BRACES/@EntryValue">True</s:Boolean>
<s:String x:Key="/Default/CodeStyle/CodeFormatting/CppFormatting/TYPE_DECLARATION_BRACES/@EntryValue">END_OF_LINE</s:String> <s:String x:Key="/Default/CodeStyle/CodeFormatting/CppFormatting/TYPE_DECLARATION_BRACES/@EntryValue">END_OF_LINE</s:String>
<s:String x:Key="/Default/CodeStyle/CodeFormatting/CppFormatting/WRAP_ENUMERATION_STYLE/@EntryValue">CHOP_ALWAYS</s:String> <s:String x:Key="/Default/CodeStyle/CodeFormatting/CppFormatting/WRAP_ENUMERATION_STYLE/@EntryValue">CHOP_ALWAYS</s:String>
<s:Boolean x:Key="/Default/CodeStyle/CodeFormatting/CppFormatting/WRAP_LINES/@EntryValue">False</s:Boolean>
<s:String x:Key="/Default/CodeStyle/CodeFormatting/CSharpFormat/ACCESSOR_DECLARATION_BRACES/@EntryValue">END_OF_LINE</s:String> <s:String x:Key="/Default/CodeStyle/CodeFormatting/CSharpFormat/ACCESSOR_DECLARATION_BRACES/@EntryValue">END_OF_LINE</s:String>
<s:String x:Key="/Default/CodeStyle/CodeFormatting/CSharpFormat/ACCESSOR_OWNER_DECLARATION_BRACES/@EntryValue">END_OF_LINE</s:String> <s:String x:Key="/Default/CodeStyle/CodeFormatting/CSharpFormat/ACCESSOR_OWNER_DECLARATION_BRACES/@EntryValue">END_OF_LINE</s:String>
<s:String x:Key="/Default/CodeStyle/CodeFormatting/CSharpFormat/ALIGNMENT_TAB_FILL_STYLE/@EntryValue">USE_TABS_ONLY</s:String> <s:String x:Key="/Default/CodeStyle/CodeFormatting/CSharpFormat/ALIGNMENT_TAB_FILL_STYLE/@EntryValue">USE_TABS_ONLY</s:String>
@ -58,6 +104,7 @@
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<s:String x:Key="/Default/CodeStyle/CodeFormatting/XmlDocFormatter/ALIGNMENT_TAB_FILL_STYLE/@EntryValue">USE_TABS_ONLY</s:String> <s:String x:Key="/Default/CodeStyle/CodeFormatting/XmlDocFormatter/ALIGNMENT_TAB_FILL_STYLE/@EntryValue">USE_TABS_ONLY</s:String>
<s:String x:Key="/Default/CodeStyle/CodeFormatting/XmlFormatter/ALIGNMENT_TAB_FILL_STYLE/@EntryValue">USE_TABS_ONLY</s:String> <s:String x:Key="/Default/CodeStyle/CodeFormatting/XmlFormatter/ALIGNMENT_TAB_FILL_STYLE/@EntryValue">USE_TABS_ONLY</s:String>
<s:Boolean x:Key="/Default/CodeStyle/CppIntroduceType/InsertTypeAlias/@EntryValue">True</s:Boolean>
<s:String x:Key="/Default/CodeStyle/CSharpVarKeywordUsage/ForBuiltInTypes/@EntryValue">UseExplicitType</s:String> <s:String x:Key="/Default/CodeStyle/CSharpVarKeywordUsage/ForBuiltInTypes/@EntryValue">UseExplicitType</s:String>
<s:String x:Key="/Default/CodeStyle/CSharpVarKeywordUsage/ForSimpleTypes/@EntryValue">UseVarWhenEvident</s:String> <s:String x:Key="/Default/CodeStyle/CSharpVarKeywordUsage/ForSimpleTypes/@EntryValue">UseVarWhenEvident</s:String>
<s:String x:Key="/Default/CodeStyle/Naming/CppNaming/Rules/=Class_0020and_0020struct_0020fields/@EntryIndexedValue">&lt;NamingElement Priority="10"&gt;&lt;Descriptor Static="Indeterminate" Constexpr="Indeterminate" Const="Indeterminate" Volatile="Indeterminate" Accessibility="NOT_APPLICABLE"&gt;&lt;type Name="class field" /&gt;&lt;type Name="struct field" /&gt;&lt;/Descriptor&gt;&lt;Policy Inspect="True" Prefix="" Suffix="_" Style="aaBb" /&gt;&lt;/NamingElement&gt;</s:String> <s:String x:Key="/Default/CodeStyle/Naming/CppNaming/Rules/=Class_0020and_0020struct_0020fields/@EntryIndexedValue">&lt;NamingElement Priority="10"&gt;&lt;Descriptor Static="Indeterminate" Constexpr="Indeterminate" Const="Indeterminate" Volatile="Indeterminate" Accessibility="NOT_APPLICABLE"&gt;&lt;type Name="class field" /&gt;&lt;type Name="struct field" /&gt;&lt;/Descriptor&gt;&lt;Policy Inspect="True" Prefix="" Suffix="_" Style="aaBb" /&gt;&lt;/NamingElement&gt;</s:String>
@ -73,7 +120,7 @@
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@ -120,18 +167,59 @@
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<s:String x:Key="/Default/Environment/PerformanceGuide/SwitchBehaviour/=XAML_0020Designer/@EntryIndexedValue">LIVE_MONITOR</s:String>
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<s:Boolean x:Key="/Default/Environment/SettingsMigration/IsMigratorApplied/=JetBrains_002EReSharper_002EFeature_002EServices_002ECpp_002ECodeStyle_002ESettingsUpgrade_002ENamespaceIndentationSettingsUpgrader/@EntryIndexedValue">True</s:Boolean> <s:Boolean x:Key="/Default/Environment/SettingsMigration/IsMigratorApplied/=JetBrains_002EReSharper_002EFeature_002EServices_002ECpp_002ECodeStyle_002ESettingsUpgrade_002ENamespaceIndentationSettingsUpgrader/@EntryIndexedValue">True</s:Boolean>
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<s:Boolean x:Key="/Default/Environment/SettingsMigration/IsMigratorApplied/=JetBrains_002EReSharper_002EPsi_002ECSharp_002ECodeStyle_002ECSharpUseContinuousIndentInsideBracesMigration/@EntryIndexedValue">True</s:Boolean>
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<s:Boolean x:Key="/Default/Environment/SettingsMigration/IsMigratorApplied/=JetBrains_002EReSharper_002EPsi_002ECSharp_002ECodeStyle_002ESettingsUpgrade_002EMigrateBlankLinesAroundFieldToBlankLinesAroundProperty/@EntryIndexedValue">True</s:Boolean> <s:Boolean x:Key="/Default/Environment/SettingsMigration/IsMigratorApplied/=JetBrains_002EReSharper_002EPsi_002ECSharp_002ECodeStyle_002ESettingsUpgrade_002EMigrateBlankLinesAroundFieldToBlankLinesAroundProperty/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/Environment/SettingsMigration/IsMigratorApplied/=JetBrains_002EReSharper_002EPsi_002ECSharp_002ECodeStyle_002ESettingsUpgrade_002EMigrateThisQualifierSettings/@EntryIndexedValue">True</s:Boolean> <s:Boolean x:Key="/Default/Environment/SettingsMigration/IsMigratorApplied/=JetBrains_002EReSharper_002EPsi_002ECSharp_002ECodeStyle_002ESettingsUpgrade_002EMigrateThisQualifierSettings/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/Environment/SettingsMigration/IsMigratorApplied/=JetBrains_002EReSharper_002EPsi_002EFormat_002ESettingsUpgrade_002EAlignmentTabFillStyleMigration/@EntryIndexedValue">True</s:Boolean> <s:Boolean x:Key="/Default/Environment/SettingsMigration/IsMigratorApplied/=JetBrains_002EReSharper_002EPsi_002EFormat_002ESettingsUpgrade_002EAlignmentTabFillStyleMigration/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=allphone/@EntryIndexedValue">True</s:Boolean> <s:Boolean x:Key="/Default/UserDictionary/Words/=allphone/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=Backoff/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=badbit/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=Bigram/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=bigrams/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=bitstream/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=centiseconds/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=cepstral/@EntryIndexedValue">True</s:Boolean> <s:Boolean x:Key="/Default/UserDictionary/Words/=cepstral/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=cmudict/@EntryIndexedValue">True</s:Boolean> <s:Boolean x:Key="/Default/UserDictionary/Words/=cmudict/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=Codepoints/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=cont_0027d/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=deflator/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=Downmix/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=downscaling/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=endian/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=failbit/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=Flite/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=fourcc/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=inbetween/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=inbetweens/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=Matthieu/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=pbeam/@EntryIndexedValue">True</s:Boolean> <s:Boolean x:Key="/Default/UserDictionary/Words/=pbeam/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=qwhy/@EntryIndexedValue">True</s:Boolean> <s:Boolean x:Key="/Default/UserDictionary/Words/=qwhy/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=rbegin/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=resample/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=retime/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=retimed/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=synth/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=tclap/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=timelines/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=Tweens/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=Unigram/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=unigrams/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=Upsampling/@EntryIndexedValue">True</s:Boolean>
<s:Boolean x:Key="/Default/UserDictionary/Words/=Viterbi/@EntryIndexedValue">True</s:Boolean> <s:Boolean x:Key="/Default/UserDictionary/Words/=Viterbi/@EntryIndexedValue">True</s:Boolean>
</wpf:ResourceDictionary> </wpf:ResourceDictionary>

View File

@ -1,26 +1,36 @@
#include "ShapeRule.h" #include "ShapeRule.h"
#include <boost/range/adaptor/transformed.hpp> #include <boost/range/adaptor/transformed.hpp>
#include <utility>
#include "time/ContinuousTimeline.h" #include "time/ContinuousTimeline.h"
using boost::optional; using boost::optional;
using boost::adaptors::transformed; using boost::adaptors::transformed;
template<typename T, bool AutoJoin> template<typename T, bool AutoJoin>
ContinuousTimeline<optional<T>, AutoJoin> boundedTimelinetoContinuousOptional(const BoundedTimeline<T, AutoJoin>& timeline) { ContinuousTimeline<optional<T>, AutoJoin> boundedTimelinetoContinuousOptional(
return{ const BoundedTimeline<T, AutoJoin>& timeline
timeline.getRange(), boost::none, ) {
timeline | transformed([](const Timed<T>& timedValue) { return Timed<optional<T>>(timedValue.getTimeRange(), timedValue.getValue()); }) return {
timeline.getRange(),
boost::none,
timeline | transformed([](const Timed<T>& timedValue) {
return Timed<optional<T>>(timedValue.getTimeRange(), timedValue.getValue());
})
}; };
} }
ShapeRule::ShapeRule(const ShapeSet& shapeSet, const optional<Phone>& phone, TimeRange phoneTiming) : ShapeRule::ShapeRule(
shapeSet(shapeSet), ShapeSet shapeSet,
phone(phone), optional<Phone> phone,
TimeRange phoneTiming
) :
shapeSet(std::move(shapeSet)),
phone(std::move(phone)),
phoneTiming(phoneTiming) phoneTiming(phoneTiming)
{} {}
ShapeRule ShapeRule::getInvalid() { ShapeRule ShapeRule::getInvalid() {
return {{}, boost::none,{0_cs, 0_cs}}; return { {}, boost::none, { 0_cs, 0_cs } };
} }
bool ShapeRule::operator==(const ShapeRule& rhs) const { bool ShapeRule::operator==(const ShapeRule& rhs) const {
@ -43,11 +53,14 @@ ContinuousTimeline<ShapeRule> getShapeRules(const BoundedTimeline<Phone>& phones
auto continuousPhones = boundedTimelinetoContinuousOptional(phones); auto continuousPhones = boundedTimelinetoContinuousOptional(phones);
// Create timeline of shape rules // Create timeline of shape rules
ContinuousTimeline<ShapeRule> shapeRules(phones.getRange(), {{Shape::X}, boost::none, {0_cs, 0_cs}}); ContinuousTimeline<ShapeRule> shapeRules(
phones.getRange(),
{ { Shape::X }, boost::none, { 0_cs, 0_cs } }
);
centiseconds previousDuration = 0_cs; centiseconds previousDuration = 0_cs;
for (const auto& timedPhone : continuousPhones) { for (const auto& timedPhone : continuousPhones) {
optional<Phone> phone = timedPhone.getValue(); optional<Phone> phone = timedPhone.getValue();
centiseconds duration = timedPhone.getDuration(); const centiseconds duration = timedPhone.getDuration();
if (phone) { if (phone) {
// Animate one phone // Animate one phone
@ -59,7 +72,10 @@ ContinuousTimeline<ShapeRule> getShapeRules(const BoundedTimeline<Phone>& phones
// Copy to timeline. // Copy to timeline.
// Later shape sets may overwrite earlier ones if overlapping. // Later shape sets may overwrite earlier ones if overlapping.
for (const auto& timedShapeSet : phoneShapeSets) { for (const auto& timedShapeSet : phoneShapeSets) {
shapeRules.set(timedShapeSet.getTimeRange(), ShapeRule(timedShapeSet.getValue(), phone, timedPhone.getTimeRange())); shapeRules.set(
timedShapeSet.getTimeRange(),
ShapeRule(timedShapeSet.getValue(), phone, timedPhone.getTimeRange())
);
} }
} }

View File

@ -11,7 +11,7 @@ struct ShapeRule {
boost::optional<Phone> phone; boost::optional<Phone> phone;
TimeRange phoneTiming; TimeRange phoneTiming;
ShapeRule(const ShapeSet& shapeSet, const boost::optional<Phone>& phone, TimeRange phoneTiming); ShapeRule(ShapeSet shapeSet, boost::optional<Phone> phone, TimeRange phoneTiming);
static ShapeRule getInvalid(); static ShapeRule getInvalid();

View File

@ -14,12 +14,14 @@ using std::map;
constexpr size_t shapeValueCount = static_cast<size_t>(Shape::EndSentinel); constexpr size_t shapeValueCount = static_cast<size_t>(Shape::EndSentinel);
Shape getBasicShape(Shape shape) { Shape getBasicShape(Shape shape) {
static constexpr array<Shape, shapeValueCount> basicShapes = make_array(A, B, C, D, E, F, B, C, A); static constexpr array<Shape, shapeValueCount> basicShapes =
make_array(A, B, C, D, E, F, B, C, A);
return basicShapes[static_cast<size_t>(shape)]; return basicShapes[static_cast<size_t>(shape)];
} }
Shape relax(Shape shape) { Shape relax(Shape shape) {
static constexpr array<Shape, shapeValueCount> relaxedShapes = make_array(A, B, B, C, C, B, X, B, X); static constexpr array<Shape, shapeValueCount> relaxedShapes =
make_array(A, B, B, C, C, B, X, B, X);
return relaxedShapes[static_cast<size_t>(shape)]; return relaxedShapes[static_cast<size_t>(shape)];
} }
@ -28,7 +30,8 @@ Shape getClosestShape(Shape reference, ShapeSet shapes) {
throw std::invalid_argument("Cannot select from empty set of shapes."); throw std::invalid_argument("Cannot select from empty set of shapes.");
} }
// A matrix that for each shape contains all shapes in ascending order of effort required to move to them // A matrix that for each shape contains all shapes in ascending order of effort required to
// move to them
constexpr static array<array<Shape, shapeValueCount>, shapeValueCount> effortMatrix = make_array( constexpr static array<array<Shape, shapeValueCount>, shapeValueCount> effortMatrix = make_array(
/* A */ make_array(A, X, G, B, C, H, E, D, F), /* A */ make_array(A, X, G, B, C, H, E, D, F),
/* B */ make_array(B, G, A, X, C, H, E, D, F), /* B */ make_array(B, G, A, X, C, H, E, D, F),
@ -38,7 +41,7 @@ Shape getClosestShape(Shape reference, ShapeSet shapes) {
/* F */ make_array(F, B, G, A, X, C, H, E, D), /* F */ make_array(F, B, G, A, X, C, H, E, D),
/* G */ make_array(G, B, C, H, A, X, E, D, F), /* G */ make_array(G, B, C, H, A, X, E, D, F),
/* H */ make_array(H, C, B, G, D, A, X, E, F), // Like C /* H */ make_array(H, C, B, G, D, A, X, E, F), // Like C
/* X */ make_array(X, A, G, B, C, H, E, D, F) // Like A /* X */ make_array(X, A, G, B, C, H, E, D, F) // Like A
); );
auto& closestShapes = effortMatrix.at(static_cast<size_t>(reference)); auto& closestShapes = effortMatrix.at(static_cast<size_t>(reference));
@ -55,107 +58,109 @@ optional<pair<Shape, TweenTiming>> getTween(Shape first, Shape second) {
// Note that most of the following rules work in one direction only. // Note that most of the following rules work in one direction only.
// That's because in animation, the mouth should usually "pop" open without inbetweens, // That's because in animation, the mouth should usually "pop" open without inbetweens,
// then close slowly. // then close slowly.
static const map<pair<Shape, Shape>, pair<Shape, TweenTiming>> lookup{ static const map<pair<Shape, Shape>, pair<Shape, TweenTiming>> lookup {
{{D, A}, {C, TweenTiming::Early}}, { { D, A }, { C, TweenTiming::Early } },
{{D, B}, {C, TweenTiming::Centered}}, { { D, B }, { C, TweenTiming::Centered } },
{{D, G}, {C, TweenTiming::Early}}, { { D, G }, { C, TweenTiming::Early } },
{{D, X}, {C, TweenTiming::Late}}, { { D, X }, { C, TweenTiming::Late } },
{{C, F}, {E, TweenTiming::Centered}}, {{F, C}, {E, TweenTiming::Centered}}, { { C, F }, { E, TweenTiming::Centered } }, { { F, C }, { E, TweenTiming::Centered } },
{{D, F}, {E, TweenTiming::Centered}}, { { D, F }, { E, TweenTiming::Centered } },
{{H, F}, {E, TweenTiming::Late}}, {{F, H}, {E, TweenTiming::Early}} { { H, F }, { E, TweenTiming::Late } }, { { F, H }, { E, TweenTiming::Early } }
}; };
auto it = lookup.find({first, second}); const auto it = lookup.find({ first, second });
return it != lookup.end() ? it->second : optional<pair<Shape, TweenTiming>>(); return it != lookup.end() ? it->second : optional<pair<Shape, TweenTiming>>();
} }
Timeline<ShapeSet> getShapeSets(Phone phone, centiseconds duration, centiseconds previousDuration) { Timeline<ShapeSet> getShapeSets(Phone phone, centiseconds duration, centiseconds previousDuration) {
// Returns a timeline with a single shape set // Returns a timeline with a single shape set
auto single = [duration](ShapeSet value) { const auto single = [duration](ShapeSet value) {
return Timeline<ShapeSet> {{0_cs, duration, value}}; return Timeline<ShapeSet> { { 0_cs, duration, value } };
}; };
// Returns a timeline with two shape sets, timed as a diphthong // Returns a timeline with two shape sets, timed as a diphthong
auto diphthong = [duration](ShapeSet first, ShapeSet second) { const auto diphthong = [duration](ShapeSet first, ShapeSet second) {
centiseconds firstDuration = duration_cast<centiseconds>(duration * 0.6); const centiseconds firstDuration = duration_cast<centiseconds>(duration * 0.6);
return Timeline<ShapeSet> { return Timeline<ShapeSet> {
{0_cs, firstDuration, first}, { 0_cs, firstDuration, first },
{firstDuration, duration, second} { firstDuration, duration, second }
}; };
}; };
// Returns a timeline with two shape sets, timed as a plosive // Returns a timeline with two shape sets, timed as a plosive
auto plosive = [duration, previousDuration](ShapeSet first, ShapeSet second) { const auto plosive = [duration, previousDuration](ShapeSet first, ShapeSet second) {
centiseconds minOcclusionDuration = 4_cs; const centiseconds minOcclusionDuration = 4_cs;
centiseconds maxOcclusionDuration = 12_cs; const centiseconds maxOcclusionDuration = 12_cs;
centiseconds occlusionDuration = clamp(previousDuration / 2, minOcclusionDuration, maxOcclusionDuration); const centiseconds occlusionDuration =
clamp(previousDuration / 2, minOcclusionDuration, maxOcclusionDuration);
return Timeline<ShapeSet> { return Timeline<ShapeSet> {
{-occlusionDuration, 0_cs, first}, { -occlusionDuration, 0_cs, first },
{0_cs, duration, second} { 0_cs, duration, second }
}; };
}; };
// Returns the result of `getShapeSets` when called with identical arguments // Returns the result of `getShapeSets` when called with identical arguments
// except for a different phone. // except for a different phone.
auto like = [duration, previousDuration](Phone referencePhone) { const auto like = [duration, previousDuration](Phone referencePhone) {
return getShapeSets(referencePhone, duration, previousDuration); return getShapeSets(referencePhone, duration, previousDuration);
}; };
static const ShapeSet any{A, B, C, D, E, F, G, H, X}; static const ShapeSet any { A, B, C, D, E, F, G, H, X };
static const ShapeSet anyOpen{B, C, D, E, F, G, H}; static const ShapeSet anyOpen { B, C, D, E, F, G, H };
// Note: // Note:
// The shapes {A, B, G, X} are very similar. You should avoid regular shape sets containing more than one of these shapes. // The shapes {A, B, G, X} are very similar. You should avoid regular shape sets containing more
// than one of these shapes.
// Otherwise, the resulting shape may be more or less random and might not be a good fit. // Otherwise, the resulting shape may be more or less random and might not be a good fit.
// As an exception, a very flexible rule may contain *all* these shapes. // As an exception, a very flexible rule may contain *all* these shapes.
switch (phone) { switch (phone) {
case Phone::AO: return single({E}); case Phone::AO: return single({ E });
case Phone::AA: return single({D}); case Phone::AA: return single({ D });
case Phone::IY: return single({B}); case Phone::IY: return single({ B });
case Phone::UW: return single({F}); case Phone::UW: return single({ F });
case Phone::EH: return single({C}); case Phone::EH: return single({ C });
case Phone::IH: return single({B}); case Phone::IH: return single({ B });
case Phone::UH: return single({F}); case Phone::UH: return single({ F });
case Phone::AH: return duration < 20_cs ? single({C}) : single({D}); case Phone::AH: return duration < 20_cs ? single({ C }) : single({ D });
case Phone::Schwa: return single({B, C}); case Phone::Schwa: return single({ B, C });
case Phone::AE: return single({C}); case Phone::AE: return single({ C });
case Phone::EY: return diphthong({C}, {B}); case Phone::EY: return diphthong({ C }, { B });
case Phone::AY: return duration < 20_cs ? diphthong({C}, {B}) : diphthong({D}, {B}); case Phone::AY: return duration < 20_cs ? diphthong({ C }, { B }) : diphthong({ D }, { B });
case Phone::OW: return single({F}); case Phone::OW: return single({ F });
case Phone::AW: return duration < 30_cs ? diphthong({C}, {E}) : diphthong({D}, {E}); case Phone::AW: return duration < 30_cs ? diphthong({ C }, { E }) : diphthong({ D }, { E });
case Phone::OY: return diphthong({E}, {B}); case Phone::OY: return diphthong({ E }, { B });
case Phone::ER: return duration < 7_cs ? like(Phone::Schwa) : single({E}); case Phone::ER: return duration < 7_cs ? like(Phone::Schwa) : single({ E });
case Phone::P: case Phone::P:
case Phone::B: return plosive({A}, any); case Phone::B: return plosive({ A }, any);
case Phone::T: case Phone::T:
case Phone::D: return plosive({B, F}, anyOpen); case Phone::D: return plosive({ B, F }, anyOpen);
case Phone::K: case Phone::K:
case Phone::G: return plosive({B, C, E, F, H}, anyOpen); case Phone::G: return plosive({ B, C, E, F, H }, anyOpen);
case Phone::CH: case Phone::CH:
case Phone::JH: return single({B, F}); case Phone::JH: return single({ B, F });
case Phone::F: case Phone::F:
case Phone::V: return single({G}); case Phone::V: return single({ G });
case Phone::TH: case Phone::TH:
case Phone::DH: case Phone::DH:
case Phone::S: case Phone::S:
case Phone::Z: case Phone::Z:
case Phone::SH: case Phone::SH:
case Phone::ZH: return single({B, F}); case Phone::ZH: return single({ B, F });
case Phone::HH: return single(any); // think "m-hm" case Phone::HH: return single(any); // think "m-hm"
case Phone::M: return single({A}); case Phone::M: return single({ A });
case Phone::N: return single({B, C, F, H}); case Phone::N: return single({ B, C, F, H });
case Phone::NG: return single({B, C, E, F}); case Phone::NG: return single({ B, C, E, F });
case Phone::L: return duration < 20_cs ? single({B, E, F, H}) : single({H}); case Phone::L: return duration < 20_cs ? single({ B, E, F, H }) : single({ H });
case Phone::R: return single({B, E, F}); case Phone::R: return single({ B, E, F });
case Phone::Y: return single({B, C, F}); case Phone::Y: return single({ B, C, F });
case Phone::W: return single({F}); case Phone::W: return single({ F });
case Phone::Breath: case Phone::Breath:
case Phone::Cough: case Phone::Cough:
case Phone::Smack: return single({C}); case Phone::Smack: return single({ C });
case Phone::Noise: return single({B}); case Phone::Noise: return single({ B });
default: throw std::invalid_argument("Unexpected phone."); default: throw std::invalid_argument("Unexpected phone.");
} }
} }

View File

@ -31,5 +31,6 @@ boost::optional<std::pair<Shape, TweenTiming>> getTween(Shape first, Shape secon
// Returns the shape set(s) to use for a given phone. // Returns the shape set(s) to use for a given phone.
// The resulting timeline will always cover the entire duration of the phone (starting at 0 cs). // The resulting timeline will always cover the entire duration of the phone (starting at 0 cs).
// It may extend into the negative time range if animation is required prior to the sound being heard. // It may extend into the negative time range if animation is required prior to the sound being
// heard.
Timeline<ShapeSet> getShapeSets(Phone phone, centiseconds duration, centiseconds previousDuration); Timeline<ShapeSet> getShapeSets(Phone phone, centiseconds duration, centiseconds previousDuration);

View File

@ -8,17 +8,21 @@
#include "targetShapeSet.h" #include "targetShapeSet.h"
#include "staticSegments.h" #include "staticSegments.h"
JoiningContinuousTimeline<Shape> animate(const BoundedTimeline<Phone> &phones, const ShapeSet& targetShapeSet) { JoiningContinuousTimeline<Shape> animate(
const BoundedTimeline<Phone>& phones,
const ShapeSet& targetShapeSet
) {
// Create timeline of shape rules // Create timeline of shape rules
ContinuousTimeline<ShapeRule> shapeRules = getShapeRules(phones); ContinuousTimeline<ShapeRule> shapeRules = getShapeRules(phones);
// Modify shape rules to only contain allowed shapes -- plus X, which is needed for pauses and will be replaced later // Modify shape rules to only contain allowed shapes -- plus X, which is needed for pauses and
// will be replaced later
ShapeSet targetShapeSetPlusX = targetShapeSet; ShapeSet targetShapeSetPlusX = targetShapeSet;
targetShapeSetPlusX.insert(Shape::X); targetShapeSetPlusX.insert(Shape::X);
shapeRules = convertToTargetShapeSet(shapeRules, targetShapeSetPlusX); shapeRules = convertToTargetShapeSet(shapeRules, targetShapeSetPlusX);
// Animate in multiple steps // Animate in multiple steps
auto performMainAnimationSteps = [&targetShapeSet](const auto& shapeRules) { const auto performMainAnimationSteps = [&targetShapeSet](const auto& shapeRules) {
JoiningContinuousTimeline<Shape> animation = animateRough(shapeRules); JoiningContinuousTimeline<Shape> animation = animateRough(shapeRules);
animation = optimizeTiming(animation); animation = optimizeTiming(animation);
animation = animatePauses(animation); animation = animatePauses(animation);
@ -26,7 +30,8 @@ JoiningContinuousTimeline<Shape> animate(const BoundedTimeline<Phone> &phones, c
animation = convertToTargetShapeSet(animation, targetShapeSet); animation = convertToTargetShapeSet(animation, targetShapeSet);
return animation; return animation;
}; };
const JoiningContinuousTimeline<Shape> result = avoidStaticSegments(shapeRules, performMainAnimationSteps); const JoiningContinuousTimeline<Shape> result =
avoidStaticSegments(shapeRules, performMainAnimationSteps);
for (const auto& timedShape : result) { for (const auto& timedShape : result) {
logTimedEvent("shape", timedShape); logTimedEvent("shape", timedShape);

View File

@ -5,4 +5,7 @@
#include "time/ContinuousTimeline.h" #include "time/ContinuousTimeline.h"
#include "targetShapeSet.h" #include "targetShapeSet.h"
JoiningContinuousTimeline<Shape> animate(const BoundedTimeline<Phone>& phones, const ShapeSet& targetShapeSet); JoiningContinuousTimeline<Shape> animate(
const BoundedTimeline<Phone>& phones,
const ShapeSet& targetShapeSet
);

View File

@ -12,7 +12,7 @@ Shape getPauseShape(Shape previous, Shape next, centiseconds duration) {
// It looks odd if the pause shape is identical to the next shape. // It looks odd if the pause shape is identical to the next shape.
// Make sure we find a relaxed shape that's different from the next one. // Make sure we find a relaxed shape that's different from the next one.
for (Shape currentRelaxedShape = previous;;) { for (Shape currentRelaxedShape = previous;;) {
Shape nextRelaxedShape = relax(currentRelaxedShape); const Shape nextRelaxedShape = relax(currentRelaxedShape);
if (nextRelaxedShape != next) { if (nextRelaxedShape != next) {
return nextRelaxedShape; return nextRelaxedShape;
} }
@ -31,11 +31,18 @@ Shape getPauseShape(Shape previous, Shape next, centiseconds duration) {
JoiningContinuousTimeline<Shape> animatePauses(const JoiningContinuousTimeline<Shape>& animation) { JoiningContinuousTimeline<Shape> animatePauses(const JoiningContinuousTimeline<Shape>& animation) {
JoiningContinuousTimeline<Shape> result(animation); JoiningContinuousTimeline<Shape> result(animation);
for_each_adjacent(animation.begin(), animation.end(), [&](const Timed<Shape>& previous, const Timed<Shape>& pause, const Timed<Shape>& next) { for_each_adjacent(
if (pause.getValue() != Shape::X) return; animation.begin(),
animation.end(),
[&](const Timed<Shape>& previous, const Timed<Shape>& pause, const Timed<Shape>& next) {
if (pause.getValue() != Shape::X) return;
result.set(pause.getTimeRange(), getPauseShape(previous.getValue(), next.getValue(), pause.getDuration())); result.set(
}); pause.getTimeRange(),
getPauseShape(previous.getValue(), next.getValue(), pause.getDuration())
);
}
);
return result; return result;
} }

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@ -1,16 +1,17 @@
#include "roughAnimation.h" #include "roughAnimation.h"
#include <boost/optional.hpp> #include <boost/optional.hpp>
using boost::optional;
// Create timeline of shapes using a bidirectional algorithm. // Create timeline of shapes using a bidirectional algorithm.
// Here's a rough sketch: // Here's a rough sketch:
// //
// * Most consonants result in shape sets with multiple options; most vowels have only one shape option. // * Most consonants result in shape sets with multiple options; most vowels have only one shape
// option.
// * When speaking, we tend to slur mouth shapes into each other. So we animate from start to end, // * When speaking, we tend to slur mouth shapes into each other. So we animate from start to end,
// always choosing a shape from the current set that resembles the last shape and is somewhat relaxed. // always choosing a shape from the current set that resembles the last shape and is somewhat
// relaxed.
// * When speaking, we anticipate vowels, trying to form their shape before the actual vowel. // * When speaking, we anticipate vowels, trying to form their shape before the actual vowel.
// So whenever we come across a one-shape vowel, we backtrack a little, spreating that shape to the left. // So whenever we come across a one-shape vowel, we backtrack a little, spreading that shape to
// the left.
JoiningContinuousTimeline<Shape> animateRough(const ContinuousTimeline<ShapeRule>& shapeRules) { JoiningContinuousTimeline<Shape> animateRough(const ContinuousTimeline<ShapeRule>& shapeRules) {
JoiningContinuousTimeline<Shape> animation(shapeRules.getRange(), Shape::X); JoiningContinuousTimeline<Shape> animation(shapeRules.getRange(), Shape::X);
@ -21,24 +22,28 @@ JoiningContinuousTimeline<Shape> animateRough(const ContinuousTimeline<ShapeRule
const ShapeRule shapeRule = it->getValue(); const ShapeRule shapeRule = it->getValue();
const Shape shape = getClosestShape(referenceShape, shapeRule.shapeSet); const Shape shape = getClosestShape(referenceShape, shapeRule.shapeSet);
animation.set(it->getTimeRange(), shape); animation.set(it->getTimeRange(), shape);
const bool anticipateShape = shapeRule.phone && isVowel(*shapeRule.phone) && shapeRule.shapeSet.size() == 1; const bool anticipateShape = shapeRule.phone
&& isVowel(*shapeRule.phone)
&& shapeRule.shapeSet.size() == 1;
if (anticipateShape) { if (anticipateShape) {
// Animate backwards a little // Animate backwards a little
const Shape anticipatedShape = shape; const Shape anticipatedShape = shape;
const centiseconds anticipatedShapeStart = it->getStart(); const centiseconds anticipatedShapeStart = it->getStart();
referenceShape = anticipatedShape; referenceShape = anticipatedShape;
for (auto reverseIt = it; reverseIt != shapeRules.begin(); ) { for (auto reverseIt = it; reverseIt != shapeRules.begin();) {
--reverseIt; --reverseIt;
// Make sure we haven't animated too far back // Make sure we haven't animated too far back
centiseconds anticipatingShapeStart = reverseIt->getStart(); centiseconds anticipatingShapeStart = reverseIt->getStart();
if (anticipatingShapeStart == lastAnticipatedShapeStart) break; if (anticipatingShapeStart == lastAnticipatedShapeStart) break;
const centiseconds maxAnticipationDuration = 20_cs; const centiseconds maxAnticipationDuration = 20_cs;
const centiseconds anticipationDuration = anticipatedShapeStart - anticipatingShapeStart; const centiseconds anticipationDuration =
anticipatedShapeStart - anticipatingShapeStart;
if (anticipationDuration > maxAnticipationDuration) break; if (anticipationDuration > maxAnticipationDuration) break;
// Overwrite forward-animated shape with backwards-animated, anticipating shape // Overwrite forward-animated shape with backwards-animated, anticipating shape
const Shape anticipatingShape = getClosestShape(referenceShape, reverseIt->getValue().shapeSet); const Shape anticipatingShape =
getClosestShape(referenceShape, reverseIt->getValue().shapeSet);
animation.set(reverseIt->getTimeRange(), anticipatingShape); animation.set(reverseIt->getTimeRange(), anticipatingShape);
// Make sure the new, backwards-animated shape still resembles the anticipated shape // Make sure the new, backwards-animated shape still resembles the anticipated shape

View File

@ -2,5 +2,6 @@
#include "ShapeRule.h" #include "ShapeRule.h"
// Does a rough animation (no tweening, special pause animation, etc.) using a bidirectional algorithm. // Does a rough animation (no tweening, special pause animation, etc.) using a bidirectional
// algorithm.
JoiningContinuousTimeline<Shape> animateRough(const ContinuousTimeline<ShapeRule>& shapeRules); JoiningContinuousTimeline<Shape> animateRough(const ContinuousTimeline<ShapeRule>& shapeRules);

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@ -4,7 +4,6 @@
#include "tools/nextCombination.h" #include "tools/nextCombination.h"
using std::vector; using std::vector;
using boost::optional;
int getSyllableCount(const ContinuousTimeline<ShapeRule>& shapeRules, TimeRange timeRange) { int getSyllableCount(const ContinuousTimeline<ShapeRule>& shapeRules, TimeRange timeRange) {
if (timeRange.empty()) return 0; if (timeRange.empty()) return 0;
@ -31,16 +30,22 @@ int getSyllableCount(const ContinuousTimeline<ShapeRule>& shapeRules, TimeRange
} }
// A static segment is a prolonged period during which the mouth shape doesn't change // A static segment is a prolonged period during which the mouth shape doesn't change
vector<TimeRange> getStaticSegments(const ContinuousTimeline<ShapeRule>& shapeRules, const JoiningContinuousTimeline<Shape>& animation) { vector<TimeRange> getStaticSegments(
const ContinuousTimeline<ShapeRule>& shapeRules,
const JoiningContinuousTimeline<Shape>& animation
) {
// A static segment must contain a certain number of syllables to look distractingly static // A static segment must contain a certain number of syllables to look distractingly static
const int minSyllableCount = 3; const int minSyllableCount = 3;
// It must also have a minimum duration. The same number of syllables in fast speech usually looks good. // It must also have a minimum duration. The same number of syllables in fast speech usually
// looks good.
const centiseconds minDuration = 75_cs; const centiseconds minDuration = 75_cs;
vector<TimeRange> result; vector<TimeRange> result;
for (const auto& timedShape : animation) { for (const auto& timedShape : animation) {
const TimeRange timeRange = timedShape.getTimeRange(); const TimeRange timeRange = timedShape.getTimeRange();
if (timeRange.getDuration() >= minDuration && getSyllableCount(shapeRules, timeRange) >= minSyllableCount) { const bool isStatic = timeRange.getDuration() >= minDuration
&& getSyllableCount(shapeRules, timeRange) >= minSyllableCount;
if (isStatic) {
result.push_back(timeRange); result.push_back(timeRange);
} }
} }
@ -48,20 +53,22 @@ vector<TimeRange> getStaticSegments(const ContinuousTimeline<ShapeRule>& shapeRu
return result; return result;
} }
// Indicates whether this shape rule can potentially be replaced by a modified version that breaks up long static segments // Indicates whether this shape rule can potentially be replaced by a modified version that breaks
// up long static segments
bool canChange(const ShapeRule& rule) { bool canChange(const ShapeRule& rule) {
return rule.phone && isVowel(*rule.phone) && rule.shapeSet.size() == 1; return rule.phone && isVowel(*rule.phone) && rule.shapeSet.size() == 1;
} }
// Returns a new shape rule that is identical to the specified one, except that it leads to a slightly different visualization // Returns a new shape rule that is identical to the specified one, except that it leads to a
// slightly different visualization
ShapeRule getChangedShapeRule(const ShapeRule& rule) { ShapeRule getChangedShapeRule(const ShapeRule& rule) {
assert(canChange(rule)); assert(canChange(rule));
ShapeRule result(rule); ShapeRule result(rule);
// So far, I've only encountered B as a static shape. // So far, I've only encountered B as a static shape.
// If there is ever a problem with another static shape, this function can easily be extended. // If there is ever a problem with another static shape, this function can easily be extended.
if (rule.shapeSet == ShapeSet{Shape::B}) { if (rule.shapeSet == ShapeSet { Shape::B }) {
result.shapeSet = {Shape::C}; result.shapeSet = { Shape::C };
} }
return result; return result;
} }
@ -70,7 +77,10 @@ ShapeRule getChangedShapeRule(const ShapeRule& rule) {
using RuleChanges = vector<centiseconds>; using RuleChanges = vector<centiseconds>;
// Replaces the indicated shape rules with slightly different ones, breaking up long static segments // Replaces the indicated shape rules with slightly different ones, breaking up long static segments
ContinuousTimeline<ShapeRule> applyChanges(const ContinuousTimeline<ShapeRule>& shapeRules, const RuleChanges& changes) { ContinuousTimeline<ShapeRule> applyChanges(
const ContinuousTimeline<ShapeRule>& shapeRules,
const RuleChanges& changes
) {
ContinuousTimeline<ShapeRule> result(shapeRules); ContinuousTimeline<ShapeRule> result(shapeRules);
for (centiseconds changedRuleStart : changes) { for (centiseconds changedRuleStart : changes) {
const Timed<ShapeRule> timedOriginalRule = *shapeRules.get(changedRuleStart); const Timed<ShapeRule> timedOriginalRule = *shapeRules.get(changedRuleStart);
@ -85,14 +95,16 @@ public:
RuleChangeScenario( RuleChangeScenario(
const ContinuousTimeline<ShapeRule>& originalRules, const ContinuousTimeline<ShapeRule>& originalRules,
const RuleChanges& changes, const RuleChanges& changes,
AnimationFunction animate) : const AnimationFunction& animate
) :
changedRules(applyChanges(originalRules, changes)), changedRules(applyChanges(originalRules, changes)),
animation(animate(changedRules)), animation(animate(changedRules)),
staticSegments(getStaticSegments(changedRules, animation)) {} staticSegments(getStaticSegments(changedRules, animation))
{}
bool isBetterThan(const RuleChangeScenario& rhs) const { bool isBetterThan(const RuleChangeScenario& rhs) const {
// We want zero static segments // We want zero static segments
if (staticSegments.size() == 0 && rhs.staticSegments.size() > 0) return true; if (staticSegments.empty() && !rhs.staticSegments.empty()) return true;
// Short shapes are better than long ones. Minimize sum-of-squares. // Short shapes are better than long ones. Minimize sum-of-squares.
if (getSumOfShapeDurationSquares() < rhs.getSumOfShapeDurationSquares()) return true; if (getSumOfShapeDurationSquares() < rhs.getSumOfShapeDurationSquares()) return true;
@ -114,10 +126,17 @@ private:
vector<TimeRange> staticSegments; vector<TimeRange> staticSegments;
double getSumOfShapeDurationSquares() const { double getSumOfShapeDurationSquares() const {
return std::accumulate(animation.begin(), animation.end(), 0.0, [](const double sum, const Timed<Shape>& timedShape) { return std::accumulate(
const double duration = std::chrono::duration_cast<std::chrono::duration<double>>(timedShape.getDuration()).count(); animation.begin(),
return sum + duration * duration; animation.end(),
}); 0.0,
[](const double sum, const Timed<Shape>& timedShape) {
const double duration = std::chrono::duration_cast<std::chrono::duration<double>>(
timedShape.getDuration()
).count();
return sum + duration * duration;
}
);
} }
}; };
@ -132,8 +151,12 @@ RuleChanges getPossibleRuleChanges(const ContinuousTimeline<ShapeRule>& shapeRul
return result; return result;
} }
ContinuousTimeline<ShapeRule> fixStaticSegmentRules(const ContinuousTimeline<ShapeRule>& shapeRules, AnimationFunction animate) { ContinuousTimeline<ShapeRule> fixStaticSegmentRules(
// The complexity of this function is exponential with the number of replacements. So let's cap that value. const ContinuousTimeline<ShapeRule>& shapeRules,
const AnimationFunction& animate
) {
// The complexity of this function is exponential with the number of replacements.
// So let's cap that value.
const int maxReplacementCount = 3; const int maxReplacementCount = 3;
// All potential changes // All potential changes
@ -142,14 +165,18 @@ ContinuousTimeline<ShapeRule> fixStaticSegmentRules(const ContinuousTimeline<Sha
// Find best solution. Start with a single replacement, then increase as necessary. // Find best solution. Start with a single replacement, then increase as necessary.
RuleChangeScenario bestScenario(shapeRules, {}, animate); RuleChangeScenario bestScenario(shapeRules, {}, animate);
for ( for (
int replacementCount = 1; int replacementCount = 1;
bestScenario.getStaticSegmentCount() > 0 && replacementCount <= std::min(static_cast<int>(possibleRuleChanges.size()), maxReplacementCount); bestScenario.getStaticSegmentCount() > 0 && replacementCount <= std::min(static_cast<int>(possibleRuleChanges.size()), maxReplacementCount);
++replacementCount ++replacementCount
) { ) {
// Only the first <replacementCount> elements of `currentRuleChanges` count // Only the first <replacementCount> elements of `currentRuleChanges` count
auto currentRuleChanges(possibleRuleChanges); auto currentRuleChanges(possibleRuleChanges);
do { do {
RuleChangeScenario currentScenario(shapeRules, {currentRuleChanges.begin(), currentRuleChanges.begin() + replacementCount}, animate); RuleChangeScenario currentScenario(
shapeRules,
{ currentRuleChanges.begin(), currentRuleChanges.begin() + replacementCount },
animate
);
if (currentScenario.isBetterThan(bestScenario)) { if (currentScenario.isBetterThan(bestScenario)) {
bestScenario = currentScenario; bestScenario = currentScenario;
} }
@ -164,8 +191,12 @@ bool isFlexible(const ShapeRule& rule) {
return rule.shapeSet.size() > 1; return rule.shapeSet.size() > 1;
} }
// Extends the specified time range until it starts and ends with a non-flexible shape rule, if possible // Extends the specified time range until it starts and ends with a non-flexible shape rule, if
TimeRange extendToFixedRules(const TimeRange& timeRange, const ContinuousTimeline<ShapeRule>& shapeRules) { // possible
TimeRange extendToFixedRules(
const TimeRange& timeRange,
const ContinuousTimeline<ShapeRule>& shapeRules
) {
auto first = shapeRules.find(timeRange.getStart()); auto first = shapeRules.find(timeRange.getStart());
while (first != shapeRules.begin() && isFlexible(first->getValue())) { while (first != shapeRules.begin() && isFlexible(first->getValue())) {
--first; --first;
@ -174,10 +205,13 @@ TimeRange extendToFixedRules(const TimeRange& timeRange, const ContinuousTimelin
while (std::next(last) != shapeRules.end() && isFlexible(last->getValue())) { while (std::next(last) != shapeRules.end() && isFlexible(last->getValue())) {
++last; ++last;
} }
return TimeRange(first->getStart(), last->getEnd()); return { first->getStart(), last->getEnd() };
} }
JoiningContinuousTimeline<Shape> avoidStaticSegments(const ContinuousTimeline<ShapeRule>& shapeRules, AnimationFunction animate) { JoiningContinuousTimeline<Shape> avoidStaticSegments(
const ContinuousTimeline<ShapeRule>& shapeRules,
const AnimationFunction& animate
) {
const auto animation = animate(shapeRules); const auto animation = animate(shapeRules);
const vector<TimeRange> staticSegments = getStaticSegments(shapeRules, animation); const vector<TimeRange> staticSegments = getStaticSegments(shapeRules, animation);
if (staticSegments.empty()) { if (staticSegments.empty()) {
@ -187,11 +221,15 @@ JoiningContinuousTimeline<Shape> avoidStaticSegments(const ContinuousTimeline<Sh
// Modify shape rules to eliminate static segments // Modify shape rules to eliminate static segments
ContinuousTimeline<ShapeRule> fixedShapeRules(shapeRules); ContinuousTimeline<ShapeRule> fixedShapeRules(shapeRules);
for (const TimeRange& staticSegment : staticSegments) { for (const TimeRange& staticSegment : staticSegments) {
// Extend time range to the left and right so we don't lose adjacent rules that might influence the animation // Extend time range to the left and right so we don't lose adjacent rules that might
// influence the animation
const TimeRange extendedStaticSegment = extendToFixedRules(staticSegment, shapeRules); const TimeRange extendedStaticSegment = extendToFixedRules(staticSegment, shapeRules);
// Fix shape rules within the static segment // Fix shape rules within the static segment
const auto fixedSegmentShapeRules = fixStaticSegmentRules({extendedStaticSegment, ShapeRule::getInvalid(), fixedShapeRules}, animate); const auto fixedSegmentShapeRules = fixStaticSegmentRules(
{ extendedStaticSegment, ShapeRule::getInvalid(), fixedShapeRules },
animate
);
for (const auto& timedShapeRule : fixedSegmentShapeRules) { for (const auto& timedShapeRule : fixedSegmentShapeRules) {
fixedShapeRules.set(timedShapeRule); fixedShapeRules.set(timedShapeRule);
} }

View File

@ -8,7 +8,11 @@
using AnimationFunction = std::function<JoiningContinuousTimeline<Shape>(const ContinuousTimeline<ShapeRule>&)>; using AnimationFunction = std::function<JoiningContinuousTimeline<Shape>(const ContinuousTimeline<ShapeRule>&)>;
// Calls the specified animation function with the specified shape rules. // Calls the specified animation function with the specified shape rules.
// If the resulting animation contains long static segments, the shape rules are tweaked and animated again. // If the resulting animation contains long static segments, the shape rules are tweaked and
// animated again.
// Static segments happen rather often. // Static segments happen rather often.
// See http://animateducated.blogspot.de/2016/10/lip-sync-animation-2.html?showComment=1478861729702#c2940729096183546458. // See http://animateducated.blogspot.de/2016/10/lip-sync-animation-2.html?showComment=1478861729702#c2940729096183546458.
JoiningContinuousTimeline<Shape> avoidStaticSegments(const ContinuousTimeline<ShapeRule>& shapeRules, AnimationFunction animate); JoiningContinuousTimeline<Shape> avoidStaticSegments(
const ContinuousTimeline<ShapeRule>& shapeRules,
const AnimationFunction& animate
);

View File

@ -4,9 +4,10 @@ Shape convertToTargetShapeSet(Shape shape, const ShapeSet& targetShapeSet) {
if (targetShapeSet.find(shape) != targetShapeSet.end()) { if (targetShapeSet.find(shape) != targetShapeSet.end()) {
return shape; return shape;
} }
Shape basicShape = getBasicShape(shape); const Shape basicShape = getBasicShape(shape);
if (targetShapeSet.find(basicShape) == targetShapeSet.end()) { if (targetShapeSet.find(basicShape) == targetShapeSet.end()) {
throw std::invalid_argument(fmt::format("Target shape set must contain basic shape {}.", basicShape)); throw std::invalid_argument(
fmt::format("Target shape set must contain basic shape {}.", basicShape));
} }
return basicShape; return basicShape;
} }
@ -19,7 +20,10 @@ ShapeSet convertToTargetShapeSet(const ShapeSet& shapes, const ShapeSet& targetS
return result; return result;
} }
ContinuousTimeline<ShapeRule> convertToTargetShapeSet(const ContinuousTimeline<ShapeRule>& shapeRules, const ShapeSet& targetShapeSet) { ContinuousTimeline<ShapeRule> convertToTargetShapeSet(
const ContinuousTimeline<ShapeRule>& shapeRules,
const ShapeSet& targetShapeSet
) {
ContinuousTimeline<ShapeRule> result(shapeRules); ContinuousTimeline<ShapeRule> result(shapeRules);
for (const auto& timedShapeRule : shapeRules) { for (const auto& timedShapeRule : shapeRules) {
ShapeRule rule = timedShapeRule.getValue(); ShapeRule rule = timedShapeRule.getValue();
@ -29,10 +33,16 @@ ContinuousTimeline<ShapeRule> convertToTargetShapeSet(const ContinuousTimeline<S
return result; return result;
} }
JoiningContinuousTimeline<Shape> convertToTargetShapeSet(const JoiningContinuousTimeline<Shape>& animation, const ShapeSet& targetShapeSet) { JoiningContinuousTimeline<Shape> convertToTargetShapeSet(
const JoiningContinuousTimeline<Shape>& animation,
const ShapeSet& targetShapeSet
) {
JoiningContinuousTimeline<Shape> result(animation); JoiningContinuousTimeline<Shape> result(animation);
for (const auto& timedShape : animation) { for (const auto& timedShape : animation) {
result.set(timedShape.getTimeRange(), convertToTargetShapeSet(timedShape.getValue(), targetShapeSet)); result.set(
timedShape.getTimeRange(),
convertToTargetShapeSet(timedShape.getValue(), targetShapeSet)
);
} }
return result; return result;
} }

View File

@ -6,11 +6,19 @@
// Returns the closest shape to the specified one that occurs in the target shape set. // Returns the closest shape to the specified one that occurs in the target shape set.
Shape convertToTargetShapeSet(Shape shape, const ShapeSet& targetShapeSet); Shape convertToTargetShapeSet(Shape shape, const ShapeSet& targetShapeSet);
// Replaces each shape in the specified set with the closest shape that occurs in the target shape set. // Replaces each shape in the specified set with the closest shape that occurs in the target shape
// set.
ShapeSet convertToTargetShapeSet(const ShapeSet& shapes, const ShapeSet& targetShapeSet); ShapeSet convertToTargetShapeSet(const ShapeSet& shapes, const ShapeSet& targetShapeSet);
// Replaces each shape in each rule with the closest shape that occurs in the target shape set. // Replaces each shape in each rule with the closest shape that occurs in the target shape set.
ContinuousTimeline<ShapeRule> convertToTargetShapeSet(const ContinuousTimeline<ShapeRule>& shapeRules, const ShapeSet& targetShapeSet); ContinuousTimeline<ShapeRule> convertToTargetShapeSet(
const ContinuousTimeline<ShapeRule>& shapeRules,
const ShapeSet& targetShapeSet
);
// Replaces each shape in the specified animation with the closest shape that occurs in the target shape set. // Replaces each shape in the specified animation with the closest shape that occurs in the target
JoiningContinuousTimeline<Shape> convertToTargetShapeSet(const JoiningContinuousTimeline<Shape>& animation, const ShapeSet& targetShapeSet); // shape set.
JoiningContinuousTimeline<Shape> convertToTargetShapeSet(
const JoiningContinuousTimeline<Shape>& animation,
const ShapeSet& targetShapeSet
);

View File

@ -11,7 +11,7 @@ using std::map;
string getShapesString(const JoiningContinuousTimeline<Shape>& shapes) { string getShapesString(const JoiningContinuousTimeline<Shape>& shapes) {
string result; string result;
for (const auto& timedShape : shapes) { for (const auto& timedShape : shapes) {
if (result.size()) { if (!result.empty()) {
result.append(" "); result.append(" ");
} }
result.append(boost::lexical_cast<std::string>(timedShape.getValue())); result.append(boost::lexical_cast<std::string>(timedShape.getValue()));
@ -44,12 +44,10 @@ Shape getRepresentativeShape(const JoiningTimeline<Shape>& timeline) {
struct ShapeReduction { struct ShapeReduction {
ShapeReduction(const JoiningTimeline<Shape>& sourceShapes) : ShapeReduction(const JoiningTimeline<Shape>& sourceShapes) :
sourceShapes(sourceShapes), sourceShapes(sourceShapes),
shape(getRepresentativeShape(sourceShapes)) shape(getRepresentativeShape(sourceShapes)) {}
{}
ShapeReduction(const JoiningTimeline<Shape>& sourceShapes, TimeRange candidateRange) : ShapeReduction(const JoiningTimeline<Shape>& sourceShapes, TimeRange candidateRange) :
ShapeReduction(JoiningBoundedTimeline<Shape>(candidateRange, sourceShapes)) ShapeReduction(JoiningBoundedTimeline<Shape>(candidateRange, sourceShapes)) {}
{}
JoiningTimeline<Shape> sourceShapes; JoiningTimeline<Shape> sourceShapes;
Shape shape; Shape shape;
@ -57,7 +55,8 @@ struct ShapeReduction {
// Returns a time range of candidate shapes for the next shape to draw. // Returns a time range of candidate shapes for the next shape to draw.
// Guaranteed to be non-empty. // Guaranteed to be non-empty.
TimeRange getNextMinimalCandidateRange(const JoiningContinuousTimeline<Shape>& sourceShapes, const TimeRange targetRange, const centiseconds writePosition) { TimeRange getNextMinimalCandidateRange(const JoiningContinuousTimeline<Shape>& sourceShapes,
const TimeRange targetRange, const centiseconds writePosition) {
if (sourceShapes.empty()) { if (sourceShapes.empty()) {
throw std::invalid_argument("Cannot determine candidate range for empty source timeline."); throw std::invalid_argument("Cannot determine candidate range for empty source timeline.");
} }
@ -70,12 +69,15 @@ TimeRange getNextMinimalCandidateRange(const JoiningContinuousTimeline<Shape>& s
const centiseconds remainingTargetDuration = writePosition - targetRange.getStart(); const centiseconds remainingTargetDuration = writePosition - targetRange.getStart();
const bool canFitOneOrLess = remainingTargetDuration <= minShapeDuration; const bool canFitOneOrLess = remainingTargetDuration <= minShapeDuration;
const bool canFitTwo = remainingTargetDuration >= 2 * minShapeDuration; const bool canFitTwo = remainingTargetDuration >= 2 * minShapeDuration;
const centiseconds duration = canFitOneOrLess || canFitTwo ? minShapeDuration : remainingTargetDuration / 2; const centiseconds duration = canFitOneOrLess || canFitTwo
? minShapeDuration
: remainingTargetDuration / 2;
TimeRange candidateRange(writePosition - duration, writePosition); TimeRange candidateRange(writePosition - duration, writePosition);
if (writePosition == targetRange.getEnd()) { if (writePosition == targetRange.getEnd()) {
// This is the first iteration. // This is the first iteration.
// Extend the candidate range to the right in order to consider all source shapes after the target range. // Extend the candidate range to the right in order to consider all source shapes after the
// target range.
candidateRange.setEndIfLater(sourceShapes.getRange().getEnd()); candidateRange.setEndIfLater(sourceShapes.getRange().getEnd());
} }
if (candidateRange.getStart() >= sourceShapes.getRange().getEnd()) { if (candidateRange.getStart() >= sourceShapes.getRange().getEnd()) {
@ -92,19 +94,31 @@ TimeRange getNextMinimalCandidateRange(const JoiningContinuousTimeline<Shape>& s
return candidateRange; return candidateRange;
} }
ShapeReduction getNextShapeReduction(const JoiningContinuousTimeline<Shape>& sourceShapes, const TimeRange targetRange, centiseconds writePosition) { ShapeReduction getNextShapeReduction(
const JoiningContinuousTimeline<Shape>& sourceShapes,
const TimeRange targetRange,
centiseconds writePosition
) {
// Determine the next time range of candidate shapes. Consider two scenarios: // Determine the next time range of candidate shapes. Consider two scenarios:
// ... the shortest-possible candidate range // ... the shortest-possible candidate range
const ShapeReduction minReduction(sourceShapes, getNextMinimalCandidateRange(sourceShapes, targetRange, writePosition)); const ShapeReduction minReduction(sourceShapes,
getNextMinimalCandidateRange(sourceShapes, targetRange, writePosition));
// ... a candidate range extended to the left to fully encompass its left-most shape // ... a candidate range extended to the left to fully encompass its left-most shape
const ShapeReduction extendedReduction(sourceShapes, const ShapeReduction extendedReduction(sourceShapes,
{minReduction.sourceShapes.begin()->getStart(), minReduction.sourceShapes.getRange().getEnd()}); {
minReduction.sourceShapes.begin()->getStart(),
minReduction.sourceShapes.getRange().getEnd()
}
);
// Determine the shape that might be picked *next* if we choose the shortest-possible candidate range now // Determine the shape that might be picked *next* if we choose the shortest-possible candidate
const ShapeReduction nextReduction(sourceShapes, // range now
getNextMinimalCandidateRange(sourceShapes, targetRange, minReduction.sourceShapes.getRange().getStart())); const ShapeReduction nextReduction(
sourceShapes,
getNextMinimalCandidateRange(sourceShapes, targetRange, minReduction.sourceShapes.getRange().getStart())
);
const bool minEqualsExtended = minReduction.shape == extendedReduction.shape; const bool minEqualsExtended = minReduction.shape == extendedReduction.shape;
const bool extendedIsSpecial = extendedReduction.shape != minReduction.shape const bool extendedIsSpecial = extendedReduction.shape != minReduction.shape
@ -113,8 +127,10 @@ ShapeReduction getNextShapeReduction(const JoiningContinuousTimeline<Shape>& sou
return minEqualsExtended || extendedIsSpecial ? extendedReduction : minReduction; return minEqualsExtended || extendedIsSpecial ? extendedReduction : minReduction;
} }
// Modifies the timing of the given animation to fit into the specified target time range without jitter. // Modifies the timing of the given animation to fit into the specified target time range without
JoiningContinuousTimeline<Shape> retime(const JoiningContinuousTimeline<Shape>& sourceShapes, const TimeRange targetRange) { // jitter.
JoiningContinuousTimeline<Shape> retime(const JoiningContinuousTimeline<Shape>& sourceShapes,
const TimeRange targetRange) {
logTimedEvent("segment", targetRange, getShapesString(sourceShapes)); logTimedEvent("segment", targetRange, getShapesString(sourceShapes));
JoiningContinuousTimeline<Shape> result(targetRange, Shape::X); JoiningContinuousTimeline<Shape> result(targetRange, Shape::X);
@ -125,7 +141,8 @@ JoiningContinuousTimeline<Shape> retime(const JoiningContinuousTimeline<Shape>&
while (writePosition > targetRange.getStart()) { while (writePosition > targetRange.getStart()) {
// Decide which shape to show next, possibly discarding short shapes // Decide which shape to show next, possibly discarding short shapes
const ShapeReduction shapeReduction = getNextShapeReduction(sourceShapes, targetRange, writePosition); const ShapeReduction shapeReduction =
getNextShapeReduction(sourceShapes, targetRange, writePosition);
// Determine how long to display the shape // Determine how long to display the shape
TimeRange targetShapeRange(shapeReduction.sourceShapes.getRange()); TimeRange targetShapeRange(shapeReduction.sourceShapes.getRange());
@ -144,7 +161,11 @@ JoiningContinuousTimeline<Shape> retime(const JoiningContinuousTimeline<Shape>&
return result; return result;
} }
JoiningContinuousTimeline<Shape> retime(const JoiningContinuousTimeline<Shape>& animation, TimeRange sourceRange, TimeRange targetRange) { JoiningContinuousTimeline<Shape> retime(
const JoiningContinuousTimeline<Shape>& animation,
TimeRange sourceRange,
TimeRange targetRange
) {
const auto sourceShapes = JoiningContinuousTimeline<Shape>(sourceRange, Shape::X, animation); const auto sourceShapes = JoiningContinuousTimeline<Shape>(sourceRange, Shape::X, animation);
return retime(sourceShapes, targetRange); return retime(sourceShapes, targetRange);
} }
@ -160,7 +181,12 @@ JoiningContinuousTimeline<Shape> optimizeTiming(const JoiningContinuousTimeline<
JoiningContinuousTimeline<MouthState> segments(animation.getRange(), MouthState::Idle); JoiningContinuousTimeline<MouthState> segments(animation.getRange(), MouthState::Idle);
for (const auto& timedShape : animation) { for (const auto& timedShape : animation) {
const Shape shape = timedShape.getValue(); const Shape shape = timedShape.getValue();
const MouthState mouthState = shape == Shape::X ? MouthState::Idle : shape == Shape::A ? MouthState::Closed : MouthState::Open; const MouthState mouthState =
shape == Shape::X
? MouthState::Idle
: shape == Shape::A
? MouthState::Closed
: MouthState::Open;
segments.set(timedShape.getTimeRange(), mouthState); segments.set(timedShape.getTimeRange(), mouthState);
} }
@ -171,7 +197,8 @@ JoiningContinuousTimeline<Shape> optimizeTiming(const JoiningContinuousTimeline<
// Make sure all open and closed segments are long enough to register visually. // Make sure all open and closed segments are long enough to register visually.
JoiningContinuousTimeline<Shape> result(animation.getRange(), Shape::X); JoiningContinuousTimeline<Shape> result(animation.getRange(), Shape::X);
// ... we're filling the result timeline from right to left, so `resultStart` points to the earliest shape already written // ... we're filling the result timeline from right to left, so `resultStart` points to the
// earliest shape already written
centiseconds resultStart = result.getRange().getEnd(); centiseconds resultStart = result.getRange().getEnd();
for (auto segmentIt = segments.rbegin(); segmentIt != segments.rend(); ++segmentIt) { for (auto segmentIt = segments.rbegin(); segmentIt != segments.rend(); ++segmentIt) {
// We don't care about idle shapes at this point. // We don't care about idle shapes at this point.
@ -188,26 +215,40 @@ JoiningContinuousTimeline<Shape> optimizeTiming(const JoiningContinuousTimeline<
resultStart = targetRange.getStart(); resultStart = targetRange.getStart();
} else { } else {
// The segment is too short; we have to extend it to the left. // The segment is too short; we have to extend it to the left.
// Find all adjacent segments to our left that are also too short, then distribute them evenly. // Find all adjacent segments to our left that are also too short, then distribute them
// evenly.
const auto begin = segmentIt; const auto begin = segmentIt;
auto end = std::next(begin); auto end = std::next(begin);
while (end != segments.rend() && end->getValue() != MouthState::Idle && end->getDuration() < minSegmentDuration) ++end; while (
end != segments.rend()
&& end->getValue() != MouthState::Idle
&& end->getDuration() < minSegmentDuration
) {
++end;
}
// Determine how much we should extend the entire set of short segments to the left // Determine how much we should extend the entire set of short segments to the left
const size_t shortSegmentCount = std::distance(begin, end); const size_t shortSegmentCount = std::distance(begin, end);
const centiseconds desiredDuration = minSegmentDuration * shortSegmentCount; const centiseconds desiredDuration = minSegmentDuration * shortSegmentCount;
const centiseconds currentDuration = begin->getEnd() - std::prev(end)->getStart(); const centiseconds currentDuration = begin->getEnd() - std::prev(end)->getStart();
const centiseconds desiredExtensionDuration = desiredDuration - currentDuration; const centiseconds desiredExtensionDuration = desiredDuration - currentDuration;
const centiseconds availableExtensionDuration = end != segments.rend() ? end->getDuration() - 1_cs : 0_cs; const centiseconds availableExtensionDuration = end != segments.rend()
const centiseconds extensionDuration = std::min({desiredExtensionDuration, availableExtensionDuration, maxExtensionDuration}); ? end->getDuration() - 1_cs
: 0_cs;
const centiseconds extensionDuration = std::min({
desiredExtensionDuration, availableExtensionDuration, maxExtensionDuration
});
// Distribute available time range evenly among all short segments // Distribute available time range evenly among all short segments
const centiseconds shortSegmentsTargetStart = std::prev(end)->getStart() - extensionDuration; const centiseconds shortSegmentsTargetStart =
std::prev(end)->getStart() - extensionDuration;
for (auto shortSegmentIt = begin; shortSegmentIt != end; ++shortSegmentIt) { for (auto shortSegmentIt = begin; shortSegmentIt != end; ++shortSegmentIt) {
size_t remainingShortSegmentCount = std::distance(shortSegmentIt, end); size_t remainingShortSegmentCount = std::distance(shortSegmentIt, end);
const centiseconds segmentDuration = (resultStart - shortSegmentsTargetStart) / remainingShortSegmentCount; const centiseconds segmentDuration = (resultStart - shortSegmentsTargetStart) /
remainingShortSegmentCount;
const TimeRange segmentTargetRange(resultStart - segmentDuration, resultStart); const TimeRange segmentTargetRange(resultStart - segmentDuration, resultStart);
const auto retimedSegment = retime(animation, shortSegmentIt->getTimeRange(), segmentTargetRange); const auto retimedSegment =
retime(animation, shortSegmentIt->getTimeRange(), segmentTargetRange);
for (const auto& timedShape : retimedSegment) { for (const auto& timedShape : retimedSegment) {
result.set(timedShape); result.set(timedShape);
} }

View File

@ -3,6 +3,7 @@
#include "core/Shape.h" #include "core/Shape.h"
#include "time/ContinuousTimeline.h" #include "time/ContinuousTimeline.h"
// Changes the timing of an existing animation to reduce jitter and to make sure all shapes register visually. // Changes the timing of an existing animation to reduce jitter and to make sure all shapes register
// visually.
// In some cases, shapes may be omitted. // In some cases, shapes may be omitted.
JoiningContinuousTimeline<Shape> optimizeTiming(const JoiningContinuousTimeline<Shape>& animation); JoiningContinuousTimeline<Shape> optimizeTiming(const JoiningContinuousTimeline<Shape>& animation);

View File

@ -19,21 +19,30 @@ JoiningContinuousTimeline<Shape> insertTweens(const JoiningContinuousTimeline<Sh
centiseconds tweenStart, tweenDuration; centiseconds tweenStart, tweenDuration;
switch (tweenTiming) { switch (tweenTiming) {
case TweenTiming::Early: { case TweenTiming::Early:
tweenDuration = std::min(firstTimeRange.getDuration() / 3, maxTweenDuration); {
tweenStart = firstTimeRange.getEnd() - tweenDuration; tweenDuration = std::min(firstTimeRange.getDuration() / 3, maxTweenDuration);
break; tweenStart = firstTimeRange.getEnd() - tweenDuration;
} break;
case TweenTiming::Centered: { }
tweenDuration = std::min({firstTimeRange.getDuration() / 4, secondTimeRange.getDuration() / 4, maxTweenDuration}); case TweenTiming::Centered:
tweenStart = firstTimeRange.getEnd() - tweenDuration / 2; {
break; tweenDuration = std::min({
} firstTimeRange.getDuration() / 4, secondTimeRange.getDuration() / 4, maxTweenDuration
case TweenTiming::Late: { });
tweenDuration = std::min(secondTimeRange.getDuration() / 3, maxTweenDuration); tweenStart = firstTimeRange.getEnd() - tweenDuration / 2;
tweenStart = secondTimeRange.getStart(); break;
break; }
} case TweenTiming::Late:
{
tweenDuration = std::min(secondTimeRange.getDuration() / 3, maxTweenDuration);
tweenStart = secondTimeRange.getStart();
break;
}
default:
{
throw std::runtime_error("Unexpected tween timing.");
}
} }
if (tweenDuration < minTweenDuration) return; if (tweenDuration < minTweenDuration) return;

View File

@ -28,7 +28,11 @@ inline AudioClip::value_type SafeSampleReader::operator()(AudioClip::size_type i
throw invalid_argument(fmt::format("Cannot read from sample index {}. Index < 0.", index)); throw invalid_argument(fmt::format("Cannot read from sample index {}. Index < 0.", index));
} }
if (index >= size) { if (index >= size) {
throw invalid_argument(fmt::format("Cannot read from sample index {}. Clip size is {}.", index, size)); throw invalid_argument(fmt::format(
"Cannot read from sample index {}. Clip size is {}.",
index,
size
));
} }
if (index == lastIndex) { if (index == lastIndex) {
return lastSample; return lastSample;
@ -51,7 +55,7 @@ AudioClip::iterator AudioClip::end() const {
return SampleIterator(*this, size()); return SampleIterator(*this, size());
} }
std::unique_ptr<AudioClip> operator|(std::unique_ptr<AudioClip> clip, AudioEffect effect) { std::unique_ptr<AudioClip> operator|(std::unique_ptr<AudioClip> clip, const AudioEffect& effect) {
return effect(std::move(clip)); return effect(std::move(clip));
} }

View File

@ -30,7 +30,7 @@ private:
using AudioEffect = std::function<std::unique_ptr<AudioClip>(std::unique_ptr<AudioClip>)>; using AudioEffect = std::function<std::unique_ptr<AudioClip>(std::unique_ptr<AudioClip>)>;
std::unique_ptr<AudioClip> operator|(std::unique_ptr<AudioClip> clip, AudioEffect effect); std::unique_ptr<AudioClip> operator|(std::unique_ptr<AudioClip> clip, const AudioEffect& effect);
using SampleReader = AudioClip::SampleReader; using SampleReader = AudioClip::SampleReader;

View File

@ -15,15 +15,19 @@ unique_ptr<AudioClip> DcOffset::clone() const {
} }
SampleReader DcOffset::createUnsafeSampleReader() const { SampleReader DcOffset::createUnsafeSampleReader() const {
return [read = inputClip->createSampleReader(), factor = factor, offset = offset](size_type index) { return [
float sample = read(index); read = inputClip->createSampleReader(),
factor = factor,
offset = offset
](size_type index) {
const float sample = read(index);
return sample * factor + offset; return sample * factor + offset;
}; };
} }
float getDcOffset(const AudioClip& audioClip) { float getDcOffset(const AudioClip& audioClip) {
int flatMeanSampleCount, fadingMeanSampleCount; int flatMeanSampleCount, fadingMeanSampleCount;
int sampleRate = audioClip.getSampleRate(); const int sampleRate = audioClip.getSampleRate();
if (audioClip.size() > 4 * sampleRate) { if (audioClip.size() > 4 * sampleRate) {
// Long audio file. Average over the first 3 seconds, then fade out over the 4th. // Long audio file. Average over the first 3 seconds, then fade out over the 4th.
flatMeanSampleCount = 3 * sampleRate; flatMeanSampleCount = 3 * sampleRate;
@ -34,31 +38,32 @@ float getDcOffset(const AudioClip& audioClip) {
fadingMeanSampleCount = 0; fadingMeanSampleCount = 0;
} }
auto read = audioClip.createSampleReader(); const auto read = audioClip.createSampleReader();
double sum = 0; double sum = 0;
for (int i = 0; i < flatMeanSampleCount; ++i) { for (int i = 0; i < flatMeanSampleCount; ++i) {
sum += read(i); sum += read(i);
} }
for (int i = 0; i < fadingMeanSampleCount; ++i) { for (int i = 0; i < fadingMeanSampleCount; ++i) {
double weight = static_cast<double>(fadingMeanSampleCount - i) / fadingMeanSampleCount; const double weight =
static_cast<double>(fadingMeanSampleCount - i) / fadingMeanSampleCount;
sum += read(flatMeanSampleCount + i) * weight; sum += read(flatMeanSampleCount + i) * weight;
} }
double totalWeight = flatMeanSampleCount + (fadingMeanSampleCount + 1) / 2.0; const double totalWeight = flatMeanSampleCount + (fadingMeanSampleCount + 1) / 2.0;
double offset = sum / totalWeight; const double offset = sum / totalWeight;
return static_cast<float>(offset); return static_cast<float>(offset);
} }
AudioEffect addDcOffset(float offset, float epsilon) { AudioEffect addDcOffset(float offset, float epsilon) {
return [offset, epsilon](unique_ptr<AudioClip> inputClip) -> unique_ptr<AudioClip> { return [offset, epsilon](unique_ptr<AudioClip> inputClip) -> unique_ptr<AudioClip> {
if (std::abs(offset) < epsilon) return std::move(inputClip); if (std::abs(offset) < epsilon) return inputClip;
return make_unique<DcOffset>(std::move(inputClip), offset); return make_unique<DcOffset>(std::move(inputClip), offset);
}; };
} }
AudioEffect removeDcOffset(float epsilon) { AudioEffect removeDcOffset(float epsilon) {
return [epsilon](unique_ptr<AudioClip> inputClip) { return [epsilon](unique_ptr<AudioClip> inputClip) {
float offset = getDcOffset(*inputClip); const float offset = getDcOffset(*inputClip);
return std::move(inputClip) | addDcOffset(-offset, epsilon); return std::move(inputClip) | addDcOffset(-offset, epsilon);
}; };
} }

View File

@ -14,30 +14,30 @@ using std::ios_base;
std::string vorbisErrorToString(int64_t errorCode) { std::string vorbisErrorToString(int64_t errorCode) {
switch (errorCode) { switch (errorCode) {
case OV_EREAD: case OV_EREAD:
return "Read error while fetching compressed data for decode."; return "Read error while fetching compressed data for decode.";
case OV_EFAULT: case OV_EFAULT:
return "Internal logic fault; indicates a bug or heap/stack corruption."; return "Internal logic fault; indicates a bug or heap/stack corruption.";
case OV_EIMPL: case OV_EIMPL:
return "Feature not implemented"; return "Feature not implemented";
case OV_EINVAL: case OV_EINVAL:
return "Either an invalid argument, or incompletely initialized argument passed to a call."; return "Either an invalid argument, or incompletely initialized argument passed to a call.";
case OV_ENOTVORBIS: case OV_ENOTVORBIS:
return "The given file/data was not recognized as Ogg Vorbis data."; return "The given file/data was not recognized as Ogg Vorbis data.";
case OV_EBADHEADER: case OV_EBADHEADER:
return "The file/data is apparently an Ogg Vorbis stream, but contains a corrupted or undecipherable header."; return "The file/data is apparently an Ogg Vorbis stream, but contains a corrupted or undecipherable header.";
case OV_EVERSION: case OV_EVERSION:
return "The bitstream format revision of the given Vorbis stream is not supported."; return "The bitstream format revision of the given Vorbis stream is not supported.";
case OV_ENOTAUDIO: case OV_ENOTAUDIO:
return "Packet is not an audio packet."; return "Packet is not an audio packet.";
case OV_EBADPACKET: case OV_EBADPACKET:
return "Error in packet."; return "Error in packet.";
case OV_EBADLINK: case OV_EBADLINK:
return "The given link exists in the Vorbis data stream, but is not decipherable due to garbacge or corruption."; return "The given link exists in the Vorbis data stream, but is not decipherable due to garbage or corruption.";
case OV_ENOSEEK: case OV_ENOSEEK:
return "The given stream is not seekable."; return "The given stream is not seekable.";
default: default:
return "An unexpected Vorbis error occurred."; return "An unexpected Vorbis error occurred.";
} }
} }
@ -64,13 +64,13 @@ size_t readCallback(void* buffer, size_t elementSize, size_t elementCount, void*
} }
int seekCallback(void* dataSource, ogg_int64_t offset, int origin) { int seekCallback(void* dataSource, ogg_int64_t offset, int origin) {
static const vector<ios_base::seekdir> seekDirections{ static const vector<ios_base::seekdir> seekDirections {
ios_base::beg, ios_base::cur, ios_base::end ios_base::beg, ios_base::cur, ios_base::end
}; };
ifstream& stream = *static_cast<ifstream*>(dataSource); ifstream& stream = *static_cast<ifstream*>(dataSource);
stream.seekg(offset, seekDirections.at(origin)); stream.seekg(offset, seekDirections.at(origin));
stream.clear(); // In case we seeked to EOF stream.clear(); // In case we sought to EOF
return 0; return 0;
} }
@ -82,26 +82,13 @@ long tellCallback(void* dataSource) {
} }
// RAII wrapper around OggVorbis_File // RAII wrapper around OggVorbis_File
class OggVorbisFile { class OggVorbisFile final {
public: public:
OggVorbisFile(const path& filePath);
OggVorbisFile(const OggVorbisFile&) = delete; OggVorbisFile(const OggVorbisFile&) = delete;
OggVorbisFile& operator=(const OggVorbisFile&) = delete; OggVorbisFile& operator=(const OggVorbisFile&) = delete;
OggVorbisFile(const path& filePath) :
stream(openFile(filePath))
{
// Throw only on badbit, not on failbit.
// Ogg Vorbis expects read operations past the end of the file to
// succeed, not to throw.
stream.exceptions(ifstream::badbit);
// Ogg Vorbis normally uses the `FILE` API from the C standard library.
// This doesn't handle Unicode paths on Windows.
// Use wrapper functions around `ifstream` instead.
const ov_callbacks callbacks{readCallback, seekCallback, nullptr, tellCallback};
throwOnError(ov_open_callbacks(&stream, &oggVorbisHandle, nullptr, 0, callbacks));
}
OggVorbis_File* get() { OggVorbis_File* get() {
return &oggVorbisHandle; return &oggVorbisHandle;
} }
@ -115,6 +102,22 @@ private:
ifstream stream; ifstream stream;
}; };
OggVorbisFile::OggVorbisFile(const path& filePath) :
oggVorbisHandle(),
stream(openFile(filePath))
{
// Throw only on badbit, not on failbit.
// Ogg Vorbis expects read operations past the end of the file to
// succeed, not to throw.
stream.exceptions(ifstream::badbit);
// Ogg Vorbis normally uses the `FILE` API from the C standard library.
// This doesn't handle Unicode paths on Windows.
// Use wrapper functions around `ifstream` instead.
const ov_callbacks callbacks { readCallback, seekCallback, nullptr, tellCallback };
throwOnError(ov_open_callbacks(&stream, &oggVorbisHandle, nullptr, 0, callbacks));
}
OggVorbisFileReader::OggVorbisFileReader(const path& filePath) : OggVorbisFileReader::OggVorbisFileReader(const path& filePath) :
filePath(filePath) filePath(filePath)
{ {
@ -153,7 +156,7 @@ SampleReader OggVorbisFileReader::createUnsafeSampleReader() const {
} }
// Downmix channels // Downmix channels
size_type bufferIndex = index - bufferStart; const size_type bufferIndex = index - bufferStart;
value_type sum = 0.0f; value_type sum = 0.0f;
for (int channel = 0; channel < channelCount; ++channel) { for (int channel = 0; channel < channelCount; ++channel) {
sum += buffer[channel][bufferIndex]; sum += buffer[channel][bufferIndex];

View File

@ -17,7 +17,10 @@ SampleRateConverter::SampleRateConverter(unique_ptr<AudioClip> inputClip, int ou
throw invalid_argument("Sample rate must be positive."); throw invalid_argument("Sample rate must be positive.");
} }
if (this->inputClip->getSampleRate() < outputSampleRate) { if (this->inputClip->getSampleRate() < outputSampleRate) {
throw invalid_argument(fmt::format("Upsampling not supported. Input sample rate must not be below {}Hz.", outputSampleRate)); throw invalid_argument(fmt::format(
"Upsampling not supported. Input sample rate must not be below {}Hz.",
outputSampleRate
));
} }
} }
@ -30,11 +33,11 @@ float mean(double inputStart, double inputEnd, const SampleReader& read) {
double sum = 0; double sum = 0;
// ... first sample (weight <= 1) // ... first sample (weight <= 1)
int64_t startIndex = static_cast<int64_t>(inputStart); const int64_t startIndex = static_cast<int64_t>(inputStart);
sum += read(startIndex) * ((startIndex + 1) - inputStart); sum += read(startIndex) * ((startIndex + 1) - inputStart);
// ... middle samples (weight 1 each) // ... middle samples (weight 1 each)
int64_t endIndex = static_cast<int64_t>(inputEnd); const int64_t endIndex = static_cast<int64_t>(inputEnd);
for (int64_t index = startIndex + 1; index < endIndex; ++index) { for (int64_t index = startIndex + 1; index < endIndex; ++index) {
sum += read(index); sum += read(index);
} }
@ -48,9 +51,14 @@ float mean(double inputStart, double inputEnd, const SampleReader& read) {
} }
SampleReader SampleRateConverter::createUnsafeSampleReader() const { SampleReader SampleRateConverter::createUnsafeSampleReader() const {
return[read = inputClip->createSampleReader(), downscalingFactor = downscalingFactor, size = inputClip->size()](size_type index) { return [
double inputStart = index * downscalingFactor; read = inputClip->createSampleReader(),
double inputEnd = std::min((index + 1) * downscalingFactor, static_cast<double>(size)); downscalingFactor = downscalingFactor,
size = inputClip->size()
](size_type index) {
const double inputStart = index * downscalingFactor;
const double inputEnd =
std::min((index + 1) * downscalingFactor, static_cast<double>(size));
return mean(inputStart, inputEnd, read); return mean(inputStart, inputEnd, read);
}; };
} }

View File

@ -1,6 +1,7 @@
#include <format.h> #include <format.h>
#include "WaveFileReader.h" #include "WaveFileReader.h"
#include "ioTools.h" #include "ioTools.h"
#include <iostream>
#include "tools/platformTools.h" #include "tools/platformTools.h"
#include "tools/fileTools.h" #include "tools/fileTools.h"
@ -32,9 +33,9 @@ namespace Codec {
string codecToString(int codec); string codecToString(int codec);
WaveFileReader::WaveFileReader(path filePath) : WaveFileReader::WaveFileReader(const path& filePath) :
filePath(filePath), filePath(filePath),
formatInfo{} formatInfo {}
{ {
auto file = openFile(filePath); auto file = openFile(filePath);
@ -43,7 +44,7 @@ WaveFileReader::WaveFileReader(path filePath) :
file.seekg(0); file.seekg(0);
auto remaining = [&](int byteCount) { auto remaining = [&](int byteCount) {
std::streamoff filePosition = file.tellg(); const std::streamoff filePosition = file.tellg();
return byteCount <= fileSize - filePosition; return byteCount <= fileSize - filePosition;
}; };
@ -51,7 +52,7 @@ WaveFileReader::WaveFileReader(path filePath) :
if (!remaining(10)) { if (!remaining(10)) {
throw runtime_error("WAVE file is corrupt. Header not found."); throw runtime_error("WAVE file is corrupt. Header not found.");
} }
uint32_t rootChunkId = read<uint32_t>(file); auto rootChunkId = read<uint32_t>(file);
if (rootChunkId != fourcc('R', 'I', 'F', 'F')) { if (rootChunkId != fourcc('R', 'I', 'F', 'F')) {
throw runtime_error("Unknown file format. Only WAVE files are supported."); throw runtime_error("Unknown file format. Only WAVE files are supported.");
} }
@ -67,69 +68,75 @@ WaveFileReader::WaveFileReader(path filePath) :
uint32_t chunkId = read<uint32_t>(file); uint32_t chunkId = read<uint32_t>(file);
int chunkSize = read<uint32_t>(file); int chunkSize = read<uint32_t>(file);
switch (chunkId) { switch (chunkId) {
case fourcc('f', 'm', 't', ' '): { case fourcc('f', 'm', 't', ' '):
// Read relevant data {
uint16_t codec = read<uint16_t>(file); // Read relevant data
formatInfo.channelCount = read<uint16_t>(file); uint16_t codec = read<uint16_t>(file);
formatInfo.frameRate = read<uint32_t>(file); formatInfo.channelCount = read<uint16_t>(file);
read<uint32_t>(file); // Bytes per second formatInfo.frameRate = read<uint32_t>(file);
int frameSize = read<uint16_t>(file); read<uint32_t>(file); // Bytes per second
int bitsPerSample = read<uint16_t>(file); int frameSize = read<uint16_t>(file);
int bitsPerSample = read<uint16_t>(file);
// We've read 16 bytes so far. Skip the remainder. // We've read 16 bytes so far. Skip the remainder.
file.seekg(roundToEven(chunkSize) - 16, file.cur); file.seekg(roundToEven(chunkSize) - 16, std::ios_base::cur);
// Determine sample format // Determine sample format
int bytesPerSample; int bytesPerSample;
switch (codec) { switch (codec) {
case Codec::Pcm: case Codec::Pcm:
// Determine sample size. // Determine sample size.
// According to the WAVE standard, sample sizes that are not multiples of 8 bits // According to the WAVE standard, sample sizes that are not multiples of 8
// (e.g. 12 bits) can be treated like the next-larger byte size. // bits (e.g. 12 bits) can be treated like the next-larger byte size.
if (bitsPerSample == 8) { if (bitsPerSample == 8) {
formatInfo.sampleFormat = SampleFormat::UInt8; formatInfo.sampleFormat = SampleFormat::UInt8;
bytesPerSample = 1; bytesPerSample = 1;
} else if (bitsPerSample <= 16) { } else if (bitsPerSample <= 16) {
formatInfo.sampleFormat = SampleFormat::Int16; formatInfo.sampleFormat = SampleFormat::Int16;
bytesPerSample = 2; bytesPerSample = 2;
} else if (bitsPerSample <= 24) { } else if (bitsPerSample <= 24) {
formatInfo.sampleFormat = SampleFormat::Int24; formatInfo.sampleFormat = SampleFormat::Int24;
bytesPerSample = 3; bytesPerSample = 3;
} else { } else {
throw runtime_error( throw runtime_error(
format("Unsupported sample format: {}-bit PCM.", bitsPerSample)); format("Unsupported sample format: {}-bit PCM.", bitsPerSample));
} }
if (bytesPerSample != frameSize / formatInfo.channelCount) { if (bytesPerSample != frameSize / formatInfo.channelCount) {
throw runtime_error("Unsupported sample organization."); throw runtime_error("Unsupported sample organization.");
}
break;
case Codec::Float:
if (bitsPerSample == 32) {
formatInfo.sampleFormat = SampleFormat::Float32;
bytesPerSample = 4;
} else {
throw runtime_error(
format("Unsupported sample format: {}-bit IEEE Float.", bitsPerSample)
);
}
break;
default:
throw runtime_error(format(
"Unsupported audio codec: '{}'. Only uncompressed codecs ('{}' and '{}') are supported.",
codecToString(codec), codecToString(Codec::Pcm), codecToString(Codec::Float)
));
} }
formatInfo.bytesPerFrame = bytesPerSample * formatInfo.channelCount;
break;
}
case fourcc('d', 'a', 't', 'a'):
{
reachedDataChunk = true;
formatInfo.dataOffset = file.tellg();
formatInfo.frameCount = chunkSize / formatInfo.bytesPerFrame;
break;
}
default:
{
// Skip unknown chunk
file.seekg(roundToEven(chunkSize), std::ios_base::cur);
break; break;
case Codec::Float:
if (bitsPerSample == 32) {
formatInfo.sampleFormat = SampleFormat::Float32;
bytesPerSample = 4;
} else {
throw runtime_error(format("Unsupported sample format: {}-bit IEEE Float.", bitsPerSample));
}
break;
default:
throw runtime_error(format(
"Unsupported audio codec: '{}'. Only uncompressed codecs ('{}' and '{}') are supported.",
codecToString(codec), codecToString(Codec::Pcm), codecToString(Codec::Float)));
} }
formatInfo.bytesPerFrame = bytesPerSample * formatInfo.channelCount;
break;
}
case fourcc('d', 'a', 't', 'a'): {
reachedDataChunk = true;
formatInfo.dataOffset = file.tellg();
formatInfo.frameCount = chunkSize / formatInfo.bytesPerFrame;
break;
}
default: {
// Skip unknown chunk
file.seekg(roundToEven(chunkSize), file.cur);
break;
}
} }
} }
} }
@ -138,30 +145,38 @@ unique_ptr<AudioClip> WaveFileReader::clone() const {
return make_unique<WaveFileReader>(*this); return make_unique<WaveFileReader>(*this);
} }
inline AudioClip::value_type readSample(std::ifstream& file, SampleFormat sampleFormat, int channelCount) { inline AudioClip::value_type readSample(
std::ifstream& file,
SampleFormat sampleFormat,
int channelCount
) {
float sum = 0; float sum = 0;
for (int channelIndex = 0; channelIndex < channelCount; channelIndex++) { for (int channelIndex = 0; channelIndex < channelCount; channelIndex++) {
switch (sampleFormat) { switch (sampleFormat) {
case SampleFormat::UInt8: { case SampleFormat::UInt8:
uint8_t raw = read<uint8_t>(file); {
sum += toNormalizedFloat(raw, 0, UINT8_MAX); const uint8_t raw = read<uint8_t>(file);
break; sum += toNormalizedFloat(raw, 0, UINT8_MAX);
} break;
case SampleFormat::Int16: { }
int16_t raw = read<int16_t>(file); case SampleFormat::Int16:
sum += toNormalizedFloat(raw, INT16_MIN, INT16_MAX); {
break; const int16_t raw = read<int16_t>(file);
} sum += toNormalizedFloat(raw, INT16_MIN, INT16_MAX);
case SampleFormat::Int24: { break;
int raw = read<int, 24>(file); }
if (raw & 0x800000) raw |= 0xFF000000; // Fix two's complement case SampleFormat::Int24:
sum += toNormalizedFloat(raw, INT24_MIN, INT24_MAX); {
break; int raw = read<int, 24>(file);
} if (raw & 0x800000) raw |= 0xFF000000; // Fix two's complement
case SampleFormat::Float32: { sum += toNormalizedFloat(raw, INT24_MIN, INT24_MAX);
sum += read<float>(file); break;
break; }
} case SampleFormat::Float32:
{
sum += read<float>(file);
break;
}
} }
} }
@ -169,10 +184,17 @@ inline AudioClip::value_type readSample(std::ifstream& file, SampleFormat sample
} }
SampleReader WaveFileReader::createUnsafeSampleReader() const { SampleReader WaveFileReader::createUnsafeSampleReader() const {
return [formatInfo = formatInfo, file = std::make_shared<std::ifstream>(openFile(filePath)), filePos = std::streampos(0)](size_type index) mutable { return
std::streampos newFilePos = formatInfo.dataOffset + static_cast<std::streamoff>(index * formatInfo.bytesPerFrame); [
formatInfo = formatInfo,
file = std::make_shared<std::ifstream>(openFile(filePath)),
filePos = std::streampos(0)
](size_type index) mutable {
const std::streampos newFilePos = formatInfo.dataOffset
+ static_cast<std::streamoff>(index * formatInfo.bytesPerFrame);
file->seekg(newFilePos); file->seekg(newFilePos);
value_type result = readSample(*file, formatInfo.sampleFormat, formatInfo.channelCount); const value_type result =
readSample(*file, formatInfo.sampleFormat, formatInfo.channelCount);
filePos = newFilePos + static_cast<std::streamoff>(formatInfo.bytesPerFrame); filePos = newFilePos + static_cast<std::streamoff>(formatInfo.bytesPerFrame);
return result; return result;
}; };
@ -180,248 +202,249 @@ SampleReader WaveFileReader::createUnsafeSampleReader() const {
string codecToString(int codec) { string codecToString(int codec) {
switch (codec) { switch (codec) {
case 0x0001: return "PCM"; case 0x0001: return "PCM";
case 0x0002: return "Microsoft ADPCM"; case 0x0002: return "Microsoft ADPCM";
case 0x0003: return "IEEE Float"; case 0x0003: return "IEEE Float";
case 0x0004: return "Compaq VSELP"; case 0x0004: return "Compaq VSELP";
case 0x0005: return "IBM CVSD"; case 0x0005: return "IBM CVSD";
case 0x0006: return "Microsoft a-Law"; case 0x0006: return "Microsoft a-Law";
case 0x0007: return "Microsoft u-Law"; case 0x0007: return "Microsoft u-Law";
case 0x0008: return "Microsoft DTS"; case 0x0008: return "Microsoft DTS";
case 0x0009: return "DRM"; case 0x0009: return "DRM";
case 0x000a: return "WMA 9 Speech"; case 0x000a: return "WMA 9 Speech";
case 0x000b: return "Microsoft Windows Media RT Voice"; case 0x000b: return "Microsoft Windows Media RT Voice";
case 0x0010: return "OKI-ADPCM"; case 0x0010: return "OKI-ADPCM";
case 0x0011: return "Intel IMA/DVI-ADPCM"; case 0x0011: return "Intel IMA/DVI-ADPCM";
case 0x0012: return "Videologic Mediaspace ADPCM"; case 0x0012: return "Videologic Mediaspace ADPCM";
case 0x0013: return "Sierra ADPCM"; case 0x0013: return "Sierra ADPCM";
case 0x0014: return "Antex G.723 ADPCM"; case 0x0014: return "Antex G.723 ADPCM";
case 0x0015: return "DSP Solutions DIGISTD"; case 0x0015: return "DSP Solutions DIGISTD";
case 0x0016: return "DSP Solutions DIGIFIX"; case 0x0016: return "DSP Solutions DIGIFIX";
case 0x0017: return "Dialoic OKI ADPCM"; case 0x0017: return "Dialoic OKI ADPCM";
case 0x0018: return "Media Vision ADPCM"; case 0x0018: return "Media Vision ADPCM";
case 0x0019: return "HP CU"; case 0x0019: return "HP CU";
case 0x001a: return "HP Dynamic Voice"; case 0x001a: return "HP Dynamic Voice";
case 0x0020: return "Yamaha ADPCM"; case 0x0020: return "Yamaha ADPCM";
case 0x0021: return "SONARC Speech Compression"; case 0x0021: return "SONARC Speech Compression";
case 0x0022: return "DSP Group True Speech"; case 0x0022: return "DSP Group True Speech";
case 0x0023: return "Echo Speech Corp."; case 0x0023: return "Echo Speech Corp.";
case 0x0024: return "Virtual Music Audiofile AF36"; case 0x0024: return "Virtual Music Audiofile AF36";
case 0x0025: return "Audio Processing Tech."; case 0x0025: return "Audio Processing Tech.";
case 0x0026: return "Virtual Music Audiofile AF10"; case 0x0026: return "Virtual Music Audiofile AF10";
case 0x0027: return "Aculab Prosody 1612"; case 0x0027: return "Aculab Prosody 1612";
case 0x0028: return "Merging Tech. LRC"; case 0x0028: return "Merging Tech. LRC";
case 0x0030: return "Dolby AC2"; case 0x0030: return "Dolby AC2";
case 0x0031: return "Microsoft GSM610"; case 0x0031: return "Microsoft GSM610";
case 0x0032: return "MSN Audio"; case 0x0032: return "MSN Audio";
case 0x0033: return "Antex ADPCME"; case 0x0033: return "Antex ADPCME";
case 0x0034: return "Control Resources VQLPC"; case 0x0034: return "Control Resources VQLPC";
case 0x0035: return "DSP Solutions DIGIREAL"; case 0x0035: return "DSP Solutions DIGIREAL";
case 0x0036: return "DSP Solutions DIGIADPCM"; case 0x0036: return "DSP Solutions DIGIADPCM";
case 0x0037: return "Control Resources CR10"; case 0x0037: return "Control Resources CR10";
case 0x0038: return "Natural MicroSystems VBX ADPCM"; case 0x0038: return "Natural MicroSystems VBX ADPCM";
case 0x0039: return "Crystal Semiconductor IMA ADPCM"; case 0x0039: return "Crystal Semiconductor IMA ADPCM";
case 0x003a: return "Echo Speech ECHOSC3"; case 0x003a: return "Echo Speech ECHOSC3";
case 0x003b: return "Rockwell ADPCM"; case 0x003b: return "Rockwell ADPCM";
case 0x003c: return "Rockwell DIGITALK"; case 0x003c: return "Rockwell DIGITALK";
case 0x003d: return "Xebec Multimedia"; case 0x003d: return "Xebec Multimedia";
case 0x0040: return "Antex G.721 ADPCM"; case 0x0040: return "Antex G.721 ADPCM";
case 0x0041: return "Antex G.728 CELP"; case 0x0041: return "Antex G.728 CELP";
case 0x0042: return "Microsoft MSG723"; case 0x0042: return "Microsoft MSG723";
case 0x0043: return "IBM AVC ADPCM"; case 0x0043: return "IBM AVC ADPCM";
case 0x0045: return "ITU-T G.726"; case 0x0045: return "ITU-T G.726";
case 0x0050: return "Microsoft MPEG"; case 0x0050: return "Microsoft MPEG";
case 0x0051: return "RT23 or PAC"; case 0x0051: return "RT23 or PAC";
case 0x0052: return "InSoft RT24"; case 0x0052: return "InSoft RT24";
case 0x0053: return "InSoft PAC"; case 0x0053: return "InSoft PAC";
case 0x0055: return "MP3"; case 0x0055: return "MP3";
case 0x0059: return "Cirrus"; case 0x0059: return "Cirrus";
case 0x0060: return "Cirrus Logic"; case 0x0060: return "Cirrus Logic";
case 0x0061: return "ESS Tech. PCM"; case 0x0061: return "ESS Tech. PCM";
case 0x0062: return "Voxware Inc."; case 0x0062: return "Voxware Inc.";
case 0x0063: return "Canopus ATRAC"; case 0x0063: return "Canopus ATRAC";
case 0x0064: return "APICOM G.726 ADPCM"; case 0x0064: return "APICOM G.726 ADPCM";
case 0x0065: return "APICOM G.722 ADPCM"; case 0x0065: return "APICOM G.722 ADPCM";
case 0x0066: return "Microsoft DSAT"; case 0x0066: return "Microsoft DSAT";
case 0x0067: return "Micorsoft DSAT DISPLAY"; case 0x0067: return "Micorsoft DSAT DISPLAY";
case 0x0069: return "Voxware Byte Aligned"; case 0x0069: return "Voxware Byte Aligned";
case 0x0070: return "Voxware AC8"; case 0x0070: return "Voxware AC8";
case 0x0071: return "Voxware AC10"; case 0x0071: return "Voxware AC10";
case 0x0072: return "Voxware AC16"; case 0x0072: return "Voxware AC16";
case 0x0073: return "Voxware AC20"; case 0x0073: return "Voxware AC20";
case 0x0074: return "Voxware MetaVoice"; case 0x0074: return "Voxware MetaVoice";
case 0x0075: return "Voxware MetaSound"; case 0x0075: return "Voxware MetaSound";
case 0x0076: return "Voxware RT29HW"; case 0x0076: return "Voxware RT29HW";
case 0x0077: return "Voxware VR12"; case 0x0077: return "Voxware VR12";
case 0x0078: return "Voxware VR18"; case 0x0078: return "Voxware VR18";
case 0x0079: return "Voxware TQ40"; case 0x0079: return "Voxware TQ40";
case 0x007a: return "Voxware SC3"; case 0x007a: return "Voxware SC3";
case 0x007b: return "Voxware SC3"; case 0x007b: return "Voxware SC3";
case 0x0080: return "Soundsoft"; case 0x0080: return "Soundsoft";
case 0x0081: return "Voxware TQ60"; case 0x0081: return "Voxware TQ60";
case 0x0082: return "Microsoft MSRT24"; case 0x0082: return "Microsoft MSRT24";
case 0x0083: return "AT&T G.729A"; case 0x0083: return "AT&T G.729A";
case 0x0084: return "Motion Pixels MVI MV12"; case 0x0084: return "Motion Pixels MVI MV12";
case 0x0085: return "DataFusion G.726"; case 0x0085: return "DataFusion G.726";
case 0x0086: return "DataFusion GSM610"; case 0x0086: return "DataFusion GSM610";
case 0x0088: return "Iterated Systems Audio"; case 0x0088: return "Iterated Systems Audio";
case 0x0089: return "Onlive"; case 0x0089: return "Onlive";
case 0x008a: return "Multitude, Inc. FT SX20"; case 0x008a: return "Multitude, Inc. FT SX20";
case 0x008b: return "Infocom ITS A/S G.721 ADPCM"; case 0x008b: return "Infocom ITS A/S G.721 ADPCM";
case 0x008c: return "Convedia G729"; case 0x008c: return "Convedia G729";
case 0x008d: return "Not specified congruency, Inc."; case 0x008d: return "Not specified congruency, Inc.";
case 0x0091: return "Siemens SBC24"; case 0x0091: return "Siemens SBC24";
case 0x0092: return "Sonic Foundry Dolby AC3 APDIF"; case 0x0092: return "Sonic Foundry Dolby AC3 APDIF";
case 0x0093: return "MediaSonic G.723"; case 0x0093: return "MediaSonic G.723";
case 0x0094: return "Aculab Prosody 8kbps"; case 0x0094: return "Aculab Prosody 8kbps";
case 0x0097: return "ZyXEL ADPCM"; case 0x0097: return "ZyXEL ADPCM";
case 0x0098: return "Philips LPCBB"; case 0x0098: return "Philips LPCBB";
case 0x0099: return "Studer Professional Audio Packed"; case 0x0099: return "Studer Professional Audio Packed";
case 0x00a0: return "Malden PhonyTalk"; case 0x00a0: return "Malden PhonyTalk";
case 0x00a1: return "Racal Recorder GSM"; case 0x00a1: return "Racal Recorder GSM";
case 0x00a2: return "Racal Recorder G720.a"; case 0x00a2: return "Racal Recorder G720.a";
case 0x00a3: return "Racal G723.1"; case 0x00a3: return "Racal G723.1";
case 0x00a4: return "Racal Tetra ACELP"; case 0x00a4: return "Racal Tetra ACELP";
case 0x00b0: return "NEC AAC NEC Corporation"; case 0x00b0: return "NEC AAC NEC Corporation";
case 0x00ff: return "AAC"; case 0x00ff: return "AAC";
case 0x0100: return "Rhetorex ADPCM"; case 0x0100: return "Rhetorex ADPCM";
case 0x0101: return "IBM u-Law"; case 0x0101: return "IBM u-Law";
case 0x0102: return "IBM a-Law"; case 0x0102: return "IBM a-Law";
case 0x0103: return "IBM ADPCM"; case 0x0103: return "IBM ADPCM";
case 0x0111: return "Vivo G.723"; case 0x0111: return "Vivo G.723";
case 0x0112: return "Vivo Siren"; case 0x0112: return "Vivo Siren";
case 0x0120: return "Philips Speech Processing CELP"; case 0x0120: return "Philips Speech Processing CELP";
case 0x0121: return "Philips Speech Processing GRUNDIG"; case 0x0121: return "Philips Speech Processing GRUNDIG";
case 0x0123: return "Digital G.723"; case 0x0123: return "Digital G.723";
case 0x0125: return "Sanyo LD ADPCM"; case 0x0125: return "Sanyo LD ADPCM";
case 0x0130: return "Sipro Lab ACEPLNET"; case 0x0130: return "Sipro Lab ACEPLNET";
case 0x0131: return "Sipro Lab ACELP4800"; case 0x0131: return "Sipro Lab ACELP4800";
case 0x0132: return "Sipro Lab ACELP8V3"; case 0x0132: return "Sipro Lab ACELP8V3";
case 0x0133: return "Sipro Lab G.729"; case 0x0133: return "Sipro Lab G.729";
case 0x0134: return "Sipro Lab G.729A"; case 0x0134: return "Sipro Lab G.729A";
case 0x0135: return "Sipro Lab Kelvin"; case 0x0135: return "Sipro Lab Kelvin";
case 0x0136: return "VoiceAge AMR"; case 0x0136: return "VoiceAge AMR";
case 0x0140: return "Dictaphone G.726 ADPCM"; case 0x0140: return "Dictaphone G.726 ADPCM";
case 0x0150: return "Qualcomm PureVoice"; case 0x0150: return "Qualcomm PureVoice";
case 0x0151: return "Qualcomm HalfRate"; case 0x0151: return "Qualcomm HalfRate";
case 0x0155: return "Ring Zero Systems TUBGSM"; case 0x0155: return "Ring Zero Systems TUBGSM";
case 0x0160: return "Microsoft Audio1"; case 0x0160: return "Microsoft Audio1";
case 0x0161: return "Windows Media Audio V2 V7 V8 V9 / DivX audio (WMA) / Alex AC3 Audio"; case 0x0161: return "Windows Media Audio V2 V7 V8 V9 / DivX audio (WMA) / Alex AC3 Audio";
case 0x0162: return "Windows Media Audio Professional V9"; case 0x0162: return "Windows Media Audio Professional V9";
case 0x0163: return "Windows Media Audio Lossless V9"; case 0x0163: return "Windows Media Audio Lossless V9";
case 0x0164: return "WMA Pro over S/PDIF"; case 0x0164: return "WMA Pro over S/PDIF";
case 0x0170: return "UNISYS NAP ADPCM"; case 0x0170: return "UNISYS NAP ADPCM";
case 0x0171: return "UNISYS NAP ULAW"; case 0x0171: return "UNISYS NAP ULAW";
case 0x0172: return "UNISYS NAP ALAW"; case 0x0172: return "UNISYS NAP ALAW";
case 0x0173: return "UNISYS NAP 16K"; case 0x0173: return "UNISYS NAP 16K";
case 0x0174: return "MM SYCOM ACM SYC008 SyCom Technologies"; case 0x0174: return "MM SYCOM ACM SYC008 SyCom Technologies";
case 0x0175: return "MM SYCOM ACM SYC701 G726L SyCom Technologies"; case 0x0175: return "MM SYCOM ACM SYC701 G726L SyCom Technologies";
case 0x0176: return "MM SYCOM ACM SYC701 CELP54 SyCom Technologies"; case 0x0176: return "MM SYCOM ACM SYC701 CELP54 SyCom Technologies";
case 0x0177: return "MM SYCOM ACM SYC701 CELP68 SyCom Technologies"; case 0x0177: return "MM SYCOM ACM SYC701 CELP68 SyCom Technologies";
case 0x0178: return "Knowledge Adventure ADPCM"; case 0x0178: return "Knowledge Adventure ADPCM";
case 0x0180: return "Fraunhofer IIS MPEG2AAC"; case 0x0180: return "Fraunhofer IIS MPEG2AAC";
case 0x0190: return "Digital Theater Systems DTS DS"; case 0x0190: return "Digital Theater Systems DTS DS";
case 0x0200: return "Creative Labs ADPCM"; case 0x0200: return "Creative Labs ADPCM";
case 0x0202: return "Creative Labs FASTSPEECH8"; case 0x0202: return "Creative Labs FASTSPEECH8";
case 0x0203: return "Creative Labs FASTSPEECH10"; case 0x0203: return "Creative Labs FASTSPEECH10";
case 0x0210: return "UHER ADPCM"; case 0x0210: return "UHER ADPCM";
case 0x0215: return "Ulead DV ACM"; case 0x0215: return "Ulead DV ACM";
case 0x0216: return "Ulead DV ACM"; case 0x0216: return "Ulead DV ACM";
case 0x0220: return "Quarterdeck Corp."; case 0x0220: return "Quarterdeck Corp.";
case 0x0230: return "I-Link VC"; case 0x0230: return "I-Link VC";
case 0x0240: return "Aureal Semiconductor Raw Sport"; case 0x0240: return "Aureal Semiconductor Raw Sport";
case 0x0241: return "ESST AC3"; case 0x0241: return "ESST AC3";
case 0x0250: return "Interactive Products HSX"; case 0x0250: return "Interactive Products HSX";
case 0x0251: return "Interactive Products RPELP"; case 0x0251: return "Interactive Products RPELP";
case 0x0260: return "Consistent CS2"; case 0x0260: return "Consistent CS2";
case 0x0270: return "Sony SCX"; case 0x0270: return "Sony SCX";
case 0x0271: return "Sony SCY"; case 0x0271: return "Sony SCY";
case 0x0272: return "Sony ATRAC3"; case 0x0272: return "Sony ATRAC3";
case 0x0273: return "Sony SPC"; case 0x0273: return "Sony SPC";
case 0x0280: return "TELUM Telum Inc."; case 0x0280: return "TELUM Telum Inc.";
case 0x0281: return "TELUMIA Telum Inc."; case 0x0281: return "TELUMIA Telum Inc.";
case 0x0285: return "Norcom Voice Systems ADPCM"; case 0x0285: return "Norcom Voice Systems ADPCM";
case 0x0300: return "Fujitsu FM TOWNS SND"; case 0x0300: return "Fujitsu FM TOWNS SND";
case 0x0301: case 0x0301:
case 0x0302: case 0x0302:
case 0x0303: case 0x0303:
case 0x0304: case 0x0304:
case 0x0305: case 0x0305:
case 0x0306: case 0x0306:
case 0x0307: case 0x0307:
case 0x0308: return "Fujitsu (not specified)"; case 0x0308: return "Fujitsu (not specified)";
case 0x0350: return "Micronas Semiconductors, Inc. Development"; case 0x0350: return "Micronas Semiconductors, Inc. Development";
case 0x0351: return "Micronas Semiconductors, Inc. CELP833"; case 0x0351: return "Micronas Semiconductors, Inc. CELP833";
case 0x0400: return "Brooktree Digital"; case 0x0400: return "Brooktree Digital";
case 0x0401: return "Intel Music Coder (IMC)"; case 0x0401: return "Intel Music Coder (IMC)";
case 0x0402: return "Ligos Indeo Audio"; case 0x0402: return "Ligos Indeo Audio";
case 0x0450: return "QDesign Music"; case 0x0450: return "QDesign Music";
case 0x0500: return "On2 VP7 On2 Technologies"; case 0x0500: return "On2 VP7 On2 Technologies";
case 0x0501: return "On2 VP6 On2 Technologies"; case 0x0501: return "On2 VP6 On2 Technologies";
case 0x0680: return "AT&T VME VMPCM"; case 0x0680: return "AT&T VME VMPCM";
case 0x0681: return "AT&T TCP"; case 0x0681: return "AT&T TCP";
case 0x0700: return "YMPEG Alpha (dummy for MPEG-2 compressor)"; case 0x0700: return "YMPEG Alpha (dummy for MPEG-2 compressor)";
case 0x08ae: return "ClearJump LiteWave (lossless)"; case 0x08ae: return "ClearJump LiteWave (lossless)";
case 0x1000: return "Olivetti GSM"; case 0x1000: return "Olivetti GSM";
case 0x1001: return "Olivetti ADPCM"; case 0x1001: return "Olivetti ADPCM";
case 0x1002: return "Olivetti CELP"; case 0x1002: return "Olivetti CELP";
case 0x1003: return "Olivetti SBC"; case 0x1003: return "Olivetti SBC";
case 0x1004: return "Olivetti OPR"; case 0x1004: return "Olivetti OPR";
case 0x1100: return "Lernout & Hauspie"; case 0x1100: return "Lernout & Hauspie";
case 0x1101: return "Lernout & Hauspie CELP codec"; case 0x1101: return "Lernout & Hauspie CELP codec";
case 0x1102: case 0x1102:
case 0x1103: case 0x1103:
case 0x1104: return "Lernout & Hauspie SBC codec"; case 0x1104: return "Lernout & Hauspie SBC codec";
case 0x1400: return "Norris Comm. Inc."; case 0x1400: return "Norris Comm. Inc.";
case 0x1401: return "ISIAudio"; case 0x1401: return "ISIAudio";
case 0x1500: return "AT&T Soundspace Music Compression"; case 0x1500: return "AT&T Soundspace Music Compression";
case 0x181c: return "VoxWare RT24 speech codec"; case 0x181c: return "VoxWare RT24 speech codec";
case 0x181e: return "Lucent elemedia AX24000P Music codec"; case 0x181e: return "Lucent elemedia AX24000P Music codec";
case 0x1971: return "Sonic Foundry LOSSLESS"; case 0x1971: return "Sonic Foundry LOSSLESS";
case 0x1979: return "Innings Telecom Inc. ADPCM"; case 0x1979: return "Innings Telecom Inc. ADPCM";
case 0x1c07: return "Lucent SX8300P speech codec"; case 0x1c07: return "Lucent SX8300P speech codec";
case 0x1c0c: return "Lucent SX5363S G.723 compliant codec"; case 0x1c0c: return "Lucent SX5363S G.723 compliant codec";
case 0x1f03: return "CUseeMe DigiTalk (ex-Rocwell)"; case 0x1f03: return "CUseeMe DigiTalk (ex-Rocwell)";
case 0x1fc4: return "NCT Soft ALF2CD ACM"; case 0x1fc4: return "NCT Soft ALF2CD ACM";
case 0x2000: return "FAST Multimedia DVM"; case 0x2000: return "FAST Multimedia DVM";
case 0x2001: return "Dolby DTS (Digital Theater System)"; case 0x2001: return "Dolby DTS (Digital Theater System)";
case 0x2002: return "RealAudio 1 / 2 14.4"; case 0x2002: return "RealAudio 1 / 2 14.4";
case 0x2003: return "RealAudio 1 / 2 28.8"; case 0x2003: return "RealAudio 1 / 2 28.8";
case 0x2004: return "RealAudio G2 / 8 Cook (low bitrate)"; case 0x2004: return "RealAudio G2 / 8 Cook (low bitrate)";
case 0x2005: return "RealAudio 3 / 4 / 5 Music (DNET)"; case 0x2005: return "RealAudio 3 / 4 / 5 Music (DNET)";
case 0x2006: return "RealAudio 10 AAC (RAAC)"; case 0x2006: return "RealAudio 10 AAC (RAAC)";
case 0x2007: return "RealAudio 10 AAC+ (RACP)"; case 0x2007: return "RealAudio 10 AAC+ (RACP)";
case 0x2500: return "Reserved range to 0x2600 Microsoft"; case 0x2500: return "Reserved range to 0x2600 Microsoft";
case 0x3313: return "makeAVIS (ffvfw fake AVI sound from AviSynth scripts)"; case 0x3313: return "makeAVIS (ffvfw fake AVI sound from AviSynth scripts)";
case 0x4143: return "Divio MPEG-4 AAC audio"; case 0x4143: return "Divio MPEG-4 AAC audio";
case 0x4201: return "Nokia adaptive multirate"; case 0x4201: return "Nokia adaptive multirate";
case 0x4243: return "Divio G726 Divio, Inc."; case 0x4243: return "Divio G726 Divio, Inc.";
case 0x434c: return "LEAD Speech"; case 0x434c: return "LEAD Speech";
case 0x564c: return "LEAD Vorbis"; case 0x564c: return "LEAD Vorbis";
case 0x5756: return "WavPack Audio"; case 0x5756: return "WavPack Audio";
case 0x674f: return "Ogg Vorbis (mode 1)"; case 0x674f: return "Ogg Vorbis (mode 1)";
case 0x6750: return "Ogg Vorbis (mode 2)"; case 0x6750: return "Ogg Vorbis (mode 2)";
case 0x6751: return "Ogg Vorbis (mode 3)"; case 0x6751: return "Ogg Vorbis (mode 3)";
case 0x676f: return "Ogg Vorbis (mode 1+)"; case 0x676f: return "Ogg Vorbis (mode 1+)";
case 0x6770: return "Ogg Vorbis (mode 2+)"; case 0x6770: return "Ogg Vorbis (mode 2+)";
case 0x6771: return "Ogg Vorbis (mode 3+)"; case 0x6771: return "Ogg Vorbis (mode 3+)";
case 0x7000: return "3COM NBX 3Com Corporation"; case 0x7000: return "3COM NBX 3Com Corporation";
case 0x706d: return "FAAD AAC"; case 0x706d: return "FAAD AAC";
case 0x7a21: return "GSM-AMR (CBR, no SID)"; case 0x7a21: return "GSM-AMR (CBR, no SID)";
case 0x7a22: return "GSM-AMR (VBR, including SID)"; case 0x7a22: return "GSM-AMR (VBR, including SID)";
case 0xa100: return "Comverse Infosys Ltd. G723 1"; case 0xa100: return "Comverse Infosys Ltd. G723 1";
case 0xa101: return "Comverse Infosys Ltd. AVQSBC"; case 0xa101: return "Comverse Infosys Ltd. AVQSBC";
case 0xa102: return "Comverse Infosys Ltd. OLDSBC"; case 0xa102: return "Comverse Infosys Ltd. OLDSBC";
case 0xa103: return "Symbol Technologies G729A"; case 0xa103: return "Symbol Technologies G729A";
case 0xa104: return "VoiceAge AMR WB VoiceAge Corporation"; case 0xa104: return "VoiceAge AMR WB VoiceAge Corporation";
case 0xa105: return "Ingenient Technologies Inc. G726"; case 0xa105: return "Ingenient Technologies Inc. G726";
case 0xa106: return "ISO/MPEG-4 advanced audio Coding"; case 0xa106: return "ISO/MPEG-4 advanced audio Coding";
case 0xa107: return "Encore Software Ltd G726"; case 0xa107: return "Encore Software Ltd G726";
case 0xa109: return "Speex ACM Codec xiph.org"; case 0xa109: return "Speex ACM Codec xiph.org";
case 0xdfac: return "DebugMode SonicFoundry Vegas FrameServer ACM Codec"; case 0xdfac: return "DebugMode SonicFoundry Vegas FrameServer ACM Codec";
case 0xf1ac: return "Free Lossless Audio Codec FLAC"; case 0xf1ac: return "Free Lossless Audio Codec FLAC";
case 0xfffe: return "Extensible"; case 0xfffe: return "Extensible";
case 0xffff: return "Development"; case 0xffff: return "Development";
default:
return format("{0:#x}", codec);
} }
return format("{0:#x}", codec);
} }

View File

@ -12,7 +12,7 @@ enum class SampleFormat {
class WaveFileReader : public AudioClip { class WaveFileReader : public AudioClip {
public: public:
WaveFileReader(boost::filesystem::path filePath); WaveFileReader(const boost::filesystem::path& filePath);
std::unique_ptr<AudioClip> clone() const override; std::unique_ptr<AudioClip> clone() const override;
int getSampleRate() const override; int getSampleRate() const override;
size_type size() const override; size_type size() const override;

View File

@ -20,7 +20,9 @@ std::unique_ptr<AudioClip> createAudioFileClip(path filePath) {
return std::make_unique<OggVorbisFileReader>(filePath); return std::make_unique<OggVorbisFileReader>(filePath);
} }
throw runtime_error(format( throw runtime_error(format(
"Unsupported file extension '{}'. Supported extensions are '.wav' and '.ogg'.", extension)); "Unsupported file extension '{}'. Supported extensions are '.wav' and '.ogg'.",
extension
));
} catch (...) { } catch (...) {
std::throw_with_nested(runtime_error(format("Could not open sound file {}.", filePath))); std::throw_with_nested(runtime_error(format("Could not open sound file {}.", filePath)));
} }

View File

@ -4,33 +4,38 @@
namespace little_endian { namespace little_endian {
template <typename Type, int bitsToRead = 8 * sizeof(Type)> template<typename Type, int bitsToRead = 8 * sizeof(Type)>
Type read(std::istream &stream) { Type read(std::istream& stream) {
static_assert(bitsToRead % 8 == 0, "Cannot read fractional bytes."); static_assert(bitsToRead % 8 == 0, "Cannot read fractional bytes.");
static_assert(bitsToRead <= sizeof(Type) * 8, "Bits to read exceed target type size."); static_assert(bitsToRead <= sizeof(Type) * 8, "Bits to read exceed target type size.");
Type result = 0; Type result = 0;
char *p = reinterpret_cast<char*>(&result); char* p = reinterpret_cast<char*>(&result);
int bytesToRead = bitsToRead / 8; const int bytesToRead = bitsToRead / 8;
for (int byteIndex = 0; byteIndex < bytesToRead; byteIndex++) { for (int byteIndex = 0; byteIndex < bytesToRead; byteIndex++) {
*(p + byteIndex) = static_cast<char>(stream.get()); *(p + byteIndex) = static_cast<char>(stream.get());
} }
return result; return result;
} }
template <typename Type, int bitsToWrite = 8 * sizeof(Type)> template<typename Type, int bitsToWrite = 8 * sizeof(Type)>
void write(Type value, std::ostream &stream) { void write(Type value, std::ostream& stream) {
static_assert(bitsToWrite % 8 == 0, "Cannot write fractional bytes."); static_assert(bitsToWrite % 8 == 0, "Cannot write fractional bytes.");
static_assert(bitsToWrite <= sizeof(Type) * 8, "Bits to write exceed target type size."); static_assert(bitsToWrite <= sizeof(Type) * 8, "Bits to write exceed target type size.");
char *p = reinterpret_cast<char*>(&value); char* p = reinterpret_cast<char*>(&value);
int bytesToWrite = bitsToWrite / 8; const int bytesToWrite = bitsToWrite / 8;
for (int byteIndex = 0; byteIndex < bytesToWrite; byteIndex++) { for (int byteIndex = 0; byteIndex < bytesToWrite; byteIndex++) {
stream.put(*(p + byteIndex)); stream.put(*(p + byteIndex));
} }
} }
constexpr uint32_t fourcc(unsigned char c0, unsigned char c1, unsigned char c2, unsigned char c3) { constexpr uint32_t fourcc(
unsigned char c0,
unsigned char c1,
unsigned char c2,
unsigned char c3
) {
return c0 | (c1 << 8) | (c2 << 16) | (c3 << 24); return c0 | (c1 << 8) | (c2 << 16) | (c3 << 24);
} }

View File

@ -3,7 +3,6 @@
using std::function; using std::function;
using std::vector; using std::vector;
using std::unique_ptr;
// Converts a float in the range -1..1 to a signed 16-bit int // Converts a float in the range -1..1 to a signed 16-bit int
inline int16_t floatSampleToInt16(float sample) { inline int16_t floatSampleToInt16(float sample) {
@ -12,13 +11,18 @@ inline int16_t floatSampleToInt16(float sample) {
return static_cast<int16_t>(((sample + 1) / 2) * (INT16_MAX - INT16_MIN) + INT16_MIN); return static_cast<int16_t>(((sample + 1) / 2) * (INT16_MAX - INT16_MIN) + INT16_MIN);
} }
void process16bitAudioClip(const AudioClip& audioClip, function<void(const vector<int16_t>&)> processBuffer, size_t bufferCapacity, ProgressSink& progressSink) { void process16bitAudioClip(
const AudioClip& audioClip,
const function<void(const vector<int16_t>&)>& processBuffer,
size_t bufferCapacity,
ProgressSink& progressSink
) {
// Process entire sound stream // Process entire sound stream
vector<int16_t> buffer; vector<int16_t> buffer;
buffer.reserve(bufferCapacity); buffer.reserve(bufferCapacity);
int sampleCount = 0; int sampleCount = 0;
auto it = audioClip.begin(); auto it = audioClip.begin();
auto end = audioClip.end(); const auto end = audioClip.end();
do { do {
// Read to buffer // Read to buffer
buffer.clear(); buffer.clear();
@ -32,10 +36,14 @@ void process16bitAudioClip(const AudioClip& audioClip, function<void(const vecto
sampleCount += buffer.size(); sampleCount += buffer.size();
progressSink.reportProgress(static_cast<double>(sampleCount) / audioClip.size()); progressSink.reportProgress(static_cast<double>(sampleCount) / audioClip.size());
} while (buffer.size()); } while (!buffer.empty());
} }
void process16bitAudioClip(const AudioClip& audioClip, function<void(const vector<int16_t>&)> processBuffer, ProgressSink& progressSink) { void process16bitAudioClip(
const AudioClip& audioClip,
const function<void(const vector<int16_t>&)>& processBuffer,
ProgressSink& progressSink
) {
const size_t capacity = 1600; // 0.1 second capacity const size_t capacity = 1600; // 0.1 second capacity
process16bitAudioClip(audioClip, processBuffer, capacity, progressSink); process16bitAudioClip(audioClip, processBuffer, capacity, progressSink);
} }
@ -46,5 +54,5 @@ vector<int16_t> copyTo16bitBuffer(const AudioClip& audioClip) {
for (float sample : audioClip) { for (float sample : audioClip) {
result[index++] = floatSampleToInt16(sample); result[index++] = floatSampleToInt16(sample);
} }
return std::move(result); return result;
} }

View File

@ -5,6 +5,17 @@
#include "AudioClip.h" #include "AudioClip.h"
#include "tools/progress.h" #include "tools/progress.h"
void process16bitAudioClip(const AudioClip& audioClip, std::function<void(const std::vector<int16_t>&)> processBuffer, size_t bufferCapacity, ProgressSink& progressSink); void process16bitAudioClip(
void process16bitAudioClip(const AudioClip& audioClip, std::function<void(const std::vector<int16_t>&)> processBuffer, ProgressSink& progressSink); const AudioClip& audioClip,
const std::function<void(const std::vector<int16_t>&)>& processBuffer,
size_t bufferCapacity,
ProgressSink& progressSink
);
void process16bitAudioClip(
const AudioClip& audioClip,
const std::function<void(const std::vector<int16_t>&)>& processBuffer,
ProgressSink& progressSink
);
std::vector<int16_t> copyTo16bitBuffer(const AudioClip& audioClip); std::vector<int16_t> copyTo16bitBuffer(const AudioClip& audioClip);

View File

@ -9,7 +9,6 @@
#include <gsl_util.h> #include <gsl_util.h>
#include "tools/parallel.h" #include "tools/parallel.h"
#include "AudioSegment.h" #include "AudioSegment.h"
#include "tools/stringTools.h"
using std::vector; using std::vector;
using boost::adaptors::transformed; using boost::adaptors::transformed;
@ -17,7 +16,10 @@ using fmt::format;
using std::runtime_error; using std::runtime_error;
using std::unique_ptr; using std::unique_ptr;
JoiningBoundedTimeline<void> webRtcDetectVoiceActivity(const AudioClip& audioClip, ProgressSink& progressSink) { JoiningBoundedTimeline<void> webRtcDetectVoiceActivity(
const AudioClip& audioClip,
ProgressSink& progressSink
) {
VadInst* vadHandle = WebRtcVad_Create(); VadInst* vadHandle = WebRtcVad_Create();
if (!vadHandle) throw runtime_error("Error creating WebRTC VAD handle."); if (!vadHandle) throw runtime_error("Error creating WebRTC VAD handle.");
@ -38,14 +40,19 @@ JoiningBoundedTimeline<void> webRtcDetectVoiceActivity(const AudioClip& audioCli
JoiningBoundedTimeline<void> activity(audioClip.getTruncatedRange()); JoiningBoundedTimeline<void> activity(audioClip.getTruncatedRange());
centiseconds time = 0_cs; centiseconds time = 0_cs;
const size_t bufferCapacity = audioClip.getSampleRate() / 100; const size_t bufferCapacity = audioClip.getSampleRate() / 100;
auto processBuffer = [&](const vector<int16_t>& buffer) { const auto processBuffer = [&](const vector<int16_t>& buffer) {
// WebRTC is picky regarding buffer size // WebRTC is picky regarding buffer size
if (buffer.size() < bufferCapacity) return; if (buffer.size() < bufferCapacity) return;
int result = WebRtcVad_Process(vadHandle, audioClip.getSampleRate(), buffer.data(), buffer.size()) == 1; const int result = WebRtcVad_Process(
vadHandle,
audioClip.getSampleRate(),
buffer.data(),
buffer.size()
) == 1;
if (result == -1) throw runtime_error("Error processing audio buffer using WebRTC VAD."); if (result == -1) throw runtime_error("Error processing audio buffer using WebRTC VAD.");
bool isActive = result != 0; const bool isActive = result != 0;
if (isActive) { if (isActive) {
activity.set(time, time + 1_cs); activity.set(time, time + 1_cs);
} }
@ -54,12 +61,14 @@ JoiningBoundedTimeline<void> webRtcDetectVoiceActivity(const AudioClip& audioCli
process16bitAudioClip(audioClip, processBuffer, bufferCapacity, pass1ProgressSink); process16bitAudioClip(audioClip, processBuffer, bufferCapacity, pass1ProgressSink);
// WebRTC adapts to the audio. This means results may not be correct at the very beginning. // WebRTC adapts to the audio. This means results may not be correct at the very beginning.
// It sometimes returns false activity at the very beginning, mistaking the background noise for speech. // It sometimes returns false activity at the very beginning, mistaking the background noise for
// speech.
// So we delete the first recognized utterance and re-process the corresponding audio segment. // So we delete the first recognized utterance and re-process the corresponding audio segment.
if (!activity.empty()) { if (!activity.empty()) {
TimeRange firstActivity = activity.begin()->getTimeRange(); TimeRange firstActivity = activity.begin()->getTimeRange();
activity.clear(firstActivity); activity.clear(firstActivity);
unique_ptr<AudioClip> streamStart = audioClip.clone() | segment(TimeRange(0_cs, firstActivity.getEnd())); const unique_ptr<AudioClip> streamStart = audioClip.clone()
| segment(TimeRange(0_cs, firstActivity.getEnd()));
time = 0_cs; time = 0_cs;
process16bitAudioClip(*streamStart, processBuffer, bufferCapacity, pass2ProgressSink); process16bitAudioClip(*streamStart, processBuffer, bufferCapacity, pass2ProgressSink);
} }
@ -67,24 +76,34 @@ JoiningBoundedTimeline<void> webRtcDetectVoiceActivity(const AudioClip& audioCli
return activity; return activity;
} }
JoiningBoundedTimeline<void> detectVoiceActivity(const AudioClip& inputAudioClip, int maxThreadCount, ProgressSink& progressSink) { JoiningBoundedTimeline<void> detectVoiceActivity(
const AudioClip& inputAudioClip,
int maxThreadCount,
ProgressSink& progressSink
) {
// Prepare audio for VAD // Prepare audio for VAD
const unique_ptr<AudioClip> audioClip = inputAudioClip.clone() | resample(16000) | removeDcOffset(); const unique_ptr<AudioClip> audioClip = inputAudioClip.clone()
| resample(16000)
| removeDcOffset();
JoiningBoundedTimeline<void> activity(audioClip->getTruncatedRange()); JoiningBoundedTimeline<void> activity(audioClip->getTruncatedRange());
std::mutex activityMutex; std::mutex activityMutex;
// Split audio into segments and perform parallel VAD // Split audio into segments and perform parallel VAD
const int segmentCount = maxThreadCount; const int segmentCount = maxThreadCount;
centiseconds audioDuration = audioClip->getTruncatedRange().getDuration(); const centiseconds audioDuration = audioClip->getTruncatedRange().getDuration();
vector<TimeRange> audioSegments; vector<TimeRange> audioSegments;
for (int i = 0; i < segmentCount; ++i) { for (int i = 0; i < segmentCount; ++i) {
TimeRange segmentRange = TimeRange(i * audioDuration / segmentCount, (i + 1) * audioDuration / segmentCount); TimeRange segmentRange = TimeRange(
i * audioDuration / segmentCount,
(i + 1) * audioDuration / segmentCount
);
audioSegments.push_back(segmentRange); audioSegments.push_back(segmentRange);
} }
runParallel([&](const TimeRange& segmentRange, ProgressSink& segmentProgressSink) { runParallel([&](const TimeRange& segmentRange, ProgressSink& segmentProgressSink) {
unique_ptr<AudioClip> audioSegment = audioClip->clone() | segment(segmentRange); const unique_ptr<AudioClip> audioSegment = audioClip->clone() | segment(segmentRange);
JoiningBoundedTimeline<void> activitySegment = webRtcDetectVoiceActivity(*audioSegment, segmentProgressSink); JoiningBoundedTimeline<void> activitySegment =
webRtcDetectVoiceActivity(*audioSegment, segmentProgressSink);
std::lock_guard<std::mutex> lock(activityMutex); std::lock_guard<std::mutex> lock(activityMutex);
for (auto activityRange : activitySegment) { for (auto activityRange : activitySegment) {
@ -109,8 +128,13 @@ JoiningBoundedTimeline<void> detectVoiceActivity(const AudioClip& inputAudioClip
} }
} }
logging::debugFormat("Found {} sections of voice activity: {}", activity.size(), logging::debugFormat(
join(activity | transformed([](const Timed<void>& t) { return format("{0}-{1}", t.getStart(), t.getEnd()); }), ", ")); "Found {} sections of voice activity: {}",
activity.size(),
join(activity | transformed([](const Timed<void>& t) {
return format("{0}-{1}", t.getStart(), t.getEnd());
}), ", ")
);
return activity; return activity;
} }

View File

@ -3,4 +3,8 @@
#include "time/BoundedTimeline.h" #include "time/BoundedTimeline.h"
#include "tools/progress.h" #include "tools/progress.h"
JoiningBoundedTimeline<void> detectVoiceActivity(const AudioClip& audioClip, int maxThreadCount, ProgressSink& progressSink); JoiningBoundedTimeline<void> detectVoiceActivity(
const AudioClip& audioClip,
int maxThreadCount,
ProgressSink& progressSink
);

View File

@ -12,26 +12,26 @@ void createWaveFile(const AudioClip& audioClip, std::string fileName) {
// Write RIFF chunk // Write RIFF chunk
write<uint32_t>(fourcc('R', 'I', 'F', 'F'), file); write<uint32_t>(fourcc('R', 'I', 'F', 'F'), file);
uint32_t formatChunkSize = 16; const uint32_t formatChunkSize = 16;
uint16_t channelCount = 1; const uint16_t channelCount = 1;
uint16_t frameSize = static_cast<uint16_t>(channelCount * sizeof(float)); const uint16_t frameSize = static_cast<uint16_t>(channelCount * sizeof(float));
uint32_t dataChunkSize = static_cast<uint32_t>(audioClip.size() * frameSize); const uint32_t dataChunkSize = static_cast<uint32_t>(audioClip.size() * frameSize);
uint32_t riffChunkSize = 4 + (8 + formatChunkSize) + (8 + dataChunkSize); const uint32_t riffChunkSize = 4 + (8 + formatChunkSize) + (8 + dataChunkSize);
write<uint32_t>(riffChunkSize, file); write<uint32_t>(riffChunkSize, file);
write<uint32_t>(fourcc('W', 'A', 'V', 'E'), file); write<uint32_t>(fourcc('W', 'A', 'V', 'E'), file);
// Write format chunk // Write format chunk
write<uint32_t>(fourcc('f', 'm', 't', ' '), file); write<uint32_t>(fourcc('f', 'm', 't', ' '), file);
write<uint32_t>(formatChunkSize, file); write<uint32_t>(formatChunkSize, file);
uint16_t codec = 0x03; // 32-bit float const uint16_t codec = 0x03; // 32-bit float
write<uint16_t>(codec, file); write<uint16_t>(codec, file);
write<uint16_t>(channelCount, file); write<uint16_t>(channelCount, file);
uint32_t frameRate = static_cast<uint16_t>(audioClip.getSampleRate()); const uint32_t frameRate = static_cast<uint16_t>(audioClip.getSampleRate());
write<uint32_t>(frameRate, file); write<uint32_t>(frameRate, file);
uint32_t bytesPerSecond = frameRate * frameSize; const uint32_t bytesPerSecond = frameRate * frameSize;
write<uint32_t>(bytesPerSecond, file); write<uint32_t>(bytesPerSecond, file);
write<uint16_t>(frameSize, file); write<uint16_t>(frameSize, file);
uint16_t bitsPerSample = 8 * sizeof(float); const uint16_t bitsPerSample = 8 * sizeof(float);
write<uint16_t>(bitsPerSample, file); write<uint16_t>(bitsPerSample, file);
// Write data chunk // Write data chunk

View File

@ -13,7 +13,7 @@ string PhoneConverter::getTypeName() {
} }
EnumConverter<Phone>::member_data PhoneConverter::getMemberData() { EnumConverter<Phone>::member_data PhoneConverter::getMemberData() {
return member_data{ return member_data {
{ Phone::AO, "AO" }, { Phone::AO, "AO" },
{ Phone::AA, "AA" }, { Phone::AA, "AA" },
{ Phone::IY, "IY" }, { Phone::IY, "IY" },

View File

@ -35,7 +35,7 @@ string ShapeConverter::getTypeName() {
} }
EnumConverter<Shape>::member_data ShapeConverter::getMemberData() { EnumConverter<Shape>::member_data ShapeConverter::getMemberData() {
return member_data{ return member_data {
{ Shape::A, "A" }, { Shape::A, "A" },
{ Shape::B, "B" }, { Shape::B, "B" },
{ Shape::C, "C" }, { Shape::C, "C" },

View File

@ -29,8 +29,8 @@ enum class Shape {
class ShapeConverter : public EnumConverter<Shape> { class ShapeConverter : public EnumConverter<Shape> {
public: public:
static ShapeConverter& get(); static ShapeConverter& get();
std::set<Shape> getBasicShapes(); static std::set<Shape> getBasicShapes();
std::set<Shape> getExtendedShapes(); static std::set<Shape> getExtendedShapes();
protected: protected:
std::string getTypeName() override; std::string getTypeName() override;
member_data getMemberData() override; member_data getMemberData() override;

View File

@ -6,7 +6,8 @@ using std::string;
void JsonExporter::exportAnimation(const ExporterInput& input, std::ostream& outputStream) { void JsonExporter::exportAnimation(const ExporterInput& input, std::ostream& outputStream) {
// Export as JSON. // Export as JSON.
// I'm not using a library because the code is short enough without one and it lets me control the formatting. // I'm not using a library because the code is short enough without one and it lets me control
// the formatting.
outputStream << "{\n"; outputStream << "{\n";
outputStream << " \"metadata\": {\n"; outputStream << " \"metadata\": {\n";
outputStream << " \"soundFile\": \"" << escapeJsonString(input.inputFilePath.string()) << "\",\n"; outputStream << " \"soundFile\": \"" << escapeJsonString(input.inputFilePath.string()) << "\",\n";

View File

@ -4,7 +4,11 @@
void TsvExporter::exportAnimation(const ExporterInput& input, std::ostream& outputStream) { void TsvExporter::exportAnimation(const ExporterInput& input, std::ostream& outputStream) {
// Output shapes with start times // Output shapes with start times
for (auto& timedShape : input.animation) { for (auto& timedShape : input.animation) {
outputStream << formatDuration(timedShape.getStart()) << "\t" << timedShape.getValue() << "\n"; outputStream
<< formatDuration(timedShape.getStart())
<< "\t"
<< timedShape.getValue()
<< "\n";
} }
// Output closed mouth with end time // Output closed mouth with end time

View File

@ -12,11 +12,17 @@ void XmlExporter::exportAnimation(const ExporterInput& input, std::ostream& outp
// Add metadata // Add metadata
tree.put("rhubarbResult.metadata.soundFile", input.inputFilePath.string()); tree.put("rhubarbResult.metadata.soundFile", input.inputFilePath.string());
tree.put("rhubarbResult.metadata.duration", formatDuration(input.animation.getRange().getDuration())); tree.put(
"rhubarbResult.metadata.duration",
formatDuration(input.animation.getRange().getDuration())
);
// Add mouth cues // Add mouth cues
for (auto& timedShape : dummyShapeIfEmpty(input.animation, input.targetShapeSet)) { for (auto& timedShape : dummyShapeIfEmpty(input.animation, input.targetShapeSet)) {
ptree& mouthCueElement = tree.add("rhubarbResult.mouthCues.mouthCue", timedShape.getValue()); ptree& mouthCueElement = tree.add(
"rhubarbResult.mouthCues.mouthCue",
timedShape.getValue()
);
mouthCueElement.put("<xmlattr>.start", formatDuration(timedShape.getStart())); mouthCueElement.put("<xmlattr>.start", formatDuration(timedShape.getStart()));
mouthCueElement.put("<xmlattr>.end", formatDuration(timedShape.getEnd())); mouthCueElement.put("<xmlattr>.end", formatDuration(timedShape.getEnd()));
} }

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@ -2,12 +2,15 @@
#include "animation/targetShapeSet.h" #include "animation/targetShapeSet.h"
// Makes sure there is at least one mouth shape // Makes sure there is at least one mouth shape
std::vector<Timed<Shape>> dummyShapeIfEmpty(const JoiningTimeline<Shape>& animation, const ShapeSet& targetShapeSet) { std::vector<Timed<Shape>> dummyShapeIfEmpty(
const JoiningTimeline<Shape>& animation,
const ShapeSet& targetShapeSet
) {
std::vector<Timed<Shape>> result; std::vector<Timed<Shape>> result;
std::copy(animation.begin(), animation.end(), std::back_inserter(result)); std::copy(animation.begin(), animation.end(), std::back_inserter(result));
if (result.empty()) { if (result.empty()) {
// Add zero-length empty mouth // Add zero-length empty mouth
result.push_back(Timed<Shape>(0_cs, 0_cs, convertToTargetShapeSet(Shape::X, targetShapeSet))); result.emplace_back(0_cs, 0_cs, convertToTargetShapeSet(Shape::X, targetShapeSet));
} }
return result; return result;
} }

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@ -4,4 +4,7 @@
#include "time/Timeline.h" #include "time/Timeline.h"
// Makes sure there is at least one mouth shape // Makes sure there is at least one mouth shape
std::vector<Timed<Shape>> dummyShapeIfEmpty(const JoiningTimeline<Shape>& animation, const ShapeSet& targetShapeSet); std::vector<Timed<Shape>> dummyShapeIfEmpty(
const JoiningTimeline<Shape>& animation,
const ShapeSet& targetShapeSet
);

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@ -22,12 +22,13 @@ namespace logging {
static int lastThreadId = 0; static int lastThreadId = 0;
thread_id threadId = std::this_thread::get_id(); thread_id threadId = std::this_thread::get_id();
if (threadCounters.find(threadId) == threadCounters.end()) { if (threadCounters.find(threadId) == threadCounters.end()) {
threadCounters.insert({threadId, ++lastThreadId}); threadCounters.insert({ threadId, ++lastThreadId });
} }
return threadCounters.find(threadId)->second; return threadCounters.find(threadId)->second;
} }
Entry::Entry(Level level, const string& message) : Entry::Entry(Level level, const string& message) :
timestamp(),
level(level), level(level),
message(message) message(message)
{ {

View File

@ -14,13 +14,13 @@ namespace logging {
} }
EnumConverter<Level>::member_data LevelConverter::getMemberData() { EnumConverter<Level>::member_data LevelConverter::getMemberData() {
return member_data{ return member_data {
{Level::Trace, "Trace"}, { Level::Trace, "Trace" },
{Level::Debug, "Debug"}, { Level::Debug, "Debug" },
{Level::Info, "Info"}, { Level::Info, "Info" },
{Level::Warn, "Warn"}, { Level::Warn, "Warn" },
{Level::Error, "Error"}, { Level::Error, "Error" },
{Level::Fatal, "Fatal"} { Level::Fatal, "Fatal" }
}; };
} }
@ -28,7 +28,7 @@ namespace logging {
return LevelConverter::get().write(stream, value); return LevelConverter::get().write(stream, value);
} }
std::istream& operator >> (std::istream& stream, Level& value) { std::istream& operator >>(std::istream& stream, Level& value) {
return LevelConverter::get().read(stream, value); return LevelConverter::get().read(stream, value);
} }

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@ -24,6 +24,6 @@ namespace logging {
std::ostream& operator<<(std::ostream& stream, Level value); std::ostream& operator<<(std::ostream& stream, Level value);
std::istream& operator >> (std::istream& stream, Level& value); std::istream& operator >>(std::istream& stream, Level& value);
} }

View File

@ -12,7 +12,12 @@ namespace logging {
} }
string SimpleFileFormatter::format(const Entry& entry) { string SimpleFileFormatter::format(const Entry& entry) {
return fmt::format("[{0}] {1} {2}", formatTime(entry.timestamp, "%F %H:%M:%S"), entry.threadCounter, consoleFormatter.format(entry)); return fmt::format(
"[{0}] {1} {2}",
formatTime(entry.timestamp, "%F %H:%M:%S"),
entry.threadCounter,
consoleFormatter.format(entry)
);
} }
} }

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@ -14,7 +14,7 @@ namespace logging {
void log(Level level, const std::string& message); void log(Level level, const std::string& message);
template <typename... Args> template<typename... Args>
void logFormat(Level level, fmt::CStringRef format, const Args&... args) { void logFormat(Level level, fmt::CStringRef format, const Args&... args) {
log(level, fmt::format(format, args...)); log(level, fmt::format(format, args...));
} }

View File

@ -3,7 +3,6 @@
#include "Entry.h" #include "Entry.h"
using std::string; using std::string;
using std::lock_guard;
using std::shared_ptr; using std::shared_ptr;
namespace logging { namespace logging {
@ -25,7 +24,7 @@ namespace logging {
{} {}
void StreamSink::receive(const Entry& entry) { void StreamSink::receive(const Entry& entry) {
string line = formatter->format(entry); const string line = formatter->format(entry);
*stream << line << std::endl; *stream << line << std::endl;
} }

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@ -3,7 +3,6 @@
#include "Sink.h" #include "Sink.h"
#include <memory> #include <memory>
#include "Formatter.h" #include "Formatter.h"
#include <mutex>
namespace logging { namespace logging {
enum class Level; enum class Level;

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@ -26,7 +26,8 @@ static lambda_unique_ptr<ps_decoder_t> createDecoder(optional<std::string> dialo
// High values (>= 1.0) can lead to imprecise or freezing animation. // High values (>= 1.0) can lead to imprecise or freezing animation.
"-lw", "0.8", "-lw", "0.8",
// The following settings are recommended at http://cmusphinx.sourceforge.net/wiki/phonemerecognition // The following settings are recommended at
// http://cmusphinx.sourceforge.net/wiki/phonemerecognition
// Set beam width applied to every frame in Viterbi search // Set beam width applied to every frame in Viterbi search
"-beam", "1e-20", "-beam", "1e-20",
@ -56,7 +57,9 @@ static Timeline<Phone> utteranceToPhones(
paddedTimeRange.grow(padding); paddedTimeRange.grow(padding);
paddedTimeRange.trim(audioClip.getTruncatedRange()); paddedTimeRange.trim(audioClip.getTruncatedRange());
const unique_ptr<AudioClip> clipSegment = audioClip.clone() | segment(paddedTimeRange) | resample(sphinxSampleRate); const unique_ptr<AudioClip> clipSegment = audioClip.clone()
| segment(paddedTimeRange)
| resample(sphinxSampleRate);
const auto audioBuffer = copyTo16bitBuffer(*clipSegment); const auto audioBuffer = copyTo16bitBuffer(*clipSegment);
// Detect phones (returned as words) // Detect phones (returned as words)

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@ -67,9 +67,15 @@ lambda_unique_ptr<ngram_model_t> createDefaultLanguageModel(ps_decoder_t& decode
return result; return result;
} }
lambda_unique_ptr<ngram_model_t> createDialogLanguageModel(ps_decoder_t& decoder, const string& dialog) { lambda_unique_ptr<ngram_model_t> createDialogLanguageModel(
ps_decoder_t& decoder,
const string& dialog
) {
// Split dialog into normalized words // Split dialog into normalized words
vector<string> words = tokenizeText(dialog, [&](const string& word) { return dictionaryContains(*decoder.dict, word); }); vector<string> words = tokenizeText(
dialog,
[&](const string& word) { return dictionaryContains(*decoder.dict, word); }
);
// Add dialog-specific words to the dictionary // Add dialog-specific words to the dictionary
addMissingDictionaryWords(words, decoder); addMissingDictionaryWords(words, decoder);
@ -80,15 +86,27 @@ lambda_unique_ptr<ngram_model_t> createDialogLanguageModel(ps_decoder_t& decoder
return createLanguageModel(words, decoder); return createLanguageModel(words, decoder);
} }
lambda_unique_ptr<ngram_model_t> createBiasedLanguageModel(ps_decoder_t& decoder, const string& dialog) { lambda_unique_ptr<ngram_model_t> createBiasedLanguageModel(
ps_decoder_t& decoder,
const string& dialog
) {
auto defaultLanguageModel = createDefaultLanguageModel(decoder); auto defaultLanguageModel = createDefaultLanguageModel(decoder);
auto dialogLanguageModel = createDialogLanguageModel(decoder, dialog); auto dialogLanguageModel = createDialogLanguageModel(decoder, dialog);
constexpr int modelCount = 2; constexpr int modelCount = 2;
array<ngram_model_t*, modelCount> languageModels{ defaultLanguageModel.get(), dialogLanguageModel.get() }; array<ngram_model_t*, modelCount> languageModels {
array<const char*, modelCount> modelNames{ "defaultLM", "dialogLM" }; defaultLanguageModel.get(),
array<float, modelCount> modelWeights{ 0.1f, 0.9f }; dialogLanguageModel.get()
};
array<const char*, modelCount> modelNames { "defaultLM", "dialogLM" };
array<float, modelCount> modelWeights { 0.1f, 0.9f };
lambda_unique_ptr<ngram_model_t> result( lambda_unique_ptr<ngram_model_t> result(
ngram_model_set_init(nullptr, languageModels.data(), const_cast<char**>(modelNames.data()), modelWeights.data(), modelCount), ngram_model_set_init(
nullptr,
languageModels.data(),
const_cast<char**>(modelNames.data()),
modelWeights.data(),
modelCount
),
[](ngram_model_t* lm) { ngram_model_free(lm); }); [](ngram_model_t* lm) { ngram_model_free(lm); });
if (!result) { if (!result) {
throw runtime_error("Error creating biased language model."); throw runtime_error("Error creating biased language model.");
@ -105,7 +123,8 @@ static lambda_unique_ptr<ps_decoder_t> createDecoder(optional<std::string> dialo
"-hmm", (getSphinxModelDirectory() / "acoustic-model").string().c_str(), "-hmm", (getSphinxModelDirectory() / "acoustic-model").string().c_str(),
// Set pronunciation dictionary // Set pronunciation dictionary
"-dict", (getSphinxModelDirectory() / "cmudict-en-us.dict").string().c_str(), "-dict", (getSphinxModelDirectory() / "cmudict-en-us.dict").string().c_str(),
// Add noise against zero silence (see http://cmusphinx.sourceforge.net/wiki/faq#qwhy_my_accuracy_is_poor) // Add noise against zero silence
// (see http://cmusphinx.sourceforge.net/wiki/faq#qwhy_my_accuracy_is_poor)
"-dither", "yes", "-dither", "yes",
// Disable VAD -- we're doing that ourselves // Disable VAD -- we're doing that ourselves
"-remove_silence", "no", "-remove_silence", "no",
@ -184,7 +203,11 @@ optional<Timeline<Phone>> getPhoneAlignment(
// Extract phones with timestamps // Extract phones with timestamps
char** phoneNames = decoder.dict->mdef->ciname; char** phoneNames = decoder.dict->mdef->ciname;
Timeline<Phone> result; Timeline<Phone> result;
for (ps_alignment_iter_t* it = ps_alignment_phones(alignment.get()); it; it = ps_alignment_iter_next(it)) { for (
ps_alignment_iter_t* it = ps_alignment_phones(alignment.get());
it;
it = ps_alignment_iter_next(it)
) {
// Get phone // Get phone
ps_alignment_entry_t* phoneEntry = ps_alignment_iter_get(it); ps_alignment_entry_t* phoneEntry = ps_alignment_iter_get(it);
const s3cipid_t phoneId = phoneEntry->id.pid.cipid; const s3cipid_t phoneId = phoneEntry->id.pid.cipid;
@ -209,7 +232,7 @@ optional<Timeline<Phone>> getPhoneAlignment(
// Some words have multiple pronunciations, one of which results in better animation than the others. // Some words have multiple pronunciations, one of which results in better animation than the others.
// This function returns the optimal pronunciation for a select set of these words. // This function returns the optimal pronunciation for a select set of these words.
string fixPronunciation(const string& word) { string fixPronunciation(const string& word) {
const static map<string, string> replacements{ const static map<string, string> replacements {
{ "into(2)", "into" }, { "into(2)", "into" },
{ "to(2)", "to" }, { "to(2)", "to" },
{ "to(3)", "to" }, { "to(3)", "to" },
@ -238,7 +261,9 @@ static Timeline<Phone> utteranceToPhones(
paddedTimeRange.grow(padding); paddedTimeRange.grow(padding);
paddedTimeRange.trim(audioClip.getTruncatedRange()); paddedTimeRange.trim(audioClip.getTruncatedRange());
const unique_ptr<AudioClip> clipSegment = audioClip.clone() | segment(paddedTimeRange) | resample(sphinxSampleRate); const unique_ptr<AudioClip> clipSegment = audioClip.clone()
| segment(paddedTimeRange)
| resample(sphinxSampleRate);
const auto audioBuffer = copyTo16bitBuffer(*clipSegment); const auto audioBuffer = copyTo16bitBuffer(*clipSegment);
// Get words // Get words
@ -273,7 +298,7 @@ static Timeline<Phone> utteranceToPhones(
const string fixedWord = fixPronunciation(timedWord.getValue()); const string fixedWord = fixPronunciation(timedWord.getValue());
wordIds.push_back(getWordId(fixedWord, *decoder.dict)); wordIds.push_back(getWordId(fixedWord, *decoder.dict));
} }
if (wordIds.empty()) return{}; if (wordIds.empty()) return {};
// Align the words' phones with speech // Align the words' phones with speech
#if BOOST_VERSION < 105600 // Support legacy syntax #if BOOST_VERSION < 105600 // Support legacy syntax
@ -309,5 +334,6 @@ BoundedTimeline<Phone> PocketSphinxRecognizer::recognizePhones(
int maxThreadCount, int maxThreadCount,
ProgressSink& progressSink ProgressSink& progressSink
) const { ) const {
return ::recognizePhones(inputAudioClip, dialog, &createDecoder, &utteranceToPhones, maxThreadCount, progressSink); return ::recognizePhones(
inputAudioClip, dialog, &createDecoder, &utteranceToPhones, maxThreadCount, progressSink);
} }

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@ -9,7 +9,7 @@ class Recognizer {
public: public:
virtual ~Recognizer() = default; virtual ~Recognizer() = default;
virtual BoundedTimeline<Phone>recognizePhones( virtual BoundedTimeline<Phone> recognizePhones(
const AudioClip& audioClip, const AudioClip& audioClip,
boost::optional<std::string> dialog, boost::optional<std::string> dialog,
int maxThreadCount, int maxThreadCount,

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@ -64,8 +64,9 @@ Phone charToPhone(wchar_t c) {
case L'r': return Phone::R; case L'r': return Phone::R;
case L'l': return Phone::L; case L'l': return Phone::L;
case L'h': return Phone::HH; case L'h': return Phone::HH;
default:
return Phone::Noise;
} }
return Phone::Noise;
} }
vector<Phone> wordToPhones(const std::string& word) { vector<Phone> wordToPhones(const std::string& word) {
@ -94,8 +95,11 @@ vector<Phone> wordToPhones(const std::string& word) {
for (wchar_t c : wideWord) { for (wchar_t c : wideWord) {
Phone phone = charToPhone(c); Phone phone = charToPhone(c);
if (phone == Phone::Noise) { if (phone == Phone::Noise) {
logging::errorFormat("G2P error determining pronunciation for '{}': Character '{}' is not a recognized phone shorthand.", logging::errorFormat(
word, static_cast<char>(c)); "G2P error determining pronunciation for '{}': Character '{}' is not a recognized phone shorthand.",
word,
static_cast<char>(c)
);
} }
if (phone != lastPhone) { if (phone != lastPhone) {

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@ -15,83 +15,94 @@ using std::vector;
using std::regex; using std::regex;
using std::map; using std::map;
using std::tuple; using std::tuple;
using std::make_tuple;
using std::get; using std::get;
using std::endl; using std::endl;
using boost::filesystem::path; using boost::filesystem::path;
using unigram_t = string; using Unigram = string;
using bigram_t = tuple<string, string>; using Bigram = tuple<string, string>;
using trigram_t = tuple<string, string, string>; using Trigram = tuple<string, string, string>;
map<unigram_t, int> getUnigramCounts(const vector<string>& words) { map<Unigram, int> getUnigramCounts(const vector<string>& words) {
map<unigram_t, int> unigramCounts; map<Unigram, int> unigramCounts;
for (const unigram_t& unigram : words) { for (const Unigram& unigram : words) {
++unigramCounts[unigram]; ++unigramCounts[unigram];
} }
return unigramCounts; return unigramCounts;
} }
map<bigram_t, int> getBigramCounts(const vector<string>& words) { map<Bigram, int> getBigramCounts(const vector<string>& words) {
map<bigram_t, int> bigramCounts; map<Bigram, int> bigramCounts;
for (auto it = words.begin(); it < words.end() - 1; ++it) { for (auto it = words.begin(); it < words.end() - 1; ++it) {
++bigramCounts[bigram_t(*it, *(it + 1))]; ++bigramCounts[Bigram(*it, *(it + 1))];
} }
return bigramCounts; return bigramCounts;
} }
map<trigram_t, int> getTrigramCounts(const vector<string>& words) { map<Trigram, int> getTrigramCounts(const vector<string>& words) {
map<trigram_t, int> trigramCounts; map<Trigram, int> trigramCounts;
if (words.size() >= 3) { if (words.size() >= 3) {
for (auto it = words.begin(); it < words.end() - 2; ++it) { for (auto it = words.begin(); it < words.end() - 2; ++it) {
++trigramCounts[trigram_t(*it, *(it + 1), *(it + 2))]; ++trigramCounts[Trigram(*it, *(it + 1), *(it + 2))];
} }
} }
return trigramCounts; return trigramCounts;
} }
map<unigram_t, double> getUnigramProbabilities(const vector<string>& words, const map<unigram_t, int>& unigramCounts, const double deflator) { map<Unigram, double> getUnigramProbabilities(
map<unigram_t, double> unigramProbabilities; const vector<string>& words,
const map<Unigram, int>& unigramCounts,
const double deflator
) {
map<Unigram, double> unigramProbabilities;
for (const auto& pair : unigramCounts) { for (const auto& pair : unigramCounts) {
unigram_t unigram = get<0>(pair); const Unigram& unigram = get<0>(pair);
int unigramCount = get<1>(pair); const int unigramCount = get<1>(pair);
unigramProbabilities[unigram] = double(unigramCount) / words.size() * deflator; unigramProbabilities[unigram] = double(unigramCount) / words.size() * deflator;
} }
return unigramProbabilities; return unigramProbabilities;
} }
map<bigram_t, double> getBigramProbabilities(const map<unigram_t, int>& unigramCounts, const map<bigram_t, int>& bigramCounts, const double deflator) { map<Bigram, double> getBigramProbabilities(
map<bigram_t, double> bigramProbabilities; const map<Unigram, int>& unigramCounts,
const map<Bigram, int>& bigramCounts,
const double deflator
) {
map<Bigram, double> bigramProbabilities;
for (const auto& pair : bigramCounts) { for (const auto& pair : bigramCounts) {
bigram_t bigram = get<0>(pair); Bigram bigram = get<0>(pair);
int bigramCount = get<1>(pair); const int bigramCount = get<1>(pair);
int unigramPrefixCount = unigramCounts.at(get<0>(bigram)); const int unigramPrefixCount = unigramCounts.at(get<0>(bigram));
bigramProbabilities[bigram] = double(bigramCount) / unigramPrefixCount * deflator; bigramProbabilities[bigram] = double(bigramCount) / unigramPrefixCount * deflator;
} }
return bigramProbabilities; return bigramProbabilities;
} }
map<trigram_t, double> getTrigramProbabilities(const map<bigram_t, int>& bigramCounts, const map<trigram_t, int>& trigramCounts, const double deflator) { map<Trigram, double> getTrigramProbabilities(
map<trigram_t, double> trigramProbabilities; const map<Bigram, int>& bigramCounts,
const map<Trigram, int>& trigramCounts,
const double deflator
) {
map<Trigram, double> trigramProbabilities;
for (const auto& pair : trigramCounts) { for (const auto& pair : trigramCounts) {
trigram_t trigram = get<0>(pair); Trigram trigram = get<0>(pair);
int trigramCount = get<1>(pair); const int trigramCount = get<1>(pair);
int bigramPrefixCount = bigramCounts.at(bigram_t(get<0>(trigram), get<1>(trigram))); const int bigramPrefixCount = bigramCounts.at(Bigram(get<0>(trigram), get<1>(trigram)));
trigramProbabilities[trigram] = double(trigramCount) / bigramPrefixCount * deflator; trigramProbabilities[trigram] = double(trigramCount) / bigramPrefixCount * deflator;
} }
return trigramProbabilities; return trigramProbabilities;
} }
map<unigram_t, double> getUnigramBackoffWeights( map<Unigram, double> getUnigramBackoffWeights(
const map<unigram_t, int>& unigramCounts, const map<Unigram, int>& unigramCounts,
const map<unigram_t, double>& unigramProbabilities, const map<Unigram, double>& unigramProbabilities,
const map<bigram_t, int>& bigramCounts, const map<Bigram, int>& bigramCounts,
const double discountMass) const double discountMass)
{ {
map<unigram_t, double> unigramBackoffWeights; map<Unigram, double> unigramBackoffWeights;
for (const unigram_t& unigram : unigramCounts | boost::adaptors::map_keys) { for (const Unigram& unigram : unigramCounts | boost::adaptors::map_keys) {
double denominator = 1; double denominator = 1;
for (const bigram_t& bigram : bigramCounts | boost::adaptors::map_keys) { for (const Bigram& bigram : bigramCounts | boost::adaptors::map_keys) {
if (get<0>(bigram) == unigram) { if (get<0>(bigram) == unigram) {
denominator -= unigramProbabilities.at(get<1>(bigram)); denominator -= unigramProbabilities.at(get<1>(bigram));
} }
@ -101,18 +112,18 @@ map<unigram_t, double> getUnigramBackoffWeights(
return unigramBackoffWeights; return unigramBackoffWeights;
} }
map<bigram_t, double> getBigramBackoffWeights( map<Bigram, double> getBigramBackoffWeights(
const map<bigram_t, int>& bigramCounts, const map<Bigram, int>& bigramCounts,
const map<bigram_t, double>& bigramProbabilities, const map<Bigram, double>& bigramProbabilities,
const map<trigram_t, int>& trigramCounts, const map<Trigram, int>& trigramCounts,
const double discountMass) const double discountMass)
{ {
map<bigram_t, double> bigramBackoffWeights; map<Bigram, double> bigramBackoffWeights;
for (const bigram_t& bigram : bigramCounts | boost::adaptors::map_keys) { for (const Bigram& bigram : bigramCounts | boost::adaptors::map_keys) {
double denominator = 1; double denominator = 1;
for (const trigram_t& trigram : trigramCounts | boost::adaptors::map_keys) { for (const Trigram& trigram : trigramCounts | boost::adaptors::map_keys) {
if (bigram_t(get<0>(trigram), get<1>(trigram)) == bigram) { if (Bigram(get<0>(trigram), get<1>(trigram)) == bigram) {
denominator -= bigramProbabilities.at(bigram_t(get<1>(trigram), get<2>(trigram))); denominator -= bigramProbabilities.at(Bigram(get<1>(trigram), get<2>(trigram)));
} }
} }
bigramBackoffWeights[bigram] = discountMass / denominator; bigramBackoffWeights[bigram] = discountMass / denominator;
@ -120,20 +131,25 @@ map<bigram_t, double> getBigramBackoffWeights(
return bigramBackoffWeights; return bigramBackoffWeights;
} }
void createLanguageModelFile(const vector<string>& words, path filePath) { void createLanguageModelFile(const vector<string>& words, const path& filePath) {
const double discountMass = 0.5; const double discountMass = 0.5;
const double deflator = 1.0 - discountMass; const double deflator = 1.0 - discountMass;
map<unigram_t, int> unigramCounts = getUnigramCounts(words); map<Unigram, int> unigramCounts = getUnigramCounts(words);
map<bigram_t, int> bigramCounts = getBigramCounts(words); map<Bigram, int> bigramCounts = getBigramCounts(words);
map<trigram_t, int> trigramCounts = getTrigramCounts(words); map<Trigram, int> trigramCounts = getTrigramCounts(words);
map<unigram_t, double> unigramProbabilities = getUnigramProbabilities(words, unigramCounts, deflator); map<Unigram, double> unigramProbabilities =
map<bigram_t, double> bigramProbabilities = getBigramProbabilities(unigramCounts, bigramCounts, deflator); getUnigramProbabilities(words, unigramCounts, deflator);
map<trigram_t, double> trigramProbabilities = getTrigramProbabilities(bigramCounts, trigramCounts, deflator); map<Bigram, double> bigramProbabilities =
getBigramProbabilities(unigramCounts, bigramCounts, deflator);
map<Trigram, double> trigramProbabilities =
getTrigramProbabilities(bigramCounts, trigramCounts, deflator);
map<unigram_t, double> unigramBackoffWeights = getUnigramBackoffWeights(unigramCounts, unigramProbabilities, bigramCounts, discountMass); map<Unigram, double> unigramBackoffWeights =
map<bigram_t, double> bigramBackoffWeights = getBigramBackoffWeights(bigramCounts, bigramProbabilities, trigramCounts, discountMass); getUnigramBackoffWeights(unigramCounts, unigramProbabilities, bigramCounts, discountMass);
map<Bigram, double> bigramBackoffWeights =
getBigramBackoffWeights(bigramCounts, bigramProbabilities, trigramCounts, discountMass);
boost::filesystem::ofstream file(filePath); boost::filesystem::ofstream file(filePath);
file << "Generated by " << appName << " " << appVersion << endl << endl; file << "Generated by " << appName << " " << appVersion << endl << endl;
@ -146,7 +162,7 @@ void createLanguageModelFile(const vector<string>& words, path filePath) {
file.setf(std::ios::fixed, std::ios::floatfield); file.setf(std::ios::fixed, std::ios::floatfield);
file.precision(4); file.precision(4);
file << "\\1-grams:" << endl; file << "\\1-grams:" << endl;
for (const unigram_t& unigram : unigramCounts | boost::adaptors::map_keys) { for (const Unigram& unigram : unigramCounts | boost::adaptors::map_keys) {
file << log10(unigramProbabilities.at(unigram)) file << log10(unigramProbabilities.at(unigram))
<< " " << unigram << " " << unigram
<< " " << log10(unigramBackoffWeights.at(unigram)) << endl; << " " << log10(unigramBackoffWeights.at(unigram)) << endl;
@ -154,7 +170,7 @@ void createLanguageModelFile(const vector<string>& words, path filePath) {
file << endl; file << endl;
file << "\\2-grams:" << endl; file << "\\2-grams:" << endl;
for (const bigram_t& bigram : bigramCounts | boost::adaptors::map_keys) { for (const Bigram& bigram : bigramCounts | boost::adaptors::map_keys) {
file << log10(bigramProbabilities.at(bigram)) file << log10(bigramProbabilities.at(bigram))
<< " " << get<0>(bigram) << " " << get<1>(bigram) << " " << get<0>(bigram) << " " << get<1>(bigram)
<< " " << log10(bigramBackoffWeights.at(bigram)) << endl; << " " << log10(bigramBackoffWeights.at(bigram)) << endl;
@ -162,7 +178,7 @@ void createLanguageModelFile(const vector<string>& words, path filePath) {
file << endl; file << endl;
file << "\\3-grams:" << endl; file << "\\3-grams:" << endl;
for (const trigram_t& trigram : trigramCounts | boost::adaptors::map_keys) { for (const Trigram& trigram : trigramCounts | boost::adaptors::map_keys) {
file << log10(trigramProbabilities.at(trigram)) file << log10(trigramProbabilities.at(trigram))
<< " " << get<0>(trigram) << " " << get<1>(trigram) << " " << get<2>(trigram) << endl; << " " << get<0>(trigram) << " " << get<1>(trigram) << " " << get<2>(trigram) << endl;
} }
@ -171,7 +187,10 @@ void createLanguageModelFile(const vector<string>& words, path filePath) {
file << "\\end\\" << endl; file << "\\end\\" << endl;
} }
lambda_unique_ptr<ngram_model_t> createLanguageModel(const vector<string>& words, ps_decoder_t& decoder) { lambda_unique_ptr<ngram_model_t> createLanguageModel(
const vector<string>& words,
ps_decoder_t& decoder
) {
path tempFilePath = getTempFilePath(); path tempFilePath = getTempFilePath();
createLanguageModelFile(words, tempFilePath); createLanguageModelFile(words, tempFilePath);
auto deleteTempFile = gsl::finally([&]() { boost::filesystem::remove(tempFilePath); }); auto deleteTempFile = gsl::finally([&]() { boost::filesystem::remove(tempFilePath); });

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@ -8,4 +8,7 @@ extern "C" {
#include <ngram_search.h> #include <ngram_search.h>
} }
lambda_unique_ptr<ngram_model_t> createLanguageModel(const std::vector<std::string>& words, ps_decoder_t& decoder); lambda_unique_ptr<ngram_model_t> createLanguageModel(
const std::vector<std::string>& words,
ps_decoder_t& decoder
);

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@ -26,18 +26,18 @@ using std::chrono::duration_cast;
logging::Level convertSphinxErrorLevel(err_lvl_t errorLevel) { logging::Level convertSphinxErrorLevel(err_lvl_t errorLevel) {
switch (errorLevel) { switch (errorLevel) {
case ERR_DEBUG: case ERR_DEBUG:
case ERR_INFO: case ERR_INFO:
case ERR_INFOCONT: case ERR_INFOCONT:
return logging::Level::Trace; return logging::Level::Trace;
case ERR_WARN: case ERR_WARN:
return logging::Level::Warn; return logging::Level::Warn;
case ERR_ERROR: case ERR_ERROR:
return logging::Level::Error; return logging::Level::Error;
case ERR_FATAL: case ERR_FATAL:
return logging::Level::Fatal; return logging::Level::Fatal;
default: default:
throw invalid_argument("Unknown log level."); throw invalid_argument("Unknown log level.");
} }
} }
@ -61,7 +61,8 @@ void sphinxLogCallback(void* user_data, err_lvl_t errorLevel, const char* format
if (!success) chars.resize(chars.size() * 2); if (!success) chars.resize(chars.size() * 2);
} }
const regex waste("^(DEBUG|INFO|INFOCONT|WARN|ERROR|FATAL): "); const regex waste("^(DEBUG|INFO|INFOCONT|WARN|ERROR|FATAL): ");
string message = std::regex_replace(chars.data(), waste, "", std::regex_constants::format_first_only); string message =
std::regex_replace(chars.data(), waste, "", std::regex_constants::format_first_only);
boost::algorithm::trim(message); boost::algorithm::trim(message);
const logging::Level logLevel = convertSphinxErrorLevel(errorLevel); const logging::Level logLevel = convertSphinxErrorLevel(errorLevel);
@ -115,8 +116,12 @@ BoundedTimeline<Phone> recognizePhones(
const auto processUtterance = [&](Timed<void> timedUtterance, ProgressSink& utteranceProgressSink) { const auto processUtterance = [&](Timed<void> timedUtterance, ProgressSink& utteranceProgressSink) {
// Detect phones for utterance // Detect phones for utterance
const auto decoder = decoderPool.acquire(); const auto decoder = decoderPool.acquire();
Timeline<Phone> utterancePhones = Timeline<Phone> utterancePhones = utteranceToPhones(
utteranceToPhones(*audioClip, timedUtterance.getTimeRange(), *decoder, utteranceProgressSink); *audioClip,
timedUtterance.getTimeRange(),
*decoder,
utteranceProgressSink
);
// Copy phones to result timeline // Copy phones to result timeline
std::lock_guard<std::mutex> lock(resultMutex); std::lock_guard<std::mutex> lock(resultMutex);
@ -137,13 +142,21 @@ BoundedTimeline<Phone> recognizePhones(
// Don't use more threads than there are utterances to be processed // Don't use more threads than there are utterances to be processed
static_cast<int>(utterances.size()), static_cast<int>(utterances.size()),
// Don't waste time creating additional threads (and decoders!) if the recording is short // Don't waste time creating additional threads (and decoders!) if the recording is short
static_cast<int>(duration_cast<std::chrono::seconds>(audioClip->getTruncatedRange().getDuration()).count() / 5) static_cast<int>(
duration_cast<std::chrono::seconds>(audioClip->getTruncatedRange().getDuration()).count() / 5
)
}); });
if (threadCount < 1) { if (threadCount < 1) {
threadCount = 1; threadCount = 1;
} }
logging::debugFormat("Speech recognition using {} threads -- start", threadCount); logging::debugFormat("Speech recognition using {} threads -- start", threadCount);
runParallel(processUtterance, utterances, threadCount, dialogProgressSink, getUtteranceProgressWeight); runParallel(
processUtterance,
utterances,
threadCount,
dialogProgressSink,
getUtteranceProgressWeight
);
logging::debug("Speech recognition -- end"); logging::debug("Speech recognition -- end");
} catch (...) { } catch (...) {
std::throw_with_nested(runtime_error("Error performing speech recognition via PocketSphinx.")); std::throw_with_nested(runtime_error("Error performing speech recognition via PocketSphinx."));
@ -200,7 +213,9 @@ BoundedTimeline<string> recognizeWords(const vector<int16_t>& audioBuffer, ps_de
error = ps_end_utt(&decoder); error = ps_end_utt(&decoder);
if (error) throw runtime_error("Error ending utterance processing for word recognition."); if (error) throw runtime_error("Error ending utterance processing for word recognition.");
BoundedTimeline<string> result(TimeRange(0_cs, centiseconds(100 * audioBuffer.size() / sphinxSampleRate))); BoundedTimeline<string> result(
TimeRange(0_cs, centiseconds(100 * audioBuffer.size() / sphinxSampleRate))
);
const bool noWordsRecognized = reinterpret_cast<ngram_search_t*>(decoder.search)->bpidx == 0; const bool noWordsRecognized = reinterpret_cast<ngram_search_t*>(decoder.search)->bpidx == 0;
if (noWordsRecognized) { if (noWordsRecognized) {
return result; return result;

View File

@ -36,4 +36,7 @@ const boost::filesystem::path& getSphinxModelDirectory();
JoiningTimeline<void> getNoiseSounds(TimeRange utteranceTimeRange, const Timeline<Phone>& phones); JoiningTimeline<void> getNoiseSounds(TimeRange utteranceTimeRange, const Timeline<Phone>& phones);
BoundedTimeline<std::string> recognizeWords(const std::vector<int16_t>& audioBuffer, ps_decoder_t& decoder); BoundedTimeline<std::string> recognizeWords(
const std::vector<int16_t>& audioBuffer,
ps_decoder_t& decoder
);

View File

@ -2,6 +2,7 @@
#include "tools/tools.h" #include "tools/tools.h"
#include "tools/stringTools.h" #include "tools/stringTools.h"
#include <regex> #include <regex>
#include <boost/optional/optional.hpp>
extern "C" { extern "C" {
#include <cst_utt_utils.h> #include <cst_utt_utils.h>
@ -21,7 +22,7 @@ lambda_unique_ptr<cst_voice> createDummyVoice() {
lambda_unique_ptr<cst_voice> voice(new_voice(), [](cst_voice* voice) { delete_voice(voice); }); lambda_unique_ptr<cst_voice> voice(new_voice(), [](cst_voice* voice) { delete_voice(voice); });
voice->name = "dummy_voice"; voice->name = "dummy_voice";
usenglish_init(voice.get()); usenglish_init(voice.get());
cst_lexicon *lexicon = cmu_lex_init(); cst_lexicon* lexicon = cmu_lex_init();
feat_set(voice->features, "lexicon", lexicon_val(lexicon)); feat_set(voice->features, "lexicon", lexicon_val(lexicon));
return voice; return voice;
} }
@ -37,7 +38,10 @@ vector<string> tokenizeViaFlite(const string& text) {
const string asciiText = utf8ToAscii(text); const string asciiText = utf8ToAscii(text);
// Create utterance object with text // Create utterance object with text
lambda_unique_ptr<cst_utterance> utterance(new_utterance(), [](cst_utterance* utterance) { delete_utterance(utterance); }); lambda_unique_ptr<cst_utterance> utterance(
new_utterance(),
[](cst_utterance* utterance) { delete_utterance(utterance); }
);
utt_set_input_text(utterance.get(), asciiText.c_str()); utt_set_input_text(utterance.get(), asciiText.c_str());
lambda_unique_ptr<cst_voice> voice = createDummyVoice(); lambda_unique_ptr<cst_voice> voice = createDummyVoice();
utt_init(utterance.get(), voice.get()); utt_init(utterance.get(), voice.get());
@ -48,14 +52,21 @@ vector<string> tokenizeViaFlite(const string& text) {
} }
vector<string> result; vector<string> result;
for (cst_item* item = relation_head(utt_relation(utterance.get(), "Word")); item; item = item_next(item)) { for (
cst_item* item = relation_head(utt_relation(utterance.get(), "Word"));
item;
item = item_next(item)
) {
const char* word = item_feat_string(item, "name"); const char* word = item_feat_string(item, "name");
result.push_back(word); result.emplace_back(word);
} }
return result; return result;
} }
optional<string> findSimilarDictionaryWord(const string& word, function<bool(const string&)> dictionaryContains) { optional<string> findSimilarDictionaryWord(
const string& word,
const function<bool(const string&)>& dictionaryContains
) {
for (bool addPeriod : { false, true }) { for (bool addPeriod : { false, true }) {
for (int apostropheIndex = -1; apostropheIndex <= static_cast<int>(word.size()); ++apostropheIndex) { for (int apostropheIndex = -1; apostropheIndex <= static_cast<int>(word.size()); ++apostropheIndex) {
string modified = word; string modified = word;
@ -75,12 +86,15 @@ optional<string> findSimilarDictionaryWord(const string& word, function<bool(con
return boost::none; return boost::none;
} }
vector<string> tokenizeText(const string& text, function<bool(const string&)> dictionaryContains) { vector<string> tokenizeText(
const string& text,
const function<bool(const string&)>& dictionaryContains
) {
vector<string> words = tokenizeViaFlite(text); vector<string> words = tokenizeViaFlite(text);
// Join words separated by apostophes // Join words separated by apostrophes
for (int i = words.size() - 1; i > 0; --i) { for (int i = words.size() - 1; i > 0; --i) {
if (words[i].size() > 0 && words[i][0] == '\'') { if (!words[i].empty() && words[i][0] == '\'') {
words[i - 1].append(words[i]); words[i - 1].append(words[i]);
words.erase(words.begin() + i); words.erase(words.begin() + i);
} }
@ -95,21 +109,24 @@ vector<string> tokenizeText(const string& text, function<bool(const string&)> di
{ regex("@"), "at" }, { regex("@"), "at" },
{ regex("[^a-z']"), "" } { regex("[^a-z']"), "" }
}; };
for (size_t i = 0; i < words.size(); ++i) { for (auto& word : words) {
for (const auto& replacement : replacements) { for (const auto& replacement : replacements) {
words[i] = regex_replace(words[i], replacement.first, replacement.second); word = regex_replace(word, replacement.first, replacement.second);
} }
} }
// Remove empty words // Remove empty words
words.erase(std::remove_if(words.begin(), words.end(), [](const string& s) { return s.empty(); }), words.end()); words.erase(
std::remove_if(words.begin(), words.end(), [](const string& s) { return s.empty(); }),
words.end()
);
// Try to replace words that are not in the dictionary with similar ones that are // Try to replace words that are not in the dictionary with similar ones that are
for (size_t i = 0; i < words.size(); ++i) { for (auto& word : words) {
if (!dictionaryContains(words[i])) { if (!dictionaryContains(word)) {
optional<string> modifiedWord = findSimilarDictionaryWord(words[i], dictionaryContains); optional<string> modifiedWord = findSimilarDictionaryWord(word, dictionaryContains);
if (modifiedWord) { if (modifiedWord) {
words[i] = *modifiedWord; word = *modifiedWord;
} }
} }
} }

View File

@ -4,4 +4,7 @@
#include <functional> #include <functional>
#include <string> #include <string>
std::vector<std::string> tokenizeText(const std::string& text, std::function<bool(const std::string&)> dictionaryContains); std::vector<std::string> tokenizeText(
const std::string& text,
const std::function<bool(const std::string&)>& dictionaryContains
);

View File

@ -12,7 +12,7 @@ string ExportFormatConverter::getTypeName() {
} }
EnumConverter<ExportFormat>::member_data ExportFormatConverter::getMemberData() { EnumConverter<ExportFormat>::member_data ExportFormatConverter::getMemberData() {
return member_data{ return member_data {
{ ExportFormat::Tsv, "tsv" }, { ExportFormat::Tsv, "tsv" },
{ ExportFormat::Xml, "xml" }, { ExportFormat::Xml, "xml" },
{ ExportFormat::Json, "json" } { ExportFormat::Json, "json" }

View File

@ -12,7 +12,7 @@ string RecognizerTypeConverter::getTypeName() {
} }
EnumConverter<RecognizerType>::member_data RecognizerTypeConverter::getMemberData() { EnumConverter<RecognizerType>::member_data RecognizerTypeConverter::getMemberData() {
return member_data{ return member_data {
{ RecognizerType::PocketSphinx, "pocketSphinx" }, { RecognizerType::PocketSphinx, "pocketSphinx" },
{ RecognizerType::Phonetic, "phonetic" } { RecognizerType::Phonetic, "phonetic" }
}; };

View File

@ -3,7 +3,6 @@
#include <tclap/CmdLine.h> #include <tclap/CmdLine.h>
#include "core/appInfo.h" #include "core/appInfo.h"
#include "tools/NiceCmdLineOutput.h" #include "tools/NiceCmdLineOutput.h"
#include "tools/ProgressBar.h"
#include "logging/logging.h" #include "logging/logging.h"
#include "logging/sinks.h" #include "logging/sinks.h"
#include "logging/formatters.h" #include "logging/formatters.h"
@ -52,45 +51,48 @@ namespace TCLAP {
struct ArgTraits<logging::Level> { struct ArgTraits<logging::Level> {
typedef ValueLike ValueCategory; typedef ValueLike ValueCategory;
}; };
template<> template<>
struct ArgTraits<ExportFormat> { struct ArgTraits<ExportFormat> {
typedef ValueLike ValueCategory; typedef ValueLike ValueCategory;
}; };
template<> template<>
struct ArgTraits<RecognizerType> { struct ArgTraits<RecognizerType> {
typedef ValueLike ValueCategory; typedef ValueLike ValueCategory;
}; };
} }
shared_ptr<logging::Sink> createFileSink(path path, logging::Level minLevel) { shared_ptr<logging::Sink> createFileSink(const path& path, logging::Level minLevel) {
auto file = make_shared<boost::filesystem::ofstream>(); auto file = make_shared<boost::filesystem::ofstream>();
file->exceptions(std::ifstream::failbit | std::ifstream::badbit); file->exceptions(std::ifstream::failbit | std::ifstream::badbit);
file->open(path); file->open(path);
auto FileSink = make_shared<logging::StreamSink>(file, make_shared<logging::SimpleFileFormatter>()); auto FileSink =
make_shared<logging::StreamSink>(file, make_shared<logging::SimpleFileFormatter>());
return make_shared<logging::LevelFilter>(FileSink, minLevel); return make_shared<logging::LevelFilter>(FileSink, minLevel);
} }
unique_ptr<Recognizer> createRecognizer(RecognizerType recognizerType) { unique_ptr<Recognizer> createRecognizer(RecognizerType recognizerType) {
switch (recognizerType) { switch (recognizerType) {
case RecognizerType::PocketSphinx: case RecognizerType::PocketSphinx:
return make_unique<PocketSphinxRecognizer>(); return make_unique<PocketSphinxRecognizer>();
case RecognizerType::Phonetic: case RecognizerType::Phonetic:
return make_unique<PhoneticRecognizer>(); return make_unique<PhoneticRecognizer>();
default: default:
throw std::runtime_error("Unknown recognizer."); throw std::runtime_error("Unknown recognizer.");
} }
} }
unique_ptr<Exporter> createExporter(ExportFormat exportFormat) { unique_ptr<Exporter> createExporter(ExportFormat exportFormat) {
switch (exportFormat) { switch (exportFormat) {
case ExportFormat::Tsv: case ExportFormat::Tsv:
return make_unique<TsvExporter>(); return make_unique<TsvExporter>();
case ExportFormat::Xml: case ExportFormat::Xml:
return make_unique<XmlExporter>(); return make_unique<XmlExporter>();
case ExportFormat::Json: case ExportFormat::Json:
return make_unique<JsonExporter>(); return make_unique<JsonExporter>();
default: default:
throw std::runtime_error("Unknown export format."); throw std::runtime_error("Unknown export format.");
} }
} }
@ -106,7 +108,7 @@ ShapeSet getTargetShapeSet(const string& extendedShapesString) {
return result; return result;
} }
int main(int platformArgc, char *platformArgv[]) { int main(int platformArgc, char* platformArgv[]) {
// Set up default logging so early errors are printed to stdout // Set up default logging so early errors are printed to stdout
const logging::Level defaultMinStderrLevel = logging::Level::Error; const logging::Level defaultMinStderrLevel = logging::Level::Error;
shared_ptr<logging::Sink> defaultSink = make_shared<NiceStderrSink>(defaultMinStderrLevel); shared_ptr<logging::Sink> defaultSink = make_shared<NiceStderrSink>(defaultMinStderrLevel);
@ -124,24 +126,71 @@ int main(int platformArgc, char *platformArgv[]) {
tclap::CmdLine cmd(appName, argumentValueSeparator, appVersion); tclap::CmdLine cmd(appName, argumentValueSeparator, appVersion);
cmd.setExceptionHandling(false); cmd.setExceptionHandling(false);
cmd.setOutput(new NiceCmdLineOutput()); cmd.setOutput(new NiceCmdLineOutput());
tclap::ValueArg<string> outputFileName("o", "output", "The output file path.", false, string(), "string", cmd);
tclap::ValueArg<string> outputFileName(
"o", "output", "The output file path.",
false, string(), "string", cmd
);
auto logLevels = vector<logging::Level>(logging::LevelConverter::get().getValues()); auto logLevels = vector<logging::Level>(logging::LevelConverter::get().getValues());
tclap::ValuesConstraint<logging::Level> logLevelConstraint(logLevels); tclap::ValuesConstraint<logging::Level> logLevelConstraint(logLevels);
tclap::ValueArg<logging::Level> logLevel("", "logLevel", "The minimum log level that will be written to the log file", false, logging::Level::Debug, &logLevelConstraint, cmd); tclap::ValueArg<logging::Level> logLevel(
tclap::ValueArg<string> logFileName("", "logFile", "The log file path.", false, string(), "string", cmd); "", "logLevel", "The minimum log level that will be written to the log file",
tclap::ValueArg<logging::Level> consoleLevel("", "consoleLevel", "The minimum log level that will be printed on the console (stderr)", false, defaultMinStderrLevel, &logLevelConstraint, cmd); false, logging::Level::Debug, &logLevelConstraint, cmd
tclap::SwitchArg machineReadableMode("", "machineReadable", "Formats all output to stderr in a structured JSON format.", cmd, false); );
tclap::SwitchArg quietMode("q", "quiet", "Suppresses all output to stderr except for warnings and error messages.", cmd, false);
tclap::ValueArg<int> maxThreadCount("", "threads", "The maximum number of worker threads to use.", false, getProcessorCoreCount(), "number", cmd); tclap::ValueArg<string> logFileName(
tclap::ValueArg<string> extendedShapes("", "extendedShapes", "All extended, optional shapes to use.", false, "GHX", "string", cmd); "", "logFile", "The log file path.",
tclap::ValueArg<string> dialogFile("d", "dialogFile", "A file containing the text of the dialog.", false, string(), "string", cmd); false, string(), "string", cmd
);
tclap::ValueArg<logging::Level> consoleLevel(
"", "consoleLevel", "The minimum log level that will be printed on the console (stderr)",
false, defaultMinStderrLevel, &logLevelConstraint, cmd
);
tclap::SwitchArg machineReadableMode(
"", "machineReadable", "Formats all output to stderr in a structured JSON format.",
cmd, false
);
tclap::SwitchArg quietMode(
"q", "quiet", "Suppresses all output to stderr except for warnings and error messages.",
cmd, false
);
tclap::ValueArg<int> maxThreadCount(
"", "threads", "The maximum number of worker threads to use.",
false, getProcessorCoreCount(), "number", cmd
);
tclap::ValueArg<string> extendedShapes(
"", "extendedShapes", "All extended, optional shapes to use.",
false, "GHX", "string", cmd
);
tclap::ValueArg<string> dialogFile(
"d", "dialogFile", "A file containing the text of the dialog.",
false, string(), "string", cmd
);
auto exportFormats = vector<ExportFormat>(ExportFormatConverter::get().getValues()); auto exportFormats = vector<ExportFormat>(ExportFormatConverter::get().getValues());
tclap::ValuesConstraint<ExportFormat> exportFormatConstraint(exportFormats); tclap::ValuesConstraint<ExportFormat> exportFormatConstraint(exportFormats);
tclap::ValueArg<ExportFormat> exportFormat("f", "exportFormat", "The export format.", false, ExportFormat::Tsv, &exportFormatConstraint, cmd); tclap::ValueArg<ExportFormat> exportFormat(
"f", "exportFormat", "The export format.",
false, ExportFormat::Tsv, &exportFormatConstraint, cmd
);
auto recognizerTypes = vector<RecognizerType>(RecognizerTypeConverter::get().getValues()); auto recognizerTypes = vector<RecognizerType>(RecognizerTypeConverter::get().getValues());
tclap::ValuesConstraint<RecognizerType> recognizerConstraint(recognizerTypes); tclap::ValuesConstraint<RecognizerType> recognizerConstraint(recognizerTypes);
tclap::ValueArg<RecognizerType> recognizerType("r", "recognizer", "The dialog recognizer.", false, RecognizerType::PocketSphinx, &recognizerConstraint, cmd); tclap::ValueArg<RecognizerType> recognizerType(
tclap::UnlabeledValueArg<string> inputFileName("inputFile", "The input file. Must be a sound file in WAVE format.", true, "", "string", cmd); "r", "recognizer", "The dialog recognizer.",
false, RecognizerType::PocketSphinx, &recognizerConstraint, cmd
);
tclap::UnlabeledValueArg<string> inputFileName(
"inputFile", "The input file. Must be a sound file in WAVE format.",
true, "", "string", cmd
);
try { try {
// Parse command line // Parse command line
@ -180,13 +229,17 @@ int main(int platformArgc, char *platformArgv[]) {
try { try {
// On progress change: Create log message // On progress change: Create log message
ProgressForwarder progressSink([](double progress) { logging::log(ProgressEntry(progress)); }); ProgressForwarder progressSink([](double progress) {
logging::log(ProgressEntry(progress));
});
// Animate the recording // Animate the recording
logging::info("Starting animation."); logging::info("Starting animation.");
JoiningContinuousTimeline<Shape> animation = animateWaveFile( JoiningContinuousTimeline<Shape> animation = animateWaveFile(
inputFilePath, inputFilePath,
dialogFile.isSet() ? readUtf8File(path(dialogFile.getValue())) : boost::optional<string>(), dialogFile.isSet()
? readUtf8File(path(dialogFile.getValue()))
: boost::optional<string>(),
*createRecognizer(recognizerType.getValue()), *createRecognizer(recognizerType.getValue()),
targetShapeSet, targetShapeSet,
maxThreadCount.getValue(), maxThreadCount.getValue(),
@ -207,7 +260,9 @@ int main(int platformArgc, char *platformArgv[]) {
logging::log(SuccessEntry()); logging::log(SuccessEntry());
} catch (...) { } catch (...) {
std::throw_with_nested(std::runtime_error(fmt::format("Error processing file {}.", inputFilePath))); std::throw_with_nested(
std::runtime_error(fmt::format("Error processing file {}.", inputFilePath))
);
} }
return 0; return 0;

View File

@ -9,7 +9,6 @@
using std::string; using std::string;
using std::make_shared; using std::make_shared;
using logging::Level; using logging::Level;
using logging::LevelFilter;
using logging::StdErrSink; using logging::StdErrSink;
using logging::SimpleConsoleFormatter; using logging::SimpleConsoleFormatter;
using boost::optional; using boost::optional;
@ -21,11 +20,14 @@ NiceStderrSink::NiceStderrSink(Level minLevel) :
{} {}
void NiceStderrSink::receive(const logging::Entry& entry) { void NiceStderrSink::receive(const logging::Entry& entry) {
// For selected semantic entries, print a user-friendly message instead of the technical log message. // For selected semantic entries, print a user-friendly message instead of
if (const StartEntry* startEntry = dynamic_cast<const StartEntry*>(&entry)) { // the technical log message.
std::cerr << fmt::format("Generating lip sync data for {}.", startEntry->getInputFilePath()) << std::endl; if (const auto* startEntry = dynamic_cast<const StartEntry*>(&entry)) {
std::cerr
<< fmt::format("Generating lip sync data for {}.", startEntry->getInputFilePath())
<< std::endl;
startProgressIndication(); startProgressIndication();
} else if (const ProgressEntry* progressEntry = dynamic_cast<const ProgressEntry*>(&entry)) { } else if (const auto* progressEntry = dynamic_cast<const ProgressEntry*>(&entry)) {
assert(progressBar); assert(progressBar);
progress = progressEntry->getProgress(); progress = progressEntry->getProgress();
progressBar->reportProgress(progress); progressBar->reportProgress(progress);
@ -65,7 +67,7 @@ QuietStderrSink::QuietStderrSink(Level minLevel) :
void QuietStderrSink::receive(const logging::Entry& entry) { void QuietStderrSink::receive(const logging::Entry& entry) {
// Set inputFilePath as soon as we get it // Set inputFilePath as soon as we get it
if (const StartEntry* startEntry = dynamic_cast<const StartEntry*>(&entry)) { if (const auto* startEntry = dynamic_cast<const StartEntry*>(&entry)) {
inputFilePath = startEntry->getInputFilePath(); inputFilePath = startEntry->getInputFilePath();
} }
@ -87,26 +89,42 @@ MachineReadableStderrSink::MachineReadableStderrSink(Level minLevel) :
{} {}
string formatLogProperty(const logging::Entry& entry) { string formatLogProperty(const logging::Entry& entry) {
return fmt::format(R"("log": {{ "level": "{}", "message": "{}" }})", entry.level, escapeJsonString(entry.message)); return fmt::format(
R"("log": {{ "level": "{}", "message": "{}" }})",
entry.level,
escapeJsonString(entry.message)
);
} }
void MachineReadableStderrSink::receive(const logging::Entry& entry) { void MachineReadableStderrSink::receive(const logging::Entry& entry) {
optional<string> line; optional<string> line;
if (dynamic_cast<const SemanticEntry*>(&entry)) { if (dynamic_cast<const SemanticEntry*>(&entry)) {
if (const StartEntry* startEntry = dynamic_cast<const StartEntry*>(&entry)) { if (const auto* startEntry = dynamic_cast<const StartEntry*>(&entry)) {
const string file = escapeJsonString(startEntry->getInputFilePath().string()); const string file = escapeJsonString(startEntry->getInputFilePath().string());
line = fmt::format(R"({{ "type": "start", "file": "{}", {} }})", file, formatLogProperty(entry)); line = fmt::format(
} else if (const ProgressEntry* progressEntry = dynamic_cast<const ProgressEntry*>(&entry)) { R"({{ "type": "start", "file": "{}", {} }})",
file,
formatLogProperty(entry)
);
} else if (const auto* progressEntry = dynamic_cast<const ProgressEntry*>(&entry)) {
const int progressPercent = static_cast<int>(progressEntry->getProgress() * 100); const int progressPercent = static_cast<int>(progressEntry->getProgress() * 100);
if (progressPercent > lastProgressPercent) { if (progressPercent > lastProgressPercent) {
line = fmt::format(R"({{ "type": "progress", "value": {:.2f}, {} }})", progressEntry->getProgress(), formatLogProperty(entry)); line = fmt::format(
R"({{ "type": "progress", "value": {:.2f}, {} }})",
progressEntry->getProgress(),
formatLogProperty(entry)
);
lastProgressPercent = progressPercent; lastProgressPercent = progressPercent;
} }
} else if (dynamic_cast<const SuccessEntry*>(&entry)) { } else if (dynamic_cast<const SuccessEntry*>(&entry)) {
line = fmt::format(R"({{ "type": "success", {} }})", formatLogProperty(entry)); line = fmt::format(R"({{ "type": "success", {} }})", formatLogProperty(entry));
} else if (const FailureEntry* failureEntry = dynamic_cast<const FailureEntry*>(&entry)) { } else if (const auto* failureEntry = dynamic_cast<const FailureEntry*>(&entry)) {
const string reason = escapeJsonString(failureEntry->getReason()); const string reason = escapeJsonString(failureEntry->getReason());
line = fmt::format(R"({{ "type": "failure", "reason": "{}", {} }})", reason, formatLogProperty(entry)); line = fmt::format(
R"({{ "type": "failure", "reason": "{}", {} }})",
reason,
formatLogProperty(entry)
);
} else { } else {
throw std::runtime_error("Unsupported type of semantic entry."); throw std::runtime_error("Unsupported type of semantic entry.");
} }

View File

@ -52,7 +52,10 @@ public:
// Clip the value's range to bounds // Clip the value's range to bounds
TimeRange& valueRange = timedValue.getTimeRange(); TimeRange& valueRange = timedValue.getTimeRange();
valueRange.resize(max(range.getStart(), valueRange.getStart()), min(range.getEnd(), valueRange.getEnd())); valueRange.resize(
max(range.getStart(), valueRange.getStart()),
min(range.getEnd(), valueRange.getEnd())
);
return Timeline<T, AutoJoin>::set(timedValue); return Timeline<T, AutoJoin>::set(timedValue);
} }

View File

@ -29,7 +29,11 @@ public:
ContinuousTimeline(range, defaultValue, collection.begin(), collection.end()) ContinuousTimeline(range, defaultValue, collection.begin(), collection.end())
{} {}
ContinuousTimeline(TimeRange range, T defaultValue, std::initializer_list<Timed<T>> initializerList) : ContinuousTimeline(
TimeRange range,
T defaultValue,
std::initializer_list<Timed<T>> initializerList
) :
ContinuousTimeline(range, defaultValue, initializerList.begin(), initializerList.end()) ContinuousTimeline(range, defaultValue, initializerList.begin(), initializerList.end())
{} {}

View File

@ -20,7 +20,11 @@ TimeRange::TimeRange(time_type start, time_type end) :
end(end) end(end)
{ {
if (start > end) { if (start > end) {
throw std::invalid_argument(fmt::format("Time range start must not be less than end. Start: {0}, end: {1}", start, end)); throw std::invalid_argument(fmt::format(
"Time range start must not be less than end. Start: {0}, end: {1}",
start,
end
));
} }
} }
@ -88,16 +92,16 @@ void TimeRange::shrink(time_type value) {
} }
void TimeRange::trim(const TimeRange& limits) { void TimeRange::trim(const TimeRange& limits) {
TimeRange newRange(std::max(start, limits.start), std::min(end, limits.end)); const TimeRange newRange(std::max(start, limits.start), std::min(end, limits.end));
resize(newRange); resize(newRange);
} }
void TimeRange::trimLeft(time_type value) { void TimeRange::trimLeft(time_type value) {
trim({value, end}); trim({ value, end });
} }
void TimeRange::trimRight(time_type value) { void TimeRange::trimRight(time_type value) {
trim({start, value}); trim({ start, value });
} }
bool TimeRange::operator==(const TimeRange& rhs) const { bool TimeRange::operator==(const TimeRange& rhs) const {

View File

@ -72,7 +72,12 @@ private:
template<typename T> template<typename T>
std::ostream& operator<<(std::ostream& stream, const Timed<T>& timedValue) { std::ostream& operator<<(std::ostream& stream, const Timed<T>& timedValue) {
return stream << "Timed(" << timedValue.getStart() << ", " << timedValue.getEnd() << ", " << timedValue.getValue() << ")"; return stream
<< "Timed("
<< timedValue.getStart() << ", "
<< timedValue.getEnd() << ", "
<< timedValue.getValue()
<< ")";
} }
template<> template<>
@ -130,5 +135,9 @@ private:
template<> template<>
inline std::ostream& operator<<(std::ostream& stream, const Timed<void>& timedValue) { inline std::ostream& operator<<(std::ostream& stream, const Timed<void>& timedValue) {
return stream << "Timed<void>(" << timedValue.getTimeRange().getStart() << ", " << timedValue.getTimeRange().getEnd() << ")"; return stream
<< "Timed<void>("
<< timedValue.getTimeRange().getStart() << ", "
<< timedValue.getTimeRange().getEnd()
<< ")";
} }

View File

@ -36,12 +36,15 @@ private:
bool operator()(const Timed<T>& lhs, const Timed<T>& rhs) const { bool operator()(const Timed<T>& lhs, const Timed<T>& rhs) const {
return lhs.getStart() < rhs.getStart(); return lhs.getStart() < rhs.getStart();
} }
bool operator()(const time_type& lhs, const Timed<T>& rhs) const { bool operator()(const time_type& lhs, const Timed<T>& rhs) const {
return lhs < rhs.getStart(); return lhs < rhs.getStart();
} }
bool operator()(const Timed<T>& lhs, const time_type& rhs) const { bool operator()(const Timed<T>& lhs, const time_type& rhs) const {
return lhs.getStart() < rhs; return lhs.getStart() < rhs;
} }
using is_transparent = int; using is_transparent = int;
}; };
@ -88,7 +91,7 @@ public:
time_type time; time_type time;
}; };
Timeline() {} Timeline() = default;
template<typename InputIterator> template<typename InputIterator>
Timeline(InputIterator first, InputIterator last) { Timeline(InputIterator first, InputIterator last) {
@ -107,7 +110,7 @@ public:
Timeline(initializerList.begin(), initializerList.end()) Timeline(initializerList.begin(), initializerList.end())
{} {}
virtual ~Timeline() {} virtual ~Timeline() = default;
bool empty() const { bool empty() const {
return elements.empty(); return elements.empty();
@ -141,35 +144,39 @@ public:
iterator find(time_type time, FindMode findMode = FindMode::SampleRight) const { iterator find(time_type time, FindMode findMode = FindMode::SampleRight) const {
switch (findMode) { switch (findMode) {
case FindMode::SampleLeft: { case FindMode::SampleLeft:
iterator left = find(time, FindMode::SearchLeft); {
return left != end() && left->getEnd() >= time ? left : end(); iterator left = find(time, FindMode::SearchLeft);
} return left != end() && left->getEnd() >= time ? left : end();
case FindMode::SampleRight: {
iterator right = find(time, FindMode::SearchRight);
return right != end() && right->getStart() <= time ? right : end();
}
case FindMode::SearchLeft: {
// Get first element starting >= time
iterator it = elements.lower_bound(time);
// Go one element back
return it != begin() ? --it : end();
}
case FindMode::SearchRight: {
// Get first element starting > time
iterator it = elements.upper_bound(time);
// Go one element back
if (it != begin()) {
iterator left = it;
--left;
if (left->getEnd() > time) return left;
} }
return it; case FindMode::SampleRight:
} {
default: iterator right = find(time, FindMode::SearchRight);
throw std::invalid_argument("Unexpected find mode."); return right != end() && right->getStart() <= time ? right : end();
}
case FindMode::SearchLeft:
{
// Get first element starting >= time
iterator it = elements.lower_bound(time);
// Go one element back
return it != begin() ? --it : end();
}
case FindMode::SearchRight:
{
// Get first element starting > time
iterator it = elements.upper_bound(time);
// Go one element back
if (it != begin()) {
iterator left = it;
--left;
if (left->getEnd() > time) return left;
}
return it;
}
default:
throw std::invalid_argument("Unexpected find mode.");
} }
} }
@ -187,7 +194,10 @@ public:
splitAt(range.getEnd()); splitAt(range.getEnd());
// Erase overlapping elements // Erase overlapping elements
elements.erase(find(range.getStart(), FindMode::SearchRight), find(range.getEnd(), FindMode::SearchRight)); elements.erase(
find(range.getStart(), FindMode::SearchRight),
find(range.getEnd(), FindMode::SearchRight)
);
} }
void clear(time_type start, time_type end) { void clear(time_type start, time_type end) {
@ -220,12 +230,19 @@ public:
} }
template<typename TElement = T> template<typename TElement = T>
iterator set(const TimeRange& timeRange, const std::enable_if_t<!std::is_void<TElement>::value, T>& value) { iterator set(
const TimeRange& timeRange,
const std::enable_if_t<!std::is_void<TElement>::value, T>& value
) {
return set(Timed<T>(timeRange, value)); return set(Timed<T>(timeRange, value));
} }
template<typename TElement = T> template<typename TElement = T>
iterator set(time_type start, time_type end, const std::enable_if_t<!std::is_void<TElement>::value, T>& value) { iterator set(
time_type start,
time_type end,
const std::enable_if_t<!std::is_void<TElement>::value, T>& value
) {
return set(Timed<T>(start, end, value)); return set(Timed<T>(start, end, value));
} }
@ -251,13 +268,16 @@ public:
for (auto it = copy.begin(); it != copy.end(); ++it) { for (auto it = copy.begin(); it != copy.end(); ++it) {
const auto rangeBegin = it; const auto rangeBegin = it;
auto rangeEnd = std::next(rangeBegin); auto rangeEnd = std::next(rangeBegin);
while (rangeEnd != copy.end() && rangeEnd->getStart() == rangeBegin->getEnd() && ::internal::valueEquals(*rangeEnd, *rangeBegin)) { while (rangeEnd != copy.end()
&& rangeEnd->getStart() == rangeBegin->getEnd()
&& ::internal::valueEquals(*rangeEnd, *rangeBegin)
) {
++rangeEnd; ++rangeEnd;
} }
if (rangeEnd != std::next(rangeBegin)) { if (rangeEnd != std::next(rangeBegin)) {
Timed<T> combined = *rangeBegin; Timed<T> combined = *rangeBegin;
combined.setTimeRange({rangeBegin->getStart(), rangeEnd->getEnd()}); combined.setTimeRange({ rangeBegin->getStart(), rangeEnd->getEnd() });
set(combined); set(combined);
it = rangeEnd; it = rangeEnd;
} }

View File

@ -3,9 +3,9 @@
#include <chrono> #include <chrono>
#include <ostream> #include <ostream>
typedef std::chrono::duration<int, std::centi> centiseconds; using centiseconds = std::chrono::duration<int, std::centi>;
std::ostream& operator <<(std::ostream& stream, const centiseconds cs); std::ostream& operator <<(std::ostream& stream, centiseconds cs);
#pragma warning(push) #pragma warning(push)
#pragma warning(disable: 4455) #pragma warning(disable: 4455)

View File

@ -7,8 +7,13 @@
template<typename TValue> template<typename TValue>
void logTimedEvent(const std::string& eventName, const Timed<TValue> timedValue) { void logTimedEvent(const std::string& eventName, const Timed<TValue> timedValue) {
logging::debugFormat("##{0}[{1}-{2}]: {3}", logging::debugFormat(
eventName, formatDuration(timedValue.getStart()), formatDuration(timedValue.getEnd()), timedValue.getValue()); "##{0}[{1}-{2}]: {3}",
eventName,
formatDuration(timedValue.getStart()),
formatDuration(timedValue.getEnd()),
timedValue.getValue()
);
} }
template<typename TValue> template<typename TValue>
@ -17,6 +22,11 @@ void logTimedEvent(const std::string& eventName, const TimeRange& timeRange, con
} }
template<typename TValue> template<typename TValue>
void logTimedEvent(const std::string& eventName, centiseconds start, centiseconds end, const TValue& value) { void logTimedEvent(
const std::string& eventName,
centiseconds start,
centiseconds end,
const TValue& value
) {
logTimedEvent(eventName, Timed<TValue>(start, end, value)); logTimedEvent(eventName, Timed<TValue>(start, end, value));
} }

View File

@ -1,6 +1,5 @@
#pragma once #pragma once
#include <initializer_list>
#include <utility> #include <utility>
#include <map> #include <map>
#include <vector> #include <vector>
@ -30,7 +29,9 @@ public:
auto result = tryToString(value); auto result = tryToString(value);
if (!result) { if (!result) {
auto numericValue = static_cast<typename std::underlying_type<TEnum>::type>(value); auto numericValue = static_cast<typename std::underlying_type<TEnum>::type>(value);
throw std::invalid_argument(fmt::format("{} is not a valid {} value.", numericValue, typeName)); throw std::invalid_argument(
fmt::format("{} is not a valid {} value.", numericValue, typeName)
);
} }
return *result; return *result;

View File

@ -55,7 +55,10 @@ public:
private: private:
void init() const { void init() const {
std::call_once(state->initialized, [&] { state->value = std::make_unique<T>(state->createValue()); }); std::call_once(
state->initialized,
[&] { state->value = std::make_unique<T>(state->createValue()); }
);
} }
std::shared_ptr<State> state = std::make_shared<State>(); std::shared_ptr<State> state = std::make_shared<State>();

View File

@ -36,7 +36,10 @@ void NiceCmdLineOutput::failure(CmdLineInterface& cli, TCLAP::ArgException& e) {
std::cerr << "Short usage:" << endl; std::cerr << "Short usage:" << endl;
printShortUsage(cli, std::cerr); printShortUsage(cli, std::cerr);
std::cerr << endl << "For complete usage and help, type `" << getBinaryName() << " --help`" << endl << endl; std::cerr
<< endl
<< "For complete usage and help, type `" << getBinaryName() << " --help`" << endl
<< endl;
} else { } else {
usage(cli); usage(cli);
} }
@ -76,8 +79,9 @@ void NiceCmdLineOutput::printLongUsage(CmdLineInterface& cli, std::ostream& outS
const vector<vector<TCLAP::Arg*>> xorArgGroups = xorHandler.getXorList(); const vector<vector<TCLAP::Arg*>> xorArgGroups = xorHandler.getXorList();
for (const vector<TCLAP::Arg*>& xorArgGroup : xorArgGroups) { for (const vector<TCLAP::Arg*>& xorArgGroup : xorArgGroups) {
for (auto arg : xorArgGroup) { for (auto arg : xorArgGroup) {
if (arg != xorArgGroup[0]) if (arg != xorArgGroup[0]) {
outStream << "-- or --" << endl; outStream << "-- or --" << endl;
}
tablePrinter.printRow({ arg->longID(), arg->getDescription() }); tablePrinter.printRow({ arg->longID(), arg->getDescription() });
} }

View File

@ -4,7 +4,7 @@
#include <stack> #include <stack>
#include <mutex> #include <mutex>
template <typename value_type, typename pointer_type = std::unique_ptr<value_type>> template<typename value_type, typename pointer_type = std::unique_ptr<value_type>>
class ObjectPool { class ObjectPool {
public: public:
using wrapper_type = lambda_unique_ptr<value_type>; using wrapper_type = lambda_unique_ptr<value_type>;

View File

@ -54,13 +54,13 @@ void ProgressBar::update(bool showSpinner) {
const int blockCount = 20; const int blockCount = 20;
const string animation = "|/-\\"; const string animation = "|/-\\";
int progressBlockCount = static_cast<int>(currentProgress * blockCount); const int progressBlockCount = static_cast<int>(currentProgress * blockCount);
const double epsilon = 0.0001; const double epsilon = 0.0001;
int percent = static_cast<int>(currentProgress * 100 + epsilon); const int percent = static_cast<int>(currentProgress * 100 + epsilon);
const string spinner = showSpinner const string spinner = showSpinner
? string(1, animation[animationIndex++ % animation.size()]) ? string(1, animation[animationIndex++ % animation.size()])
: ""; : "";
string text = fmt::format("[{0}{1}] {2:3}% {3}", const string text = fmt::format("[{0}{1}] {2:3}% {3}",
string(progressBlockCount, '#'), string(blockCount - progressBlockCount, '-'), string(progressBlockCount, '#'), string(blockCount - progressBlockCount, '-'),
percent, percent,
spinner spinner
@ -71,7 +71,7 @@ void ProgressBar::update(bool showSpinner) {
void ProgressBar::updateText(const string& text) { void ProgressBar::updateText(const string& text) {
// Get length of common portion // Get length of common portion
int commonPrefixLength = 0; int commonPrefixLength = 0;
int commonLength = std::min(currentText.size(), text.size()); const int commonLength = std::min(currentText.size(), text.size());
while (commonPrefixLength < commonLength && text[commonPrefixLength] == currentText[commonPrefixLength]) { while (commonPrefixLength < commonLength && text[commonPrefixLength] == currentText[commonPrefixLength]) {
commonPrefixLength++; commonPrefixLength++;
} }
@ -86,7 +86,7 @@ void ProgressBar::updateText(const string& text) {
output.append(text, commonPrefixLength, text.size() - commonPrefixLength); output.append(text, commonPrefixLength, text.size() - commonPrefixLength);
// ... if the new text is shorter than the old one: delete overlapping characters // ... if the new text is shorter than the old one: delete overlapping characters
int overlapCount = currentText.size() - text.size(); const int overlapCount = currentText.size() - text.size();
if (overlapCount > 0) { if (overlapCount > 0) {
output.append(overlapCount, ' '); output.append(overlapCount, ' ');
output.append(overlapCount, '\b'); output.append(overlapCount, '\b');

View File

@ -10,21 +10,23 @@ using std::invalid_argument;
using std::vector; using std::vector;
using std::string; using std::string;
TablePrinter::TablePrinter(ostream *stream, initializer_list<int> columnWidths, int columnSpacing) : TablePrinter::TablePrinter(ostream* stream, initializer_list<int> columnWidths, int columnSpacing) :
stream(stream), stream(stream),
columnWidths(columnWidths.begin(), columnWidths.end()), columnWidths(columnWidths.begin(), columnWidths.end()),
columnSpacing(columnSpacing) columnSpacing(columnSpacing)
{ {
if (stream == nullptr) throw invalid_argument("stream is null."); if (stream == nullptr) throw invalid_argument("stream is null.");
if (columnWidths.size() < 1) throw invalid_argument("No columns defined."); if (columnWidths.size() < 1) throw invalid_argument("No columns defined.");
if (std::any_of(columnWidths.begin(), columnWidths.end(), [](int width){ return width <= 1; })) { if (std::any_of(columnWidths.begin(), columnWidths.end(), [](int width) { return width <= 1; })) {
throw invalid_argument("All columns must have a width of at least 1."); throw invalid_argument("All columns must have a width of at least 1.");
} }
if (columnSpacing < 0) throw invalid_argument("columnSpacing must not be negative."); if (columnSpacing < 0) throw invalid_argument("columnSpacing must not be negative.");
} }
void TablePrinter::printRow(initializer_list<string> columns) const { void TablePrinter::printRow(initializer_list<string> columns) const {
if (columns.size() != columnWidths.size()) throw invalid_argument("Number of specified strings does not match number of defined columns."); if (columns.size() != columnWidths.size()) {
throw invalid_argument("Number of specified strings does not match number of defined columns.");
}
// Some cells may span multiple lines. // Some cells may span multiple lines.
// Create matrix of text lines in columns. // Create matrix of text lines in columns.
@ -50,7 +52,7 @@ void TablePrinter::printRow(initializer_list<string> columns) const {
// Print lines // Print lines
*stream << std::left; *stream << std::left;
string spacer(columnSpacing, ' '); const string spacer(columnSpacing, ' ');
for (size_t rowIndex = 0; rowIndex < lineCount; rowIndex++) { for (size_t rowIndex = 0; rowIndex < lineCount; rowIndex++) {
for (size_t columnIndex = 0; columnIndex < columns.size(); columnIndex++) { for (size_t columnIndex = 0; columnIndex < columns.size(); columnIndex++) {
if (columnIndex != 0) { if (columnIndex != 0) {

View File

@ -6,7 +6,11 @@
class TablePrinter { class TablePrinter {
public: public:
TablePrinter(std::ostream* stream, std::initializer_list<int> columnWidths, int columnSpacing = 2); TablePrinter(
std::ostream* stream,
std::initializer_list<int> columnWidths,
int columnSpacing = 2
);
void printRow(std::initializer_list<std::string> columns) const; void printRow(std::initializer_list<std::string> columns) const;
private: private:
std::ostream* const stream; std::ostream* const stream;

View File

@ -9,13 +9,16 @@ namespace details {
struct negation : std::integral_constant<bool, !B::value> {}; struct negation : std::integral_constant<bool, !B::value> {};
template<class> struct is_ref_wrapper : std::false_type {}; template<class> struct is_ref_wrapper : std::false_type {};
template<class T> struct is_ref_wrapper<std::reference_wrapper<T>> : std::true_type {}; template<class T> struct is_ref_wrapper<std::reference_wrapper<T>> : std::true_type {};
template<class T> template<class T>
using not_ref_wrapper = negation<is_ref_wrapper<std::decay_t<T>>>; using not_ref_wrapper = negation<is_ref_wrapper<std::decay_t<T>>>;
template<class...> struct conjunction : std::true_type { }; template<class...> struct conjunction : std::true_type { };
template<class B1> struct conjunction<B1> : B1 { }; template<class B1> struct conjunction<B1> : B1 { };
template<class B1, class... Bn> template<class B1, class... Bn>
struct conjunction<B1, Bn...> struct conjunction<B1, Bn...>
: std::conditional_t<bool(B1::value), conjunction<Bn...>, B1> {}; : std::conditional_t<bool(B1::value), conjunction<Bn...>, B1> {};
@ -23,19 +26,20 @@ namespace details {
template<class... B> template<class... B>
constexpr bool conjunction_v = conjunction<B...>::value; constexpr bool conjunction_v = conjunction<B...>::value;
template <class D, class...> struct return_type_helper { using type = D; }; template<class D, class...> struct return_type_helper { using type = D; };
template <class... Types>
template<class... Types>
struct return_type_helper<void, Types...> : std::common_type<Types...> { struct return_type_helper<void, Types...> : std::common_type<Types...> {
static_assert(conjunction_v<not_ref_wrapper<Types>...>, static_assert(conjunction_v<not_ref_wrapper<Types>...>,
"Types cannot contain reference_wrappers when D is void"); "Types cannot contain reference_wrappers when D is void");
}; };
template <class D, class... Types> template<class D, class... Types>
using return_type = std::array<typename return_type_helper<D, Types...>::type, using return_type = std::array<typename return_type_helper<D, Types...>::type,
sizeof...(Types)>; sizeof...(Types)>;
} }
template < class D = void, class... Types> template<class D = void, class... Types>
constexpr details::return_type<D, Types...> make_array(Types&&... t) { constexpr details::return_type<D, Types...> make_array(Types&&... t) {
return {std::forward<Types>(t)...}; return { std::forward<Types>(t)... };
} }

View File

@ -10,7 +10,8 @@ std::ifstream openFile(path filePath) {
file.exceptions(std::ifstream::failbit | std::ifstream::badbit); file.exceptions(std::ifstream::failbit | std::ifstream::badbit);
file.open(filePath.c_str(), std::ios::binary); file.open(filePath.c_str(), std::ios::binary);
// Read some dummy data so that we can throw a decent exception in case the file is missing, locked, etc. // Read some dummy data so that we can throw a decent exception in case the file is missing,
// locked, etc.
file.seekg(0, std::ios_base::end); file.seekg(0, std::ios_base::end);
if (file.tellg()) { if (file.tellg()) {
file.seekg(0); file.seekg(0);
@ -18,7 +19,7 @@ std::ifstream openFile(path filePath) {
file.seekg(0); file.seekg(0);
} }
return std::move(file); return file;
} catch (const std::ifstream::failure&) { } catch (const std::ifstream::failure&) {
// Error messages on stream exceptions are mostly useless. // Error messages on stream exceptions are mostly useless.
throw std::runtime_error(errorNumberToString(errno)); throw std::runtime_error(errorNumberToString(errno));

View File

@ -12,7 +12,7 @@
// After each iteration, the first k elements of the container will be // After each iteration, the first k elements of the container will be
// a combination. When there are no more combinations, the container // a combination. When there are no more combinations, the container
// will return to the original sorted order. // will return to the original sorted order.
template <typename Iterator> template<typename Iterator>
inline bool next_combination(const Iterator first, Iterator k, const Iterator last) { inline bool next_combination(const Iterator first, Iterator k, const Iterator last) {
// Handle degenerate cases // Handle degenerate cases
if (first == last || std::next(first) == last || first == k || k == last) { if (first == last || std::next(first) == last || first == k || k == last) {

View File

@ -2,7 +2,9 @@
#include <vector> #include <vector>
template<typename TCollection> template<typename TCollection>
std::vector<std::pair<typename TCollection::value_type, typename TCollection::value_type>> getPairs(const TCollection& collection) { std::vector<std::pair<typename TCollection::value_type, typename TCollection::value_type>> getPairs(
const TCollection& collection
) {
using TElement = typename TCollection::value_type; using TElement = typename TCollection::value_type;
using TPair = std::pair<TElement, TElement>; using TPair = std::pair<TElement, TElement>;
using TIterator = typename TCollection::const_iterator; using TIterator = typename TCollection::const_iterator;

View File

@ -32,12 +32,12 @@ void runParallel(
// Before exiting, wait for all running tasks to finish, but don't re-throw exceptions. // Before exiting, wait for all running tasks to finish, but don't re-throw exceptions.
// This only applies if one task already failed with an exception. // This only applies if one task already failed with an exception.
auto finishRunning = gsl::finally([&]{ auto finishRunning = gsl::finally([&] {
std::unique_lock<std::mutex> lock(mutex); std::unique_lock<std::mutex> lock(mutex);
elementFinished.wait(lock, [&] { return currentThreadCount == 0; }); elementFinished.wait(lock, [&] { return currentThreadCount == 0; });
}); });
// Asyncronously run all elements // Asynchronously run all elements
for (auto it = collection.begin(); it != collection.end(); ++it) { for (auto it = collection.begin(); it != collection.end(); ++it) {
// This variable will later hold the future, but can be value-captured right now // This variable will later hold the future, but can be value-captured right now
auto future = std::make_shared<future_type>(); auto future = std::make_shared<future_type>();
@ -66,7 +66,7 @@ void runParallel(
// Wait for threads to finish, if necessary // Wait for threads to finish, if necessary
{ {
std::unique_lock<std::mutex> lock(mutex); std::unique_lock<std::mutex> lock(mutex);
int targetThreadCount = it == collection.end() ? 0 : maxThreadCount - 1; const int targetThreadCount = it == collection.end() ? 0 : maxThreadCount - 1;
while (currentThreadCount > targetThreadCount) { while (currentThreadCount > targetThreadCount) {
elementFinished.wait(lock); elementFinished.wait(lock);
if (finishedElement.valid()) { if (finishedElement.valid()) {
@ -86,7 +86,8 @@ void runParallel(
TCollection& collection, TCollection& collection,
int maxThreadCount, int maxThreadCount,
ProgressSink& progressSink, ProgressSink& progressSink,
std::function<double(const typename TCollection::reference)> getElementProgressWeight = [](typename TCollection::reference) { return 1.0; }) std::function<double(typename TCollection::reference)> getElementProgressWeight =
[](typename TCollection::reference) { return 1.0; })
{ {
// Create a collection of wrapper functions that take care of progress handling // Create a collection of wrapper functions that take care of progress handling
ProgressMerger progressMerger(progressSink); ProgressMerger progressMerger(progressSink);
@ -101,7 +102,7 @@ void runParallel(
} }
inline int getProcessorCoreCount() { inline int getProcessorCoreCount() {
int coreCount = std::thread::hardware_concurrency(); const int coreCount = std::thread::hardware_concurrency();
// If the number of cores cannot be determined, use a reasonable default // If the number of cores cannot be determined, use a reasonable default
return coreCount != 0 ? coreCount : 4; return coreCount != 0 ? coreCount : 4;

View File

@ -14,8 +14,6 @@
#ifdef _WIN32 #ifdef _WIN32
#include <Windows.h> #include <Windows.h>
#include <io.h>
#include <fcntl.h>
#endif #endif
using boost::filesystem::path; using boost::filesystem::path;
@ -26,13 +24,14 @@ path getBinPath() {
static const path binPath = [] { static const path binPath = [] {
try { try {
// Determine path length // Determine path length
int pathLength = wai_getExecutablePath(nullptr, 0, nullptr); const int pathLength = wai_getExecutablePath(nullptr, 0, nullptr);
if (pathLength == -1) { if (pathLength == -1) {
throw std::runtime_error("Error determining path length."); throw std::runtime_error("Error determining path length.");
} }
// Get path // Get path
// Note: According to documentation, pathLength does *not* include the trailing zero. Actually, it does. // Note: According to documentation, pathLength does *not* include the trailing zero.
// Actually, it does.
// In case there are situations where it doesn't, we allocate one character more. // In case there are situations where it doesn't, we allocate one character more.
std::vector<char> buffer(pathLength + 1); std::vector<char> buffer(pathLength + 1);
if (wai_getExecutablePath(buffer.data(), buffer.size(), nullptr) == -1) { if (wai_getExecutablePath(buffer.data(), buffer.size(), nullptr) == -1) {
@ -41,7 +40,7 @@ path getBinPath() {
buffer[pathLength] = 0; buffer[pathLength] = 0;
// Convert to boost::filesystem::path // Convert to boost::filesystem::path
string pathString(buffer.data()); const string pathString(buffer.data());
path result(boost::filesystem::canonical(pathString).make_preferred()); path result(boost::filesystem::canonical(pathString).make_preferred());
return result; return result;
} catch (...) { } catch (...) {
@ -56,14 +55,14 @@ path getBinDirectory() {
} }
path getTempFilePath() { path getTempFilePath() {
path tempDirectory = boost::filesystem::temp_directory_path(); const path tempDirectory = boost::filesystem::temp_directory_path();
static boost::uuids::random_generator generateUuid; static boost::uuids::random_generator generateUuid;
string fileName = to_string(generateUuid()); const string fileName = to_string(generateUuid());
return tempDirectory / fileName; return tempDirectory / fileName;
} }
std::tm getLocalTime(const time_t& time) { std::tm getLocalTime(const time_t& time) {
tm timeInfo; tm timeInfo {};
#if (__unix || __linux || __APPLE__) #if (__unix || __linux || __APPLE__)
localtime_r(&time, &timeInfo); localtime_r(&time, &timeInfo);
#else #else
@ -92,7 +91,8 @@ vector<string> argsToUtf8(int argc, char* argv[]) {
// Get command-line arguments as UTF16 strings // Get command-line arguments as UTF16 strings
int argumentCount; int argumentCount;
static_assert(sizeof(wchar_t) == sizeof(char16_t), "Expected wchar_t to be a 16-bit type."); static_assert(sizeof(wchar_t) == sizeof(char16_t), "Expected wchar_t to be a 16-bit type.");
char16_t** args = reinterpret_cast<char16_t**>(CommandLineToArgvW(GetCommandLineW(), &argumentCount)); char16_t** args =
reinterpret_cast<char16_t**>(CommandLineToArgvW(GetCommandLineW(), &argumentCount));
if (!args) { if (!args) {
throw std::runtime_error("Error splitting the UTF-16 command line arguments."); throw std::runtime_error("Error splitting the UTF-16 command line arguments.");
} }
@ -134,7 +134,7 @@ private:
}; };
void useUtf8ForConsole() { void useUtf8ForConsole() {
// Unix systems already expect UTF-8-encoded data // Unix systems already expect UTF-8-encoded data
#ifdef _WIN32 #ifdef _WIN32
// Set console code page to UTF-8 so the console knows how to interpret string data // Set console code page to UTF-8 so the console knows how to interpret string data
SetConsoleOutputCP(CP_UTF8); SetConsoleOutputCP(CP_UTF8);
@ -147,7 +147,7 @@ void useUtf8ForConsole() {
} }
void useUtf8ForBoostFilesystem() { void useUtf8ForBoostFilesystem() {
std::locale globalLocale = std::locale(); const std::locale globalLocale = std::locale();
std::locale utf8Locale(globalLocale, new boost::filesystem::detail::utf8_codecvt_facet); const std::locale utf8Locale(globalLocale, new boost::filesystem::detail::utf8_codecvt_facet);
path::imbue(utf8Locale); path::imbue(utf8Locale);
} }

View File

@ -11,7 +11,7 @@ boost::filesystem::path getTempFilePath();
std::tm getLocalTime(const time_t& time); std::tm getLocalTime(const time_t& time);
std::string errorNumberToString(int errorNumber); std::string errorNumberToString(int errorNumber);
std::vector<std::string> argsToUtf8(int argc, char *argv[]); std::vector<std::string> argsToUtf8(int argc, char* argv[]);
void useUtf8ForConsole(); void useUtf8ForConsole();
void useUtf8ForBoostFilesystem(); void useUtf8ForBoostFilesystem();

View File

@ -22,10 +22,10 @@ ProgressSink& ProgressMerger::addSink(double weight) {
totalWeight += weight; totalWeight += weight;
int sinkIndex = weightedValues.size(); int sinkIndex = weightedValues.size();
weightedValues.push_back(0); weightedValues.push_back(0);
forwarders.push_back(ProgressForwarder([weight, sinkIndex, this](double progress) { forwarders.emplace_back([weight, sinkIndex, this](double progress) {
weightedValues[sinkIndex] = progress * weight; weightedValues[sinkIndex] = progress * weight;
report(); report();
})); });
return forwarders.back(); return forwarders.back();
} }
@ -37,7 +37,7 @@ void ProgressMerger::report() {
for (double weightedValue : weightedValues) { for (double weightedValue : weightedValues) {
weightedSum += weightedValue; weightedSum += weightedValue;
} }
double progress = weightedSum / totalWeight; const double progress = weightedSum / totalWeight;
sink.reportProgress(progress); sink.reportProgress(progress);
} else { } else {
sink.reportProgress(0); sink.reportProgress(0);

View File

@ -9,7 +9,6 @@ using std::string;
using std::wstring; using std::wstring;
using std::u32string; using std::u32string;
using std::vector; using std::vector;
using boost::optional;
using std::regex; using std::regex;
using std::regex_replace; using std::regex_replace;
@ -17,7 +16,7 @@ vector<string> splitIntoLines(const string& s) {
vector<string> lines; vector<string> lines;
auto p = &s[0]; auto p = &s[0];
auto lineBegin = p; auto lineBegin = p;
auto end = p + s.size(); const auto end = p + s.size();
// Iterate over input string // Iterate over input string
while (p <= end) { while (p <= end) {
// Add a new result line when we hit a \n character or the end of the string // Add a new result line when we hit a \n character or the end of the string
@ -45,7 +44,7 @@ vector<string> wrapSingleLineString(const string& s, int lineLength, int hanging
auto p = &s[0]; auto p = &s[0];
auto lineBegin = p; auto lineBegin = p;
auto lineEnd = p; auto lineEnd = p;
auto end = p + s.size(); const auto end = p + s.size();
// Iterate over input string // Iterate over input string
while (p <= end) { while (p <= end) {
// If we're at a word boundary: update lineEnd // If we're at a word boundary: update lineEnd
@ -54,7 +53,7 @@ vector<string> wrapSingleLineString(const string& s, int lineLength, int hanging
} }
// If we've hit lineLength or the end of the string: add a new result line // If we've hit lineLength or the end of the string: add a new result line
int currentIndent = lines.empty() ? 0 : hangingIndent; const int currentIndent = lines.empty() ? 0 : hangingIndent;
if (p == end || p - lineBegin == lineLength - currentIndent) { if (p == end || p - lineBegin == lineLength - currentIndent) {
if (lineEnd == lineBegin) { if (lineEnd == lineBegin) {
// The line contains a single word, which is too long. Split mid-word. // The line contains a single word, which is too long. Split mid-word.
@ -80,7 +79,7 @@ vector<string> wrapSingleLineString(const string& s, int lineLength, int hanging
vector<string> wrapString(const string& s, int lineLength, int hangingIndent) { vector<string> wrapString(const string& s, int lineLength, int hangingIndent) {
vector<string> lines; vector<string> lines;
for (string paragraph : splitIntoLines(s)) { for (const string& paragraph : splitIntoLines(s)) {
auto paragraphLines = wrapSingleLineString(paragraph, lineLength, hangingIndent); auto paragraphLines = wrapSingleLineString(paragraph, lineLength, hangingIndent);
copy(paragraphLines.cbegin(), paragraphLines.cend(), back_inserter(lines)); copy(paragraphLines.cbegin(), paragraphLines.cend(), back_inserter(lines));
} }
@ -100,7 +99,7 @@ wstring latin1ToWide(const string& s) {
return result; return result;
} }
string utf8ToAscii(const string s) { string utf8ToAscii(const string& s) {
// Normalize string, simplifying it as much as possible // Normalize string, simplifying it as much as possible
const NormalizationOptions options = NormalizationOptions::CompatibilityMode const NormalizationOptions options = NormalizationOptions::CompatibilityMode
| NormalizationOptions::Decompose | NormalizationOptions::Decompose
@ -111,15 +110,15 @@ string utf8ToAscii(const string s) {
string simplified = normalizeUnicode(s, options); string simplified = normalizeUnicode(s, options);
// Replace common Unicode characters with ASCII equivalents // Replace common Unicode characters with ASCII equivalents
static const vector<std::pair<regex, string>> replacements{ static const vector<std::pair<regex, string>> replacements {
{regex("«|»|“|”|„|‟"), "\""}, { regex("«|»|“|”|„|‟"), "\"" },
{regex("|||||"), "'"}, { regex("|||||"), "'" },
{regex("||||⁻|₋||||—|―||﹣|"), "-"}, { regex("||||⁻|₋||||—|―||﹣|"), "-" },
{regex("…|⋯"), "..."}, { regex("…|⋯"), "..." },
{regex(""), "*"}, { regex(""), "*" },
{regex("†|"), "+"}, { regex("†|"), "+" },
{regex("||||/"), "/"}, { regex("||||/"), "/" },
{regex("×"), "x"}, { regex("×"), "x" },
}; };
for (const auto& replacement : replacements) { for (const auto& replacement : replacements) {
simplified = regex_replace(simplified, replacement.first, replacement.second); simplified = regex_replace(simplified, replacement.first, replacement.second);
@ -137,7 +136,7 @@ string utf8ToAscii(const string s) {
return result; return result;
} }
string normalizeUnicode(const string s, NormalizationOptions options) { string normalizeUnicode(const string& s, NormalizationOptions options) {
char* result; char* result;
const utf8proc_ssize_t charCount = utf8proc_map( const utf8proc_ssize_t charCount = utf8proc_map(
reinterpret_cast<const uint8_t*>(s.data()), reinterpret_cast<const uint8_t*>(s.data()),
@ -168,23 +167,23 @@ string escapeJsonString(const string& s) {
string result; string result;
for (char16_t c : utf16String) { for (char16_t c : utf16String) {
switch (c) { switch (c) {
case '"': result += "\\\""; break; case '"': result += "\\\""; break;
case '\\': result += "\\\\"; break; case '\\': result += "\\\\"; break;
case '\b': result += "\\b"; break; case '\b': result += "\\b"; break;
case '\f': result += "\\f"; break; case '\f': result += "\\f"; break;
case '\n': result += "\\n"; break; case '\n': result += "\\n"; break;
case '\r': result += "\\r"; break; case '\r': result += "\\r"; break;
case '\t': result += "\\t"; break; case '\t': result += "\\t"; break;
default: default:
{ {
bool needsEscaping = c < '\x20' || c >= 0x80; const bool needsEscaping = c < '\x20' || c >= 0x80;
if (needsEscaping) { if (needsEscaping) {
result += fmt::format("\\u{0:04x}", c); result += fmt::format("\\u{0:04x}", c);
} else { } else {
result += static_cast<char>(c); result += static_cast<char>(c);
}
} }
} }
}
} }
return result; return result;
} }

View File

@ -1,13 +1,16 @@
#pragma once #pragma once
#include <vector> #include <vector>
#include <boost/optional.hpp>
#include <boost/lexical_cast.hpp> #include <boost/lexical_cast.hpp>
#include <utf8proc.h> #include <utf8proc.h>
std::vector<std::string> splitIntoLines(const std::string& s); std::vector<std::string> splitIntoLines(const std::string& s);
std::vector<std::string> wrapSingleLineString(const std::string& s, int lineLength, int hangingIndent = 0); std::vector<std::string> wrapSingleLineString(
const std::string& s,
int lineLength,
int hangingIndent = 0
);
std::vector<std::string> wrapString(const std::string& s, int lineLength, int hangingIndent = 0); std::vector<std::string> wrapString(const std::string& s, int lineLength, int hangingIndent = 0);
@ -15,9 +18,7 @@ bool isValidUtf8(const std::string& s);
std::wstring latin1ToWide(const std::string& s); std::wstring latin1ToWide(const std::string& s);
boost::optional<char> toAscii(char32_t ch); std::string utf8ToAscii(const std::string& s);
std::string utf8ToAscii(const std::string s);
enum class NormalizationOptions : int { enum class NormalizationOptions : int {
CompatibilityMode = UTF8PROC_COMPAT, CompatibilityMode = UTF8PROC_COMPAT,
@ -35,7 +36,7 @@ operator|(NormalizationOptions a, NormalizationOptions b) {
return static_cast<NormalizationOptions>(static_cast<int>(a) | static_cast<int>(b)); return static_cast<NormalizationOptions>(static_cast<int>(a) | static_cast<int>(b));
} }
std::string normalizeUnicode(const std::string s, NormalizationOptions options); std::string normalizeUnicode(const std::string& s, NormalizationOptions options);
template<typename T> template<typename T>
std::string join(T range, const std::string separator) { std::string join(T range, const std::string separator) {

View File

@ -18,8 +18,8 @@ template<unsigned int n, typename iterator_type>
void for_each_adjacent( void for_each_adjacent(
iterator_type begin, iterator_type begin,
iterator_type end, iterator_type end,
std::function<void(const std::deque<std::reference_wrapper<const typename iterator_type::value_type>>&)> f) std::function<void(const std::deque<std::reference_wrapper<const typename iterator_type::value_type>>&)> f
{ ) {
// Get the first n values // Get the first n values
iterator_type it = begin; iterator_type it = begin;
using element_type = std::reference_wrapper<const typename iterator_type::value_type>; using element_type = std::reference_wrapper<const typename iterator_type::value_type>;
@ -42,20 +42,28 @@ template<typename iterator_type>
void for_each_adjacent( void for_each_adjacent(
iterator_type begin, iterator_type begin,
iterator_type end, iterator_type end,
std::function<void(const typename iterator_type::reference a, const typename iterator_type::reference b)> f) std::function<void(const typename iterator_type::reference a, const typename iterator_type::reference b)> f
{ ) {
for_each_adjacent<2>(begin, end, [&](const std::deque<std::reference_wrapper<const typename iterator_type::value_type>>& args) { for_each_adjacent<2>(
f(args[0], args[1]); begin,
}); end,
[&](const std::deque<std::reference_wrapper<const typename iterator_type::value_type>>& args) {
f(args[0], args[1]);
}
);
} }
template<typename iterator_type> template<typename iterator_type>
void for_each_adjacent( void for_each_adjacent(
iterator_type begin, iterator_type begin,
iterator_type end, iterator_type end,
std::function<void(const typename iterator_type::reference a, const typename iterator_type::reference b, const typename iterator_type::reference c)> f) std::function<void(const typename iterator_type::reference a, const typename iterator_type::reference b, const typename iterator_type::reference c)> f
{ ) {
for_each_adjacent<3>(begin, end, [&](const std::deque<std::reference_wrapper<const typename iterator_type::value_type>>& args) { for_each_adjacent<3>(
f(args[0], args[1], args[2]); begin,
}); end,
[&](const std::deque<std::reference_wrapper<const typename iterator_type::value_type>>& args) {
f(args[0], args[1], args[2]);
}
);
} }

View File

@ -6,13 +6,13 @@ namespace std {
namespace { namespace {
template <typename T> template<typename T>
void hash_combine(size_t& seed, const T& value) { void hash_combine(size_t& seed, const T& value) {
seed ^= std::hash<T>()(value) + 0x9e3779b9 + (seed << 6) + (seed >> 2); seed ^= std::hash<T>()(value) + 0x9e3779b9 + (seed << 6) + (seed >> 2);
} }
// Recursive template code derived from Matthieu M. // Recursive template code derived from Matthieu M.
template <typename Tuple, size_t Index = tuple_size<Tuple>::value - 1> template<typename Tuple, size_t Index = tuple_size<Tuple>::value - 1>
struct HashValueImpl { struct HashValueImpl {
static void apply(size_t& seed, const Tuple& tuple) { static void apply(size_t& seed, const Tuple& tuple) {
HashValueImpl<Tuple, Index - 1>::apply(seed, tuple); HashValueImpl<Tuple, Index - 1>::apply(seed, tuple);
@ -20,7 +20,7 @@ namespace std {
} }
}; };
template <typename Tuple> template<typename Tuple>
struct HashValueImpl<Tuple, 0> { struct HashValueImpl<Tuple, 0> {
static void apply(size_t& seed, const Tuple& tuple) { static void apply(size_t& seed, const Tuple& tuple) {
hash_combine(seed, std::get<0>(tuple)); hash_combine(seed, std::get<0>(tuple));
@ -28,11 +28,11 @@ namespace std {
}; };
} }
template <typename ... TT> template<typename ... TT>
struct hash<tuple<TT...>> { struct hash<tuple<TT...>> {
size_t operator()(const tuple<TT...>& tt) const { size_t operator()(const tuple<TT...>& tt) const {
size_t seed = 0; size_t seed = 0;
HashValueImpl<tuple<TT...> >::apply(seed, tt); HashValueImpl<tuple<TT...>>::apply(seed, tt);
return seed; return seed;
} }
}; };

View File

@ -7,7 +7,7 @@ using boost::optional;
using std::initializer_list; using std::initializer_list;
TEST(BoundedTimeline, constructors_initializeState) { TEST(BoundedTimeline, constructors_initializeState) {
TimeRange range(-5_cs, 55_cs); const TimeRange range(-5_cs, 55_cs);
auto args = { auto args = {
Timed<int>(-10_cs, 30_cs, 1), Timed<int>(-10_cs, 30_cs, 1),
Timed<int>(10_cs, 40_cs, 2), Timed<int>(10_cs, 40_cs, 2),
@ -52,7 +52,7 @@ TEST(BoundedTimeline, getRange) {
} }
TEST(BoundedTimeline, setAndClear) { TEST(BoundedTimeline, setAndClear) {
TimeRange range(0_cs, 10_cs); const TimeRange range(0_cs, 10_cs);
BoundedTimeline<int> timeline(range); BoundedTimeline<int> timeline(range);
// Out of range // Out of range
@ -83,8 +83,14 @@ TEST(BoundedTimeline, setAndClear) {
} }
TEST(BoundedTimeline, shift) { TEST(BoundedTimeline, shift) {
BoundedTimeline<int> timeline(TimeRange(0_cs, 10_cs), { { 1_cs, 2_cs, 1 }, { 2_cs, 5_cs, 2 }, { 7_cs, 9_cs, 3 } }); BoundedTimeline<int> timeline(
BoundedTimeline<int> expected(TimeRange(2_cs, 12_cs), { { 3_cs, 4_cs, 1 }, { 4_cs, 7_cs, 2 }, { 9_cs, 11_cs, 3 } }); TimeRange(0_cs, 10_cs),
{ { 1_cs, 2_cs, 1 }, { 2_cs, 5_cs, 2 }, { 7_cs, 9_cs, 3 } }
);
BoundedTimeline<int> expected(
TimeRange(2_cs, 12_cs),
{ { 3_cs, 4_cs, 1 }, { 4_cs, 7_cs, 2 }, { 9_cs, 11_cs, 3 } }
);
timeline.shift(2_cs); timeline.shift(2_cs);
EXPECT_EQ(expected, timeline); EXPECT_EQ(expected, timeline);
} }
@ -99,9 +105,11 @@ TEST(BoundedTimeline, equality) {
for (size_t i = 0; i < timelines.size(); ++i) { for (size_t i = 0; i < timelines.size(); ++i) {
for (size_t j = 0; j < timelines.size(); ++j) { for (size_t j = 0; j < timelines.size(); ++j) {
if (i == j) { if (i == j) {
EXPECT_EQ(timelines[i], BoundedTimeline<int>(timelines[j])) << "i: " << i << ", j: " << j; EXPECT_EQ(timelines[i], BoundedTimeline<int>(timelines[j]))
<< "i: " << i << ", j: " << j;
} else { } else {
EXPECT_NE(timelines[i], timelines[j]) << "i: " << i << ", j: " << j; EXPECT_NE(timelines[i], timelines[j])
<< "i: " << i << ", j: " << j;
} }
} }
} }

View File

@ -7,8 +7,8 @@ using boost::optional;
using std::initializer_list; using std::initializer_list;
TEST(ContinuousTimeline, constructors_initializeState) { TEST(ContinuousTimeline, constructors_initializeState) {
TimeRange range(-5_cs, 55_cs); const TimeRange range(-5_cs, 55_cs);
int defaultValue = -1; const int defaultValue = -1;
auto args = { auto args = {
Timed<int>(-10_cs, 30_cs, 1), Timed<int>(-10_cs, 30_cs, 1),
Timed<int>(10_cs, 40_cs, 2), Timed<int>(10_cs, 40_cs, 2),
@ -49,8 +49,8 @@ TEST(ContinuousTimeline, empty) {
} }
TEST(ContinuousTimeline, setAndClear) { TEST(ContinuousTimeline, setAndClear) {
TimeRange range(0_cs, 10_cs); const TimeRange range(0_cs, 10_cs);
int defaultValue = -1; const int defaultValue = -1;
ContinuousTimeline<int> timeline(range, defaultValue); ContinuousTimeline<int> timeline(range, defaultValue);
// Out of range // Out of range
@ -82,8 +82,16 @@ TEST(ContinuousTimeline, setAndClear) {
} }
TEST(ContinuousTimeline, shift) { TEST(ContinuousTimeline, shift) {
ContinuousTimeline<int> timeline(TimeRange(0_cs, 10_cs), -1, { { 1_cs, 2_cs, 1 },{ 2_cs, 5_cs, 2 },{ 7_cs, 9_cs, 3 } }); ContinuousTimeline<int> timeline(
ContinuousTimeline<int> expected(TimeRange(2_cs, 12_cs), -1, { { 3_cs, 4_cs, 1 },{ 4_cs, 7_cs, 2 },{ 9_cs, 11_cs, 3 } }); TimeRange(0_cs, 10_cs),
-1,
{ { 1_cs, 2_cs, 1 }, { 2_cs, 5_cs, 2 }, { 7_cs, 9_cs, 3 } }
);
ContinuousTimeline<int> expected(
TimeRange(2_cs, 12_cs),
-1,
{ { 3_cs, 4_cs, 1 }, { 4_cs, 7_cs, 2 }, { 9_cs, 11_cs, 3 } }
);
timeline.shift(2_cs); timeline.shift(2_cs);
EXPECT_EQ(expected, timeline); EXPECT_EQ(expected, timeline);
} }
@ -99,7 +107,8 @@ TEST(ContinuousTimeline, equality) {
for (size_t i = 0; i < timelines.size(); ++i) { for (size_t i = 0; i < timelines.size(); ++i) {
for (size_t j = 0; j < timelines.size(); ++j) { for (size_t j = 0; j < timelines.size(); ++j) {
if (i == j) { if (i == j) {
EXPECT_EQ(timelines[i], ContinuousTimeline<int>(timelines[j])) << "i: " << i << ", j: " << j; EXPECT_EQ(timelines[i], ContinuousTimeline<int>(timelines[j]))
<< "i: " << i << ", j: " << j;
} else { } else {
EXPECT_NE(timelines[i], timelines[j]) << "i: " << i << ", j: " << j; EXPECT_NE(timelines[i], timelines[j]) << "i: " << i << ", j: " << j;
} }

View File

@ -2,16 +2,15 @@
#include "tools/Lazy.h" #include "tools/Lazy.h"
using namespace testing; using namespace testing;
using std::make_unique;
// Not copyable, no default constrctor, movable // Not copyable, no default constructor, movable
struct Foo { struct Foo {
const int value; const int value;
Foo(int value) : value(value) {} Foo(int value) : value(value) {}
Foo() = delete; Foo() = delete;
Foo(const Foo&) = delete; Foo(const Foo&) = delete;
Foo& operator=(const Foo &) = delete; Foo& operator=(const Foo&) = delete;
Foo(Foo&&) = default; Foo(Foo&&) = default;
Foo& operator=(Foo&&) = default; Foo& operator=(Foo&&) = default;
@ -44,7 +43,7 @@ TEST(Lazy, constUsage) {
TEST(Lazy, copying) { TEST(Lazy, copying) {
Lazy<Foo> a; Lazy<Foo> a;
int counter = 0; int counter = 0;
auto createValue = [&] { return counter++; }; const auto createValue = [&] { return counter++; };
Lazy<Foo> b(createValue); Lazy<Foo> b(createValue);
a = b; a = b;
EXPECT_EQ(0, counter); EXPECT_EQ(0, counter);

View File

@ -1,6 +1,5 @@
#include <gmock/gmock.h> #include <gmock/gmock.h>
#include "time/Timeline.h" #include "time/Timeline.h"
#include <limits>
#include <functional> #include <functional>
using namespace testing; using namespace testing;
@ -39,15 +38,15 @@ TEST(Timeline, empty) {
EXPECT_TRUE(empty0.empty()); EXPECT_TRUE(empty0.empty());
EXPECT_THAT(empty0, IsEmpty()); EXPECT_THAT(empty0, IsEmpty());
Timeline<int> empty1{}; Timeline<int> empty1 {};
EXPECT_TRUE(empty1.empty()); EXPECT_TRUE(empty1.empty());
EXPECT_THAT(empty1, IsEmpty()); EXPECT_THAT(empty1, IsEmpty());
Timeline<int> empty2{ Timed<int>(1_cs, 1_cs, 1) }; Timeline<int> empty2 { Timed<int>(1_cs, 1_cs, 1) };
EXPECT_TRUE(empty2.empty()); EXPECT_TRUE(empty2.empty());
EXPECT_THAT(empty2, IsEmpty()); EXPECT_THAT(empty2, IsEmpty());
Timeline<int> nonEmpty{ Timed<int>(1_cs, 2_cs, 1) }; Timeline<int> nonEmpty { Timed<int>(1_cs, 2_cs, 1) };
EXPECT_FALSE(nonEmpty.empty()); EXPECT_FALSE(nonEmpty.empty());
EXPECT_THAT(nonEmpty, Not(IsEmpty())); EXPECT_THAT(nonEmpty, Not(IsEmpty()));
} }
@ -57,19 +56,19 @@ TEST(Timeline, size) {
EXPECT_EQ(0, empty0.size()); EXPECT_EQ(0, empty0.size());
EXPECT_THAT(empty0, SizeIs(0)); EXPECT_THAT(empty0, SizeIs(0));
Timeline<int> empty1{}; Timeline<int> empty1 {};
EXPECT_EQ(0, empty1.size()); EXPECT_EQ(0, empty1.size());
EXPECT_THAT(empty1, SizeIs(0)); EXPECT_THAT(empty1, SizeIs(0));
Timeline<int> empty2{ Timed<int>(1_cs, 1_cs, 1) }; Timeline<int> empty2 { Timed<int>(1_cs, 1_cs, 1) };
EXPECT_EQ(0, empty2.size()); EXPECT_EQ(0, empty2.size());
EXPECT_THAT(empty2, SizeIs(0)); EXPECT_THAT(empty2, SizeIs(0));
Timeline<int> size1{ Timed<int>(1_cs, 10_cs, 1) }; Timeline<int> size1 { Timed<int>(1_cs, 10_cs, 1) };
EXPECT_EQ(1, size1.size()); EXPECT_EQ(1, size1.size());
EXPECT_THAT(size1, SizeIs(1)); EXPECT_THAT(size1, SizeIs(1));
Timeline<int> size2{ Timed<int>(-10_cs, 10_cs, 1), Timed<int>(10_cs, 11_cs, 5) }; Timeline<int> size2 { Timed<int>(-10_cs, 10_cs, 1), Timed<int>(10_cs, 11_cs, 5) };
EXPECT_EQ(2, size2.size()); EXPECT_EQ(2, size2.size());
EXPECT_THAT(size2, SizeIs(2)); EXPECT_THAT(size2, SizeIs(2));
} }
@ -78,21 +77,21 @@ TEST(Timeline, getRange) {
Timeline<int> empty0; Timeline<int> empty0;
EXPECT_EQ(TimeRange(0_cs, 0_cs), empty0.getRange()); EXPECT_EQ(TimeRange(0_cs, 0_cs), empty0.getRange());
Timeline<int> empty1{}; Timeline<int> empty1 {};
EXPECT_EQ(TimeRange(0_cs, 0_cs), empty1.getRange()); EXPECT_EQ(TimeRange(0_cs, 0_cs), empty1.getRange());
Timeline<int> empty2{ Timed<int>(1_cs, 1_cs, 1) }; Timeline<int> empty2 { Timed<int>(1_cs, 1_cs, 1) };
EXPECT_EQ(TimeRange(0_cs, 0_cs), empty2.getRange()); EXPECT_EQ(TimeRange(0_cs, 0_cs), empty2.getRange());
Timeline<int> nonEmpty1{ Timed<int>(1_cs, 10_cs, 1) }; Timeline<int> nonEmpty1 { Timed<int>(1_cs, 10_cs, 1) };
EXPECT_EQ(TimeRange(1_cs, 10_cs), nonEmpty1.getRange()); EXPECT_EQ(TimeRange(1_cs, 10_cs), nonEmpty1.getRange());
Timeline<int> nonEmpty2{ Timed<int>(-10_cs, 5_cs, 1), Timed<int>(10_cs, 11_cs, 5) }; Timeline<int> nonEmpty2 { Timed<int>(-10_cs, 5_cs, 1), Timed<int>(10_cs, 11_cs, 5) };
EXPECT_EQ(TimeRange(-10_cs, 11_cs), nonEmpty2.getRange()); EXPECT_EQ(TimeRange(-10_cs, 11_cs), nonEmpty2.getRange());
} }
TEST(Timeline, iterators) { TEST(Timeline, iterators) {
Timeline<int> timeline{ Timed<int>(-5_cs, 0_cs, 10), Timed<int>(5_cs, 15_cs, 9) }; Timeline<int> timeline { Timed<int>(-5_cs, 0_cs, 10), Timed<int>(5_cs, 15_cs, 9) };
auto expected = { Timed<int>(-5_cs, 0_cs, 10), Timed<int>(5_cs, 15_cs, 9) }; auto expected = { Timed<int>(-5_cs, 0_cs, 10), Timed<int>(5_cs, 15_cs, 9) };
EXPECT_THAT(timeline, ElementsAreArray(expected)); EXPECT_THAT(timeline, ElementsAreArray(expected));
@ -103,17 +102,24 @@ TEST(Timeline, iterators) {
EXPECT_THAT(reversedActual, ElementsAreArray(reversedExpected)); EXPECT_THAT(reversedActual, ElementsAreArray(reversedExpected));
} }
void testFind(const Timeline<int>& timeline, FindMode findMode, const initializer_list<Timed<int>*> expectedResults) { void testFind(
const Timeline<int>& timeline,
FindMode findMode,
const initializer_list<Timed<int>*> expectedResults
) {
int i = -1; int i = -1;
for (Timed<int>* expectedResult : expectedResults) { for (Timed<int>* expectedResult : expectedResults) {
auto it = timeline.find(centiseconds(++i), findMode); auto it = timeline.find(centiseconds(++i), findMode);
if (expectedResult != nullptr) { if (expectedResult != nullptr) {
EXPECT_NE(it, timeline.end()) << "Timeline: " << timeline << "; findMode: " << static_cast<int>(findMode) << "; i: " << i; EXPECT_NE(it, timeline.end())
<< "Timeline: " << timeline << "; findMode: " << static_cast<int>(findMode) << "; i: " << i;
if (it != timeline.end()) { if (it != timeline.end()) {
EXPECT_EQ(*expectedResult, *it) << "Timeline: " << timeline << "; findMode: " << static_cast<int>(findMode) << "; i: " << i; EXPECT_EQ(*expectedResult, *it)
<< "Timeline: " << timeline << "; findMode: " << static_cast<int>(findMode) << "; i: " << i;
} }
} else { } else {
EXPECT_EQ(timeline.end(), it) << "Timeline: " << timeline << "; findMode: " << static_cast<int>(findMode) << "; i: " << i; EXPECT_EQ(timeline.end(), it)
<< "Timeline: " << timeline << "; findMode: " << static_cast<int>(findMode) << "; i: " << i;
} }
} }
} }
@ -122,7 +128,7 @@ TEST(Timeline, find) {
Timed<int> a = Timed<int>(1_cs, 2_cs, 1); Timed<int> a = Timed<int>(1_cs, 2_cs, 1);
Timed<int> b = Timed<int>(2_cs, 5_cs, 2); Timed<int> b = Timed<int>(2_cs, 5_cs, 2);
Timed<int> c = Timed<int>(7_cs, 9_cs, 3); Timed<int> c = Timed<int>(7_cs, 9_cs, 3);
Timeline<int> timeline{ a, b, c }; const Timeline<int> timeline { a, b, c };
testFind(timeline, FindMode::SampleLeft, { nullptr, nullptr, &a, &b, &b, &b, nullptr, nullptr, &c, &c, nullptr }); testFind(timeline, FindMode::SampleLeft, { nullptr, nullptr, &a, &b, &b, &b, nullptr, nullptr, &c, &c, nullptr });
testFind(timeline, FindMode::SampleRight, { nullptr, &a, &b, &b, &b, nullptr, nullptr, &c, &c, nullptr, nullptr }); testFind(timeline, FindMode::SampleRight, { nullptr, &a, &b, &b, &b, nullptr, nullptr, &c, &c, nullptr, nullptr });
@ -134,9 +140,10 @@ TEST(Timeline, get) {
Timed<int> a = Timed<int>(1_cs, 2_cs, 1); Timed<int> a = Timed<int>(1_cs, 2_cs, 1);
Timed<int> b = Timed<int>(2_cs, 5_cs, 2); Timed<int> b = Timed<int>(2_cs, 5_cs, 2);
Timed<int> c = Timed<int>(7_cs, 9_cs, 3); Timed<int> c = Timed<int>(7_cs, 9_cs, 3);
Timeline<int> timeline{ a, b, c }; Timeline<int> timeline { a, b, c };
initializer_list<Timed<int>*> expectedResults = { nullptr, &a, &b, &b, &b, nullptr, nullptr, &c, &c, nullptr, nullptr }; initializer_list<Timed<int>*> expectedResults =
{ nullptr, &a, &b, &b, &b, nullptr, nullptr, &c, &c, nullptr, nullptr };
int i = -1; int i = -1;
for (Timed<int>* expectedResult : expectedResults) { for (Timed<int>* expectedResult : expectedResults) {
optional<const Timed<int>&> value = timeline.get(centiseconds(++i)); optional<const Timed<int>&> value = timeline.get(centiseconds(++i));
@ -152,7 +159,7 @@ TEST(Timeline, get) {
} }
TEST(Timeline, clear) { TEST(Timeline, clear) {
Timeline<int> original{ { 1_cs, 2_cs, 1 }, { 2_cs, 5_cs, 2 }, { 7_cs, 9_cs, 3 } }; const Timeline<int> original { { 1_cs, 2_cs, 1 }, { 2_cs, 5_cs, 2 }, { 7_cs, 9_cs, 3 } };
{ {
auto timeline = original; auto timeline = original;
@ -163,33 +170,33 @@ TEST(Timeline, clear) {
{ {
auto timeline = original; auto timeline = original;
timeline.clear(1_cs, 2_cs); timeline.clear(1_cs, 2_cs);
Timeline<int> expected{ { 2_cs, 5_cs, 2 }, { 7_cs, 9_cs, 3 } }; Timeline<int> expected { { 2_cs, 5_cs, 2 }, { 7_cs, 9_cs, 3 } };
EXPECT_EQ(expected, timeline); EXPECT_EQ(expected, timeline);
} }
{ {
auto timeline = original; auto timeline = original;
timeline.clear(3_cs, 4_cs); timeline.clear(3_cs, 4_cs);
Timeline<int> expected{ { 1_cs, 2_cs, 1 }, { 2_cs, 3_cs, 2 }, { 4_cs, 5_cs, 2}, { 7_cs, 9_cs, 3} }; Timeline<int> expected { { 1_cs, 2_cs, 1 }, { 2_cs, 3_cs, 2 }, { 4_cs, 5_cs, 2 }, { 7_cs, 9_cs, 3 } };
EXPECT_EQ(expected, timeline); EXPECT_EQ(expected, timeline);
} }
{ {
auto timeline = original; auto timeline = original;
timeline.clear(6_cs, 8_cs); timeline.clear(6_cs, 8_cs);
Timeline<int> expected{ { 1_cs, 2_cs, 1 }, { 2_cs, 5_cs, 2 }, { 8_cs, 9_cs, 3 } }; Timeline<int> expected { { 1_cs, 2_cs, 1 }, { 2_cs, 5_cs, 2 }, { 8_cs, 9_cs, 3 } };
EXPECT_EQ(expected, timeline); EXPECT_EQ(expected, timeline);
} }
{ {
auto timeline = original; auto timeline = original;
timeline.clear(8_cs, 10_cs); timeline.clear(8_cs, 10_cs);
Timeline<int> expected{ { 1_cs, 2_cs, 1 }, { 2_cs, 5_cs, 2 }, { 7_cs, 8_cs, 3 } }; Timeline<int> expected { { 1_cs, 2_cs, 1 }, { 2_cs, 5_cs, 2 }, { 7_cs, 8_cs, 3 } };
EXPECT_EQ(expected, timeline); EXPECT_EQ(expected, timeline);
} }
} }
void testSetter(std::function<void(const Timed<int>&, Timeline<int>&)> set) { void testSetter(const std::function<void(const Timed<int>&, Timeline<int>&)>& set) {
Timeline<int> timeline; Timeline<int> timeline;
vector<optional<int>> expectedValues(20, none); vector<optional<int>> expectedValues(20, none);
auto newElements = { auto newElements = {
@ -218,7 +225,7 @@ void testSetter(std::function<void(const Timed<int>&, Timeline<int>&)> set) {
set(newElement, timeline); set(newElement, timeline);
// Update expected value for every index // Update expected value for every index
centiseconds elementStart = max(newElement.getStart(), 0_cs); const centiseconds elementStart = max(newElement.getStart(), 0_cs);
centiseconds elementEnd = newElement.getEnd(); centiseconds elementEnd = newElement.getEnd();
for (centiseconds t = elementStart; t < elementEnd; ++t) { for (centiseconds t = elementStart; t < elementEnd; ++t) {
expectedValues[t.count()] = newElement.getValue(); expectedValues[t.count()] = newElement.getValue();
@ -232,13 +239,14 @@ void testSetter(std::function<void(const Timed<int>&, Timeline<int>&)> set) {
// Check timeline via iterators // Check timeline via iterators
for (const auto& element : timeline) { for (const auto& element : timeline) {
// No element shound have zero-length // No element should have zero-length
EXPECT_LT(0_cs, element.getDuration()); EXPECT_LT(0_cs, element.getDuration());
// Element should match expected values // Element should match expected values
for (centiseconds t = std::max(centiseconds::zero(), element.getStart()); t < element.getEnd(); ++t) { for (centiseconds t = std::max(centiseconds::zero(), element.getStart()); t < element.getEnd(); ++t) {
optional<int> expectedValue = expectedValues[t.count()]; optional<int> expectedValue = expectedValues[t.count()];
EXPECT_TRUE(expectedValue) << "Index " << t.count() << " should not have a value, but is within element " << element << ". " EXPECT_TRUE(expectedValue)
<< "Index " << t.count() << " should not have a value, but is within element " << element << ". "
<< "newElementIndex: " << newElementIndex; << "newElementIndex: " << newElementIndex;
if (expectedValue) { if (expectedValue) {
EXPECT_EQ(*expectedValue, element.getValue()); EXPECT_EQ(*expectedValue, element.getValue());
@ -261,8 +269,8 @@ TEST(Timeline, set) {
} }
TEST(Timeline, indexer_get) { TEST(Timeline, indexer_get) {
Timeline<int> timeline{ { 1_cs, 2_cs, 1 }, { 2_cs, 4_cs, 2 }, { 6_cs, 9_cs, 3 } }; Timeline<int> timeline { { 1_cs, 2_cs, 1 }, { 2_cs, 4_cs, 2 }, { 6_cs, 9_cs, 3 } };
vector<optional<int>> expectedValues{ none, 1, 2, 2, none, none, 3, 3, 3 }; vector<optional<int>> expectedValues { none, 1, 2, 2, none, none, 3, 3, 3 };
for (centiseconds t = 0_cs; t < 9_cs; ++t) { for (centiseconds t = 0_cs; t < 9_cs; ++t) {
{ {
optional<int> actual = timeline[t]; optional<int> actual = timeline[t];
@ -294,63 +302,63 @@ TEST(Timeline, indexer_set) {
} }
TEST(Timeline, joinAdjacent) { TEST(Timeline, joinAdjacent) {
Timeline<int> timeline{ Timeline<int> timeline {
{1_cs, 2_cs, 1}, { 1_cs, 2_cs, 1 },
{2_cs, 4_cs, 2}, { 2_cs, 4_cs, 2 },
{3_cs, 6_cs, 2}, { 3_cs, 6_cs, 2 },
{6_cs, 7_cs, 2}, { 6_cs, 7_cs, 2 },
// Gap // Gap
{8_cs, 10_cs, 2}, { 8_cs, 10_cs, 2 },
{11_cs, 12_cs, 3} { 11_cs, 12_cs, 3 }
}; };
EXPECT_EQ(6, timeline.size()); EXPECT_EQ(6, timeline.size());
timeline.joinAdjacent(); timeline.joinAdjacent();
EXPECT_EQ(4, timeline.size()); EXPECT_EQ(4, timeline.size());
Timed<int> expectedJoined[] = { Timed<int> expectedJoined[] = {
{1_cs, 2_cs, 1}, { 1_cs, 2_cs, 1 },
{2_cs, 7_cs, 2}, { 2_cs, 7_cs, 2 },
// Gap // Gap
{8_cs, 10_cs, 2}, { 8_cs, 10_cs, 2 },
{11_cs, 12_cs, 3} { 11_cs, 12_cs, 3 }
}; };
EXPECT_THAT(timeline, ElementsAreArray(expectedJoined)); EXPECT_THAT(timeline, ElementsAreArray(expectedJoined));
} }
TEST(Timeline, autoJoin) { TEST(Timeline, autoJoin) {
JoiningTimeline<int> timeline{ JoiningTimeline<int> timeline {
{1_cs, 2_cs, 1}, { 1_cs, 2_cs, 1 },
{2_cs, 4_cs, 2}, { 2_cs, 4_cs, 2 },
{3_cs, 6_cs, 2}, { 3_cs, 6_cs, 2 },
{6_cs, 7_cs, 2}, { 6_cs, 7_cs, 2 },
// Gap // Gap
{8_cs, 10_cs, 2}, { 8_cs, 10_cs, 2 },
{11_cs, 12_cs, 3} { 11_cs, 12_cs, 3 }
}; };
Timed<int> expectedJoined[] = { Timed<int> expectedJoined[] = {
{1_cs, 2_cs, 1}, { 1_cs, 2_cs, 1 },
{2_cs, 7_cs, 2}, { 2_cs, 7_cs, 2 },
// Gap // Gap
{8_cs, 10_cs, 2}, { 8_cs, 10_cs, 2 },
{11_cs, 12_cs, 3} { 11_cs, 12_cs, 3 }
}; };
EXPECT_EQ(4, timeline.size()); EXPECT_EQ(4, timeline.size());
EXPECT_THAT(timeline, ElementsAreArray(expectedJoined)); EXPECT_THAT(timeline, ElementsAreArray(expectedJoined));
} }
TEST(Timeline, shift) { TEST(Timeline, shift) {
Timeline<int> timeline{ { 1_cs, 2_cs, 1 },{ 2_cs, 5_cs, 2 },{ 7_cs, 9_cs, 3 } }; Timeline<int> timeline { { 1_cs, 2_cs, 1 }, { 2_cs, 5_cs, 2 }, { 7_cs, 9_cs, 3 } };
Timeline<int> expected{ { 3_cs, 4_cs, 1 },{ 4_cs, 7_cs, 2 },{ 9_cs, 11_cs, 3 } }; Timeline<int> expected { { 3_cs, 4_cs, 1 }, { 4_cs, 7_cs, 2 }, { 9_cs, 11_cs, 3 } };
timeline.shift(2_cs); timeline.shift(2_cs);
EXPECT_EQ(expected, timeline); EXPECT_EQ(expected, timeline);
} }
TEST(Timeline, equality) { TEST(Timeline, equality) {
vector<Timeline<int>> timelines = { vector<Timeline<int>> timelines = {
Timeline<int>{}, Timeline<int> {},
Timeline<int>{ { 1_cs, 2_cs, 0 } }, Timeline<int> { { 1_cs, 2_cs, 0 } },
Timeline<int>{ { 1_cs, 2_cs, 1 } }, Timeline<int> { { 1_cs, 2_cs, 1 } },
Timeline<int>{ { -10_cs, 0_cs, 0 } } Timeline<int> { { -10_cs, 0_cs, 0 } }
}; };
for (size_t i = 0; i < timelines.size(); ++i) { for (size_t i = 0; i < timelines.size(); ++i) {

View File

@ -13,19 +13,20 @@ TEST(wordToPhones, basic) {
// The following phones are based on actual output, *not* ideal output. // The following phones are based on actual output, *not* ideal output.
vector<pair<string, vector<Phone>>> words { vector<pair<string, vector<Phone>>> words {
{ "once", { Phone::AA, Phone::N, Phone::S }}, { "once", { Phone::AA, Phone::N, Phone::S } },
{ "upon", { Phone::UW, Phone::P, Phone::AH, Phone::N }}, { "upon", { Phone::UW, Phone::P, Phone::AH, Phone::N } },
{ "a", { Phone::AH }}, { "a", { Phone::AH } },
{ "midnight", { Phone::M, Phone::IH, Phone::D, Phone::N, Phone::AY, Phone::T }}, { "midnight", { Phone::M, Phone::IH, Phone::D, Phone::N, Phone::AY, Phone::T } },
{ "dreary", { Phone::D, Phone::R, Phone::IY, Phone::R, Phone::IY }}, { "dreary", { Phone::D, Phone::R, Phone::IY, Phone::R, Phone::IY } },
{ "while", { Phone::W, Phone::AY, Phone::L }}, { "while", { Phone::W, Phone::AY, Phone::L } },
{ "i", { Phone::IY }}, { "i", { Phone::IY } },
{ "pondered", { Phone::P, Phone::AA, Phone::N, Phone::D, Phone::IY, Phone::R, Phone::EH, Phone::D }}, { "pondered", { Phone::P, Phone::AA, Phone::N, Phone::D, Phone::IY, Phone::R, Phone::EH, Phone::D } },
{ "weak", { Phone::W, Phone::IY, Phone::K }}, { "weak", { Phone::W, Phone::IY, Phone::K } },
{ "and", { Phone::AE, Phone::N, Phone::D }}, { "and", { Phone::AE, Phone::N, Phone::D } },
{ "weary", { Phone::W, Phone::IY, Phone::R, Phone::IY }} { "weary", { Phone::W, Phone::IY, Phone::R, Phone::IY } }
}; };
for (const auto& word : words) { for (const auto& word : words) {
EXPECT_THAT(wordToPhones(word.first), ElementsAreArray(word.second)) << "Original word: '" << word.first << "'"; EXPECT_THAT(wordToPhones(word.first), ElementsAreArray(word.second))
<< "Original word: '" << word.first << "'";
} }
} }

View File

@ -3,7 +3,6 @@
using namespace testing; using namespace testing;
using std::vector; using std::vector;
using std::initializer_list;
using std::pair; using std::pair;
TEST(getPairs, emptyCollection) { TEST(getPairs, emptyCollection) {
@ -16,18 +15,18 @@ TEST(getPairs, oneElementCollection) {
TEST(getPairs, validCollection) { TEST(getPairs, validCollection) {
{ {
auto actual = getPairs(vector<int>{ 1, 2 }); const auto actual = getPairs(vector<int> { 1, 2 });
vector<pair<int, int>> expected{ {1, 2} }; const vector<pair<int, int>> expected { { 1, 2 } };
EXPECT_THAT(actual, ElementsAreArray(expected)); EXPECT_THAT(actual, ElementsAreArray(expected));
} }
{ {
auto actual = getPairs(vector<int>{ 1, 2, 3 }); const auto actual = getPairs(vector<int> { 1, 2, 3 });
vector<pair<int, int>> expected{ {1, 2}, {2, 3} }; const vector<pair<int, int>> expected { { 1, 2 }, { 2, 3 } };
EXPECT_THAT(actual, ElementsAreArray(expected)); EXPECT_THAT(actual, ElementsAreArray(expected));
} }
{ {
auto actual = getPairs(vector<int>{ 1, 2, 3, 4 }); const auto actual = getPairs(vector<int> { 1, 2, 3, 4 });
vector<pair<int, int>> expected{ {1, 2}, {2, 3}, {3, 4} }; const vector<pair<int, int>> expected { { 1, 2 }, { 2, 3 }, { 3, 4 } };
EXPECT_THAT(actual, ElementsAreArray(expected)); EXPECT_THAT(actual, ElementsAreArray(expected));
} }
} }

View File

@ -20,7 +20,8 @@ TEST(splitIntoLines, handlesEmptyElements) {
// wrapSingleLineString // wrapSingleLineString
TEST(wrapSingleLineString, basic) { TEST(wrapSingleLineString, basic) {
const char* lipsum = "Lorem ipsum dolor sit amet, consectetur adipisici elit, sed eiusmod tempor incidunt ut labore et dolore magna aliqua."; const char* lipsum =
"Lorem ipsum dolor sit amet, consectetur adipisici elit, sed eiusmod tempor incidunt ut labore et dolore magna aliqua.";
EXPECT_THAT(wrapSingleLineString(lipsum, 30), ElementsAre("Lorem ipsum dolor sit amet,", "consectetur adipisici elit,", "sed eiusmod tempor incidunt ut", "labore et dolore magna aliqua.")); EXPECT_THAT(wrapSingleLineString(lipsum, 30), ElementsAre("Lorem ipsum dolor sit amet,", "consectetur adipisici elit,", "sed eiusmod tempor incidunt ut", "labore et dolore magna aliqua."));
} }
@ -76,8 +77,10 @@ TEST(wrapString, basic) {
// latin1ToWide // latin1ToWide
TEST(latin1ToWide, basic) { TEST(latin1ToWide, basic) {
string pangramLatin1 = "D\350s No\353l o\371 un z\351phyr ha\357 me v\352t de gla\347ons w\374rmiens, je d\356ne d'exquis r\364tis de boeuf au kir \340 l'a\377 d'\342ge m\373r & c\346tera!"; const string pangramLatin1 =
wstring pangramWide = L"Dès Noël où un zéphyr haï me vêt de glaçons würmiens, je dîne d'exquis rôtis de boeuf au kir à l'aÿ d'âge mûr & cætera!"; "D\350s No\353l o\371 un z\351phyr ha\357 me v\352t de gla\347ons w\374rmiens, je d\356ne d'exquis r\364tis de boeuf au kir \340 l'a\377 d'\342ge m\373r & c\346tera!";
wstring pangramWide =
L"Dès Noël où un zéphyr haï me vêt de glaçons würmiens, je dîne d'exquis rôtis de boeuf au kir à l'aÿ d'âge mûr & cætera!";
EXPECT_EQ(pangramWide, latin1ToWide(pangramLatin1)); EXPECT_EQ(pangramWide, latin1ToWide(pangramLatin1));
} }

View File

@ -40,15 +40,22 @@ TEST(tokenizeText, numbers) {
TEST(tokenizeText, abbreviations) { TEST(tokenizeText, abbreviations) {
EXPECT_THAT( EXPECT_THAT(
tokenizeText("Prof. Foo lives on Dr. Dolittle Dr.", [](const string& word) { return word == "prof."; }), tokenizeText(
"Prof. Foo lives on Dr. Dolittle Dr.",
[](const string& word) { return word == "prof."; }
),
ElementsAre("prof.", "foo", "lives", "on", "doctor", "dolittle", "drive") ElementsAre("prof.", "foo", "lives", "on", "doctor", "dolittle", "drive")
); );
} }
TEST(tokenizeText, apostrophes) { TEST(tokenizeText, apostrophes) {
EXPECT_THAT( EXPECT_THAT(
tokenizeText("'Tis said he'd wish'd for a 'bus 'cause he wouldn't walk.", [](const string& word) { return word == "wouldn't"; }), tokenizeText(
ElementsAreArray(vector<string>{ "tis", "said", "he'd", "wish'd", "for", "a", "bus", "cause", "he", "wouldn't", "walk" }) "'Tis said he'd wish'd for a 'bus 'cause he wouldn't walk.",
[](const string& word) { return word == "wouldn't"; }
),
ElementsAreArray(
vector<string>{ "tis", "said", "he'd", "wish'd", "for", "a", "bus", "cause", "he", "wouldn't", "walk" })
); );
} }
@ -75,7 +82,7 @@ TEST(tokenizeText, wordsUseLimitedCharacters) {
utf8::append(c, back_inserter(input)); utf8::append(c, back_inserter(input));
} }
regex legal("^[a-z']+$"); const regex legal("^[a-z']+$");
auto words = tokenizeText(input, returnTrue); auto words = tokenizeText(input, returnTrue);
for (const string& word : words) { for (const string& word : words) {
EXPECT_TRUE(std::regex_match(word, legal)) << word; EXPECT_TRUE(std::regex_match(word, legal)) << word;