zig-clap
zig-clap

Hejsil/zig-clap

MIT

Command line argument parsing library

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Updated: 7:56:09 AM Fri Nov 22 2024 Size: 424KB Created: 1:06:16 PM Wed Mar 14 2018
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No known dependencies
zig  fetch  --save  git+https://github.com/Hejsil/zig-clap

zig-clap

A simple and easy to use command line argument parser library for Zig.

Installation

Developers tend to either use

  • The latest tagged release of Zig
  • The latest build of Zigs master branch

Depending on which developer you are, you need to run different zig fetch commands:

# Version of zig-clap that works with a tagged release of Zig
# Replace `<REPLACE ME>` with the version of zig-clap that you want to use
# See: https://github.com/Hejsil/zig-clap/releases
zig fetch --save https://github.com/Hejsil/zig-clap/archive/refs/tags/<REPLACE ME>.tar.gz

# Version of zig-clap that works with latest build of Zigs master branch
zig fetch --save git+https://github.com/Hejsil/zig-clap

Then add the following to build.zig:

const clap = b.dependency("clap", .{});
exe.root_module.addImport("clap", clap.module("clap"));

Features

  • Short arguments -a
    • Chaining -abc where a and b does not take values.
    • Multiple specifications are tallied (e.g. -v -v).
  • Long arguments --long
  • Supports both passing values using spacing and = (-a 100, -a=100)
    • Short args also support passing values with no spacing or = (-a100)
    • This all works with chaining (-ba 100, -ba=100, -ba100)
  • Supports options that can be specified multiple times (-e 1 -e 2 -e 3)
  • Print help message from parameter specification.
  • Parse help message to parameter specification.

API Reference

Automatically generated API Reference for the project can be found at https://Hejsil.github.io/zig-clap. Note that Zig autodoc is in beta; the website may be broken or incomplete.

Examples

clap.parse

The simplest way to use this library is to just call the clap.parse function.

pub fn main() !void {
    var gpa = std.heap.GeneralPurposeAllocator(.{}){};
    defer _ = gpa.deinit();

    // First we specify what parameters our program can take.
    // We can use `parseParamsComptime` to parse a string into an array of `Param(Help)`
    const params = comptime clap.parseParamsComptime(
        \\-h, --help             Display this help and exit.
        \\-n, --number <usize>   An option parameter, which takes a value.
        \\-s, --string <str>...  An option parameter which can be specified multiple times.
        \\<str>...
        \\
    );

    // Initialize our diagnostics, which can be used for reporting useful errors.
    // This is optional. You can also pass `.{}` to `clap.parse` if you don't
    // care about the extra information `Diagnostics` provides.
    var diag = clap.Diagnostic{};
    var res = clap.parse(clap.Help, &params, clap.parsers.default, .{
        .diagnostic = &diag,
        .allocator = gpa.allocator(),
    }) catch |err| {
        // Report useful error and exit
        diag.report(std.io.getStdErr().writer(), err) catch {};
        return err;
    };
    defer res.deinit();

    if (res.args.help != 0)
        std.debug.print("--help\n", .{});
    if (res.args.number) |n|
        std.debug.print("--number = {}\n", .{n});
    for (res.args.string) |s|
        std.debug.print("--string = {s}\n", .{s});
    for (res.positionals[0]) |pos|
        std.debug.print("{s}\n", .{pos});
}

const clap = @import("clap");
const std = @import("std");

The result will contain an args field and a positionals field. args will have one field for each none positional parameter of your program. The name of the field will be the longest name of the parameter. positionals be a tuple with one field for each positional parameter.

The fields in args and postionals are typed. The type is based on the name of the value the parameter takes. Since --number takes a usize the field res.args.number has the type usize.

Note that this is only the case because clap.parsers.default has a field called usize which contains a parser that returns usize. You can pass in something other than clap.parsers.default if you want some other mapping.

pub fn main() !void {
    var gpa = std.heap.GeneralPurposeAllocator(.{}){};
    defer _ = gpa.deinit();

    // First we specify what parameters our program can take.
    // We can use `parseParamsComptime` to parse a string into an array of `Param(Help)`
    const params = comptime clap.parseParamsComptime(
        \\-h, --help             Display this help and exit.
        \\-n, --number <INT>     An option parameter, which takes a value.
        \\-a, --answer <ANSWER>  An option parameter which takes an enum.
        \\-s, --string <STR>...  An option parameter which can be specified multiple times.
        \\<FILE>...
        \\
    );

    // Declare our own parsers which are used to map the argument strings to other
    // types.
    const YesNo = enum { yes, no };
    const parsers = comptime .{
        .STR = clap.parsers.string,
        .FILE = clap.parsers.string,
        .INT = clap.parsers.int(usize, 10),
        .ANSWER = clap.parsers.enumeration(YesNo),
    };

    var diag = clap.Diagnostic{};
    var res = clap.parse(clap.Help, &params, parsers, .{
        .diagnostic = &diag,
        .allocator = gpa.allocator(),
        // The assignment separator can be configured. `--number=1` and `--number:1` is now
        // allowed.
        .assignment_separators = "=:",
    }) catch |err| {
        diag.report(std.io.getStdErr().writer(), err) catch {};
        return err;
    };
    defer res.deinit();

    if (res.args.help != 0)
        std.debug.print("--help\n", .{});
    if (res.args.number) |n|
        std.debug.print("--number = {}\n", .{n});
    if (res.args.answer) |a|
        std.debug.print("--answer = {s}\n", .{@tagName(a)});
    for (res.args.string) |s|
        std.debug.print("--string = {s}\n", .{s});
    for (res.positionals[0]) |pos|
        std.debug.print("{s}\n", .{pos});
}

const clap = @import("clap");
const std = @import("std");

Subcommands

There is an option for clap.parse and clap.parseEx called terminating_positional. It allows for users of clap to implement subcommands in their cli application:

// These are our subcommands
const SubCommands = enum {
    help,
    math,
};

const main_parsers = .{
    .command = clap.parsers.enumeration(SubCommands),
};

// The parameters for main. Parameters for the subcommands are specified further down
const main_params = clap.parseParamsComptime(
    \\-h, --help  Display this help and exit.
    \\<command>
    \\
);

// To pass around arguments returned by clap, `clap.Result` and `clap.ResultEx` can be used to
// get the return type of `clap.parse` and `clap.parseEx`
const MainArgs = clap.ResultEx(clap.Help, &main_params, main_parsers);

pub fn main() !void {
    var gpa_state = std.heap.GeneralPurposeAllocator(.{}){};
    const gpa = gpa_state.allocator();
    defer _ = gpa_state.deinit();

    var iter = try std.process.ArgIterator.initWithAllocator(gpa);
    defer iter.deinit();

    _ = iter.next();

    var diag = clap.Diagnostic{};
    var res = clap.parseEx(clap.Help, &main_params, main_parsers, &iter, .{
        .diagnostic = &diag,
        .allocator = gpa,

        // Terminate the parsing of arguments after parsing the first positional (0 is passed
        // here because parsed positionals are, like slices and arrays, indexed starting at 0).
        //
        // This will terminate the parsing after parsing the subcommand enum and leave `iter`
        // not fully consumed. It can then be reused to parse the arguments for subcommands
        .terminating_positional = 0,
    }) catch |err| {
        diag.report(std.io.getStdErr().writer(), err) catch {};
        return err;
    };
    defer res.deinit();

    if (res.args.help != 0)
        std.debug.print("--help\n", .{});

    const command = res.positionals[0] orelse return error.MissingCommand;
    switch (command) {
        .help => std.debug.print("--help\n", .{}),
        .math => try mathMain(gpa, &iter, res),
    }
}

fn mathMain(gpa: std.mem.Allocator, iter: *std.process.ArgIterator, main_args: MainArgs) !void {
    // The parent arguments are not used it, but there are cases where it might be useful, so
    // the example shows how to pass the arguments around.
    _ = main_args;

    // The parameters for the subcommand
    const params = comptime clap.parseParamsComptime(
        \\-h, --help  Display this help and exit.
        \\-a, --add   Add the two numbers
        \\-s, --sub   Subtract the two numbers
        \\<isize>
        \\<isize>
        \\
    );

    // Here we pass the partially parsed argument iterator
    var diag = clap.Diagnostic{};
    var res = clap.parseEx(clap.Help, &params, clap.parsers.default, iter, .{
        .diagnostic = &diag,
        .allocator = gpa,
    }) catch |err| {
        diag.report(std.io.getStdErr().writer(), err) catch {};
        return err;
    };
    defer res.deinit();

    const a = res.positionals[0] orelse return error.MissingArg1;
    const b = res.positionals[1] orelse return error.MissingArg1;
    if (res.args.help != 0)
        std.debug.print("--help\n", .{});
    if (res.args.add != 0)
        std.debug.print("added: {}\n", .{a + b});
    if (res.args.sub != 0)
        std.debug.print("subtracted: {}\n", .{a - b});
}

const clap = @import("clap");
const std = @import("std");

streaming.Clap

The streaming.Clap is the base of all the other parsers. It's a streaming parser that uses an args.Iterator to provide it with arguments lazily.

pub fn main() !void {
    const allocator = std.heap.page_allocator;

    // First we specify what parameters our program can take.
    const params = [_]clap.Param(u8){
        .{
            .id = 'h',
            .names = .{ .short = 'h', .long = "help" },
        },
        .{
            .id = 'n',
            .names = .{ .short = 'n', .long = "number" },
            .takes_value = .one,
        },
        .{ .id = 'f', .takes_value = .one },
    };

    var iter = try std.process.ArgIterator.initWithAllocator(allocator);
    defer iter.deinit();

    // Skip exe argument
    _ = iter.next();

    // Initialize our diagnostics, which can be used for reporting useful errors.
    // This is optional. You can also leave the `diagnostic` field unset if you
    // don't care about the extra information `Diagnostic` provides.
    var diag = clap.Diagnostic{};
    var parser = clap.streaming.Clap(u8, std.process.ArgIterator){
        .params = &params,
        .iter = &iter,
        .diagnostic = &diag,
    };

    // Because we use a streaming parser, we have to consume each argument parsed individually.
    while (parser.next() catch |err| {
        // Report useful error and exit
        diag.report(std.io.getStdErr().writer(), err) catch {};
        return err;
    }) |arg| {
        // arg.param will point to the parameter which matched the argument.
        switch (arg.param.id) {
            'h' => std.debug.print("Help!\n", .{}),
            'n' => std.debug.print("--number = {s}\n", .{arg.value.?}),

            // arg.value == null, if arg.param.takes_value == .none.
            // Otherwise, arg.value is the value passed with the argument, such as "-a=10"
            // or "-a 10".
            'f' => std.debug.print("{s}\n", .{arg.value.?}),
            else => unreachable,
        }
    }
}

const clap = @import("clap");
const std = @import("std");

Currently, this parser is the only parser that allows an array of Param that is generated at runtime.

help

The help prints a simple list of all parameters the program can take. It expects the Id to have a description method and an value method so that it can provide that in the output. HelpOptions is passed to help to control how the help message is printed.

pub fn main() !void {
    var gpa = std.heap.GeneralPurposeAllocator(.{}){};
    defer _ = gpa.deinit();

    const params = comptime clap.parseParamsComptime(
        \\-h, --help     Display this help and exit.
        \\-v, --version  Output version information and exit.
        \\
    );

    var res = try clap.parse(clap.Help, &params, clap.parsers.default, .{
        .allocator = gpa.allocator(),
    });
    defer res.deinit();

    // `clap.help` is a function that can print a simple help message. It can print any `Param`
    // where `Id` has a `description` and `value` method (`Param(Help)` is one such parameter).
    // The last argument contains options as to how `help` should print those parameters. Using
    // `.{}` means the default options.
    if (res.args.help != 0)
        return clap.help(std.io.getStdErr().writer(), clap.Help, &params, .{});
}

const clap = @import("clap");
const std = @import("std");
$ zig-out/bin/help --help
    -h, --help
            Display this help and exit.

    -v, --version
            Output version information and exit.

usage

The usage prints a small abbreviated version of the help message. It expects the Id to have a value method so it can provide that in the output.

pub fn main() !void {
    var gpa = std.heap.GeneralPurposeAllocator(.{}){};
    defer _ = gpa.deinit();

    const params = comptime clap.parseParamsComptime(
        \\-h, --help         Display this help and exit.
        \\-v, --version      Output version information and exit.
        \\    --value <str>  An option parameter, which takes a value.
        \\
    );

    var res = try clap.parse(clap.Help, &params, clap.parsers.default, .{
        .allocator = gpa.allocator(),
    });
    defer res.deinit();

    // `clap.usage` is a function that can print a simple help message. It can print any `Param`
    // where `Id` has a `value` method (`Param(Help)` is one such parameter).
    if (res.args.help != 0)
        return clap.usage(std.io.getStdErr().writer(), clap.Help, &params);
}

const clap = @import("clap");
const std = @import("std");
$ zig-out/bin/usage --help
[-hv] [--value <str>]