編寫命令列應用
- Running an app with the standalone Dart VM
- Overview of the dcat app code
- Parsing command-line arguments
- Reading and writing with stdin, stdout, and stderr
- Getting info about a file
- Reading a file
- Writing a file
- Getting environment information
- Setting exit codes
- Summary
- What next?
What's the point?
- Command-line applications need to do input and output.
- The dart:io library provides I/O functionality.
- The args package helps define and parse command-line arguments.
- A
Future
object represents a value that will be available at some time in the future. - Streams provide a series of asynchronous data events.
- Most input and output requires the use of streams.
This tutorial teaches you how to build command-line apps and shows you a few small command-line applications. These programs use resources that most command-line applications need, including the standard output, error, and input streams, command-line arguments, files and directories, and more.
Running an app with the standalone Dart VM
To run a command-line app in the Dart VM, use dart run
.
The dart
commands are included with the Dart SDK.
Let’s run a small program.
-
Create a file called
hello_world.dart
that contains this code:void main() { print('Hello, World!'); }
-
In the directory that contains the file you just created, run the program:
$ dart run hello_world.dart Hello, World!
The Dart tool supports many commands and options.
Use dart --help
to see commonly used commands and options.
Use dart --verbose
to see all options.
Overview of the dcat app code
This tutorial covers the details of a small sample app called dcat
, which
displays the contents of any files listed on the command line. This app uses
various classes, functions, and properties available to command-line apps. For a
brief description of key app features, click the highlighted code below.
import 'dart:convert';
import 'dart:io';
import 'package:args/args.dart';
const lineNumber = 'line-number';
void main(List<String> arguments) {
exitCode = 0; // presume success
final parser = ArgParser()..addFlag(lineNumber, negatable: false, abbr: 'n');
ArgResults argResults = parser.parse(arguments);
final paths = argResults.rest;
dcat(paths, showLineNumbers: argResults[lineNumber] as bool);
}
Future<void> dcat(List<String> paths, {bool showLineNumbers = false}) async {
if (paths.isEmpty) {
// No files provided as arguments. Read from stdin and print each line.
await stdin.pipe(stdout);
} else {
for (final path in paths) {
var lineNumber = 1;
final lines = utf8.decoder
.bind(File(path).openRead())
.transform(const LineSplitter());
try {
await for (final line in lines) {
if (showLineNumbers) {
stdout.write('${lineNumber++} ');
}
stdout.writeln(line);
}
} catch (_) {
await _handleError(path);
}
}
}
}
Future<void> _handleError(String path) async {
if (await FileSystemEntity.isDirectory(path)) {
stderr.writeln('error: $path is a directory');
} else {
exitCode = 2;
}
}
Getting dependencies
You might notice that dcat depends on a package named args. To get the args package, use the pub package manager.
A real app has tests, license files, dependency files, examples, and so on.
For the first app though, we can easily create only what is necessary
with the dart create
command.
-
Inside a directory, create the dcat app with the dart tool.
$ dart create dcat
-
Change to the created directory.
$ cd dcat
-
Inside the
dcat
directory, use dart pub add to add theargs
package as a dependency. This addsargs
to the list of your dependencies found in thepubspec.yaml
file.$ dart pub add args
-
Open the
bin/dcat.dart
file and copy the preceding code into it.
Running dcat
Once you have your app’s dependencies,
you can run the app from the command line over any text file,
like pubspec.yaml
:
$ dart run bin/dcat.dart -n pubspec.yaml
1 name: dcat
2 description: A sample command-line application.
3 version: 1.0.0
4 # repository: https://github.com/my_org/my_repo
5
6 environment:
7 sdk: '>=2.19.0 <3.0.0'
8
9 # dependencies:
10 # path: ^1.8.0
11
12 dev_dependencies:
13 lints: ^2.0.0
14 test: ^1.21.0
15 dependencies:
16 args: ^2.3.2
This command displays each line of the specified file. Because the -n
argument
is present, a line number is displayed before each line.
Parsing command-line arguments
The args package provides parser support for transforming command-line arguments into a set of options, flags, and additional values. Import the package’s args library as follows:
import 'package:args/args.dart';
The args
library contains these classes, among others:
Class | Description |
---|---|
ArgParser | A command-line argument parser. |
ArgResults | The result of parsing command-line arguments using ArgParser . |
Here is the dcat
code that uses these classes to parse and store command-line
arguments:
void main(List<String> arguments) {
exitCode = 0; // presume success
final parser = ArgParser()..addFlag(lineNumber, negatable: false, abbr: 'n');
ArgResults argResults = parser.parse(arguments);
final paths = argResults.rest;
dcat(paths, showLineNumbers: argResults[lineNumber] as bool);
}
The runtime passes command-line arguments to the app’s main()
function as a
list of strings. The ArgParser
is configured to parse the -n
flag. The
result of parsing command-line arguments is stored in argResults
.
The following diagram shows how the dcat
command line used above
is parsed into an ArgResults
object.
You can access flags and options by name,
treating an ArgResults
like a Map
.
You can access other values using the rest
property.
The API reference
for the args
library provides detailed information to help you use
the ArgParser
and ArgResults
classes.
Reading and writing with stdin, stdout, and stderr
Like other languages, Dart has standard output, standard error, and standard input streams. The standard I/O streams are defined at the top level of the dart:io library:
Stream | Description |
---|---|
stdout | The standard output |
stderr | The standard error |
stdin | The standard input |
Import the dart:io library as follows:
import 'dart:io';
stdout
Here’s the code from the dcat
program that writes the line number to
the stdout
(if the -n
flag is set) followed by the line from the file.
if (showLineNumbers) {
stdout.write('${lineNumber++} ');
}
stdout.writeln(line);
The write()
and writeln()
methods take an object of any type,
convert it to a string, and print it. The writeln()
method
also prints a newline character.
dcat
uses the write()
method to print the line number so the
line number and text appear on the same line.
You can also use the writeAll()
method to print a list of objects,
or use addStream()
to asynchronously print all the elements from a stream.
stdout
provides more functionality than the print()
function.
For example, you can display the contents of a stream with stdout
.
However, you must use print()
instead of stdout
for programs that run on the web.
stderr
Use stderr
to write error messages to the console.
The standard error stream has the same methods as stdout
,
and you use it in the same way.
Although both stdout
and stderr
print to the console,
their output is separate
and can be redirected or piped at the command line
or programmatically to different destinations.
This code from dcat
prints an error message if the user
tries to list a directory.
if (await FileSystemEntity.isDirectory(path)) {
stderr.writeln('error: $path is a directory');
} else {
exitCode = 2;
}
stdin
The standard input stream typically reads data synchronously from the keyboard, although it can read asynchronously and get input piped in from the standard output of another program.
Here’s a small program that reads a single line from stdin
:
import 'dart:io';
void main() {
stdout.writeln('Type something');
final input = stdin.readLineSync();
stdout.writeln('You typed: $input');
}
The readLineSync()
method reads text from the standard input stream,
blocking until the user types in text and presses return.
This little program prints out the typed text.
In the dcat
program,
if the user does not provide a filename on the command line,
the program instead reads from stdin
using the pipe()
method.
Because pipe()
is asynchronous
(returning a future, even though this code doesn’t use that return value),
the code that calls it uses await
.
await stdin.pipe(stdout);
In this case, the user types in lines of text, and the program copies them to stdout. The user signals the end of input by pressing Control+D (or Control+Z on Windows).
$ dart run bin/dcat.dart
The quick brown fox jumps over the lazy dog.
The quick brown fox jumps over the lazy dog.
Getting info about a file
The FileSystemEntity class in the dart:io library provides properties and static methods that help you inspect and manipulate the file system.
For example, if you have a path,
you can determine whether the path is a file, a directory, a link, or not found
by using the type()
method from the FileSystemEntity
class.
Because the type()
method accesses the file system,
it performs the check asynchronously.
The following code from the dcat
example uses FileSystemEntity
to determine if the path provided on the command line is a directory.
The future returns a boolean that indicates if the path is a directory or not.
Because the check is asynchronous, the code calls isDirectory()
using await
.
if (await FileSystemEntity.isDirectory(path)) {
stderr.writeln('error: $path is a directory');
} else {
exitCode = 2;
}
Other interesting methods in the FileSystemEntity
class
include isFile()
, exists()
, stat()
, delete()
,
and rename()
, all of which also use a future to return a value.
FileSystemEntity
is the superclass for the File
, Directory
, and Link
classes.
Reading a file
dcat
opens each file listed on the command line
with the openRead()
method, which returns a stream.
The await for
block waits for the file to be read
asynchronously. The data prints to stdout when it
becomes available on the stream.
for (final path in paths) {
var lineNumber = 1;
final lines = utf8.decoder
.bind(File(path).openRead())
.transform(const LineSplitter());
try {
await for (final line in lines) {
if (showLineNumbers) {
stdout.write('${lineNumber++} ');
}
stdout.writeln(line);
}
} catch (_) {
await _handleError(path);
}
}
The following shows the rest of the code, which uses two decoders that
transform the data before making it available in the await for
block.
The UTF8 decoder converts the data into Dart strings.
LineSplitter
splits the data at newlines.
for (final path in paths) {
var lineNumber = 1;
final lines = utf8.decoder
.bind(File(path).openRead())
.transform(const LineSplitter());
try {
await for (final line in lines) {
if (showLineNumbers) {
stdout.write('${lineNumber++} ');
}
stdout.writeln(line);
}
} catch (_) {
await _handleError(path);
}
}
The dart:convert library contains these and other data converters, including one for JSON. To use these converters you need to import the dart:convert library:
import 'dart:convert';
Writing a file
The easiest way to write text to a file is to create a
File
object and use the writeAsString()
method:
final quotes = File('quotes.txt');
const stronger = 'That which does not kill us makes us stronger. -Nietzsche';
await quotes.writeAsString(stronger, mode: FileMode.append);
The writeAsString()
method writes the data asynchronously.
It opens the file before writing and closes the file when done.
To append data to an existing file, you can use the optional
parameter mode
and set its value to FileMode.append
.
Otherwise, the mode is FileMode.write
and the previous contents of the file,
if any, are overwritten.
If you want to write more data, you can open the file for writing.
The openWrite()
method returns an IOSink (the same type as stdin and stderr).
You can continue to write to the file until done,
at which time, you must close the file.
The close()
method is asynchronous and returns a future.
final quotes = File('quotes.txt').openWrite(mode: FileMode.append);
quotes.write("Don't cry because it's over, ");
quotes.writeln('smile because it happened. -Dr. Seuss');
await quotes.close();
Getting environment information
Use the Platform class to get information about the machine and OS that the program is running on.
Platform.environment
provides a copy of the environment
variables in an immutable map. If you need a mutable map (modifiable copy) you
can use Map.of(Platform.environment)
.
final envVarMap = Platform.environment;
print('PWD = ${envVarMap['PWD']}');
print('LOGNAME = ${envVarMap['LOGNAME']}');
print('PATH = ${envVarMap['PATH']}');
Platform
provides other useful properties that give
information about the machine, OS, and currently
running program. For example:
Setting exit codes
The dart:io library defines a top-level property,
exitCode
, that you can change to set the exit code for
the current invocation of the Dart VM.
An exit code is a number passed from
the Dart program to the parent process
to indicate the success, failure, or other state of the
execution of the program.
The dcat
program sets the exit code
in the _handleError()
function to indicate that an error
occurred during execution.
Future<void> _handleError(String path) async {
if (await FileSystemEntity.isDirectory(path)) {
stderr.writeln('error: $path is a directory');
} else {
exitCode = 2;
}
}
An exit code of 2 indicates that the program encountered an error.
An alternative to using exitCode
is to use the top-level exit()
function,
which sets the exit code and quits the program immediately.
For example, the _handleError()
function could call exit(2)
instead of setting exitCode
to 2,
but exit()
would quit the program
and it might not process all of the files on the command line.
Although you can use any number for an exit code, by convention, the codes in the table below have the following meanings:
Code | Meaning |
---|---|
0 | Success |
1 | Warnings |
2 | Errors |
Summary
This tutorial described some basic API found in these classes from the dart:io library:
API | Description |
---|---|
IOSink | Helper class for objects that consume data from streams |
File | Represents a file on the native file system |
Directory | Represents a directory on the native file system |
FileSystemEntity | Superclass for File and Directory |
Platform | Provides information about the machine and operating system |
stdout | The standard output stream |
stderr | The standard error stream |
stdin | The standard input stream |
exitCode | Access and set the exit code |
exit() | Sets the exit code and quits |
In addition, this tutorial covers two classes that help with command-line arguments: ArgParser and ArgResults.
For more classes, functions, and properties, consult to the API reference for dart:io, dart:convert, and the args package.
For another example of a command line app, see the command_line sample.
What next?
If you’re interested in server-side programming, check out the next tutorial.