// This file was autogenerated by the `uniffi-bindgen-gecko-js` crate. // Trust me, you don't want to mess with it! import { UniFFITypeError } from "resource://gre/modules/UniFFI.sys.mjs"; // Objects intended to be used in the unit tests export var UnitTestObjs = {}; // Write/Read data to/from an ArrayBuffer class ArrayBufferDataStream { constructor(arrayBuffer) { this.dataView = new DataView(arrayBuffer); this.pos = 0; } readUint8() { let rv = this.dataView.getUint8(this.pos); this.pos += 1; return rv; } writeUint8(value) { this.dataView.setUint8(this.pos, value); this.pos += 1; } readUint16() { let rv = this.dataView.getUint16(this.pos); this.pos += 2; return rv; } writeUint16(value) { this.dataView.setUint16(this.pos, value); this.pos += 2; } readUint32() { let rv = this.dataView.getUint32(this.pos); this.pos += 4; return rv; } writeUint32(value) { this.dataView.setUint32(this.pos, value); this.pos += 4; } readUint64() { let rv = this.dataView.getBigUint64(this.pos); this.pos += 8; return Number(rv); } writeUint64(value) { this.dataView.setBigUint64(this.pos, BigInt(value)); this.pos += 8; } readInt8() { let rv = this.dataView.getInt8(this.pos); this.pos += 1; return rv; } writeInt8(value) { this.dataView.setInt8(this.pos, value); this.pos += 1; } readInt16() { let rv = this.dataView.getInt16(this.pos); this.pos += 2; return rv; } writeInt16(value) { this.dataView.setInt16(this.pos, value); this.pos += 2; } readInt32() { let rv = this.dataView.getInt32(this.pos); this.pos += 4; return rv; } writeInt32(value) { this.dataView.setInt32(this.pos, value); this.pos += 4; } readInt64() { let rv = this.dataView.getBigInt64(this.pos); this.pos += 8; return Number(rv); } writeInt64(value) { this.dataView.setBigInt64(this.pos, BigInt(value)); this.pos += 8; } readFloat32() { let rv = this.dataView.getFloat32(this.pos); this.pos += 4; return rv; } writeFloat32(value) { this.dataView.setFloat32(this.pos, value); this.pos += 4; } readFloat64() { let rv = this.dataView.getFloat64(this.pos); this.pos += 8; return rv; } writeFloat64(value) { this.dataView.setFloat64(this.pos, value); this.pos += 8; } writeString(value) { const encoder = new TextEncoder(); // Note: in order to efficiently write this data, we first write the // string data, reserving 4 bytes for the size. const dest = new Uint8Array(this.dataView.buffer, this.pos + 4); const encodeResult = encoder.encodeInto(value, dest); if (encodeResult.read != value.length) { throw new UniFFIError( "writeString: out of space when writing to ArrayBuffer. Did the computeSize() method returned the wrong result?" ); } const size = encodeResult.written; // Next, go back and write the size before the string data this.dataView.setUint32(this.pos, size); // Finally, advance our position past both the size and string data this.pos += size + 4; } readString() { const decoder = new TextDecoder(); const size = this.readUint32(); const source = new Uint8Array(this.dataView.buffer, this.pos, size) const value = decoder.decode(source); this.pos += size; return value; } // Reads a Sprite pointer from the data stream // UniFFI Pointers are **always** 8 bytes long. That is enforced // by the C++ and Rust Scaffolding code. readPointerSprite() { const pointerId = 10; // sprites:Sprite const res = UniFFIScaffolding.readPointer(pointerId, this.dataView.buffer, this.pos); this.pos += 8; return res; } // Writes a Sprite pointer into the data stream // UniFFI Pointers are **always** 8 bytes long. That is enforced // by the C++ and Rust Scaffolding code. writePointerSprite(value) { const pointerId = 10; // sprites:Sprite UniFFIScaffolding.writePointer(pointerId, value, this.dataView.buffer, this.pos); this.pos += 8; } } function handleRustResult(result, liftCallback, liftErrCallback) { switch (result.code) { case "success": return liftCallback(result.data); case "error": throw liftErrCallback(result.data); case "internal-error": let message = result.internalErrorMessage; if (message) { throw new UniFFIInternalError(message); } else { throw new UniFFIInternalError("Unknown error"); } default: throw new UniFFIError(`Unexpected status code: ${result.code}`); } } class UniFFIError { constructor(message) { this.message = message; } toString() { return `UniFFIError: ${this.message}` } } class UniFFIInternalError extends UniFFIError {} // Base class for FFI converters class FfiConverter { // throw `UniFFITypeError` if a value to be converted has an invalid type static checkType(value) { if (value === undefined ) { throw new UniFFITypeError(`undefined`); } if (value === null ) { throw new UniFFITypeError(`null`); } } } // Base class for FFI converters that lift/lower by reading/writing to an ArrayBuffer class FfiConverterArrayBuffer extends FfiConverter { static lift(buf) { return this.read(new ArrayBufferDataStream(buf)); } static lower(value) { const buf = new ArrayBuffer(this.computeSize(value)); const dataStream = new ArrayBufferDataStream(buf); this.write(dataStream, value); return buf; } } // Symbols that are used to ensure that Object constructors // can only be used with a proper UniFFI pointer const uniffiObjectPtr = Symbol("uniffiObjectPtr"); const constructUniffiObject = Symbol("constructUniffiObject"); UnitTestObjs.uniffiObjectPtr = uniffiObjectPtr; // Export the FFIConverter object to make external types work. export class FfiConverterF64 extends FfiConverter { static computeSize() { return 8; } static lift(value) { return value; } static lower(value) { return value; } static write(dataStream, value) { dataStream.writeFloat64(value) } static read(dataStream) { return dataStream.readFloat64() } } // Export the FFIConverter object to make external types work. export class FfiConverterString extends FfiConverter { static checkType(value) { super.checkType(value); if (typeof value !== "string") { throw new UniFFITypeError(`${value} is not a string`); } } static lift(buf) { const decoder = new TextDecoder(); const utf8Arr = new Uint8Array(buf); return decoder.decode(utf8Arr); } static lower(value) { const encoder = new TextEncoder(); return encoder.encode(value).buffer; } static write(dataStream, value) { dataStream.writeString(value); } static read(dataStream) { return dataStream.readString(); } static computeSize(value) { const encoder = new TextEncoder(); return 4 + encoder.encode(value).length } } export class Sprite { // Use `init` to instantiate this class. // DO NOT USE THIS CONSTRUCTOR DIRECTLY constructor(opts) { if (!Object.prototype.hasOwnProperty.call(opts, constructUniffiObject)) { throw new UniFFIError("Attempting to construct an object using the JavaScript constructor directly" + "Please use a UDL defined constructor, or the init function for the primary constructor") } if (!opts[constructUniffiObject] instanceof UniFFIPointer) { throw new UniFFIError("Attempting to create a UniFFI object with a pointer that is not an instance of UniFFIPointer") } this[uniffiObjectPtr] = opts[constructUniffiObject]; } /** * An async constructor for Sprite. * * @returns {Promise}: A promise that resolves * to a newly constructed Sprite */ static init(initialPosition) { const liftResult = (result) => FfiConverterTypeSprite.lift(result); const liftError = null; const functionCall = () => { try { FfiConverterOptionalTypePoint.checkType(initialPosition) } catch (e) { if (e instanceof UniFFITypeError) { e.addItemDescriptionPart("initialPosition"); } throw e; } return UniFFIScaffolding.callAsync( 127, // sprites:uniffi_uniffi_sprites_fn_constructor_sprite_new FfiConverterOptionalTypePoint.lower(initialPosition), ) } try { return functionCall().then((result) => handleRustResult(result, liftResult, liftError)); } catch (error) { return Promise.reject(error) }} /** * An async constructor for Sprite. * * @returns {Promise}: A promise that resolves * to a newly constructed Sprite */ static newRelativeTo(reference,direction) { const liftResult = (result) => FfiConverterTypeSprite.lift(result); const liftError = null; const functionCall = () => { try { FfiConverterTypePoint.checkType(reference) } catch (e) { if (e instanceof UniFFITypeError) { e.addItemDescriptionPart("reference"); } throw e; } try { FfiConverterTypeVector.checkType(direction) } catch (e) { if (e instanceof UniFFITypeError) { e.addItemDescriptionPart("direction"); } throw e; } return UniFFIScaffolding.callAsync( 128, // sprites:uniffi_uniffi_sprites_fn_constructor_sprite_new_relative_to FfiConverterTypePoint.lower(reference), FfiConverterTypeVector.lower(direction), ) } try { return functionCall().then((result) => handleRustResult(result, liftResult, liftError)); } catch (error) { return Promise.reject(error) }} getPosition() { const liftResult = (result) => FfiConverterTypePoint.lift(result); const liftError = null; const functionCall = () => { return UniFFIScaffolding.callAsync( 129, // sprites:uniffi_uniffi_sprites_fn_method_sprite_get_position FfiConverterTypeSprite.lower(this), ) } try { return functionCall().then((result) => handleRustResult(result, liftResult, liftError)); } catch (error) { return Promise.reject(error) } } moveBy(direction) { const liftResult = (result) => undefined; const liftError = null; const functionCall = () => { try { FfiConverterTypeVector.checkType(direction) } catch (e) { if (e instanceof UniFFITypeError) { e.addItemDescriptionPart("direction"); } throw e; } return UniFFIScaffolding.callAsync( 130, // sprites:uniffi_uniffi_sprites_fn_method_sprite_move_by FfiConverterTypeSprite.lower(this), FfiConverterTypeVector.lower(direction), ) } try { return functionCall().then((result) => handleRustResult(result, liftResult, liftError)); } catch (error) { return Promise.reject(error) } } moveTo(position) { const liftResult = (result) => undefined; const liftError = null; const functionCall = () => { try { FfiConverterTypePoint.checkType(position) } catch (e) { if (e instanceof UniFFITypeError) { e.addItemDescriptionPart("position"); } throw e; } return UniFFIScaffolding.callAsync( 131, // sprites:uniffi_uniffi_sprites_fn_method_sprite_move_to FfiConverterTypeSprite.lower(this), FfiConverterTypePoint.lower(position), ) } try { return functionCall().then((result) => handleRustResult(result, liftResult, liftError)); } catch (error) { return Promise.reject(error) } } } // Export the FFIConverter object to make external types work. export class FfiConverterTypeSprite extends FfiConverter { static lift(value) { const opts = {}; opts[constructUniffiObject] = value; return new Sprite(opts); } static lower(value) { const ptr = value[uniffiObjectPtr]; if (!(ptr instanceof UniFFIPointer)) { throw new UniFFITypeError("Object is not a 'Sprite' instance"); } return ptr; } static read(dataStream) { return this.lift(dataStream.readPointerSprite()); } static write(dataStream, value) { dataStream.writePointerSprite(value[uniffiObjectPtr]); } static computeSize(value) { return 8; } } export class Point { constructor({ x, y } = {}) { try { FfiConverterF64.checkType(x) } catch (e) { if (e instanceof UniFFITypeError) { e.addItemDescriptionPart("x"); } throw e; } try { FfiConverterF64.checkType(y) } catch (e) { if (e instanceof UniFFITypeError) { e.addItemDescriptionPart("y"); } throw e; } this.x = x; this.y = y; } equals(other) { return ( this.x == other.x && this.y == other.y ) } } // Export the FFIConverter object to make external types work. export class FfiConverterTypePoint extends FfiConverterArrayBuffer { static read(dataStream) { return new Point({ x: FfiConverterF64.read(dataStream), y: FfiConverterF64.read(dataStream), }); } static write(dataStream, value) { FfiConverterF64.write(dataStream, value.x); FfiConverterF64.write(dataStream, value.y); } static computeSize(value) { let totalSize = 0; totalSize += FfiConverterF64.computeSize(value.x); totalSize += FfiConverterF64.computeSize(value.y); return totalSize } static checkType(value) { super.checkType(value); if (!(value instanceof Point)) { throw new UniFFITypeError(`Expected 'Point', found '${typeof value}'`); } try { FfiConverterF64.checkType(value.x); } catch (e) { if (e instanceof UniFFITypeError) { e.addItemDescriptionPart(".x"); } throw e; } try { FfiConverterF64.checkType(value.y); } catch (e) { if (e instanceof UniFFITypeError) { e.addItemDescriptionPart(".y"); } throw e; } } } export class Vector { constructor({ dx, dy } = {}) { try { FfiConverterF64.checkType(dx) } catch (e) { if (e instanceof UniFFITypeError) { e.addItemDescriptionPart("dx"); } throw e; } try { FfiConverterF64.checkType(dy) } catch (e) { if (e instanceof UniFFITypeError) { e.addItemDescriptionPart("dy"); } throw e; } this.dx = dx; this.dy = dy; } equals(other) { return ( this.dx == other.dx && this.dy == other.dy ) } } // Export the FFIConverter object to make external types work. export class FfiConverterTypeVector extends FfiConverterArrayBuffer { static read(dataStream) { return new Vector({ dx: FfiConverterF64.read(dataStream), dy: FfiConverterF64.read(dataStream), }); } static write(dataStream, value) { FfiConverterF64.write(dataStream, value.dx); FfiConverterF64.write(dataStream, value.dy); } static computeSize(value) { let totalSize = 0; totalSize += FfiConverterF64.computeSize(value.dx); totalSize += FfiConverterF64.computeSize(value.dy); return totalSize } static checkType(value) { super.checkType(value); if (!(value instanceof Vector)) { throw new UniFFITypeError(`Expected 'Vector', found '${typeof value}'`); } try { FfiConverterF64.checkType(value.dx); } catch (e) { if (e instanceof UniFFITypeError) { e.addItemDescriptionPart(".dx"); } throw e; } try { FfiConverterF64.checkType(value.dy); } catch (e) { if (e instanceof UniFFITypeError) { e.addItemDescriptionPart(".dy"); } throw e; } } } // Export the FFIConverter object to make external types work. export class FfiConverterOptionalTypePoint extends FfiConverterArrayBuffer { static checkType(value) { if (value !== undefined && value !== null) { FfiConverterTypePoint.checkType(value) } } static read(dataStream) { const code = dataStream.readUint8(0); switch (code) { case 0: return null case 1: return FfiConverterTypePoint.read(dataStream) default: throw UniFFIError(`Unexpected code: ${code}`); } } static write(dataStream, value) { if (value === null || value === undefined) { dataStream.writeUint8(0); return; } dataStream.writeUint8(1); FfiConverterTypePoint.write(dataStream, value) } static computeSize(value) { if (value === null || value === undefined) { return 1; } return 1 + FfiConverterTypePoint.computeSize(value) } } export function translate(position,direction) { const liftResult = (result) => FfiConverterTypePoint.lift(result); const liftError = null; const functionCall = () => { try { FfiConverterTypePoint.checkType(position) } catch (e) { if (e instanceof UniFFITypeError) { e.addItemDescriptionPart("position"); } throw e; } try { FfiConverterTypeVector.checkType(direction) } catch (e) { if (e instanceof UniFFITypeError) { e.addItemDescriptionPart("direction"); } throw e; } return UniFFIScaffolding.callAsync( 132, // sprites:uniffi_uniffi_sprites_fn_func_translate FfiConverterTypePoint.lower(position), FfiConverterTypeVector.lower(direction), ) } try { return functionCall().then((result) => handleRustResult(result, liftResult, liftError)); } catch (error) { return Promise.reject(error) } }