- Documentation
- Reference manual
- Overview
- Getting started quickly
- The user's initialisation file
- Initialisation files and goals
- Command line options
- UI Themes
- GNU Emacs Interface
- Online Help
- Command line history
- Reuse of top-level bindings
- Overview of the Debugger
- Compilation
- Environment Control (Prolog flags)
- An overview of hook predicates
- Automatic loading of libraries
- Packs: community add-ons
- The SWI-Prolog syntax
- Rational trees (cyclic terms)
- Just-in-time clause indexing
- Wide character support
- System limits
- SWI-Prolog and 64-bit machines
- Binary compatibility
- Overview
- Packages
- Reference manual
2.16 The SWI-Prolog syntax
SWI-Prolog syntax is close to ISO-Prolog standard syntax, which is based on the Edinburgh Prolog syntax. A formal description can be found in the ISO standard document. For an informal introduction we refer to Prolog text books (see section 1) and online tutorials. In addition to the differences from the ISO standard documented here, SWI-Prolog offers several extensions, some of which also extend the syntax. See section 5 for more information.
2.16.1 ISO Syntax Support
This section lists various extensions w.r.t. the ISO Prolog syntax.
2.16.1.1 Processor Character Set
The processor character set specifies the class of each character used for parsing Prolog source text. Character classification is fixed to Unicode. See also section 2.19.
2.16.1.2 Nested comments
SWI-Prolog allows for nesting /* ... */
comments. Where
the ISO standard accepts /* ... /* ... */
as a comment,
SWI-Prolog will search for a terminating */
. This is useful
if some code with /* ... */
comment statements in it should
be commented out. This modification also avoids unintended commenting in
the example below, where the closing */
of the first
comment has been forgotten.25Recent
copies of GCC give a style warning if /*
is encountered in
a comment, which suggests that this problem has been recognised more
widely.
/* comment code /* second comment */ code
2.16.1.3 Character Escape Syntax
Within quoted atoms (using single quotes: ’<atom>’
)
special characters are represented using escape sequences. An escape
sequence is led in by the backslash (
)
character. The list of escape sequences is compatible with the ISO
standard but contains some extensions, and the interpretation of
numerically specified characters is slightly more flexible to improve
compatibility. Undefined escape characters raise a \
syntax_error
exception.26Up to SWI-Prolog 6.1.9,
undefined escape characters were copied verbatim, i.e., removing the
backslash.
\a
- Alert character. Normally the ASCII character 7 (beep).
\b
- Backspace character.
\c
- No output. All input characters up to but not including the first
non-layout character are skipped. This allows for the specification of
pretty-looking long lines. Not supported by ISO. Example:
format('This is a long line that looks better if it was \c split across multiple physical lines in the input')
\<NEWLINE>
- When in ISO mode (see the Prolog flag iso),
only skip this sequence. In native mode, white space that follows the
newline is skipped as well and a warning is printed, indicating that
this construct is deprecated and advising to use
\c
. We advise using\c
or putting the layout before the
, as shown below. Using\
\c
is supported by various other Prolog implementations and will remain supported by SWI-Prolog. The style shown below is the most compatible solution.27Future versions will interpret
<return> according to ISO.\
format('This is a long line that looks better if it was \ split across multiple physical lines in the input')
instead of
format('This is a long line that looks better if it was\ split across multiple physical lines in the input')
Note that SWI-Prolog also allows unescaped newlines to appear in quoted material. This is not allowed by the ISO standard, but used to be common practice before.
\e
- Escape character (ASCII 27). Not ISO, but widely supported.
\f
- Form-feed character.
\n
- Next-line character.
\r
- Carriage-return only (i.e., go back to the start of the line).
\s
- Space character. Intended to allow writing
0'\s
to get the character code of the space character. Not ISO. \t
- Horizontal tab character.
\v
- Vertical tab character (ASCII 11).
\
xXX..\
- Hexadecimal specification of a character. The closing
\
is obligatory according to the ISO standard, but optional in SWI-Prolog to enhance compatibility with the older Edinburgh standard. The code\xa\3
emits the character 10 (hexadecimal‘a') followed by‘3'. Characters specified this way are interpreted as Unicode characters. See also\u
. \uXXXX
- Unicode character specification where the character is specified using
exactly 4 hexadecimal digits. This is an extension to the ISO
standard, fixing two problems. First, where
\x
defines a numeric character code, it doesn't specify the character set in which the character should be interpreted. Second, it is not needed to use the idiosyncratic closing
ISO Prolog syntax.\
\UXXXXXXXX
- Same as
\uXXXX
, but using 8 digits to cover the whole Unicode set. \40
- Octal character specification. The rules and remarks for hexadecimal specifications apply to octal specifications as well.
\
\
- Escapes the backslash itself. Thus,
'\\'
is an atom consisting of a single
.\
\’
- Single quote. Note that
'\''
and''''
both describe the atom with a single’
, i.e.,'\'' == ''''
is true. \"
- Double quote.
\‘
- Back quote.
Character escaping is only available if
current_prolog_flag(character_escapes, true)
is active
(default). See current_prolog_flag/2.
Character escapes conflict with writef/2
in two ways: \40
is interpreted as decimal 40 by writef/2,
but as octal 40 (decimal 32) by read
. Also, the writef/2
sequence
\l
is illegal. It is advised to use the more widely
supported
format/[2,3]
predicate instead. If you insist upon using writef/2,
either switch character_escapes
to false
, or use double \\
, as in writef('\\l')
.
2.16.1.4 Syntax for non-decimal numbers
SWI-Prolog implements both Edinburgh and ISO representations for
non-decimal numbers. According to Edinburgh syntax, such numbers are
written as <radix>’<number>
,
where <radix> is a number between 2 and 36. ISO defines
binary, octal and hexadecimal numbers using
0[bxo]<number>
. For example: A is 0b100 \/ 0xf00
is a valid expression. Such numbers are always unsigned.
2.16.1.5 Using digit groups in large integers
SWI-Prolog supports splitting long integers into digit groups. Digit groups can be separated with the sequence <underscore>, <optional white space>. If the <radix> is 10 or lower, they may also be separated with exactly one space. The following all express the integer 1 million:
1_000_000 1 000 000 1_000_/*more*/000
Integers can be printed using this notation with format/2,
using the
~I
format specifier. For example:
?- format('~I', [1000000]). 1_000_000
The current syntax has been proposed by Ulrich Neumerkel on the SWI-Prolog mailinglist.
2.16.1.6 Rational number syntax
As of version 8.1.22, SWI-Prolog supports rational numbers as a
primary citizen atomic data type if SWI-Prolog is compiled with the GMP
library. This can be tested using the bounded
Prolog flag. An atomic type also requires a syntax. Unfortunately there
are few options for adding rational numbers without breaking the ISO
standard.28ECLiPSe uses numerator_denominator.
This syntax conflicts with SWI-Prolog digit groups (see section
2.16.1.5) and does not have a recognised link to rational numbers.
The notation 1/3r
and 1/3R
have also been
proposed. The 1/3r
is compatible to Ruby, but is hard to
parse due to the required look-ahead and not very natural. See also https://en.wikipedia.org/wiki/Rational_data_type.
ECLiPSe and SWI-Prolog have agreed to define the canonical syntax for
rational numbers to be e.g., 1r3
. In addition, ECLiPSe
accepts
1_3
and SWI-Prolog can be asked to accept 1/3
using the module sensitive Prolog flag rational_syntax,
which has the values below. Note that write_canonical/1
always uses the compatible
1r3
syntax.
- natural
- This is the default mode where we ignore the ambiguity issue and follow
the most natural <integer>/<nonneg>
alternative. Here, <integer> follows the normal rules
for Prolog decimal integers and <nonneg> does the same,
but does not allows for a sign. Note that the parser translates a
rational number to its canonical form which implies there are no common
divisors in the resulting numerator and denominator. Examples of ration
numbers are:
1/2 1/2 2/4 1/2 1 000 000/33 000 1000/33 -3/5 -3/5 We expect very few programs to have text parsed into a rational number while a term was expected. Note that for rationals appearing in an arithmetic expression the only difference is that evaluation moves from runtime to compiletime. The utility list_rationals/0 may be used on a loaded program to check whether the program contains rational numbers inside clauses and thus may be subject to compatibility issues. If a term is intended this can be written as
/(1,2)
,(1)/2
,1 / 2
or some variation thereof. - compatibility
- Read and write rational numbers as e.g.,
1r3
. In other words, this adheres to the same rules asnatural
above, but using the‘r
’instead of‘
’. Note that this may conflict with traditional Prolog as‘/
r
’can be defined as an infix operator. The same argument holds for0x23
and similar syntax for numbers that are part of the ISO standard.
While the syntax is controlled by the flag rational_syntax, behavior on integer division and exponentiation is controlled by the flag prefer_rationals. See section section 4.27.2.2 for arithmetic on rational numbers.
2.16.1.7 NaN and Infinity floats and their syntax
SWI-Prolog supports reading and printing‘special' floating point values according to Proposal for Prolog Standard core update wrt floating point arithmetic by Joachim Schimpf and available in ECLiPSe Prolog. In particular,
- Infinity is printed as
1.0Inf
or-1.0Inf
. Any sequence matching the regular expression[+-]?\sd+[.]\sd+Inf
is mapped to plus or minus infinity. NaN
(Not a Number) is printed as1.xxxNaN
, where 1.xxx is the float after replacing the exponent by‘1'. Such numbers are read, resulting in the sameNaN
. TheNaN
constant can also be produced using the function nan/0, e.g.,?- A is nan. A = 1.5NaN.
By default SWI-Prolog arithmetic (see section 4.27) follows the ISO standard with describes that floating point operations either produce a normal floating point number or raise an exception. section 4.27.2.4 describes the Prolog flags that can be used to support the IEEE special float values. The ability to create, read and write such values facilitates the exchange of data with languages that can represent the full range of IEEE doubles.
2.16.1.8 Force only underscore to introduce a variable
According to the ISO standard and most Prolog systems, identifiers
that start with an uppercase letter or an underscore are variables. In
the past, Prolog by BIM provided an alternative syntax, where
only the underscore (_
) introduces a variable. As of
SWI-Prolog 7.3.27 SWI-Prolog supports this alternative syntax,
controlled by the Prolog flag var_prefix.
As the character_escapes
flag, this flag is maintained per module, where the default is
false
, supporting standard syntax.
Having only the underscore introduce a variable is particularly useful if code contains identifiers for case sensitive external languages. Examples are the RDF library where code frequently specifies property and class names29Samer Abdallah suggested this feature based on experience with non-Prolog users using the RDF library. and the R interface for specifying functions or variables that start with an uppercase character. Lexical databases where part of the terms start with an uppercase letter is another category were the readability of the code improves using this option.
2.16.1.9 Unicode Prolog source
The ISO standard specifies the Prolog syntax in ASCII characters. As SWI-Prolog supports Unicode in source files we must extend the syntax. This section describes the implication for the source files, while writing international source files is described in section 3.1.3.
The SWI-Prolog Unicode character classification is based on version 6.0.0 of the Unicode standard. Please note that char_type/2 and friends, intended to be used with all text except Prolog source code, is based on the C library locale-based classification routines.
- Quoted atoms and strings
Any character of any script can be used in quoted atoms and strings. The escape sequences\uXXXX
and\UXXXXXXXX
(see section 2.16.1.3) were introduced to specify Unicode code points in ASCII files. - Atoms and Variables
We handle them in one item as they are closely related. The Unicode standard defines a syntax for identifiers in computer languages.30http://www.unicode.org/reports/tr31/ In this syntax identifiers start withID_Start
followed by a sequence ofID_Continue
codes. Such sequences are handled as a single token in SWI-Prolog. The token is a variable iff it starts with an uppercase character or an underscore (_
). Otherwise it is an atom. Note that many languages do not have the notion of character case. In such languages variables must be written as_name
. - White space
All characters marked as separators (Z*) in the Unicode tables are handled as layout characters. - Control and unassigned characters
Control and unassigned (C*) characters produce a syntax error if encountered outside quoted atoms/strings and outside comments. - Other characters
The first 128 characters follow the ISO Prolog standard. Unicode symbol and punctuation characters (general category S* and P*) act as glueing symbol characters (i.e., just like
: an unquoted sequence of symbol characters are combined into an atom).==
Other characters (this is mainly
No
: a numeric character of other type) are currently handled as‘solo'.
2.16.1.10 Singleton variable checking
A singleton
variable is a variable that appears only one time in a clause. It
can always be replaced by _
, the
anonymous variable. In some cases, however, people prefer to
give the variable a name. As mistyping a variable is a common mistake,
Prolog systems generally give a warning (controlled by style_check/1)
if a variable is used only once. The system can be informed that a
variable is meant to appear once by starting it with an
underscore, e.g.,
_Name
. Please note that any variable, except plain _
,
shares with variables of the same name. The term t(_X, _X)
is equivalent to t(X, X)
, which is different from
t(_, _)
.
As Unicode requires variables to start with an underscore in many languages, this schema needs to be extended.31After a proposal by Richard O'Keefe. First we define the two classes of named variables.
- Named singleton variables
Named singletons start with a double underscore (__
) or a single underscore followed by an uppercase letter, e.g.,__var
or_Var
. - Normal variables
All other variables are‘normal' variables. Note this makes_var
a normal variable.32Some Prolog dialects write variables this way.
Any normal variable appearing exactly once in the clause and any named singleton variables appearing more than once are reported. Below are some examples with warnings in the right column. Singleton messages can be suppressed using the style_check/1 directive.
test(_). | |
test(_a). | Singleton variables: [_a] |
test(_12). | Singleton variables: [_12] |
test(A). | Singleton variables: [A] |
test(_A). | |
test(__a). | |
test(_, _). | |
test(_a, _a). | |
test(__a, __a). | Singleton-marked variables appearing more than once: [__a] |
test(_A, _A). | Singleton-marked variables appearing more than once: [_A] |
test(A, A). |
Semantic singletons
Starting with version 6.5.1, SWI-Prolog has syntactic singletons
and semantic singletons. The first are checked by
read_clause/3
(and read_term/3
using the option
singletons(warning)
). The latter are generated by the
compiler for variables that appear alone in a branch. For
example, in the code below the variable X is not a syntactic
singleton, but the variable X does not communicate any
bindings and replacing
X with _ does not change the semantics.
test :- ( test_1(X) ; test_2(X) ).