# Text `Text` is Tomo's datatype to represent text. The name `Text` is used instead of "string" because Tomo text represents immutable, normalized unicode data with fast indexing that has an implementation that is efficient for concatenation. These are _not_ C-style NUL-terminated character lists. GNU libunistring is used for full Unicode functionality (grapheme cluster counts, capitalization, etc.). ## Implementation Internally, Tomo text's implementation is based on [Raku/MoarVM's strings](https://docs.raku.org/language/unicode) and [Boehm et al's Cords](https://www.cs.tufts.edu/comp/150FP/archive/hans-boehm/ropes.pdf). Strings store their grapheme cluster count and either a compact list of 8-bit ASCII characters (for ASCII text), a list of 32-bit normal-form grapheme cluster values (see below), or a (roughly) balanced binary tree concatenation of two texts. The upside is that repeated concatenations are typically a constant-time operation, which will occasionally require a small rebalancing operation. Index-based text operations (like retrieving an arbitrary index or slicing) are very fast: typically a constant-time operation for arbitrary unicode text, but in the worst case scenario (text built from many concatenations), `O(log(n))` time with very generous constant factors typically amounting to only a handful of steps. Since concatenations use shared substructures, they are very memory-efficient and can be used efficiently for applications like implementing a text editor that stores a full edit history of a large file's contents. ### Normal-Form Graphemes In order to maintain compact storage, fast indexing, and fast slicing, non-ASCII text is stored as 32-bit normal-form graphemes. A normal-form grapheme is either a positive value representing a Unicode codepoint that corresponds to a grapheme cluster (most Unicode letters used in natural language fall into this category after normalization) or a negative value representing an index into an internal list of "synthetic grapheme cluster codepoints." Here are some examples: - `A` is a normal codepoint that is also a grapheme cluster, so it would be represented as the number `65` - `ABC` is three separate grapheme clusters, one for `A`, one for `B`, one for `C`. - `Å` is also a single codepoint (`LATIN CAPITAL LETTER A WITH RING ABOVE`) that is also a grapheme cluster, so it would be represented as the number `197`. - `家` (Japanese for "house") is a single codepoint (`CJK Unified Ideograph-5BB6`) that is also a grapheme cluster, so it would be represented as the number `23478` -`👩🏽‍🚀` is a single graphical cluster, but it's made up of several combining codepoints (`["WOMAN", "EMOJI MODIFIER FITZPATRICK TYPE-4", "ZERO WITDH JOINER", "ROCKET"]`). Since this can't be represented with a single codepoint, we must create a synthetic codepoint for it. If this was the `n`th synthetic codepoint that we've found, then we would represent it with the number `-n`, which can be used to look it up in a lookup table. The lookup table holds the full sequence of codepoints used in the grapheme cluster. ## Syntax Text has a flexible syntax designed to make it easy to hold values from different languages without the need to have lots of escape sequences and without using printf-style string formatting. ``` // Basic text: str := "Hello world" str2 := 'Also text' str3 := `Backticks too` ``` ### Line Splits Long text can be split across multiple lines by having two or more dots at the start of a new line on the same indentation level that started the text: ``` str := "This is a long ....... line that is split in code" ``` ### Multi-line Text Multi-line text has indented (i.e. at least one tab more than the start of the text) text inside quotation marks. The leading and trailing newline are ignored: ``` multi_line := " This text has multiple lines. Line two. You can split a line .... using two or more dots to make an elipsis. Remember to include whitespace after the elipsis if desired. Or don't if you're splitting a long word like supercalifragilisticexpia ....lidocious This text is indented by one level in the text "quotes" are ignored unless they're at the same indentation level as the .... start of the text. The end (no newline after this). " ``` ## Text Interpolations Inside double quoted text, you can use a dollar sign (`$`) to insert an expression that you want converted to text. This is called text interpolation: ``` // Interpolation: my_var := 5 str := "My var is $my_var!" // Equivalent to "My var is 5!" // Using parentheses: str := "Sum: $(1 + 2)" // equivalent to "Sum: 3" ``` Single-quoted text does not have interpolations: ``` // No interpolation here: str := 'Sum: $(1 + 2)' ``` ### Text Escapes Unlike other languages, backslash is *not* a special character inside of text. For example, `"x\ny"` has the characters `x`, `\`, `n`, `y`, not a newline. Instead, a series of character escapes act as complete text literals without quotation marks: ``` newline := \n crlf := \r\n quote := \" ``` These text literals can be used as interpolation values with or without parentheses, depending on which you find more readable: ``` two_lines := "one\ntwo" has_quotes := "some $\"quotes$\" here" ``` However, in general it is best practice to use multi-line text to avoid these problems: ``` str := " This has multiple lines and "quotes" too! " ``` ### Customizable `$`-Text Sometimes you might need to use a lot of literal `$`s or quotation marks in text. In such cases, you can use the more customizable form of text. The customizable form lets you explicitly specify which character to use for interpolation and which characters to use for delimiting the text. The first character after the `$` is the custom interpolation character, which can be any of the following symbols: `~!@#$%^&*+=\?`. If none of these characters is used, the default interpolation character is `$`. Since this is the default, you can disable interpolation altogether by using `$` here (i.e. a double `$$`). The next thing in a customizable text is the character used to delimit the text. The text delimiter can be any of the following symbols: `` "'`|/;([{< `` If the text delimiter is one of `([{<`, then the text will continue until a matching `)]}>` is found, not terminating unless the delimiters are balanced (i.e. nested pairs of delimiters are considered part of the text). Here are some examples: ``` $"Equivalent to normal text with dollar interps: $(1 + 2)" $@"The same, but the AT symbol interpolates: @(1 + 2)" $$"No interpolation here, $ is just a literal character" $|This text is pipe-delimited, so it can have "quotes" and 'single quotes' and interpolates with dollar sign: $(1+2)| $(This text is parens-delimited, so you can have (nested) parens without ending the text) $=[This text is square-bracket delimited [which can be nested] and uses equals for interps: =(1 + 2)] $@/look ma, regex literals!/ ``` When text is delimited by matching pairs (`()`, `[]`, `{}`, or `<>`), they can only be closed by a matched closing character at the same indentation level, ignoring nested pairs: ``` $$(Inside parens, you can have (nested ()) parens no problem) $$"But only (), [], {}, and <> are matching pairs, you can't have nested quotes" $$( When indented, an unmatched ) won't close the text An unmatched ( won't mess things up either Only matching pairs on the same indentation level are counted: ) $$(Multi-line text with nested (parens) and .. line continuation) ``` As a special case, when you use the same character for interpolation and text delimiting, no interpolations are allowed: ``` plain := $""This text has {no interpolations}!" ``` **Note:** Normal doubly quoted text with no dollar sign (e.g. `"foo"`) are a shorthand for `${}"foo"`. Singly quoted text with no dollar sign (e.g. `'foo'`) are shorthand for `$''foo'`. ## Operations ### Concatenation Concatenation in the typical case is a fast operation: `"{x}{y}"` or `x ++ y`. Because text concatenation is typically fast, there is no need for a separate "string builder" class in the language and no need to use a list of text fragments. ### Text Length Text length gives you the number of grapheme clusters in the text, according to the unicode standard. This corresponds to what you would intuitively think of when you think of "letters" in a string. If you have text with an emoji that has several joining modifiers attached to it, that text has a length of 1. ```tomo >> "hello".length = 5 >> "👩🏽‍🚀".length = 1 ``` ### Iteration Iteration is *not* supported for text. It is rarely ever the case that you will need to iterate over text, but if you do, you can iterate over the length of the text and retrieve 1-wide slices. Alternatively, you can split the text into its constituent grapheme clusters with `text.split()` and iterate over those. ### Equality, Comparison, and Hashing All text is compared and hashed using unicode normalization. Unicode provides several different ways to represent the same text. For example, the single codepoint `U+E9` (latin small e with accent) is rendered the same as the two code points `U+65 U+301` (latin small e, acute combining accent) and has an equivalent linguistic meaning. These are simply different ways to represent the same "letter." In order to make it easy to write correct code that takes this into account, Tomo uses unicode normalization for all text comparisons and hashing. Normalization does the equivalent of converting text to a canonical form before performing comparisons or hashing. This means that if a table is created that has text with the codepoint `U+E9` as a key, then a lookup with the same text but with `U+65 U+301` instead of `U+E9` will still succeed in finding the value because the two texts are equivalent under normalization. # API [API documentation](../api/text.md)