- Documentation
- Reference manual
- Built-in Predicates
- Notation of Predicate Descriptions
- Character representation
- Loading Prolog source files
- Editor Interface
- List the program, predicates or clauses
- Verify Type of a Term
- Comparison and Unification of Terms
- Control Predicates
- Meta-Call Predicates
- Delimited continuations
- Exception handling
- Handling signals
- DCG Grammar rules
- Database
- Declaring predicate properties
- Examining the program
- Input and output
- Status of streams
- Primitive character I/O
- Term reading and writing
- Analysing and Constructing Terms
- Analysing and Constructing Atoms
- Localization (locale) support
- Character properties
- Operators
- Character Conversion
- Arithmetic
- Misc arithmetic support predicates
- Built-in list operations
- Finding all Solutions to a Goal
- Forall
- Formatted Write
- Global variables
- Terminal Control
- Operating System Interaction
- File System Interaction
- User Top-level Manipulation
- Creating a Protocol of the User Interaction
- Debugging and Tracing Programs
- Obtaining Runtime Statistics
- Execution profiling
- Memory Management
- Windows DDE interface
- Miscellaneous
- Built-in Predicates
- Packages
- Reference manual
4.2 Character representation
In traditional (Edinburgh) Prolog, characters are represented using character codes. Character codes are integer indices into a specific character set. Traditionally the character set was 7-bit US-ASCII. 8-bit character sets have been allowed for a long time, providing support for national character sets, of which iso-latin-1 (ISO 8859-1) is applicable to many Western languages.
ISO Prolog introduces three types, two of which are used for characters and one for accessing binary streams (see open/4). These types are:
- code
A character code is an integer representing a single character. As files may use multi-byte encoding for supporting different character sets (utf-8 encoding for example), reading a code from a text file is in general not the same as reading a byte. - char
Alternatively, characters may be represented as one-character atoms. This is a natural representation, hiding encoding problems from the programmer as well as providing much easier debugging. - byte
Bytes are used for accessing binary streams.
In SWI-Prolog, character codes are always the Unicode
equivalent of the encoding. That is, if get_code/1
reads from a stream encoded as
KOI8-R
(used for the Cyrillic alphabet), it returns the
corresponding Unicode code points. Similarly, assembling or
disassembling atoms using atom_codes/2
interprets the codes as Unicode points. See
section 2.19.1 for details.
To ease the pain of the two character representations (code and
char), SWI-Prolog's built-in predicates dealing with character data work
as flexible as possible: they accept data in any of these formats as
long as the interpretation is unambiguous. In addition, for output
arguments that are instantiated, the character is extracted before
unification. This implies that the following two calls are identical,
both testing whether the next input character is an a
.
peek_code(Stream, a). peek_code(Stream, 97).
The two character representations are handled by a large number of built-in predicates, all of which are ISO-compatible. For converting between code and character there is char_code/2. For breaking atoms and numbers into characters there are atom_chars/2, atom_codes/2, number_chars/2 and number_codes/2. For character I/O on streams there are get_char/[1,2], get_code/[1,2], get_byte/[1,2], peek_char/[1,2], peek_code/[1,2], peek_byte/[1,2], put_code/[1,2], put_char/[1,2] and put_byte/[1,2]. The Prolog flag double_quotes controls how text between double quotes is interpreted.