ReliableTXT is a modern text file format that was designed to make working with text files as robust as possible. For that ReliableTXT strictly defines rules for the used line-break convention, the allowed characters, the encoding and decoding process, and it's associated error handling.
ReliableTXT builds the foundation for text file formats like OML, WSV, SML, and TBL (see also the Stenway Text File Format Stack). All of these formats don't need to bother about encoding and decoding anymore, because they rely on ReliableTXT, which takes care of that aspect. Defining encoding settings on content level, like it can be done in XML and HTML files, or specifying encoding rules on format level, like the JSON specification does, are thus unnecessary. Scanning the complete file in order to guess it's encoding is not required anymore, because a ReliableTXT file always starts with an unambiguous preamble, that clearly identifies the used encoding. The loading of a ReliableTXT file is therefore always 100% automatic, and thus robust and reliable.
The line break convention of ReliableTXT combines the line separation aspect of the Windows line break convention with the single line feed character of POSIX text files, and thus represents the best of both worlds. It simplifies the specification of line-based formats, because those formats can rely on a single line break convention, instead of having to handle multiple conventions, which might even occur mixed in a file.
Learn more about ReliableTXT on the official website www.reliabletxt.com where you can find the complete specification and can try out ReliableTXT in an online editor. Find out what can be done with ReliableTXT on the official YouTube channel from Stenway. Here is a selection of videos you might start with:
- Why I like the UTF-8 Byte Order Mark (BOM)
- Stop Using Windows Line Breaks (CRLF)
- Convert To ReliableTXT
- ReliableTXT Editor in your browser - Stenway Notepad
- ReliableTXT Summary - The Reliable Text File Format
- Document does not have a ReliableTXT preamble
This package provides functionality to handle the encoding and decoding of ReliableTXT documents, as well as functionality to join and split lines according to the ReliableTXT line break convention. It also offers a way to encode and decode Base64 strings based on ReliableTXT, called Reliable Base64.
This package works both in the browser and Node.js, because it does not require environment specific functionality. If you want to read and write ReliableTXT files using Node.js's file system module, you can use the reliabletxt-io package. The reliabletxt-browser package on the other hand offers functionality to easily provide ReliableTXT documents as downloadable files.
If you want to get a first impression on how to use this package, you can watch this video. But always check the changelog of the presented packages for possible changes, that are not reflected in the video.
First get the ReliableTXT package installed with a package manager of your choice. If you are using NPM just run the following command:
npm install @stenway/reliabletxt
As a first example how to use the package, let's create a ReliableTXT document and convert its content to bytes. For that we first import the ReliableTxtDocument class from the ReliableTXT package:
import { ReliableTxtDocument } from "@stenway/reliabletxt"
const document = new ReliableTxtDocument("Hello 🌎")
console.log(document.toBytes())
We then create a new ReliableTxtDocument object and pass our text string as argument to the constructor. After that we call the toBytes method and log the returned bytes to the console. The method returns a Uint8Array with the following byte values:
[239, 187, 191, 72, 101, 108, 108, 111, 32, 240, 159, 140, 142]
The first three bytes represent the UTF-8 BOM (byte order mark) with hexadecimal values EF, BB and BF, which are the UTF-8 representation of the Unicode codepoint U+FEFF. The six bytes after that represent the letters of the word 'Hello' and the space character. The last four bytes are the UTF-8 representation of the world emoji with Unicode codepoint U+1F30E, which is a supplementary character.
UTF-8 encoding is the default encoding, and one of the four encodings that ReliableTXT supports, which are:
- UTF-8
- UTF-16
- UTF-16 Reverse (Little Endian)
- UTF-32
The ReliableTXT package contains an enumeration type called ReliableTxtEncoding that we can use to specify, which encoding should be used. Let's import the type and pass the encoding as argument to the constructor of the ReliableTxtDocument class:
import { ReliableTxtDocument, ReliableTxtEncoding } from "@stenway/reliabletxt"
const document = new ReliableTxtDocument("Hello 🌎", ReliableTxtEncoding.Utf16)
console.log(document.toBytes())
We specify to use the UTF-16 encoding with big endianess byte order. Let's see how the returned bytes look like:
[254, 255, 0, 72, 0, 101, 0, 108, 0, 108, 0, 111, 0, 32, 216, 60, 223, 14]
The first two bytes represent the BOM codepoint U+FEFF, expressed with decimal values 254 and 255. UTF-16 is a variable-width encoding using either 2 or 4 bytes to encode a Unicode codepoint. Codepoints of the basic multilingual plane (BMP) - like the letters of the word 'Hello' and the space character - need 2 bytes to be encoded. In our case the characters are part of the basic latin block (from U+0000 to U+007F) and have the characteristic zero byte in front, like for the capital letter H, which is encoded using the bytes 0 and 72. If we would have used the UTF-16 Reverse encoding (which represents little endianess), then the byte order would be switched and the zero bytes would follow, which would mean in the case of our capital letter H that we would get the two bytes 72 and 0.
Supplementary characters like the world emoji need 4 bytes to be encoded and use a surrogate pair consisting of a high and a low surrogate to express their codepoint, which is bigger than a single 16-bit value. In our case the world emoji codepoint U+1F30E is expressed as a combination of U+D83C and U+DF0E, which are 4 bytes with the decimal numbers 216, 60, 223 and 14.
The concept of surrogate pairs was introduced to Unicode 2.0 in 1996 when Unicode switched from the original 16-bit range to the bigger 21-bit range, with the new maximum codepoint of U+10FFFF. The problem with surrogate pairs is that they introduce the case of invalid surrogate sequences and unpaired surrogates, for example when only a high surrogate exists, which is not followed by a low surrogate. In formats like JSON these invalid surrogate sequences and unpaired surrogates lead to unpredictable behaviour.
With ReliableTXT on the other hand, the behavior is strictly defined. If such an invalid surrogate sequence or an unpaired surrogate is encountered - both in the encoding and decoding process - then an error must be thrown. Let's try to encode such an unpaired surrogate first:
const document = new ReliableTxtDocument("\uDEAD")
console.log(document.toBytes())
Here we pass a string containing only a low surrogate (inside the range of U+DC00 to U+DFFF). When we call the toBytes method, it will throw an InvalidUtf16StringError. Let's try it the other way around and decode an invalid byte sequence.
const invalidBytes = new Uint8Array([0xFE, 0xFF, 0xDE, 0xAD])
const document = ReliableTxtDocument.fromBytes(invalidBytes)
Here we pass a Uint8Array to the static method fromBytes of the ReliableTxtDocument class, which will try to decode the byte sequence. In this case the byte sequence starts with a valid UTF-16 big endian byte order mark, followed by an unpaired low surrogate. The fromBytes method will throw a StringDecodingError and thus makes sure that only valid codepoints will be decoded correctly.
This behavior is different to a lot of other frameworks or libraries in many different programming languages where the default behavior is often to ignore invalid bytes, or to insert question marks or the Unicode replacement character (U+FFFD �). This is not the approach of ReliableTXT, because if a file has a defect, it shouldn't be loaded.
ReliableTXT makes sure that documents only contain Unicode scalar values when they are encoded or decoded, which means that valid code points are in the range of U+0000 to U+D7FF and U+E000 to U+10FFFF.
This also means another difference to other text file approaches, because it allows the usage of the completely valid Unicode null codepoint U+0000, which is for example not allowed in POSIX text files, because of its usage as string terminator in older programs. So the following code - where we pass a null codepoint between the letters a and b - is perfectly valid with ReliableTXT and won't produce an error or truncate parts of the string:
const document = new ReliableTxtDocument("a\u0000b")
console.log(document.toBytes())
The combination of all of these aspects of ReliableTXT make it such a robust and modern text file format.
Encoding or decoding text as Base64 in a reliable and comfortable way is also something you can do with this package. Base64 is a binary-to-text encoding scheme. So in order to encode text as Base64 string, we first must encode the text as binary data. This is where ReliableTXT comes into play, to handle the encoding and decoding of text into bytes and back again. And with the ReliableTXT preamble it's always clear, which encoding was used. So if we for example would encode an empty string with the default ReliableTXT encoding - which is UTF-8 - we would get the following Base64 string:
77u/
This is because an empty string would be encoded as three bytes, which are the three bytes of the UTF-8 byte order mark, and "77u/" would be its Base64 representation.
But a problem is, that Base64 comes in many variations, using different alphabets and rules. A variant for example might allow the use of padding characters, or might allow line breaks inbetween the Base64 string, posing certain line length restrictions as well. The variation in this package for example does not allow to use padding characters and line breaks inbetween, and the alphabet used is:
ABCDEFGHIJKLMNOPQRSTUVXYZabcdefghijklmnopqrstuvwxyz0123456789+/
In order to make it clear for the decoding routine, that these rules were applied during encoding, Reliable Base64 strings start with the prefix "Base64|" and end with a single pipe character, which looks like in the following examples:
"" -> Base64|77u/|
"Hello" -> Base64|77u/SGVsbG8|
"a¥ßä€東𝄞" -> Base64|77u/YcKlw5/DpOKCrOadsfCdhJ4|
This notation clearly identifies Reliable Base64 and makes the encoding and decoding process 100% automatic. It relies on all the robustness features of ReliableTXT, when it comes to error handling, and also makes it possible to differentiate, whether text or actual binary data was encoded - like image data - because it uses the ReliableTXT preamble to indicate that it is a text document. The following four examples encode the same text - which is "Hello" - with all four available ReliableTXT encodings:
Base64|77u/SGVsbG8|
Base64|/v8ASABlAGwAbABv|
Base64|//5IAGUAbABsAG8A|
Base64|AAD+/wAAAEgAAABlAAAAbAAAAGwAAABv|
Because all four encodings write the ReliableTXT preamble, detecting that it is a ReliableTXT document only takes reading the first two to four bytes. All other byte sequences are simply considered to be arbitrary binary data.
Reliable Base64 uses Unicode, so using supplementary characters is supported. Let's see it in action. The ReliableTXT package has a static class called Base64String that offers the static method encodeText, which we will use to pass a text string as argument that will be converted to the respective Reliable Base64 string:
import { Base64String } from "@stenway/reliabletxt"
console.log(Base64String.encodeText("Hello 🌎"))
And the returned Reliable Base64 string will be:
Base64|77u/SGVsbG8g8J+Mjg|
Let's convert the Reliable Base64 string back to its original text content using the static method decodeAsText:
console.log(Base64String.decodeAsText("Base64|77u/SGVsbG8g8J+Mjg|"))
And the original text will be logged to the console. If we take our original text string and use another ReliableTXT encoding (e.g. UTF-16 big endian encoding), the resulting Reliable Base64 string will look different, but will be correctly and automatically converted back to text:
import { Base64String, ReliableTxtEncoding } from "@stenway/reliabletxt"
console.log(Base64String.encodeText("Hello 🌎", ReliableTxtEncoding.Utf16))
console.log(Base64String.decodeAsText("Base64|/v8ASABlAGwAbABvACDYPN8O|"))
Let's try to remove the UTF-8 byte order mark from our previously with UTF-8 encoded Reliable Base64 string and see what happens when we try to decode it. The UTF-8 byte order mark is represented by three bytes, that map directly to the four Base64 characters "77u/", which we can easily remove from the string:
Base64String.decodeAsText("Base64|SGVsbG8g8J+Mjg|")
This will result in a NoReliableTxtPreambleError, because a text document without a valid ReliableTXT preamble cannot be decoded. But we can decode the Reliable Base64 string as byte sequence using the static decodeAsBytes method:
console.log(Base64String.decodeAsBytes("Base64|SGVsbG8g8J+Mjg|"))
The counterpart to the toBytes method is the static encodeBytes method, which can be used like this:
const bytes = new Uint8Array([0x48, 0x65, 0x6C, 0x6C, 0x6F])
const base64str = Base64String.encodeBytes(bytes)
If you want to be flexible and want to pass both strings and bytes, you can use the encode method, which either takes a string as argument or a Uint8Array:
const base64Str1 = Base64String.encode("Hello 🌎")
const base64Str2 = Base64String.encode(new Uint8Array([0x00, 0x01, 0x02, 0x03])
The counterpart is the decode method which will either return a string or a Uint8Array.
const stringOrBytes: string | Uint8Array = Base64String.decode(base64Str1)
if (stringOrBytes instanceof Uint8Array) { /* binary data */ }
else { /* text data */ }
The automatic detection is possible, because the Reliable Base64 approach encodes text as a ReliableTXT document which has an easily detectable preamble. If the preamble was found, the bytes are decoded as text, or else the bytes are simply returned.
If you want to know more about Reliable Base64, you can watch the following videos:
If you want to transfer ReliableTXT documents over the network using HTTP, use the following MIME type:
application/reliabletxt
Learn more about it in detail in this video.
The static Base64String class provides all the functionality needed to encode and decode Reliable Base64 strings. It has the following members:
static encodeBytes(bytes: Uint8Array): string
static encodeText(text: string, encoding?: ReliableTxtEncoding): string
static decodeAsBytes(base64Str: string): Uint8Array
static decodeAsText(base64Str: string): string
static encode(stringOrBytes: string | Uint8Array): string
static decode(base64Str: string): string | Uint8Array
Use the static encodeBytes and decodeAsBytes methods to convert from bytes to a Reliable Base64 string and back again:
const bytes = new Uint8Array([0x4D, 0x61, 0x6E])
const base64str = Base64String.encodeBytes(bytes)
console.log(base64str)
const returnedBytes = Base64String.decodeAsBytes(base64str)
console.log(returnedBytes)
Use the static encodeText and decodeAsText methods to convert from text to a Reliable Base64 string and back again:
const text = "a¥ßä€東𝄞"
const base64str = Base64String.encodeText(text)
console.log(base64str)
const returnedText = Base64String.decodeAsText(base64str)
console.log(returnedText)
console.log(text === returnedText)
Specify the used encoding, by passing a ReliableTxtEncoding enum value to the encodeText method:
const base64str = Base64String.encodeText("abc", ReliableTxtEncoding.Utf16)
If you want to use the Base64 encoder and decoder without the Reliable Base64 prefix 'Base64|' and suffix '|', use the analogous static methods of the RawBase64String class.
const text = "a¥ßä€東𝄞"
const base64str = RawBase64String.encodeText(text)
console.log(base64str)
const returnedText = RawBase64String.decodeAsText(base64str)
console.log(returnedText)
console.log(text === returnedText)
static encodeBytes(bytes: Uint8Array): string
static encodeText(text: string, encoding?: ReliableTxtEncoding): string
static decodeAsBytes(base64Str: string): Uint8Array
static decodeAsText(base64Str: string): string
static encode(stringOrBytes: string | Uint8Array): string
static decode(base64Str: string): string | Uint8Array
An error of type InvalidBase64StringError is thrown when an invalid Reliable Base64 string is passed to a Base64 decoding method, like in the following example the static decodeAsText method:
Base64String.decodeAsText("")
An error of type InvalidUtf16StringError is thrown when an invalid surrogate sequence or an unpaired surrogate is encountered in a string, like here in this example:
ReliableTxtEncoder.encode("\uDEAD", ReliableTxtEncoding.Utf8)
An error of type NoReliableTxtPreambleError is thrown when a byte sequence is passed to the decoder, which does not start with a valid ReliableTXT preamble, like in this example where an empty byte array is passed:
let emptyByteArray = new Uint8Array()
try {
let x = ReliableTxtDecoder.decode(emptyByteArray)
} catch (err) {
console.log("Error: Document does not have a ReliableTXT preamble")
}
let encoding = ReliableTxtDecoder.getEncodingOrNull(emptyByteArray)
The static ReliableTxtDecoder class contains all methods needed to decode ReliableTXT documents from byte sequences. The members of the class are:
static getEncodingOrNull(bytes: Uint8Array): ReliableTxtEncoding | null
static getEncoding(bytes: Uint8Array): ReliableTxtEncoding
static decode(bytes: Uint8Array): ReliableTxtDocument
static decodePart(bytes: Uint8Array, encoding: ReliableTxtEncoding): string
The static getEncoding and getEncodingOrNull methods differ in the handling of the erroneous case, that a provided byte sequence does not contain a valid ReliableTXT preamble. The first one throws a NoReliableTxtPreambleError in that case, while the second one simply returns null:
let emptyByteArray = new Uint8Array()
let encoding = ReliableTxtDecoder.getEncodingOrNull(emptyByteArray)
ReliableTxtDecoder.getEncoding(emptyByteArray)
The ReliableTxtDocument class is used to represent a ReliableTXT document as a comfortable object to work with. It stores the text as a property and the encoding as well, which should be used when converting the text to bytes, or which was detected during the decoding process. It has multiple comfort methods to use the functionality provided in the other static classes, like the ReliableTxtEncoder, ReliableTxtDecoder and Base64String class. The members of the class are:
text: string
encoding: ReliableTxtEncoding
constructor(text?: string, encoding?: ReliableTxtEncoding)
toBytes(): Uint8Array
getLines(): string[]
setLines(lines: string[])
getCodePoints(): number[]
setCodePoints(codePoints: number[])
toBase64String(): string
static fromBytes(bytes: Uint8Array): ReliableTxtDocument
static fromLines(lines: string[], encoding?: ReliableTxtEncoding): ReliableTxtDocument
static fromCodePoints(codePoints: number[], encoding?: ReliableTxtEncoding): ReliableTxtDocument
static fromBase64String(base64Str: string): ReliableTxtDocument
Here are some methods in action:
let document = new ReliableTxtDocument(text)
let documentUtf16 = new ReliableTxtDocument(text, ReliableTxtEncoding.Utf16)
let documentEncoding = document.encoding
let documentText = document.text
let documentBytes = document.toBytes()
let documentCodePoints = document.getCodePoints()
let documentLines = document.getLines()
document.setCodePoints([0x61, 0x6771, 0x1D11E])
documentText = document.text
document.setLines(["A", "B", "C"])
documentText = document.text
document = ReliableTxtDocument.fromBytes(utf8Bytes)
document = ReliableTxtDocument.fromLines(["A", "B", "C"])
try {
let invalidUtf8Bytes = new Uint8Array([0xEF, 0xBB, 0xBF, 0xFF])
document = ReliableTxtDocument.fromBytes(invalidUtf8Bytes)
} catch (err) {
console.log("Error: Decoding error")
}
The ReliableTxtDocument class has the comfort methods toBase64String and fromBase64String to simply convert the content of the document to a Reliable Base64 string and back again. The chosen encoding of the ReliableTxtDocument will be preserved:
let document = new ReliableTxtDocument("abc")
let base64Str = document.toBase64String()
let document2 = ReliableTxtDocument.fromBase64String(base64Str)
console.log(document.text === document2.text)
console.log(document.encoding === document2.encoding)
The static ReliableTxtEncoder class provides methods for the encoding of ReliableTXT documents. Its members are:
static encode(text: string, encoding: ReliableTxtEncoding): Uint8Array
static encodePart(text: string, encoding: ReliableTxtEncoding): Uint8Array
Here is the same string encoded four times with all of the four available ReliableTXT encodings:
let text = "A\nB"
let utf8Bytes = ReliableTxtEncoder.encode(text, ReliableTxtEncoding.Utf8)
let utf16Bytes = ReliableTxtEncoder.encode(text, ReliableTxtEncoding.Utf16)
let utf16ReverseBytes = ReliableTxtEncoder.encode(text, ReliableTxtEncoding.Utf16Reverse)
let utf32Bytes = ReliableTxtEncoder.encode(text, ReliableTxtEncoding.Utf32)
This enumeration lists all of the four available ReliableTXT encodings, which are:
Utf8 = 0
Utf16 = 1
Utf16Reverse = 2
Utf32 = 3
The static ReliableTxtEncodingUtil class offers utility functionality, like providing the preamble bytes for every available encoding. Its members are:
static getPreambleSize(encoding: ReliableTxtEncoding): number
static getPreambleBytes(encoding: ReliableTxtEncoding): Uint8Array
The static ReliableTxtLines class provides comfort methods to join and split lines according to the ReliableTXT line break convention, as well as getting line index information. Its members are:
static join(lines: string[]): string
static split(text: string): string[]
static getLineInfo(text: string, codeUnitIndex: number): [charIndex: number, lineIndex: number, lineCharIndex: number]
Here is an example of how to join and split lines:
let twoJoinedLines = ReliableTxtLines.join(["Line 1", "Line 2"])
let twoLines = ReliableTxtLines.split(twoJoinedLines)
let threeLines = ReliableTxtLines.split("Line 1\r\nLine 2\n")
An error of type StringDecodingError is thrown, when invalid bytes sequences are passed to the decoder, that cannot be decoded using UTF-8, UTF-16 or UTF-32 encoding, for example:
const invalidUtf8Bytes = new Uint8Array([0xEF, 0xBB, 0xBF, 0xFF])
const invalidUtf16Bytes = new Uint8Array([0xFE, 0xFF, 0xDE, 0xAD])
const document = ReliableTxtDocument.fromBytes(invalidUtf16Bytes)
The static Utf16String class is a utility class that provides all the encoding and decoding functionality for UTF-8, UTF-16 and UTF-32. Its members are:
static isValid(str: string): boolean
static validate(str: string)
static getCodePointCount(str: string): number
static getCodePointArray(str: string): number[]
static getCodePoints(str: string): Uint32Array
static toUtf8Bytes(text: string): Uint8Array
static toUtf16Bytes(text: string, littleEndian?: boolean): Uint8Array
static toUtf32Bytes(str: string, littleEndian?: boolean): Uint8Array
static fromUtf8Bytes(bytes: Uint8Array, skipFirstBom?: boolean): string
static fromUtf16Bytes(bytes: Uint8Array, littleEndian: boolean, skipFirstBom?: boolean): string
static fromUtf32Bytes(bytes: Uint8Array, littleEndian: boolean, skipFirstBom?: boolean): string
static fromCodePointArray(codePoints: number[]): string
The Stenway Text File Format Stack defines a set of formats that are built upon ReliableTXT. Check out the following related packages: