23 KiB
title | weight | toc |
---|---|---|
Built-in methods | 10 | true |
Overview
This section lists the methods of built-in types. Methods are selected
using dot expressions.
For example, strings have a count
method that counts
occurrences of a substring; "banana".count("a")
yields 3
.
As with built-in functions, built-in methods accept only positional arguments except where noted. The parameter names serve merely as documentation.
dict·clear
D.clear()
removes all the entries of dictionary D and returns None
.
It fails if the dictionary is frozen or if there are active iterators.
x = {"one": 1, "two": 2}
x.clear() # None
print(x) # {}
dict·get
D.get(key[, default])
returns the dictionary value corresponding to the given key.
If the dictionary contains no such value, get
returns None
, or the
value of the optional default
parameter if present.
get
fails if key
is unhashable, or the dictionary is frozen or has active iterators.
x = {"one": 1, "two": 2}
x.get("one") # 1
x.get("three") # None
x.get("three", 0) # 0
dict·items
D.items()
returns a new list of key/value pairs, one per element in
dictionary D, in the same order as they would be returned by a for
loop.
x = {"one": 1, "two": 2}
x.items() # [("one", 1), ("two", 2)]
dict·keys
D.keys()
returns a new list containing the keys of dictionary D, in the
same order as they would be returned by a for
loop.
x = {"one": 1, "two": 2}
x.keys() # ["one", "two"]
dict·pop
D.pop(key[, default])
returns the value corresponding to the specified
key, and removes it from the dictionary. If the dictionary contains no
such value, and the optional default
parameter is present, pop
returns that value; otherwise, it fails.
pop
fails if key
is unhashable, or the dictionary is frozen or has active iterators.
x = {"one": 1, "two": 2}
x.pop("one") # 1
x # {"two": 2}
x.pop("three", 0) # 0
x.pop("four") # error: missing key
dict·popitem
D.popitem()
returns the first key/value pair, removing it from the dictionary.
popitem
fails if the dictionary is empty, frozen, or has active iterators.
x = {"one": 1, "two": 2}
x.popitem() # ("one", 1)
x.popitem() # ("two", 2)
x.popitem() # error: empty dict
dict·setdefault
D.setdefault(key[, default])
returns the dictionary value corresponding to the given key.
If the dictionary contains no such value, setdefault
, like get
,
returns None
or the value of the optional default
parameter if
present; setdefault
additionally inserts the new key/value entry into the dictionary.
setdefault
fails if the key is unhashable, or if the dictionary is frozen or has active iterators.
x = {"one": 1, "two": 2}
x.setdefault("one") # 1
x.setdefault("three", 0) # 0
x # {"one": 1, "two": 2, "three": 0}
x.setdefault("four") # None
x # {"one": 1, "two": 2, "three": None}
dict·update
D.update([pairs][, name=value[, ...])
makes a sequence of key/value
insertions into dictionary D, then returns None.
If the positional argument pairs
is present, it must be None
,
another dict
, or some other iterable.
If it is another dict
, then its key/value pairs are inserted into D.
If it is an iterable, it must provide a sequence of pairs (or other iterables of length 2),
each of which is treated as a key/value pair to be inserted into D.
For each name=value
argument present, the name is converted to a
string and used as the key for an insertion into D, with its corresponding
value being value
.
update
fails if the dictionary is frozen or has active iterators.
x = {}
x.update([("a", 1), ("b", 2)], c=3)
x.update({"d": 4})
x.update(e=5)
x # {"a": 1, "b": "2", "c": 3, "d": 4, "e": 5}
dict·values
D.values()
returns a new list containing the dictionary's values, in the
same order as they would be returned by a for
loop over the
dictionary.
x = {"one": 1, "two": 2}
x.values() # [1, 2]
list·append
L.append(x)
appends x
to the list L, and returns None
.
append
fails if the list is frozen or has active iterators.
x = []
x.append(1) # None
x.append(2) # None
x.append(3) # None
x # [1, 2, 3]
list·clear
L.clear()
removes all the elements of the list L and returns None
.
It fails if the list is frozen or if there are active iterators.
x = [1, 2, 3]
x.clear() # None
x # []
list·extend
L.extend(x)
appends the elements of x
, which must be iterable, to
the list L, and returns None
.
extend
fails if x
is not iterable, or if the list L is frozen or has active iterators.
x = []
x.extend([1, 2, 3]) # None
x.extend(["foo"]) # None
x # [1, 2, 3, "foo"]
list·index
L.index(x[, start[, end]])
finds x
within the list L and returns its index.
The optional start
and end
parameters restrict the portion of
list L that is inspected. If provided and not None
, they must be list
indices of type int
. If an index is negative, len(L)
is effectively
added to it, then if the index is outside the range [0:len(L)]
, the
nearest value within that range is used; see Indexing.
index
fails if x
is not found in L, or if start
or end
is not a valid index (int
or None
).
x = list("banana".codepoints())
x.index("a") # 1 (bAnana)
x.index("a", 2) # 3 (banAna)
x.index("a", -2) # 5 (bananA)
list·insert
L.insert(i, x)
inserts the value x
in the list L at index i
, moving
higher-numbered elements along by one. It returns None
.
As usual, the index i
must be an int
. If its value is negative,
the length of the list is added, then its value is clamped to the
nearest value in the range [0:len(L)]
to yield the effective index.
insert
fails if the list is frozen or has active iterators.
x = ["b", "c", "e"]
x.insert(0, "a") # None
x.insert(-1, "d") # None
x # ["a", "b", "c", "d", "e"]
list·pop
L.pop([index])
removes and returns the last element of the list L, or,
if the optional index is provided, at that index.
pop
fails if the index is not valid for L[i]
,
or if the list is frozen or has active iterators.
x = [1, 2, 3, 4, 5]
x.pop() # 5
x # [1, 2, 3, 4]
x.pop(-2) # 3
x # [1, 2, 4]
x.pop(-3) # 1
x # [2, 4]
x.pop() # 4
x # [2]
list·remove
L.remove(x)
removes the first occurrence of the value x
from the list L, and returns None
.
remove
fails if the list does not contain x
, is frozen, or has active iterators.
x = [1, 2, 3, 2]
x.remove(2) # None (x == [1, 3, 2])
x.remove(2) # None (x == [1, 3])
x.remove(2) # error: element not found
set·union
S.union(iterable)
returns a new set into which have been inserted
all the elements of set S and all the elements of the argument, which
must be iterable.
union
fails if any element of the iterable is not hashable.
x = set([1, 2])
y = set([2, 3])
x.union(y) # set([1, 2, 3])
string·elem_ords
S.elem_ords()
returns an iterable value containing the
sequence of numeric bytes values in the string S.
To materialize the entire sequence of bytes, apply list(...)
to the result.
Example:
list("Hello, 世界".elem_ords()) # [72, 101, 108, 108, 111, 44, 32, 228, 184, 150, 231, 149, 140]
See also: string·elems
.
Implementation note: elem_ords
is not provided by the Java implementation.
string·capitalize
S.capitalize()
returns a copy of string S with its first code point
changed to its title case and all subsequent letters changed to their
lower case.
"hello, world!".capitalize() # "Hello, world!"
"hElLo, wOrLd!".capitalize() # "Hello, world!"
"¿Por qué?".capitalize() # "¿por qué?"
string·codepoint_ords
S.codepoint_ords()
returns an iterable value containing the
sequence of integer Unicode code points encoded by the string S.
Each invalid code within the string is treated as if it encodes the
Unicode replacement character, U+FFFD.
By returning an iterable, not a list, the cost of decoding the string
is deferred until actually needed; apply list(...)
to the result to
materialize the entire sequence.
Example:
list("Hello, 世界".codepoint_ords()) # [72, 101, 108, 108, 111, 44, 32, 19990, 30028]
for cp in "Hello, 世界".codepoint_ords():
print(chr(cp)) # prints 'H', 'e', 'l', 'l', 'o', ',', ' ', '世', '界'
See also: string·codepoints
.
Implementation note: codepoint_ords
is not provided by the Java implementation.
string·count
S.count(sub[, start[, end]])
returns the number of occcurences of
sub
within the string S, or, if the optional substring indices
start
and end
are provided, within the designated substring of S.
They are interpreted according to Starlark's indexing conventions.
"hello, world!".count("o") # 2
"hello, world!".count("o", 7, 12) # 1 (in "world")
string·endswith
S.endswith(suffix[, start[, end]])
reports whether the string
S[start:end]
has the specified suffix.
"filename.star".endswith(".star") # True
The suffix
argument may be a tuple of strings, in which case the
function reports whether any one of them is a suffix.
'foo.cc'.endswith(('.cc', '.h')) # True
string·find
S.find(sub[, start[, end]])
returns the index of the first
occurrence of the substring sub
within S.
If either or both of start
or end
are specified,
they specify a subrange of S to which the search should be restricted.
They are interpreted according to Starlark's indexing conventions.
If no occurrence is found, found
returns -1.
"bonbon".find("on") # 1
"bonbon".find("on", 2) # 4
"bonbon".find("on", 2, 5) # -1
string·format
S.format(*args, **kwargs)
returns a version of the format string S
in which bracketed portions {...}
are replaced
by arguments from args
and kwargs
.
Within the format string, a pair of braces {{
or }}
is treated as
a literal open or close brace.
Each unpaired open brace must be matched by a close brace }
.
The optional text between corresponding open and close braces
specifies which argument to use and how to format it, and consists of
three components, all optional:
a field name, a conversion preceded by '!
', and a format specifier
preceded by ':
'.
{field}
{field:spec}
{field!conv}
{field!conv:spec}
The field name may be either a decimal number or a keyword. A number is interpreted as the index of a positional argument; a keyword specifies the value of a keyword argument. If all the numeric field names form the sequence 0, 1, 2, and so on, they may be omitted and those values will be implied; however, the explicit and implicit forms may not be mixed.
The conversion specifies how to convert an argument value x
to a
string. It may be either !r
, which converts the value using
repr(x)
, or !s
, which converts the value using str(x)
and is
the default.
The format specifier, after a colon, specifies field width, alignment, padding, and numeric precision. Currently it must be empty, but it is reserved for future use.
"a{x}b{y}c{}".format(1, x=2, y=3) # "a2b3c1"
"a{}b{}c".format(1, 2) # "a1b2c"
"({1}, {0})".format("zero", "one") # "(one, zero)"
"Is {0!r} {0!s}?".format('heterological') # 'is "heterological" heterological?'
string·index
S.index(sub[, start[, end]])
returns the index of the first
occurrence of the substring sub
within S, like S.find
, except
that if the substring is not found, the operation fails.
"bonbon".index("on") # 1
"bonbon".index("on", 2) # 4
"bonbon".index("on", 2, 5) # error: substring not found (in "nbo")
string·isalnum
S.isalnum()
reports whether the string S is non-empty and consists only
Unicode letters and digits.
"base64".isalnum() # True
"Catch-22".isalnum() # False
string·isalpha
S.isalpha()
reports whether the string S is non-empty and consists only of Unicode letters.
"ABC".isalpha() # True
"Catch-22".isalpha() # False
"".isalpha() # False
string·isdigit
S.isdigit()
reports whether the string S is non-empty and consists only of Unicode digits.
"123".isdigit() # True
"Catch-22".isdigit() # False
"".isdigit() # False
string·islower
S.islower()
reports whether the string S contains at least one cased Unicode
letter, and all such letters are lowercase.
"hello, world".islower() # True
"Catch-22".islower() # False
"123".islower() # False
string·isspace
S.isspace()
reports whether the string S is non-empty and consists only of Unicode spaces.
" ".isspace() # True
"\r\t\n".isspace() # True
"".isspace() # False
string·istitle
S.istitle()
reports whether the string S contains at least one cased Unicode
letter, and all such letters that begin a word are in title case.
"Hello, World!".istitle() # True
"Catch-22".istitle() # True
"HAL-9000".istitle() # False
"Dženan".istitle() # True
"DŽenan".istitle() # False ("DŽ" is a single Unicode letter)
"123".istitle() # False
string·isupper
S.isupper()
reports whether the string S contains at least one cased Unicode
letter, and all such letters are uppercase.
"HAL-9000".isupper() # True
"Catch-22".isupper() # False
"123".isupper() # False
string·join
S.join(iterable)
returns the string formed by concatenating each
element of its argument, with a copy of the string S between
successive elements. The argument must be an iterable whose elements
are strings.
", ".join(["one", "two", "three"]) # "one, two, three"
"a".join("ctmrn".codepoints()) # "catamaran"
string·lower
S.lower()
returns a copy of the string S with letters converted to lowercase.
"Hello, World!".lower() # "hello, world!"
string·lstrip
S.lstrip()
returns a copy of the string S with leading whitespace removed.
Like strip
, it accepts an optional string parameter that specifies an
alternative set of Unicode code points to remove.
" hello ".lstrip() # "hello "
" hello ".lstrip("h o") # "ello "
string·partition
S.partition(x)
splits string S into three parts and returns them as
a tuple: the portion before the first occurrence of string x
, x
itself,
and the portion following it.
If S does not contain x
, partition
returns (S, "", "")
.
partition
fails if x
is not a string, or is the empty string.
"one/two/three".partition("/") # ("one", "/", "two/three")
string·replace
S.replace(old, new[, count])
returns a copy of string S with all
occurrences of substring old
replaced by new
. If the optional
argument count
, which must be an int
, is non-negative, it
specifies a maximum number of occurrences to replace.
"banana".replace("a", "o") # "bonono"
"banana".replace("a", "o", 2) # "bonona"
string·rfind
S.rfind(sub[, start[, end]])
returns the index of the substring sub
within
S, like S.find
, except that rfind
returns the index of the substring's
last occurrence.
"bonbon".rfind("on") # 4
"bonbon".rfind("on", None, 5) # 1
"bonbon".rfind("on", 2, 5) # -1
string·rindex
S.rindex(sub[, start[, end]])
returns the index of the substring sub
within
S, like S.index
, except that rindex
returns the index of the substring's
last occurrence.
"bonbon".rindex("on") # 4
"bonbon".rindex("on", None, 5) # 1 (in "bonbo")
"bonbon".rindex("on", 2, 5) # error: substring not found (in "nbo")
string·rpartition
S.rpartition(x)
is like partition
, but splits S
at the last occurrence of x
.
"one/two/three".partition("/") # ("one/two", "/", "three")
string·rsplit
S.rsplit([sep[, maxsplit]])
splits a string into substrings like S.split
,
except that when a maximum number of splits is specified, rsplit
chooses the
rightmost splits.
"banana".rsplit("n") # ["ba", "a", "a"]
"banana".rsplit("n", 1) # ["bana", "a"]
"one two three".rsplit(None, 1) # ["one two", "three"]
"".rsplit("n") # [""]
string·rstrip
S.rstrip()
returns a copy of the string S with trailing whitespace removed.
Like strip
, it accepts an optional string parameter that specifies an
alternative set of Unicode code points to remove.
" hello ".rstrip() # " hello"
" hello ".rstrip("h o") # " hell"
string·split
S.split([sep [, maxsplit]])
returns the list of substrings of S,
splitting at occurrences of the delimiter string sep
.
Consecutive occurrences of sep
are considered to delimit empty
strings, so 'food'.split('o')
returns ['f', '', 'd']
.
Splitting an empty string with a specified separator returns ['']
.
If sep
is the empty string, split
fails.
If sep
is not specified or is None
, split
uses a different
algorithm: it removes all leading spaces from S
(or trailing spaces in the case of rsplit
),
then splits the string around each consecutive non-empty sequence of
Unicode white space characters.
If S consists only of white space, S.split()
returns the empty list.
If maxsplit
is given and non-negative, it specifies a maximum number of splits.
"one two three".split() # ["one", "two", "three"]
"one two three".split(" ") # ["one", "two", "", "three"]
"one two three".split(None, 1) # ["one", "two three"]
"banana".split("n") # ["ba", "a", "a"]
"banana".split("n", 1) # ["ba", "ana"]
"".split("n") # [""]
string·elems
S.elems()
returns an iterable value containing successive
1-byte substrings of S.
To materialize the entire sequence, apply list(...)
to the result.
Example:
list('Hello, 世界'.elems()) # ["H", "e", "l", "l", "o", ",", " ", "\xe4", "\xb8", "\x96", "\xe7", "\x95", "\x8c"]
See also: string·elem_ords
.
string·codepoints
S.codepoints()
returns an iterable value containing the sequence of
substrings of S that each encode a single Unicode code point.
Each invalid code within the string is treated as if it encodes the
Unicode replacement character, U+FFFD.
By returning an iterable, not a list, the cost of decoding the string
is deferred until actually needed; apply list(...)
to the result to
materialize the entire sequence.
Example:
list('Hello, 世界'.codepoints()) # ['H', 'e', 'l', 'l', 'o', ',', ' ', '世', '界']
for cp in 'Hello, 世界'.codepoints():
print(cp) # prints 'H', 'e', 'l', 'l', 'o', ',', ' ', '世', '界'
See also: string·codepoint_ords
.
Implementation note: codepoints
is not provided by the Java implementation.
string·splitlines
S.splitlines([keepends])
returns a list whose elements are the
successive lines of S, that is, the strings formed by splitting S at
line terminators (currently assumed to be a single newline, \n
,
regardless of platform).
The optional argument, keepends
, is interpreted as a Boolean.
If true, line terminators are preserved in the result, though
the final element does not necessarily end with a line terminator.
As a special case, if S is the empty string,
splitlines
returns the empty list.
"one\n\ntwo".splitlines() # ["one", "", "two"]
"one\n\ntwo".splitlines(True) # ["one\n", "\n", "two"]
"".splitlines() # [] -- a special case
string·startswith
S.startswith(prefix[, start[, end]])
reports whether the string
S[start:end]
has the specified prefix.
"filename.star".startswith("filename") # True
The prefix
argument may be a tuple of strings, in which case the
function reports whether any one of them is a prefix.
'abc'.startswith(('a', 'A')) # True
'ABC'.startswith(('a', 'A')) # True
'def'.startswith(('a', 'A')) # False
string·strip
S.strip()
returns a copy of the string S with leading and trailing whitespace removed.
It accepts an optional string argument:
S.strip(cutset)
instead removes all leading
and trailing Unicode code points contained in cutset
.
" hello ".strip() # "hello"
" hello ".strip("h o") # "ell"
string·title
S.title()
returns a copy of the string S with letters converted to title case.
Letters are converted to upper case at the start of words, lower case elsewhere.
"hElLo, WoRlD!".title() # "Hello, World!"
"dženan".title() # "Dženan" ("Dž" is a single Unicode letter)
string·upper
S.upper()
returns a copy of the string S with letters converted to uppercase.
"Hello, World!".upper() # "HELLO, WORLD!"