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denoland-deno/test_ffi/tests/test.js

796 lines
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JavaScript

// Copyright 2018-2023 the Deno authors. All rights reserved. MIT license.
// deno-lint-ignore-file
// Run using cargo test or `--v8-flags=--allow-natives-syntax`
import {
assertThrows,
assert,
assertNotEquals,
assertInstanceOf,
assertEquals,
assertFalse,
} from "../../test_util/std/testing/asserts.ts";
const targetDir = Deno.execPath().replace(/[^\/\\]+$/, "");
const [libPrefix, libSuffix] = {
darwin: ["lib", "dylib"],
linux: ["lib", "so"],
windows: ["", "dll"],
}[Deno.build.os];
const libPath = `${targetDir}/${libPrefix}test_ffi.${libSuffix}`;
const resourcesPre = Deno.resources();
// dlopen shouldn't panic
assertThrows(() => {
Deno.dlopen("cli/src/main.rs", {});
});
assertThrows(
() => {
Deno.dlopen(libPath, {
non_existent_symbol: {
parameters: [],
result: "void",
},
});
},
Error,
"Failed to register symbol non_existent_symbol",
);
assertThrows(() => {
Deno.dlopen(libPath, {
print_something: {
parameters: [],
result: { struct: [] }
},
}),
TypeError,
"Struct must have at least one field"
});
assertThrows(() => {
Deno.dlopen(libPath, {
print_something: {
parameters: [ { struct: [] } ],
result: "void",
},
}),
TypeError,
"Struct must have at least one field"
});
const Empty = { struct: [] }
assertThrows(() => {
Deno.dlopen(libPath, {
print_something: {
parameters: [ { struct: [Empty] } ],
result: "void",
},
}),
TypeError,
"Struct must have at least one field"
});
const Point = ["f64", "f64"];
const Size = ["f64", "f64"];
const Rect = ["f64", "f64", "f64", "f64"];
const RectNested = [{ struct: Point }, { struct: Size }];
const Mixed = ["u8", "f32", { struct: Rect }, "usize", { struct: ["u32", "u32"] }];
const dylib = Deno.dlopen(libPath, {
"printSomething": {
name: "print_something",
parameters: [],
result: "void",
},
"print_buffer": { parameters: ["buffer", "usize"], result: "void" },
"print_pointer": { name: "print_buffer", parameters: ["pointer", "usize"], result: "void" },
"print_buffer2": {
parameters: ["buffer", "usize", "buffer", "usize"],
result: "void",
},
"return_buffer": { parameters: [], result: "buffer" },
"is_null_ptr": { parameters: ["pointer"], result: "bool" },
"is_null_buf": { name: "is_null_ptr", parameters: ["buffer"], result: "bool" },
"add_u32": { parameters: ["u32", "u32"], result: "u32" },
"add_i32": { parameters: ["i32", "i32"], result: "i32" },
"add_u64": { parameters: ["u64", "u64"], result: "u64" },
"add_i64": { parameters: ["i64", "i64"], result: "i64" },
"add_usize": { parameters: ["usize", "usize"], result: "usize" },
"add_usize_fast": { parameters: ["usize", "usize"], result: "u32" },
"add_isize": { parameters: ["isize", "isize"], result: "isize" },
"add_f32": { parameters: ["f32", "f32"], result: "f32" },
"add_f64": { parameters: ["f64", "f64"], result: "f64" },
"and": { parameters: ["bool", "bool"], result: "bool" },
"add_u32_nonblocking": {
name: "add_u32",
parameters: ["u32", "u32"],
result: "u32",
nonblocking: true,
},
"add_i32_nonblocking": {
name: "add_i32",
parameters: ["i32", "i32"],
result: "i32",
nonblocking: true,
},
"add_u64_nonblocking": {
name: "add_u64",
parameters: ["u64", "u64"],
result: "u64",
nonblocking: true,
},
"add_i64_nonblocking": {
name: "add_i64",
parameters: ["i64", "i64"],
result: "i64",
nonblocking: true,
},
"add_usize_nonblocking": {
name: "add_usize",
parameters: ["usize", "usize"],
result: "usize",
nonblocking: true,
},
"add_isize_nonblocking": {
name: "add_isize",
parameters: ["isize", "isize"],
result: "isize",
nonblocking: true,
},
"add_f32_nonblocking": {
name: "add_f32",
parameters: ["f32", "f32"],
result: "f32",
nonblocking: true,
},
"add_f64_nonblocking": {
name: "add_f64",
parameters: ["f64", "f64"],
result: "f64",
nonblocking: true,
},
"fill_buffer": { parameters: ["u8", "buffer", "usize"], result: "void" },
"sleep_nonblocking": {
name: "sleep_blocking",
parameters: ["u64"],
result: "void",
nonblocking: true,
},
"sleep_blocking": { parameters: ["u64"], result: "void" },
"nonblocking_buffer": {
parameters: ["buffer", "usize"],
result: "void",
nonblocking: true,
},
"get_add_u32_ptr": {
parameters: [],
result: "pointer",
},
"get_sleep_blocking_ptr": {
parameters: [],
result: "pointer",
},
// Callback function
call_fn_ptr: {
parameters: ["function"],
result: "void",
},
call_fn_ptr_thread_safe: {
name: "call_fn_ptr",
parameters: ["function"],
result: "void",
nonblocking: true,
},
call_fn_ptr_many_parameters: {
parameters: ["function"],
result: "void",
},
call_fn_ptr_return_u8: {
parameters: ["function"],
result: "void",
},
call_fn_ptr_return_u8_thread_safe: {
name: "call_fn_ptr_return_u8",
parameters: ["function"],
result: "void",
},
call_fn_ptr_return_buffer: {
parameters: ["function"],
result: "void",
},
store_function: {
parameters: ["function"],
result: "void",
},
store_function_2: {
parameters: ["function"],
result: "void",
},
call_stored_function: {
parameters: [],
result: "void",
callback: true,
},
call_stored_function_2: {
parameters: ["u8"],
result: "void",
callback: true,
},
log_many_parameters: {
parameters: ["u8", "u16", "u32", "u64", "f64", "f32", "i64", "i32", "i16", "i8", "isize", "usize", "f64", "f32", "f64", "f32", "f64", "f32", "f64"],
result: "void",
},
cast_u8_u32: {
parameters: ["u8"],
result: "u32",
},
cast_u32_u8: {
parameters: ["u32"],
result: "u8",
},
add_many_u16: {
parameters: ["u16", "u16", "u16", "u16", "u16", "u16", "u16", "u16", "u16", "u16", "u16", "u16", "u16"],
result: "u16",
},
// Statics
"static_u32": {
type: "u32",
},
"static_i64": {
type: "i64",
},
"static_ptr": {
type: "pointer",
},
/**
* Invalid UTF-8 characters, buffer of length 14
*/
"static_char": {
type: "pointer",
},
"hash": { parameters: ["buffer", "u32"], result: "u32" },
make_rect: {
parameters: ["f64", "f64", "f64", "f64"],
result: { struct: Rect },
},
make_rect_async: {
name: "make_rect",
nonblocking: true,
parameters: ["f64", "f64", "f64", "f64"],
result: { struct: RectNested },
},
print_rect: {
parameters: [{ struct: Rect }],
result: "void",
},
print_rect_async: {
name: "print_rect",
nonblocking: true,
parameters: [{ struct: Rect }],
result: "void",
},
create_mixed: {
parameters: ["u8", "f32", { struct: Rect }, "pointer", "buffer"],
result: { struct: Mixed }
},
print_mixed: {
parameters: [{ struct: Mixed }],
result: "void",
},
});
const { symbols } = dylib;
symbols.printSomething();
const buffer = new Uint8Array([1, 2, 3, 4, 5, 6, 7, 8]);
const buffer2 = new Uint8Array([9, 10]);
dylib.symbols.print_buffer(buffer, buffer.length);
// Test subarrays
const subarray = buffer.subarray(3);
dylib.symbols.print_buffer(subarray, subarray.length - 2);
dylib.symbols.print_buffer2(buffer, buffer.length, buffer2, buffer2.length);
const { return_buffer } = symbols;
function returnBuffer() { return return_buffer(); };
%PrepareFunctionForOptimization(returnBuffer);
returnBuffer();
%OptimizeFunctionOnNextCall(returnBuffer);
const ptr0 = returnBuffer();
assertIsOptimized(returnBuffer);
dylib.symbols.print_pointer(ptr0, 8);
const ptrView = new Deno.UnsafePointerView(ptr0);
const into = new Uint8Array(6);
const into2 = new Uint8Array(3);
const into2ptr = Deno.UnsafePointer.of(into2);
const into2ptrView = new Deno.UnsafePointerView(into2ptr);
const into3 = new Uint8Array(3);
ptrView.copyInto(into);
console.log([...into]);
ptrView.copyInto(into2, 3);
console.log([...into2]);
into2ptrView.copyInto(into3);
console.log([...into3]);
const string = new Uint8Array([
...new TextEncoder().encode("Hello from pointer!"),
0,
]);
const stringPtr = Deno.UnsafePointer.of(string);
const stringPtrview = new Deno.UnsafePointerView(stringPtr);
console.log(stringPtrview.getCString());
console.log(stringPtrview.getCString(11));
console.log(dylib.symbols.is_null_ptr(ptr0));
console.log(dylib.symbols.is_null_ptr(null));
console.log(dylib.symbols.is_null_ptr(Deno.UnsafePointer.of(into)));
const emptyBuffer = new Uint8Array(0);
console.log(dylib.symbols.is_null_ptr(Deno.UnsafePointer.of(emptyBuffer)));
const emptySlice = into.subarray(6);
console.log(dylib.symbols.is_null_ptr(Deno.UnsafePointer.of(emptySlice)));
const { is_null_buf } = symbols;
function isNullBuffer(buffer) { return is_null_buf(buffer); };
function isNullBufferDeopt(buffer) { return is_null_buf(buffer); };
%PrepareFunctionForOptimization(isNullBuffer);
isNullBuffer(emptyBuffer);
%NeverOptimizeFunction(isNullBufferDeopt);
%OptimizeFunctionOnNextCall(isNullBuffer);
isNullBuffer(emptyBuffer);
assertIsOptimized(isNullBuffer);
// ==== ZERO LENGTH BUFFER TESTS ====
assertEquals(isNullBuffer(emptyBuffer), true, "isNullBuffer(emptyBuffer) !== true");
assertEquals(isNullBufferDeopt(emptyBuffer), true, "isNullBufferDeopt(emptyBuffer) !== true");
assertEquals(isNullBuffer(emptySlice), false, "isNullBuffer(emptySlice) !== false");
assertEquals(isNullBufferDeopt(emptySlice), false, "isNullBufferDeopt(emptySlice) !== false");
assertEquals(isNullBufferDeopt(new Uint8Array()), true, "isNullBufferDeopt(new Uint8Array()) !== true");
// ==== V8 ZERO LENGTH BUFFER ANOMALIES ====
// V8 bug: inline Uint8Array creation to fast call sees non-null pointer
// https://bugs.chromium.org/p/v8/issues/detail?id=13489
assertEquals(isNullBuffer(new Uint8Array()), false, "isNullBuffer(new Uint8Array()) !== false");
// Externally backed ArrayBuffer has a non-null data pointer, even though its length is zero.
const externalZeroBuffer = new Uint8Array(Deno.UnsafePointerView.getArrayBuffer(ptr0, 0));
// However: V8 Fast calls get null pointers for zero-sized buffers.
assertEquals(isNullBuffer(externalZeroBuffer), true, "isNullBuffer(externalZeroBuffer) !== true");
// Also: V8's `Local<ArrayBuffer>->Data()` method returns null pointers for zero-sized buffers.
// Using `Local<ArrayBuffer>->GetBackingStore()->Data()` would give the original pointer.
assertEquals(isNullBufferDeopt(externalZeroBuffer), true, "isNullBufferDeopt(externalZeroBuffer) !== true");
// The same pointer with a non-zero byte length for the buffer will return non-null pointers in
// both Fast call and V8 API calls.
const externalOneBuffer = new Uint8Array(Deno.UnsafePointerView.getArrayBuffer(ptr0, 1));
assertEquals(isNullBuffer(externalOneBuffer), false, "isNullBuffer(externalOneBuffer) !== false");
assertEquals(isNullBufferDeopt(externalOneBuffer), false, "isNullBufferDeopt(externalOneBuffer) !== false");
// Due to ops macro using `Local<ArrayBuffer>->Data()` to get the pointer for the slice that is then used to get
// the pointer of an ArrayBuffer / TypedArray, the same effect can be seen where a zero byte length buffer returns
// a null pointer as its pointer value.
assertEquals(Deno.UnsafePointer.of(externalZeroBuffer), null, "Deno.UnsafePointer.of(externalZeroBuffer) !== null");
assertNotEquals(Deno.UnsafePointer.of(externalOneBuffer), null, "Deno.UnsafePointer.of(externalOneBuffer) === null");
const addU32Ptr = dylib.symbols.get_add_u32_ptr();
const addU32 = new Deno.UnsafeFnPointer(addU32Ptr, {
parameters: ["u32", "u32"],
result: "u32",
});
console.log(addU32.call(123, 456));
const sleepBlockingPtr = dylib.symbols.get_sleep_blocking_ptr();
const sleepNonBlocking = new Deno.UnsafeFnPointer(sleepBlockingPtr, {
nonblocking: true,
parameters: ["u64"],
result: "void",
});
const before = performance.now();
await sleepNonBlocking.call(100);
console.log(performance.now() - before >= 100);
const { add_u32, add_usize_fast } = symbols;
function addU32Fast(a, b) {
return add_u32(a, b);
};
testOptimized(addU32Fast, () => addU32Fast(123, 456));
function addU64Fast(a, b) { return add_usize_fast(a, b); };
testOptimized(addU64Fast, () => addU64Fast(2, 3));
console.log(dylib.symbols.add_i32(123, 456));
console.log(dylib.symbols.add_u64(0xffffffffn, 0xffffffffn));
console.log(dylib.symbols.add_i64(-0xffffffffn, -0xffffffffn));
console.log(dylib.symbols.add_usize(0xffffffffn, 0xffffffffn));
console.log(dylib.symbols.add_isize(-0xffffffffn, -0xffffffffn));
console.log(dylib.symbols.add_u64(Number.MAX_SAFE_INTEGER, 1));
console.log(dylib.symbols.add_i64(Number.MAX_SAFE_INTEGER, 1));
console.log(dylib.symbols.add_i64(Number.MIN_SAFE_INTEGER, -1));
console.log(dylib.symbols.add_usize(Number.MAX_SAFE_INTEGER, 1));
console.log(dylib.symbols.add_isize(Number.MAX_SAFE_INTEGER, 1));
console.log(dylib.symbols.add_isize(Number.MIN_SAFE_INTEGER, -1));
console.log(dylib.symbols.add_f32(123.123, 456.789));
console.log(dylib.symbols.add_f64(123.123, 456.789));
console.log(dylib.symbols.and(true, true));
console.log(dylib.symbols.and(true, false));
function addF32Fast(a, b) {
return dylib.symbols.add_f32(a, b);
};
testOptimized(addF32Fast, () => addF32Fast(123.123, 456.789));
function addF64Fast(a, b) {
return dylib.symbols.add_f64(a, b);
};
testOptimized(addF64Fast, () => addF64Fast(123.123, 456.789));
// Test adders as nonblocking calls
console.log(await dylib.symbols.add_i32_nonblocking(123, 456));
console.log(await dylib.symbols.add_u64_nonblocking(0xffffffffn, 0xffffffffn));
console.log(
await dylib.symbols.add_i64_nonblocking(-0xffffffffn, -0xffffffffn),
);
console.log(
await dylib.symbols.add_usize_nonblocking(0xffffffffn, 0xffffffffn),
);
console.log(
await dylib.symbols.add_isize_nonblocking(-0xffffffffn, -0xffffffffn),
);
console.log(await dylib.symbols.add_u64_nonblocking(Number.MAX_SAFE_INTEGER, 1));
console.log(await dylib.symbols.add_i64_nonblocking(Number.MAX_SAFE_INTEGER, 1));
console.log(await dylib.symbols.add_i64_nonblocking(Number.MIN_SAFE_INTEGER, -1));
console.log(await dylib.symbols.add_usize_nonblocking(Number.MAX_SAFE_INTEGER, 1));
console.log(await dylib.symbols.add_isize_nonblocking(Number.MAX_SAFE_INTEGER, 1));
console.log(await dylib.symbols.add_isize_nonblocking(Number.MIN_SAFE_INTEGER, -1));
console.log(await dylib.symbols.add_f32_nonblocking(123.123, 456.789));
console.log(await dylib.symbols.add_f64_nonblocking(123.123, 456.789));
// test mutating sync calls
function test_fill_buffer(fillValue, arr) {
let buf = new Uint8Array(arr);
dylib.symbols.fill_buffer(fillValue, buf, buf.length);
for (let i = 0; i < buf.length; i++) {
if (buf[i] !== fillValue) {
throw new Error(`Found '${buf[i]}' in buffer, expected '${fillValue}'.`);
}
}
}
test_fill_buffer(0, [2, 3, 4]);
test_fill_buffer(5, [2, 7, 3, 2, 1]);
// Test non blocking calls
function deferred() {
let methods;
const promise = new Promise((resolve, reject) => {
methods = {
async resolve(value) {
await value;
resolve(value);
},
reject(reason) {
reject(reason);
},
};
});
return Object.assign(promise, methods);
}
const promise = deferred();
const buffer3 = new Uint8Array([1, 2, 3, 4, 5, 6, 7, 8]);
dylib.symbols.nonblocking_buffer(buffer3, buffer3.length).then(() => {
promise.resolve();
});
await promise;
let start = performance.now();
dylib.symbols.sleep_blocking(100);
assert(performance.now() - start >= 100);
start = performance.now();
const promise_2 = dylib.symbols.sleep_nonblocking(100).then(() => {
console.log("After");
assert(performance.now() - start >= 100);
});
console.log("Before");
assert(performance.now() - start < 100);
// Await to make sure `sleep_nonblocking` calls and logs before we proceed
await promise_2;
// Test calls with callback parameters
const logCallback = new Deno.UnsafeCallback(
{ parameters: [], result: "void" },
() => console.log("logCallback"),
);
const logManyParametersCallback = new Deno.UnsafeCallback({
parameters: [
"u8",
"i8",
"u16",
"i16",
"u32",
"i32",
"u64",
"i64",
"f32",
"f64",
"pointer",
],
result: "void",
}, (u8, i8, u16, i16, u32, i32, u64, i64, f32, f64, pointer) => {
const view = new Deno.UnsafePointerView(pointer);
const copy_buffer = new Uint8Array(8);
view.copyInto(copy_buffer);
console.log(u8, i8, u16, i16, u32, i32, u64, i64, f32, f64, ...copy_buffer);
});
const returnU8Callback = new Deno.UnsafeCallback(
{ parameters: [], result: "u8" },
() => 8,
);
const returnBufferCallback = new Deno.UnsafeCallback({
parameters: [],
result: "buffer",
}, () => {
return buffer;
});
const add10Callback = new Deno.UnsafeCallback({
parameters: ["u8"],
result: "u8",
}, (value) => value + 10);
const throwCallback = new Deno.UnsafeCallback({
parameters: [],
result: "void",
}, () => {
throw new TypeError("hi");
});
assertThrows(
() => {
dylib.symbols.call_fn_ptr(throwCallback.pointer);
},
TypeError,
"hi",
);
const { call_stored_function } = dylib.symbols;
dylib.symbols.call_fn_ptr(logCallback.pointer);
dylib.symbols.call_fn_ptr_many_parameters(logManyParametersCallback.pointer);
dylib.symbols.call_fn_ptr_return_u8(returnU8Callback.pointer);
dylib.symbols.call_fn_ptr_return_buffer(returnBufferCallback.pointer);
dylib.symbols.store_function(logCallback.pointer);
call_stored_function();
dylib.symbols.store_function_2(add10Callback.pointer);
dylib.symbols.call_stored_function_2(20);
function logManyParametersFast(a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s) {
return symbols.log_many_parameters(a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s);
};
testOptimized(
logManyParametersFast,
() => logManyParametersFast(
255, 65535, 4294967295, 4294967296, 123.456, 789.876, -1, -2, -3, -4, -1000, 1000,
12345.678910, 12345.678910, 12345.678910, 12345.678910, 12345.678910, 12345.678910, 12345.678910
)
);
// Some ABIs rely on the convention to zero/sign-extend arguments by the caller to optimize the callee function.
// If the trampoline did not zero/sign-extend arguments, this would return 256 instead of the expected 0 (in optimized builds)
function castU8U32Fast(x) { return symbols.cast_u8_u32(x); };
testOptimized(castU8U32Fast, () => castU8U32Fast(256));
// Some ABIs rely on the convention to expect garbage in the bits beyond the size of the return value to optimize the callee function.
// If the trampoline did not zero/sign-extend the return value, this would return 256 instead of the expected 0 (in optimized builds)
function castU32U8Fast(x) { return symbols.cast_u32_u8(x); };
testOptimized(castU32U8Fast, () => castU32U8Fast(256));
// Generally the trampoline tail-calls into the FFI function, but in certain cases (e.g. when returning 8 or 16 bit integers)
// the tail call is not possible and a new stack frame must be created. We need enough parameters to have some on the stack
function addManyU16Fast(a, b, c, d, e, f, g, h, i, j, k, l, m) {
return symbols.add_many_u16(a, b, c, d, e, f, g, h, i, j, k, l, m);
};
// N.B. V8 does not currently follow Aarch64 Apple's calling convention.
// The current implementation of the JIT trampoline follows the V8 incorrect calling convention. This test covers the use-case
// and is expected to fail once Deno uses a V8 version with the bug fixed.
// The V8 bug is being tracked in https://bugs.chromium.org/p/v8/issues/detail?id=13171
testOptimized(addManyU16Fast, () => addManyU16Fast(0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12));
const nestedCallback = new Deno.UnsafeCallback(
{ parameters: [], result: "void" },
() => {
dylib.symbols.call_stored_function_2(10);
},
);
dylib.symbols.store_function(nestedCallback.pointer);
dylib.symbols.store_function(null);
dylib.symbols.store_function_2(null);
let counter = 0;
const addToFooCallback = new Deno.UnsafeCallback({
parameters: [],
result: "void",
}, () => counter++);
// Test thread safe callbacks
assertEquals(counter, 0);
addToFooCallback.ref();
await dylib.symbols.call_fn_ptr_thread_safe(addToFooCallback.pointer);
addToFooCallback.unref();
logCallback.ref();
await dylib.symbols.call_fn_ptr_thread_safe(logCallback.pointer);
logCallback.unref();
assertEquals(counter, 1);
returnU8Callback.ref();
await dylib.symbols.call_fn_ptr_return_u8_thread_safe(returnU8Callback.pointer);
// Purposefully do not unref returnU8Callback: Instead use it to test close() unrefing.
// Test statics
assertEquals(dylib.symbols.static_u32, 42);
assertEquals(dylib.symbols.static_i64, -1242464576485);
assert(
typeof dylib.symbols.static_ptr === "object"
);
assertEquals(
Object.keys(dylib.symbols.static_ptr).length, 0
);
const view = new Deno.UnsafePointerView(dylib.symbols.static_ptr);
assertEquals(view.getUint32(), 42);
// Test struct returning
const rect_sync = dylib.symbols.make_rect(10, 20, 100, 200);
assertInstanceOf(rect_sync, Uint8Array);
assertEquals(rect_sync.length, 4 * 8);
assertEquals(Array.from(new Float64Array(rect_sync.buffer)), [10, 20, 100, 200]);
// Test struct passing
dylib.symbols.print_rect(rect_sync);
// Test struct passing asynchronously
await dylib.symbols.print_rect_async(rect_sync);
dylib.symbols.print_rect(new Float64Array([20, 20, 100, 200]));
// Test struct returning asynchronously
const rect_async = await dylib.symbols.make_rect_async(10, 20, 100, 200);
assertInstanceOf(rect_async, Uint8Array);
assertEquals(rect_async.length, 4 * 8);
assertEquals(Array.from(new Float64Array(rect_async.buffer)), [10, 20, 100, 200]);
// Test complex, mixed struct returning and passing
const mixedStruct = dylib.symbols.create_mixed(3, 12.515000343322754, rect_async, Deno.UnsafePointer.create(12456789), new Uint32Array([8, 32]));
assertEquals(mixedStruct.length, 56);
assertEquals(Array.from(mixedStruct.subarray(0, 4)), [3, 0, 0, 0]);
assertEquals(new Float32Array(mixedStruct.buffer, 4, 1)[0], 12.515000343322754);
assertEquals(new Float64Array(mixedStruct.buffer, 8, 4), new Float64Array(rect_async.buffer));
assertEquals(new BigUint64Array(mixedStruct.buffer, 40, 1)[0], 12456789n);
assertEquals(new Uint32Array(mixedStruct.buffer, 48, 2), new Uint32Array([8, 32]));
dylib.symbols.print_mixed(mixedStruct);
const cb = new Deno.UnsafeCallback({
parameters: [{ struct: Rect }],
result: { struct: Rect },
}, (innerRect) => {
innerRect = new Float64Array(innerRect.buffer);
return new Float64Array([innerRect[0] + 10, innerRect[1] + 10, innerRect[2] + 10, innerRect[3] + 10]);
});
const cbFfi = new Deno.UnsafeFnPointer(cb.pointer, cb.definition);
const cbResult = new Float64Array(cbFfi.call(rect_async).buffer);
assertEquals(Array.from(cbResult), [20, 30, 110, 210]);
cb.close();
const arrayBuffer = view.getArrayBuffer(4);
const uint32Array = new Uint32Array(arrayBuffer);
assertEquals(arrayBuffer.byteLength, 4);
assertEquals(uint32Array.length, 1);
assertEquals(uint32Array[0], 42);
uint32Array[0] = 55; // MUTATES!
assertEquals(uint32Array[0], 55);
assertEquals(view.getUint32(), 55);
{
// Test UnsafePointer APIs
assertEquals(Deno.UnsafePointer.create(0), null);
const createdPointer = Deno.UnsafePointer.create(1);
assertNotEquals(createdPointer, null);
assertEquals(typeof createdPointer, "object");
assertEquals(Deno.UnsafePointer.value(null), 0);
assertEquals(Deno.UnsafePointer.value(createdPointer), 1);
assert(Deno.UnsafePointer.equals(null, null));
assertFalse(Deno.UnsafePointer.equals(null, createdPointer));
assertFalse(Deno.UnsafePointer.equals(Deno.UnsafePointer.create(2), createdPointer));
// Do not allow offsetting from null, `create` function should be used instead.
assertThrows(() => Deno.UnsafePointer.offset(null, 5));
const offsetPointer = Deno.UnsafePointer.offset(createdPointer, 5);
assertEquals(Deno.UnsafePointer.value(offsetPointer), 6);
assertEquals(Deno.UnsafePointer.offset(offsetPointer, -6), null);
}
// Test non-UTF-8 characters
const charView = new Deno.UnsafePointerView(dylib.symbols.static_char);
const charArrayBuffer = charView.getArrayBuffer(14);
const uint8Array = new Uint8Array(charArrayBuffer);
assertEquals([...uint8Array], [
0xC0, 0xC1, 0xF5, 0xF6, 0xF7, 0xF8, 0xF9, 0xFA, 0xFB, 0xFC, 0xFD, 0xFE, 0xFF,
0x00
]);
// Check that `getCString` works equally to `TextDecoder`
assertEquals(charView.getCString(), new TextDecoder().decode(uint8Array.subarray(0, uint8Array.length - 1)));
// Check a selection of various invalid UTF-8 sequences in C strings and verify
// that the `getCString` API does not cause unexpected behaviour.
for (const charBuffer of [
Uint8Array.from([0xA0, 0xA1, 0x00]),
Uint8Array.from([0xE2, 0x28, 0xA1, 0x00]),
Uint8Array.from([0xE2, 0x82, 0x28, 0x00]),
Uint8Array.from([0xF0, 0x28, 0x8C, 0xBC, 0x00]),
Uint8Array.from([0xF0, 0x90, 0x28, 0xBC, 0x00]),
Uint8Array.from([0xF0, 0x28, 0x8C, 0x28, 0x00]),
Uint8Array.from([0xF8, 0xA1, 0xA1, 0xA1, 0xA1, 0x00]),
Uint8Array.from([0xFC, 0xA1, 0xA1, 0xA1, 0xA1, 0xA1, 0x00]),
]) {
const charBufferPointer = Deno.UnsafePointer.of(charBuffer);
const charString = Deno.UnsafePointerView.getCString(charBufferPointer);
const charBufferPointerArrayBuffer = new Uint8Array(Deno.UnsafePointerView.getArrayBuffer(charBufferPointer, charBuffer.length - 1));
assertEquals(charString, new TextDecoder().decode(charBufferPointerArrayBuffer));
assertEquals([...charBuffer.subarray(0, charBuffer.length - 1)], [...charBufferPointerArrayBuffer]);
}
const bytes = new Uint8Array([0, 1, 2, 3, 4, 5, 6, 7, 8, 9]);
function hash() { return dylib.symbols.hash(bytes, bytes.byteLength); };
testOptimized(hash, () => hash());
(function cleanup() {
dylib.close();
throwCallback.close();
logCallback.close();
logManyParametersCallback.close();
returnU8Callback.close();
returnBufferCallback.close();
add10Callback.close();
nestedCallback.close();
addToFooCallback.close();
const resourcesPost = Deno.resources();
const preStr = JSON.stringify(resourcesPre, null, 2);
const postStr = JSON.stringify(resourcesPost, null, 2);
if (preStr !== postStr) {
throw new Error(
`Difference in open resources before dlopen and after closing:
Before: ${preStr}
After: ${postStr}`,
);
}
console.log("Correct number of resources");
})();
function assertIsOptimized(fn) {
const status = %GetOptimizationStatus(fn);
assert(status & (1 << 4), `expected ${fn.name} to be optimized, but wasn't`);
}
function testOptimized(fn, callback) {
%PrepareFunctionForOptimization(fn);
const r1 = callback();
if (r1 !== undefined) {
console.log(r1);
}
%OptimizeFunctionOnNextCall(fn);
const r2 = callback();
if (r2 !== undefined) {
console.log(r2);
}
assertIsOptimized(fn);
}