// deno-lint-ignore-file no-deprecated-deno-api // Copyright 2018-2024 the Deno authors. All rights reserved. MIT license. import { assert, assertEquals, assertStrictEquals, assertStringIncludes, assertThrows, } from "./test_util.ts"; Deno.test( { permissions: { read: true, run: false } }, function runPermissions() { assertThrows(() => { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. Deno.run({ cmd: [Deno.execPath(), "eval", "console.log('hello world')"], }); }, Deno.errors.NotCapable); }, ); Deno.test( { permissions: { run: true, read: true } }, async function runSuccess() { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ // freeze the array to ensure it's not modified cmd: Object.freeze([ Deno.execPath(), "eval", "console.log('hello world')", ]), stdout: "piped", stderr: "null", }); const status = await p.status(); assertEquals(status.success, true); assertEquals(status.code, 0); assertEquals(status.signal, undefined); p.stdout.close(); p.close(); }, ); Deno.test( { permissions: { run: true, read: true } }, async function runUrl() { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [ new URL(`file:///${Deno.execPath()}`), "eval", "console.log('hello world')", ], stdout: "piped", stderr: "null", }); const status = await p.status(); assertEquals(status.success, true); assertEquals(status.code, 0); assertEquals(status.signal, undefined); p.stdout.close(); p.close(); }, ); Deno.test( { permissions: { run: true, read: true } }, async function runStdinRid0(): Promise< void > { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [Deno.execPath(), "eval", "console.log('hello world')"], stdin: 0, stdout: "piped", stderr: "null", }); const status = await p.status(); assertEquals(status.success, true); assertEquals(status.code, 0); assertEquals(status.signal, undefined); p.stdout.close(); p.close(); }, ); Deno.test( { permissions: { run: true, read: true } }, function runInvalidStdio() { assertThrows(() => // @ts-ignore `Deno.run()` was soft-removed in Deno 2. Deno.run({ cmd: [Deno.execPath(), "eval", "console.log('hello world')"], stdin: "a", }) ); assertThrows(() => // @ts-ignore `Deno.run()` was soft-removed in Deno 2. Deno.run({ cmd: [Deno.execPath(), "eval", "console.log('hello world')"], stdout: "b", }) ); assertThrows(() => // @ts-ignore `Deno.run()` was soft-removed in Deno 2. Deno.run({ cmd: [Deno.execPath(), "eval", "console.log('hello world')"], stderr: "c", }) ); }, ); Deno.test( { permissions: { run: true, read: true } }, async function runCommandFailedWithCode() { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [Deno.execPath(), "eval", "Deno.exit(41 + 1)"], }); const status = await p.status(); assertEquals(status.success, false); assertEquals(status.code, 42); assertEquals(status.signal, undefined); p.close(); }, ); Deno.test( { permissions: { run: true, read: true }, }, async function runCommandFailedWithSignal() { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [ Deno.execPath(), "eval", "Deno.kill(Deno.pid, 'SIGKILL')", ], }); const status = await p.status(); assertEquals(status.success, false); if (Deno.build.os === "windows") { assertEquals(status.code, 1); assertEquals(status.signal, undefined); } else { assertEquals(status.code, 128 + 9); assertEquals(status.signal, 9); } p.close(); }, ); Deno.test({ permissions: { run: true } }, function runNotFound() { let error; try { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. Deno.run({ cmd: ["this file hopefully doesn't exist"] }); } catch (e) { error = e; } assert(error !== undefined); assert(error instanceof Deno.errors.NotFound); }); Deno.test( { permissions: { write: true, run: true, read: true } }, async function runWithCwdIsAsync() { const enc = new TextEncoder(); const cwd = await Deno.makeTempDir({ prefix: "deno_command_test" }); const exitCodeFile = "deno_was_here"; const programFile = "poll_exit.ts"; const program = ` async function tryExit() { try { const code = parseInt(await Deno.readTextFile("${exitCodeFile}")); Deno.exit(code); } catch { // Retry if we got here before deno wrote the file. setTimeout(tryExit, 0.01); } } tryExit(); `; Deno.writeFileSync(`${cwd}/${programFile}`, enc.encode(program)); // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cwd, cmd: [Deno.execPath(), "run", "--allow-read", programFile], }); // Write the expected exit code *after* starting deno. // This is how we verify that `run()` is actually asynchronous. const code = 84; Deno.writeFileSync(`${cwd}/${exitCodeFile}`, enc.encode(`${code}`)); const status = await p.status(); assertEquals(status.success, false); assertEquals(status.code, code); assertEquals(status.signal, undefined); p.close(); }, ); Deno.test( { permissions: { run: true, read: true } }, async function runStdinPiped(): Promise< void > { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [ Deno.execPath(), "eval", ` const buffer = new Uint8Array(5); await Deno.stdin.read(buffer); if (new TextDecoder().decode(buffer) !== "hello") { throw new Error('Expected \\'hello\\'') } `, ], stdin: "piped", }); assert(p.stdin); assert(!p.stdout); assert(!p.stderr); const msg = new TextEncoder().encode("hello"); const n = await p.stdin.write(msg); assertEquals(n, msg.byteLength); p.stdin.close(); const status = await p.status(); assertEquals(status.success, true); assertEquals(status.code, 0); assertEquals(status.signal, undefined); p.close(); }, ); Deno.test( { permissions: { run: true, read: true } }, async function runStdoutPiped(): Promise< void > { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [ Deno.execPath(), "eval", "await Deno.stdout.write(new TextEncoder().encode('hello'))", ], stdout: "piped", }); assert(!p.stdin); assert(!p.stderr); const data = new Uint8Array(10); let r = await p.stdout.read(data); if (r === null) { throw new Error("p.stdout.read(...) should not be null"); } assertEquals(r, 5); const s = new TextDecoder().decode(data.subarray(0, r)); assertEquals(s, "hello"); r = await p.stdout.read(data); assertEquals(r, null); p.stdout.close(); const status = await p.status(); assertEquals(status.success, true); assertEquals(status.code, 0); assertEquals(status.signal, undefined); p.close(); }, ); Deno.test( { permissions: { run: true, read: true } }, async function runStderrPiped(): Promise< void > { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [ Deno.execPath(), "eval", "await Deno.stderr.write(new TextEncoder().encode('hello'))", ], stderr: "piped", }); assert(!p.stdin); assert(!p.stdout); const data = new Uint8Array(10); let r = await p.stderr.read(data); if (r === null) { throw new Error("p.stderr.read should not return null here"); } assertEquals(r, 5); const s = new TextDecoder().decode(data.subarray(0, r)); assertEquals(s, "hello"); r = await p.stderr.read(data); assertEquals(r, null); p.stderr!.close(); const status = await p.status(); assertEquals(status.success, true); assertEquals(status.code, 0); assertEquals(status.signal, undefined); p.close(); }, ); Deno.test( { permissions: { run: true, read: true } }, async function runOutput() { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [ Deno.execPath(), "eval", "await Deno.stdout.write(new TextEncoder().encode('hello'))", ], stdout: "piped", }); const output = await p.output(); const s = new TextDecoder().decode(output); assertEquals(s, "hello"); p.close(); }, ); Deno.test( { permissions: { run: true, read: true } }, async function runStderrOutput(): Promise< void > { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [ Deno.execPath(), "eval", "await Deno.stderr.write(new TextEncoder().encode('error'))", ], stderr: "piped", }); const error = await p.stderrOutput(); const s = new TextDecoder().decode(error); assertEquals(s, "error"); p.close(); }, ); Deno.test( { permissions: { run: true, write: true, read: true }, }, async function runRedirectStdoutStderr() { const tempDir = await Deno.makeTempDir(); const fileName = tempDir + "/redirected_stdio.txt"; using file = await Deno.open(fileName, { create: true, write: true, }); // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [ Deno.execPath(), "eval", "Deno.stderr.write(new TextEncoder().encode('error\\n')); Deno.stdout.write(new TextEncoder().encode('output\\n'));", ], stdout: "piped", stderr: "piped", }); await p.stdout.readable.pipeTo(file.writable, { preventClose: true }); await p.stderr.readable.pipeTo(file.writable); await p.status(); p.close(); const fileContents = await Deno.readFile(fileName); const decoder = new TextDecoder(); const text = decoder.decode(fileContents); assertStringIncludes(text, "error"); assertStringIncludes(text, "output"); // deno-lint-ignore no-console console.log("finished tgis test"); }, ); Deno.test( { permissions: { run: true, write: true, read: true }, }, async function runRedirectStdin() { const tempDir = await Deno.makeTempDir(); const fileName = tempDir + "/redirected_stdio.txt"; await Deno.writeTextFile(fileName, "hello"); using file = await Deno.open(fileName); // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [ Deno.execPath(), "eval", ` const buffer = new Uint8Array(5); await Deno.stdin.read(buffer); if (new TextDecoder().decode(buffer) !== "hello") { throw new Error('Expected \\'hello\\'') } `, ], stdin: "piped", }); await file.readable.pipeTo(p.stdin.writable); const status = await p.status(); assertEquals(status.code, 0); p.close(); }, ); Deno.test( { permissions: { run: true, read: true } }, async function runEnv() { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [ Deno.execPath(), "eval", "Deno.stdout.write(new TextEncoder().encode(Deno.env.get('FOO') + Deno.env.get('BAR')))", ], env: { FOO: "0123", BAR: "4567", }, stdout: "piped", }); const output = await p.output(); const s = new TextDecoder().decode(output); assertEquals(s, "01234567"); p.close(); }, ); Deno.test( { permissions: { run: true, read: true } }, async function runClose() { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [ Deno.execPath(), "eval", "setTimeout(() => Deno.stdout.write(new TextEncoder().encode('error')), 10000)", ], stderr: "piped", }); assert(!p.stdin); assert(!p.stdout); p.close(); const data = new Uint8Array(10); const r = await p.stderr.read(data); assertEquals(r, null); p.stderr.close(); }, ); Deno.test( { permissions: { run: true, read: true } }, async function runKillAfterStatus() { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [Deno.execPath(), "eval", 'console.log("hello")'], }); await p.status(); let error = null; try { p.kill("SIGTERM"); } catch (e) { error = e; } assert( error instanceof Deno.errors.NotFound || // On Windows, the underlying Windows API may return // `ERROR_ACCESS_DENIED` when the process has exited, but hasn't been // completely cleaned up yet and its `pid` is still valid. (Deno.build.os === "windows" && error instanceof Deno.errors.PermissionDenied), ); p.close(); }, ); Deno.test({ permissions: { run: false } }, function killPermissions() { assertThrows(() => { // Unlike the other test cases, we don't have permission to spawn a // subprocess we can safely kill. Instead we send SIGCONT to the current // process - assuming that Deno does not have a special handler set for it // and will just continue even if a signal is erroneously sent. Deno.kill(Deno.pid, "SIGCONT"); }, Deno.errors.NotCapable); }); Deno.test( { ignore: Deno.build.os !== "windows", permissions: { run: true } }, function negativePidInvalidWindows() { assertThrows(() => { Deno.kill(-1, "SIGTERM"); }, TypeError); }, ); Deno.test( { ignore: Deno.build.os !== "windows", permissions: { run: true } }, function invalidSignalNameWindows() { assertThrows(() => { Deno.kill(Deno.pid, "SIGUSR1"); }, TypeError); }, ); Deno.test( { permissions: { run: true, read: true } }, async function killSuccess() { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [Deno.execPath(), "eval", "setTimeout(() => {}, 10000)"], }); try { Deno.kill(p.pid, "SIGKILL"); const status = await p.status(); assertEquals(status.success, false); if (Deno.build.os === "windows") { assertEquals(status.code, 1); assertEquals(status.signal, undefined); } else { assertEquals(status.code, 137); assertEquals(status.signal, 9); } } finally { p.close(); } }, ); Deno.test({ permissions: { run: true, read: true } }, function killFailed() { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [Deno.execPath(), "eval", "setTimeout(() => {}, 10000)"], }); assert(!p.stdin); assert(!p.stdout); assertThrows(() => { // @ts-expect-error testing runtime error of bad signal Deno.kill(p.pid, "foobar"); }, TypeError); p.close(); }); Deno.test( { permissions: { run: true, read: true, write: true }, ignore: Deno.build.os === "windows", }, async function non_existent_cwd(): Promise { // @ts-ignore `Deno.run()` was soft-removed in Deno 2. const p = Deno.run({ cmd: [ Deno.execPath(), "eval", `const dir = Deno.makeTempDirSync(); Deno.chdir(dir); Deno.removeSync(dir); const p = Deno.run({cmd:[Deno.execPath(), "eval", "console.log(1);"]}); const { code } = await p.status(); p.close(); Deno.exit(code); `, ], stdout: "piped", stderr: "piped", }); const { code } = await p.status(); const stderr = new TextDecoder().decode(await p.stderrOutput()); p.close(); p.stdout.close(); assertStrictEquals(code, 1); assertStringIncludes(stderr, "failed resolving cwd:"); }, );