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140 lines
4.6 KiB
Zig
140 lines
4.6 KiB
Zig
//
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// Terminals have come a long way over the years. Starting with
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// monochrome lines on flickering CRT monitors and continuously
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// improving to today's modern terminal emulators with sharp
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// images, true color, fonts, ligatures, and characters in every
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// known language.
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//
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// Formatting our results to be appealing and allow quick visual
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// comprehension of the information is what users desire. <3
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//
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// C set string formatting standards over the years, and Zig is
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// following suit and growing daily. Due to this growth, there is
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// no official documentation for standard library features such
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// as string formatting.
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//
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// Therefore, the comments for the format() function are the only
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// way to definitively learn how to format strings in Zig:
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//
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// https://github.com/ziglang/zig/blob/master/lib/std/fmt.zig#L29
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//
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// Zig already has a very nice selection of formatting options.
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// These can be used in different ways, but typically to convert
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// numerical values into various text representations. The
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// results can be used for direct output to a terminal or stored
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// for later use or written to file. The latter is useful when
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// large amounts of data are to be processed by other programs.
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//
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// In Ziglings, we are concerned with the output to the console.
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// But since the formatting instructions for files are the same,
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// what you learn applies universally.
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//
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// Since we write to "debug" output in Ziglings, our answers
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// usually look something like this:
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//
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// print("Text {placeholder} another text \n", .{foo});
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//
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// In addition to being replaced with foo in this example, the
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// {placeholder} in the string can also have formatting applied.
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// How does that work?
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//
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// This actually happens in several stages. In one stage, escape
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// sequences are evaluated. The one we've seen the most
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// (including the example above) is "\n" which means "line feed".
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// Whenever this statement is found, a new line is started in the
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// output. Escape sequences can also be written one after the
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// other, e.g. "\n\n" will cause two line feeds.
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//
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// By the way, the result of these escape sequences are passed
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// directly to the terminal program. Other than translating them
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// into control codes, escape sequences have nothing to do with
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// Zig. Zig knows nothing about "line feeds" or "tabs" or
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// "bells".
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//
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// The formatting that Zig *does* perform itself is found in the
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// curly brackets: "{placeholder}". Formatting instructions in
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// the placeholder will determine how the corresponding value,
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// e.g. foo, is displayed.
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//
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// And this is where it gets exciting, because format() accepts a
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// variety of formatting instructions. It's basically a tiny
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// language of its own. Here's a numeric example:
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//
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// print("Catch-{x:0>4}.", .{twenty_two});
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//
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// This formatting instruction outputs a hexadecimal number with
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// leading zeros:
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//
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// Catch-0x0016.
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//
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// Or you can center-align a string like so:
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//
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// print("{s:*^20}\n", .{"Hello!"});
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//
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// Output:
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//
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// *******Hello!*******
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//
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// Let's try making use of some formatting. We've decided that
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// the one thing missing from our lives is a multiplication table
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// for all numbers from 1-15. We want the table to be nice and
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// neat, with numbers in straight columns like so:
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//
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// X | 1 2 3 4 5 ...
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// ---+---+---+---+---+---+
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// 1 | 1 2 3 4 5
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//
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// 2 | 2 4 6 8 10
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//
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// 3 | 3 6 9 12 15
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//
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// 4 | 4 8 12 16 20
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//
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// 5 | 5 10 15 20 25
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//
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// ...
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//
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// Without string formatting, this would be a more challenging
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// assignment because the number of digits in the numbers vary
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// from 1 to 3. But formatting can help us with that.
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//
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const std = @import("std");
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const print = std.debug.print;
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pub fn main() !void {
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// Max number to multiply
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const size = 15;
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// Print the header:
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//
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// We start with a single 'X' for the diagonal.
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print("\n X |", .{});
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// Header row with all numbers from 1 to size.
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for (0..size) |n| {
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print("{d:>3} ", .{n + 1});
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}
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print("\n", .{});
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// Header column rule line.
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var n: u8 = 0;
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while (n <= size) : (n += 1) {
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print("---+", .{});
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}
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print("\n", .{});
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// Now the actual table. (Is there anything more beautiful
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// than a well-formatted table?)
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for (0..size) |a| {
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print("{d:>2} |", .{a + 1});
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for (0..size) |b| {
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// What formatting is needed here to make our columns
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// nice and straight?
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print("{???} ", .{(a + 1) * (b + 1)});
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}
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// After each row we use double line feed:
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print("\n\n", .{});
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}
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}
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