// Copyright (c) 2016, the Dart project authors. Please see the AUTHORS file // for details. 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:collection'; import 'dart:convert'; import 'dart:math'; import 'dart:typed_data'; const int _sizeofUint8 = 1; const int _sizeofUint16 = 2; const int _sizeofUint32 = 4; const int _sizeofUint64 = 8; const int _sizeofInt8 = 1; const int _sizeofInt16 = 2; const int _sizeofInt32 = 4; const int _sizeofInt64 = 8; const int _sizeofFloat32 = 4; const int _sizeofFloat64 = 8; /// Callback used to invoke a struct builder's finish method. /// /// This callback is used by other struct's `finish` methods to write the nested /// struct's fields inline. typedef void StructBuilder(); /// Buffer with data and some context about it. class BufferContext { final ByteData _buffer; factory BufferContext.fromBytes(List byteList) { Uint8List uint8List = _asUint8List(byteList); ByteData buf = new ByteData.view(uint8List.buffer, uint8List.offsetInBytes); return new BufferContext._(buf); } BufferContext._(this._buffer); int derefObject(int offset) { return offset + _getUint32(offset); } Uint8List _asUint8LIst(int offset, int length) => _buffer.buffer.asUint8List(_buffer.offsetInBytes + offset, length); double _getFloat64(int offset) => _buffer.getFloat64(offset, Endian.little); double _getFloat32(int offset) => _buffer.getFloat32(offset, Endian.little); int _getInt64(int offset) => _buffer.getInt64(offset, Endian.little); int _getInt32(int offset) => _buffer.getInt32(offset, Endian.little); int _getInt16(int offset) => _buffer.getInt16(offset, Endian.little); int _getInt8(int offset) => _buffer.getInt8(offset); int _getUint64(int offset) => _buffer.getUint64(offset, Endian.little); int _getUint32(int offset) => _buffer.getUint32(offset, Endian.little); int _getUint16(int offset) => _buffer.getUint16(offset, Endian.little); int _getUint8(int offset) => _buffer.getUint8(offset); /// If the [byteList] is already a [Uint8List] return it. /// Otherwise return a [Uint8List] copy of the [byteList]. static Uint8List _asUint8List(List byteList) { if (byteList is Uint8List) { return byteList; } else { return new Uint8List.fromList(byteList); } } } /// Class implemented by typed builders generated by flatc. abstract class ObjectBuilder { int _firstOffset; /// Can be used to write the data represented by this builder to the [Builder] /// and reuse the offset created in multiple tables. /// /// Note that this method assumes you call it using the same [Builder] instance /// every time. The returned offset is only good for the [Builder] used in the /// first call to this method. int getOrCreateOffset(Builder fbBuilder) { _firstOffset ??= finish(fbBuilder); return _firstOffset; } /// Writes the data in this helper to the [Builder]. int finish(Builder fbBuilder); /// Convenience method that will create a new [Builder], [finish]es the data, /// and returns the buffer as a [Uint8List] of bytes. Uint8List toBytes(); } /// Class that helps building flat buffers. class Builder { final int initialSize; /// The list of existing VTable(s). //final List<_VTable> _vTables = <_VTable>[]; final List _vTables = []; ByteData _buf; /// The maximum alignment that has been seen so far. If [_buf] has to be /// reallocated in the future (to insert room at its start for more bytes) the /// reallocation will need to be a multiple of this many bytes. int _maxAlign; /// The number of bytes that have been written to the buffer so far. The /// most recently written byte is this many bytes from the end of [_buf]. int _tail; /// The location of the end of the current table, measured in bytes from the /// end of [_buf], or `null` if a table is not currently being built. int _currentTableEndTail; _VTable _currentVTable; /// Map containing all strings that have been written so far. This allows us /// to avoid duplicating strings. /// /// Allocated only if `internStrings` is set to true on the constructor. Map _strings; /// Creates a new FlatBuffers Builder. /// /// `initialSize` is the initial array size in bytes. The [Builder] will /// automatically grow the array if/as needed. `internStrings`, if set to /// true, will cause [writeString] to pool strings in the buffer so that /// identical strings will always use the same offset in tables. Builder({this.initialSize: 1024, bool internStrings = false}) { if (internStrings == true) { _strings = new Map(); } reset(); } /// Add the [field] with the given boolean [value]. The field is not added if /// the [value] is equal to [def]. Booleans are stored as 8-bit fields with /// `0` for `false` and `1` for `true`. void addBool(int field, bool value, [bool def]) { _ensureCurrentVTable(); if (value != null && value != def) { _prepare(_sizeofUint8, 1); _trackField(field); _buf.setInt8(_buf.lengthInBytes - _tail, value ? 1 : 0); } } /// Add the [field] with the given 32-bit signed integer [value]. The field is /// not added if the [value] is equal to [def]. void addInt32(int field, int value, [int def]) { _ensureCurrentVTable(); if (value != null && value != def) { _prepare(_sizeofInt32, 1); _trackField(field); _setInt32AtTail(_buf, _tail, value); } } /// Add the [field] with the given 32-bit signed integer [value]. The field is /// not added if the [value] is equal to [def]. void addInt16(int field, int value, [int def]) { _ensureCurrentVTable(); if (value != null && value != def) { _prepare(_sizeofInt16, 1); _trackField(field); _setInt16AtTail(_buf, _tail, value); } } /// Add the [field] with the given 8-bit signed integer [value]. The field is /// not added if the [value] is equal to [def]. void addInt8(int field, int value, [int def]) { _ensureCurrentVTable(); if (value != null && value != def) { _prepare(_sizeofInt8, 1); _trackField(field); _setInt8AtTail(_buf, _tail, value); } } void addStruct(int field, int offset) { _ensureCurrentVTable(); _trackField(field); _currentVTable.addField(field, offset); } /// Add the [field] referencing an object with the given [offset]. void addOffset(int field, int offset) { _ensureCurrentVTable(); if (offset != null) { _prepare(_sizeofUint32, 1); _trackField(field); _setUint32AtTail(_buf, _tail, _tail - offset); } } /// Add the [field] with the given 32-bit unsigned integer [value]. The field /// is not added if the [value] is equal to [def]. void addUint32(int field, int value, [int def]) { _ensureCurrentVTable(); if (value != null && value != def) { _prepare(_sizeofUint32, 1); _trackField(field); _setUint32AtTail(_buf, _tail, value); } } /// Add the [field] with the given 32-bit unsigned integer [value]. The field /// is not added if the [value] is equal to [def]. void addUint16(int field, int value, [int def]) { _ensureCurrentVTable(); if (value != null && value != def) { _prepare(_sizeofUint16, 1); _trackField(field); _setUint16AtTail(_buf, _tail, value); } } /// Add the [field] with the given 8-bit unsigned integer [value]. The field /// is not added if the [value] is equal to [def]. void addUint8(int field, int value, [int def]) { _ensureCurrentVTable(); if (value != null && value != def) { _prepare(_sizeofUint8, 1); _trackField(field); _setUint8AtTail(_buf, _tail, value); } } /// Add the [field] with the given 32-bit float [value]. The field /// is not added if the [value] is equal to [def]. void addFloat32(int field, double value, [double def]) { _ensureCurrentVTable(); if (value != null && value != def) { _prepare(_sizeofFloat32, 1); _trackField(field); _setFloat32AtTail(_buf, _tail, value); } } /// Add the [field] with the given 64-bit double [value]. The field /// is not added if the [value] is equal to [def]. void addFloat64(int field, double value, [double def]) { _ensureCurrentVTable(); if (value != null && value != def) { _prepare(_sizeofFloat64, 1); _trackField(field); _setFloat64AtTail(_buf, _tail, value); } } /// Add the [field] with the given 64-bit unsigned integer [value]. The field /// is not added if the [value] is equal to [def]. void addUint64(int field, int value, [double def]) { _ensureCurrentVTable(); if (value != null && value != def) { _prepare(_sizeofUint64, 1); _trackField(field); _setUint64AtTail(_buf, _tail, value); } } /// Add the [field] with the given 64-bit unsigned integer [value]. The field /// is not added if the [value] is equal to [def]. void addInt64(int field, int value, [double def]) { _ensureCurrentVTable(); if (value != null && value != def) { _prepare(_sizeofInt64, 1); _trackField(field); _setInt64AtTail(_buf, _tail, value); } } /// End the current table and return its offset. int endTable() { if (_currentVTable == null) { throw new StateError('Start a table before ending it.'); } // Prepare for writing the VTable. _prepare(_sizeofInt32, 1); int tableTail = _tail; // Prepare the size of the current table. _currentVTable.tableSize = tableTail - _currentTableEndTail; // Prepare the VTable to use for the current table. int vTableTail; { _currentVTable.computeFieldOffsets(tableTail); // Try to find an existing compatible VTable. // Search backward - more likely to have recently used one for (int i = _vTables.length - 1; i >= 0; i--) { final int vt2Offset = _vTables[i]; final int vt2Start = _buf.lengthInBytes - vt2Offset; final int vt2Size = _buf.getUint16(vt2Start, Endian.little); if (_currentVTable._vTableSize == vt2Size && _currentVTable._offsetsMatch(vt2Start, _buf)) { vTableTail = vt2Offset; break; } } // Write a new VTable. if (vTableTail == null) { _prepare(_sizeofUint16, _currentVTable.numOfUint16); vTableTail = _tail; _currentVTable.tail = vTableTail; _currentVTable.output(_buf, _buf.lengthInBytes - _tail); _vTables.add(_currentVTable.tail); } } // Set the VTable offset. _setInt32AtTail(_buf, tableTail, vTableTail - tableTail); // Done with this table. _currentVTable = null; return tableTail; } /// This method low level method can be used to return a raw piece of the buffer /// after using the the put* methods. /// /// Most clients should prefer calling [finish]. Uint8List lowFinish() { int alignedTail = _tail + ((-_tail) % _maxAlign); return _buf.buffer.asUint8List(_buf.lengthInBytes - alignedTail); } /// Finish off the creation of the buffer. The given [offset] is used as the /// root object offset, and usually references directly or indirectly every /// written object. If [fileIdentifier] is specified (and not `null`), it is /// interpreted as a 4-byte Latin-1 encoded string that should be placed at /// bytes 4-7 of the file. Uint8List finish(int offset, [String fileIdentifier]) { _prepare(max(_sizeofUint32, _maxAlign), fileIdentifier == null ? 1 : 2); int alignedTail = _tail + ((-_tail) % _maxAlign); _setUint32AtTail(_buf, alignedTail, alignedTail - offset); if (fileIdentifier != null) { for (int i = 0; i < 4; i++) { _setUint8AtTail(_buf, alignedTail - _sizeofUint32 - i, fileIdentifier.codeUnitAt(i)); } } return _buf.buffer.asUint8List(_buf.lengthInBytes - alignedTail); } /// Writes a Float64 to the tail of the buffer after preparing space for it. /// /// Updates the [offset] pointer. This method is intended for use when writing structs to the buffer. void putFloat64(double value) { _prepare(_sizeofFloat64, 1); _setFloat32AtTail(_buf, _tail, value); } /// Writes a Float32 to the tail of the buffer after preparing space for it. /// /// Updates the [offset] pointer. This method is intended for use when writing structs to the buffer. void putFloat32(double value) { _prepare(_sizeofFloat32, 1); _setFloat32AtTail(_buf, _tail, value); } /// Writes a Int64 to the tail of the buffer after preparing space for it. /// /// Updates the [offset] pointer. This method is intended for use when writing structs to the buffer. void putInt64(int value) { _prepare(_sizeofInt64, 1); _setInt64AtTail(_buf, _tail, value); } /// Writes a Uint32 to the tail of the buffer after preparing space for it. /// /// Updates the [offset] pointer. This method is intended for use when writing structs to the buffer. void putInt32(int value) { _prepare(_sizeofInt32, 1); _setInt32AtTail(_buf, _tail, value); } /// Writes a Uint16 to the tail of the buffer after preparing space for it. /// /// Updates the [offset] pointer. This method is intended for use when writing structs to the buffer. void putInt16(int value) { _prepare(_sizeofInt16, 1); _setInt16AtTail(_buf, _tail, value); } /// Writes a Uint8 to the tail of the buffer after preparing space for it. /// /// Updates the [offset] pointer. This method is intended for use when writing structs to the buffer. void putInt8(int value) { _prepare(_sizeofInt8, 1); _buf.setInt8(_buf.lengthInBytes - _tail, value); } /// Writes a Uint64 to the tail of the buffer after preparing space for it. /// /// Updates the [offset] pointer. This method is intended for use when writing structs to the buffer. void putUint64(int value) { _prepare(_sizeofUint64, 1); _setUint64AtTail(_buf, _tail, value); } /// Writes a Uint32 to the tail of the buffer after preparing space for it. /// /// Updates the [offset] pointer. This method is intended for use when writing structs to the buffer. void putUint32(int value) { _prepare(_sizeofUint32, 1); _setUint32AtTail(_buf, _tail, value); } /// Writes a Uint16 to the tail of the buffer after preparing space for it. /// /// Updates the [offset] pointer. This method is intended for use when writing structs to the buffer. void putUint16(int value) { _prepare(_sizeofUint16, 1); _setUint16AtTail(_buf, _tail, value); } /// Writes a Uint8 to the tail of the buffer after preparing space for it. /// /// Updates the [offset] pointer. This method is intended for use when writing structs to the buffer. void putUint8(int value) { _prepare(_sizeofUint8, 1); _buf.setUint8(_buf.lengthInBytes - _tail, value); } /// Reset the builder and make it ready for filling a new buffer. void reset() { _buf = new ByteData(initialSize); _maxAlign = 1; _tail = 0; _currentVTable = null; if (_strings != null) { _strings = new Map(); } } /// Start a new table. Must be finished with [endTable] invocation. void startTable() { if (_currentVTable != null) { throw new StateError('Inline tables are not supported.'); } _currentVTable = new _VTable(); _currentTableEndTail = _tail; } /// Finish a Struct vector. Most callers should preferto use [writeListOfStructs]. /// /// Most callers should prefer [writeListOfStructs]. int endStructVector(int count) { putUint32(count); return _tail; } /// Writes a list of Structs to the buffer, returning the offset int writeListOfStructs(List structBuilders) { _ensureNoVTable(); for (int i = structBuilders.length - 1; i >= 0; i--) { structBuilders[i].finish(this); } return endStructVector(structBuilders.length); } /// Write the given list of [values]. int writeList(List values) { _ensureNoVTable(); _prepare(_sizeofUint32, 1 + values.length); final int result = _tail; int tail = _tail; _setUint32AtTail(_buf, tail, values.length); tail -= _sizeofUint32; for (int value in values) { _setUint32AtTail(_buf, tail, tail - value); tail -= _sizeofUint32; } return result; } /// Write the given list of 64-bit float [values]. int writeListFloat64(List values) { _ensureNoVTable(); _prepare(4, 1 + (2 * values.length)); final int result = _tail; int tail = _tail; _setUint32AtTail(_buf, tail, values.length); tail -= _sizeofUint32; for (double value in values) { _setFloat64AtTail(_buf, tail, value); tail -= _sizeofFloat64; } return result; } /// Write the given list of 32-bit float [values]. int writeListFloat32(List values) { _ensureNoVTable(); _prepare(_sizeofFloat32, 1 + values.length); final int result = _tail; int tail = _tail; _setUint32AtTail(_buf, tail, values.length); tail -= _sizeofUint32; for (double value in values) { _setFloat32AtTail(_buf, tail, value); tail -= _sizeofFloat32; } return result; } /// Write the given list of signed 64-bit integer [values]. int writeListInt64(List values) { _ensureNoVTable(); _prepare(_sizeofUint32, 2 * values.length); final int result = _tail; int tail = _tail; _setUint32AtTail(_buf, tail, values.length); tail -= _sizeofUint32; for (int value in values) { _setInt64AtTail(_buf, tail, value); tail -= _sizeofInt64; } return result; } /// Write the given list of signed 64-bit integer [values]. int writeListUint64(List values) { _ensureNoVTable(); _prepare(_sizeofUint32, 2 * values.length); final int result = _tail; int tail = _tail; _setUint32AtTail(_buf, tail, values.length); tail -= _sizeofUint32; for (int value in values) { _setUint64AtTail(_buf, tail, value); tail -= _sizeofUint64; } return result; } /// Write the given list of signed 32-bit integer [values]. int writeListInt32(List values) { _ensureNoVTable(); _prepare(_sizeofUint32, 1 + values.length); final int result = _tail; int tail = _tail; _setUint32AtTail(_buf, tail, values.length); tail -= _sizeofUint32; for (int value in values) { _setInt32AtTail(_buf, tail, value); tail -= _sizeofInt32; } return result; } /// Write the given list of unsigned 32-bit integer [values]. int writeListUint32(List values) { _ensureNoVTable(); _prepare(_sizeofUint32, 1 + values.length); final int result = _tail; int tail = _tail; _setUint32AtTail(_buf, tail, values.length); tail -= _sizeofUint32; for (int value in values) { _setUint32AtTail(_buf, tail, value); tail -= _sizeofUint32; } return result; } /// Write the given list of signed 16-bit integer [values]. int writeListInt16(List values) { _ensureNoVTable(); _prepare(_sizeofUint32, 1, additionalBytes: 2 * values.length); final int result = _tail; int tail = _tail; _setUint32AtTail(_buf, tail, values.length); tail -= _sizeofUint32; for (int value in values) { _setInt16AtTail(_buf, tail, value); tail -= _sizeofInt16; } return result; } /// Write the given list of unsigned 16-bit integer [values]. int writeListUint16(List values) { _ensureNoVTable(); _prepare(_sizeofUint32, 1, additionalBytes: 2 * values.length); final int result = _tail; int tail = _tail; _setUint32AtTail(_buf, tail, values.length); tail -= _sizeofUint32; for (int value in values) { _setUint16AtTail(_buf, tail, value); tail -= _sizeofUint16; } return result; } /// Write the given list of bools as unsigend 8-bit integer [values]. int writeListBool(List values) { return writeListUint8(values?.map((b) => b ? 1 : 0)?.toList()); } /// Write the given list of signed 8-bit integer [values]. int writeListInt8(List values) { _ensureNoVTable(); _prepare(_sizeofUint32, 1, additionalBytes: values.length); final int result = _tail; int tail = _tail; _setUint32AtTail(_buf, tail, values.length); tail -= _sizeofUint32; for (int value in values) { _setInt8AtTail(_buf, tail, value); tail -= _sizeofUint8; } return result; } /// Write the given list of unsigned 8-bit integer [values]. int writeListUint8(List values) { _ensureNoVTable(); _prepare(_sizeofUint32, 1, additionalBytes: values.length); final int result = _tail; int tail = _tail; _setUint32AtTail(_buf, tail, values.length); tail -= _sizeofUint32; for (int value in values) { _setUint8AtTail(_buf, tail, value); tail -= _sizeofUint8; } return result; } /// Write the given string [value] and return its offset, or `null` if /// the [value] is `null`. int writeString(String value) { _ensureNoVTable(); if (value != null) { if (_strings != null) { return _strings.putIfAbsent(value, () => _writeString(value)); } else { return _writeString(value); } } return null; } int _writeString(String value) { // TODO(scheglov) optimize for ASCII strings List bytes = utf8.encode(value); int length = bytes.length; _prepare(4, 1, additionalBytes: length + 1); final int result = _tail; _setUint32AtTail(_buf, _tail, length); int offset = _buf.lengthInBytes - _tail + 4; for (int i = 0; i < length; i++) { _buf.setUint8(offset++, bytes[i]); } return result; } /// Throw an exception if there is not currently a vtable. void _ensureCurrentVTable() { if (_currentVTable == null) { throw new StateError('Start a table before adding values.'); } } /// Throw an exception if there is currently a vtable. void _ensureNoVTable() { if (_currentVTable != null) { throw new StateError( 'Cannot write a non-scalar value while writing a table.'); } } /// The number of bytes that have been written to the buffer so far. The /// most recently written byte is this many bytes from the end of the buffer. int get offset => _tail; /// Zero-pads the buffer, which may be required for some struct layouts. void pad(int howManyBytes) { for (int i = 0; i < howManyBytes; i++) putUint8(0); } /// Prepare for writing the given `count` of scalars of the given `size`. /// Additionally allocate the specified `additionalBytes`. Update the current /// tail pointer to point at the allocated space. void _prepare(int size, int count, {int additionalBytes = 0}) { // Update the alignment. if (_maxAlign < size) { _maxAlign = size; } // Prepare amount of required space. int dataSize = size * count + additionalBytes; int alignDelta = (-(_tail + dataSize)) % size; int bufSize = alignDelta + dataSize; // Ensure that we have the required amount of space. { int oldCapacity = _buf.lengthInBytes; if (_tail + bufSize > oldCapacity) { int desiredNewCapacity = (oldCapacity + bufSize) * 2; int deltaCapacity = desiredNewCapacity - oldCapacity; deltaCapacity += (-deltaCapacity) % _maxAlign; int newCapacity = oldCapacity + deltaCapacity; ByteData newBuf = new ByteData(newCapacity); newBuf.buffer .asUint8List() .setAll(deltaCapacity, _buf.buffer.asUint8List()); _buf = newBuf; } } // Update the tail pointer. _tail += bufSize; } /// Record the offset of the given [field]. void _trackField(int field) { _currentVTable.addField(field, _tail); } static void _setFloat64AtTail(ByteData _buf, int tail, double x) { _buf.setFloat64(_buf.lengthInBytes - tail, x, Endian.little); } static void _setFloat32AtTail(ByteData _buf, int tail, double x) { _buf.setFloat32(_buf.lengthInBytes - tail, x, Endian.little); } static void _setUint64AtTail(ByteData _buf, int tail, int x) { _buf.setUint64(_buf.lengthInBytes - tail, x, Endian.little); } static void _setInt64AtTail(ByteData _buf, int tail, int x) { _buf.setInt64(_buf.lengthInBytes - tail, x, Endian.little); } static void _setInt32AtTail(ByteData _buf, int tail, int x) { _buf.setInt32(_buf.lengthInBytes - tail, x, Endian.little); } static void _setUint32AtTail(ByteData _buf, int tail, int x) { _buf.setUint32(_buf.lengthInBytes - tail, x, Endian.little); } static void _setInt16AtTail(ByteData _buf, int tail, int x) { _buf.setInt16(_buf.lengthInBytes - tail, x, Endian.little); } static void _setUint16AtTail(ByteData _buf, int tail, int x) { _buf.setUint16(_buf.lengthInBytes - tail, x, Endian.little); } static void _setInt8AtTail(ByteData _buf, int tail, int x) { _buf.setInt8(_buf.lengthInBytes - tail, x); } static void _setUint8AtTail(ByteData _buf, int tail, int x) { _buf.setUint8(_buf.lengthInBytes - tail, x); } } /// Reader of lists of boolean values. /// /// The returned unmodifiable lists lazily read values on access. class BoolListReader extends Reader> { const BoolListReader(); @override int get size => _sizeofUint32; @override List read(BufferContext bc, int offset) => new _FbBoolList(bc, bc.derefObject(offset)); } /// The reader of booleans. class BoolReader extends Reader { const BoolReader() : super(); @override int get size => _sizeofUint8; @override bool read(BufferContext bc, int offset) => bc._getInt8(offset) != 0; } /// The reader of lists of 64-bit float values. /// /// The returned unmodifiable lists lazily read values on access. class Float64ListReader extends Reader> { const Float64ListReader(); @override int get size => _sizeofFloat64; @override List read(BufferContext bc, int offset) => new _FbFloat64List(bc, bc.derefObject(offset)); } class Float32ListReader extends Reader> { const Float32ListReader(); @override int get size => _sizeofFloat32; @override List read(BufferContext bc, int offset) => new _FbFloat32List(bc, bc.derefObject(offset)); } class Float64Reader extends Reader { const Float64Reader(); @override int get size => _sizeofFloat64; @override double read(BufferContext bc, int offset) => bc._getFloat64(offset); } class Float32Reader extends Reader { const Float32Reader(); @override int get size => _sizeofFloat32; @override double read(BufferContext bc, int offset) => bc._getFloat32(offset); } class Int64Reader extends Reader { const Int64Reader() : super(); @override int get size => _sizeofInt64; @override int read(BufferContext bc, int offset) => bc._getInt64(offset); } /// The reader of signed 32-bit integers. class Int32Reader extends Reader { const Int32Reader() : super(); @override int get size => _sizeofInt32; @override int read(BufferContext bc, int offset) => bc._getInt32(offset); } /// The reader of signed 32-bit integers. class Int16Reader extends Reader { const Int16Reader() : super(); @override int get size => _sizeofInt16; @override int read(BufferContext bc, int offset) => bc._getInt16(offset); } /// The reader of 8-bit signed integers. class Int8Reader extends Reader { const Int8Reader() : super(); @override int get size => _sizeofInt8; @override int read(BufferContext bc, int offset) => bc._getInt8(offset); } /// The reader of lists of objects. /// /// The returned unmodifiable lists lazily read objects on access. class ListReader extends Reader> { final Reader _elementReader; const ListReader(this._elementReader); @override int get size => _sizeofUint32; @override List read(BufferContext bc, int offset) => new _FbGenericList(_elementReader, bc, bc.derefObject(offset)); } /// Object that can read a value at a [BufferContext]. abstract class Reader { const Reader(); /// The size of the value in bytes. int get size; /// Read the value at the given [offset] in [bc]. T read(BufferContext bc, int offset); /// Read the value of the given [field] in the given [object]. T vTableGet(BufferContext object, int offset, int field, [T defaultValue]) { int vTableSOffset = object._getInt32(offset); int vTableOffset = offset - vTableSOffset; int vTableSize = object._getUint16(vTableOffset); int vTableFieldOffset = field; if (vTableFieldOffset < vTableSize) { int fieldOffsetInObject = object._getUint16(vTableOffset + vTableFieldOffset); if (fieldOffsetInObject != 0) { return read(object, offset + fieldOffsetInObject); } } return defaultValue; } } /// The reader of string values. class StringReader extends Reader { const StringReader() : super(); @override int get size => 4; @override String read(BufferContext bc, int offset) { int strOffset = bc.derefObject(offset); int length = bc._getUint32(strOffset); Uint8List bytes = bc._asUint8LIst(strOffset + 4, length); if (_isLatin(bytes)) { return new String.fromCharCodes(bytes); } return utf8.decode(bytes); } static bool _isLatin(Uint8List bytes) { int length = bytes.length; for (int i = 0; i < length; i++) { if (bytes[i] > 127) { return false; } } return true; } } /// An abstract reader for structs. abstract class StructReader extends Reader { const StructReader(); /// Return the object at `offset`. T createObject(BufferContext bc, int offset); T read(BufferContext bp, int offset) { return createObject(bp, offset); } } /// An abstract reader for tables. abstract class TableReader extends Reader { const TableReader(); @override int get size => 4; /// Return the object at [offset]. T createObject(BufferContext bc, int offset); @override T read(BufferContext bp, int offset) { int objectOffset = bp.derefObject(offset); return createObject(bp, objectOffset); } } /// Reader of lists of unsigned 32-bit integer values. /// /// The returned unmodifiable lists lazily read values on access. class Uint32ListReader extends Reader> { const Uint32ListReader(); @override int get size => _sizeofUint32; @override List read(BufferContext bc, int offset) => new _FbUint32List(bc, bc.derefObject(offset)); } /// The reader of unsigned 64-bit integers. /// /// WARNING: May have compatibility issues with JavaScript class Uint64Reader extends Reader { const Uint64Reader() : super(); @override int get size => _sizeofUint64; @override int read(BufferContext bc, int offset) => bc._getUint64(offset); } /// The reader of unsigned 32-bit integers. class Uint32Reader extends Reader { const Uint32Reader() : super(); @override int get size => _sizeofUint32; @override int read(BufferContext bc, int offset) => bc._getUint32(offset); } /// Reader of lists of unsigned 32-bit integer values. /// /// The returned unmodifiable lists lazily read values on access. class Uint16ListReader extends Reader> { const Uint16ListReader(); @override int get size => _sizeofUint32; @override List read(BufferContext bc, int offset) => new _FbUint16List(bc, bc.derefObject(offset)); } /// The reader of unsigned 32-bit integers. class Uint16Reader extends Reader { const Uint16Reader() : super(); @override int get size => _sizeofUint16; @override int read(BufferContext bc, int offset) => bc._getUint16(offset); } /// Reader of lists of unsigned 8-bit integer values. /// /// The returned unmodifiable lists lazily read values on access. class Uint8ListReader extends Reader> { const Uint8ListReader(); @override int get size => _sizeofUint32; @override List read(BufferContext bc, int offset) => new _FbUint8List(bc, bc.derefObject(offset)); } /// The reader of unsigned 8-bit integers. class Uint8Reader extends Reader { const Uint8Reader() : super(); @override int get size => _sizeofUint8; @override int read(BufferContext bc, int offset) => bc._getUint8(offset); } /// The list backed by 64-bit values - Uint64 length and Float64. class _FbFloat64List extends _FbList { _FbFloat64List(BufferContext bc, int offset) : super(bc, offset); @override double operator [](int i) { return bc._getFloat64(offset + 4 + 8 * i); } } /// The list backed by 32-bit values - Float32. class _FbFloat32List extends _FbList { _FbFloat32List(BufferContext bc, int offset) : super(bc, offset); @override double operator [](int i) { return bc._getFloat32(offset + 4 + 4 * i); } } /// List backed by a generic object which may have any size. class _FbGenericList extends _FbList { final Reader elementReader; List _items; _FbGenericList(this.elementReader, BufferContext bp, int offset) : super(bp, offset); @override E operator [](int i) { _items ??= new List(length); E item = _items[i]; if (item == null) { item = elementReader.read(bc, offset + 4 + elementReader.size * i); _items[i] = item; } return item; } } /// The base class for immutable lists read from flat buffers. abstract class _FbList extends Object with ListMixin implements List { final BufferContext bc; final int offset; int _length; _FbList(this.bc, this.offset); @override int get length { _length ??= bc._getUint32(offset); return _length; } @override void set length(int i) => throw new StateError('Attempt to modify immutable list'); @override void operator []=(int i, E e) => throw new StateError('Attempt to modify immutable list'); } /// List backed by 32-bit unsigned integers. class _FbUint32List extends _FbList { _FbUint32List(BufferContext bc, int offset) : super(bc, offset); @override int operator [](int i) { return bc._getUint32(offset + 4 + 4 * i); } } /// List backed by 16-bit unsigned integers. class _FbUint16List extends _FbList { _FbUint16List(BufferContext bc, int offset) : super(bc, offset); @override int operator [](int i) { return bc._getUint16(offset + 4 + 2 * i); } } /// List backed by 8-bit unsigned integers. class _FbUint8List extends _FbList { _FbUint8List(BufferContext bc, int offset) : super(bc, offset); @override int operator [](int i) { return bc._getUint8(offset + 4 + i); } } /// List backed by 8-bit unsigned integers. class _FbBoolList extends _FbList { _FbBoolList(BufferContext bc, int offset) : super(bc, offset); @override bool operator [](int i) { return bc._getUint8(offset + 4 + i) == 1 ? true : false; } } /// Class that describes the structure of a table. class _VTable { static const int _metadataLength = 4; final List fieldTails = []; final List fieldOffsets = []; /// The size of the table that uses this VTable. int tableSize; /// The tail of this VTable. It is used to share the same VTable between /// multiple tables of identical structure. int tail; int get _vTableSize => numOfUint16 * _sizeofUint16; int get numOfUint16 => 1 + 1 + fieldTails.length; void addField(int field, int offset) { while (fieldTails.length <= field) { fieldTails.add(null); } fieldTails[field] = offset; } bool _offsetsMatch(int vt2Start, ByteData buf) { for (int i = 0; i < fieldOffsets.length; i++) { if (fieldOffsets[i] != buf.getUint16( vt2Start + _metadataLength + (2 * i), Endian.little)) { return false; } } return true; } /// Fill the [fieldOffsets] field. void computeFieldOffsets(int tableTail) { assert(fieldOffsets.isEmpty); for (int fieldTail in fieldTails) { int fieldOffset = fieldTail == null ? 0 : tableTail - fieldTail; fieldOffsets.add(fieldOffset); } } /// Outputs this VTable to [buf], which is is expected to be aligned to 16-bit /// and have at least [numOfUint16] 16-bit words available. void output(ByteData buf, int bufOffset) { // VTable size. buf.setUint16(bufOffset, numOfUint16 * 2, Endian.little); bufOffset += 2; // Table size. buf.setUint16(bufOffset, tableSize, Endian.little); bufOffset += 2; // Field offsets. for (int fieldOffset in fieldOffsets) { buf.setUint16(bufOffset, fieldOffset, Endian.little); bufOffset += 2; } } }