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// Copyright 2013 The Flutter Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
import 'dart:convert';
import 'dart:io';
import 'dart:mirrors';
import 'ast.dart';
/// The current version of pigeon. This must match the version in pubspec.yaml.
const String pigeonVersion = '1.0.12';
/// Read all the content from [stdin] to a String.
String readStdin() {
final List<int> bytes = <int>[];
int byte = stdin.readByteSync();
while (byte >= 0) {
bytes.add(byte);
byte = stdin.readByteSync();
}
return utf8.decode(bytes);
}
/// A helper class for managing indentation, wrapping a [StringSink].
class Indent {
/// Constructor which takes a [StringSink] [Ident] will wrap.
Indent(this._sink);
int _count = 0;
final StringSink _sink;
/// String used for newlines (ex "\n").
final String newline = '\n';
/// String used to represent a tab.
final String tab = ' ';
/// Increase the indentation level.
void inc([int level = 1]) {
_count += level;
}
/// Decrement the indentation level.
void dec([int level = 1]) {
_count -= level;
}
/// Returns the String representing the current indentation.
String str() {
String result = '';
for (int i = 0; i < _count; i++) {
result += tab;
}
return result;
}
/// Replaces the newlines and tabs of input and adds it to the stream.
void format(String input,
{bool leadingSpace = true, bool trailingNewline = true}) {
final List<String> lines = input.split('\n');
for (int i = 0; i < lines.length; ++i) {
final String line = lines[i];
if (i == 0 && !leadingSpace) {
addln(line.replaceAll('\t', tab));
} else if (i == lines.length - 1 && !trailingNewline) {
write(line.replaceAll('\t', tab));
} else {
writeln(line.replaceAll('\t', tab));
}
}
}
/// Scoped increase of the ident level. For the execution of [func] the
/// indentation will be incremented.
void scoped(
String? begin,
String? end,
Function func, {
bool addTrailingNewline = true,
}) {
if (begin != null) {
_sink.write(begin + newline);
}
nest(1, func);
if (end != null) {
_sink.write(str() + end);
if (addTrailingNewline) {
_sink.write(newline);
}
}
}
/// Like `scoped` but writes the current indentation level.
void writeScoped(
String? begin,
String end,
Function func, {
bool addTrailingNewline = true,
}) {
scoped(str() + (begin ?? ''), end, func,
addTrailingNewline: addTrailingNewline);
}
/// Scoped increase of the ident level. For the execution of [func] the
/// indentation will be incremented by the given amount.
void nest(int count, Function func) {
inc(count);
func();
dec(count);
}
/// Add [text] with indentation and a newline.
void writeln(String text) {
if (text.isEmpty) {
_sink.write(newline);
} else {
_sink.write(str() + text + newline);
}
}
/// Add [text] with indentation.
void write(String text) {
_sink.write(str() + text);
}
/// Add [text] with a newline.
void addln(String text) {
_sink.write(text + newline);
}
/// Just adds [text].
void add(String text) {
_sink.write(text);
}
}
/// Create the generated channel name for a [func] on a [api].
String makeChannelName(Api api, Method func) {
return 'dev.flutter.pigeon.${api.name}.${func.name}';
}
/// Represents the mapping of a Dart datatype to a Host datatype.
class HostDatatype {
/// Parametric constructor for HostDatatype.
HostDatatype({
required this.datatype,
required this.isBuiltin,
});
/// The [String] that can be printed into host code to represent the type.
final String datatype;
/// `true` if the host datatype is something builtin.
final bool isBuiltin;
}
/// Calculates the [HostDatatype] for the provided [NamedType]. It will check
/// the field against [classes], the list of custom classes, to check if it is a
/// builtin type. [builtinResolver] will return the host datatype for the Dart
/// datatype for builtin types. [customResolver] can modify the datatype of
/// custom types.
HostDatatype getHostDatatype(NamedType field, List<Class> classes,
List<Enum> enums, String? Function(NamedType) builtinResolver,
{String Function(String)? customResolver}) {
final String? datatype = builtinResolver(field);
if (datatype == null) {
if (classes.map((Class x) => x.name).contains(field.type.baseName)) {
final String customName = customResolver != null
? customResolver(field.type.baseName)
: field.type.baseName;
return HostDatatype(datatype: customName, isBuiltin: false);
} else if (enums.map((Enum x) => x.name).contains(field.type.baseName)) {
final String customName = customResolver != null
? customResolver(field.type.baseName)
: field.type.baseName;
return HostDatatype(datatype: customName, isBuiltin: false);
} else {
throw Exception(
'unrecognized datatype for field:"${field.name}" of type:"${field.type.baseName}"');
}
} else {
return HostDatatype(datatype: datatype, isBuiltin: true);
}
}
/// Warning printed at the top of all generated code.
const String generatedCodeWarning =
'Autogenerated from Pigeon (v$pigeonVersion), do not edit directly.';
/// String to be printed after `generatedCodeWarning`.
const String seeAlsoWarning = 'See also: https://pub.dev/packages/pigeon';
/// Collection of keys used in dictionaries across generators.
class Keys {
/// The key in the result hash for the 'result' value.
static const String result = 'result';
/// The key in the result hash for the 'error' value.
static const String error = 'error';
/// The key in an error hash for the 'code' value.
static const String errorCode = 'code';
/// The key in an error hash for the 'message' value.
static const String errorMessage = 'message';
/// The key in an error hash for the 'details' value.
static const String errorDetails = 'details';
}
/// Returns true if `type` represents 'void'.
bool isVoid(TypeMirror type) {
return MirrorSystem.getName(type.simpleName) == 'void';
}
/// Adds the [lines] to [indent].
void addLines(Indent indent, Iterable<String> lines, {String? linePrefix}) {
final String prefix = linePrefix ?? '';
for (final String line in lines) {
indent.writeln('$prefix$line');
}
}
/// Recursively merges [modification] into [base]. In other words, whenever
/// there is a conflict over the value of a key path, [modification]'s value for
/// that key path is selected.
Map<String, Object> mergeMaps(
Map<String, Object> base,
Map<String, Object> modification,
) {
final Map<String, Object> result = <String, Object>{};
for (final MapEntry<String, Object> entry in modification.entries) {
if (base.containsKey(entry.key)) {
final Object entryValue = entry.value;
if (entryValue is Map<String, Object>) {
assert(base[entry.key] is Map<String, Object>);
result[entry.key] =
mergeMaps((base[entry.key] as Map<String, Object>?)!, entryValue);
} else {
result[entry.key] = entry.value;
}
} else {
result[entry.key] = entry.value;
}
}
for (final MapEntry<String, Object> entry in base.entries) {
if (!result.containsKey(entry.key)) {
result[entry.key] = entry.value;
}
}
return result;
}
/// A class name that is enumerated.
class EnumeratedClass {
/// Constructor.
EnumeratedClass(this.name, this.enumeration);
/// The name of the class.
final String name;
/// The enumeration of the class.
final int enumeration;
}
/// Supported basic datatypes.
const List<String> validTypes = <String>[
'String',
'bool',
'int',
'double',
'Uint8List',
'Int32List',
'Int64List',
'Float64List',
'List',
'Map',
'Object',
];
/// Custom codecs' custom types are enumerated from 255 down to this number to
/// avoid collisions with the StandardMessageCodec.
const int _minimumCodecFieldKey = 128;
Iterable<TypeDeclaration> _getTypeArguments(TypeDeclaration type) sync* {
for (final TypeDeclaration typeArg in type.typeArguments) {
yield* _getTypeArguments(typeArg);
}
yield type;
}
bool _isUnseenCustomType(
TypeDeclaration type, Set<String> referencedTypeNames) {
return !referencedTypeNames.contains(type.baseName) &&
!validTypes.contains(type.baseName);
}
class _Bag<Key, Value> {
Map<Key, List<Value>> map = <Key, List<Value>>{};
void add(Key key, Value? value) {
if (!map.containsKey(key)) {
map[key] = value == null ? <Value>[] : <Value>[value];
} else {
if (value != null) {
map[key]!.add(value);
}
}
}
void addMany(Iterable<Key> keys, Value? value) {
for (final Key key in keys) {
add(key, value);
}
}
}
/// Recurses into a list of [Api]s and produces a list of all referenced types
/// and an associated [List] of the offsets where they are found.
Map<TypeDeclaration, List<int>> getReferencedTypes(
List<Api> apis, List<Class> classes) {
final _Bag<TypeDeclaration, int> references = _Bag<TypeDeclaration, int>();
for (final Api api in apis) {
for (final Method method in api.methods) {
for (final NamedType field in method.arguments) {
references.addMany(_getTypeArguments(field.type), field.offset);
}
references.addMany(_getTypeArguments(method.returnType), method.offset);
}
}
final Set<String> referencedTypeNames =
references.map.keys.map((TypeDeclaration e) => e.baseName).toSet();
final List<String> classesToCheck = List<String>.from(referencedTypeNames);
while (classesToCheck.isNotEmpty) {
final String next = classesToCheck.removeLast();
final Class aClass = classes.firstWhere((Class x) => x.name == next,
orElse: () => Class(name: '', fields: <NamedType>[]));
for (final NamedType field in aClass.fields) {
if (_isUnseenCustomType(field.type, referencedTypeNames)) {
references.add(field.type, field.offset);
classesToCheck.add(field.type.baseName);
}
for (final TypeDeclaration typeArg in field.type.typeArguments) {
if (_isUnseenCustomType(typeArg, referencedTypeNames)) {
references.add(typeArg, field.offset);
classesToCheck.add(typeArg.baseName);
}
}
}
}
return references.map;
}
/// Returns true if the concrete type cannot be determined at compile-time.
bool _isConcreteTypeAmbiguous(TypeDeclaration type) {
return (type.baseName == 'List' && type.typeArguments.isEmpty) ||
(type.baseName == 'Map' && type.typeArguments.isEmpty) ||
type.baseName == 'Object';
}
/// Given an [Api], return the enumerated classes that must exist in the codec
/// where the enumeration should be the key used in the buffer.
Iterable<EnumeratedClass> getCodecClasses(Api api, Root root) sync* {
final Set<String> enumNames = root.enums.map((Enum e) => e.name).toSet();
final Map<TypeDeclaration, List<int>> referencedTypes =
getReferencedTypes(<Api>[api], root.classes);
final Iterable<String> allTypeNames =
referencedTypes.keys.any(_isConcreteTypeAmbiguous)
? root.classes.map((Class aClass) => aClass.name)
: referencedTypes.keys.map((TypeDeclaration e) => e.baseName);
final List<String> sortedNames = allTypeNames
.where((String element) =>
element != 'void' &&
!validTypes.contains(element) &&
!enumNames.contains(element))
.toList();
sortedNames.sort();
int enumeration = _minimumCodecFieldKey;
const int maxCustomClassesPerApi = 255 - _minimumCodecFieldKey;
if (sortedNames.length > maxCustomClassesPerApi) {
throw Exception(
'Pigeon doesn\'t support more than $maxCustomClassesPerApi referenced custom classes per API, try splitting up your APIs.');
}
for (final String name in sortedNames) {
yield EnumeratedClass(name, enumeration);
enumeration += 1;
}
}