# Japanese translations for Rust package # Copyright (C) 2013 The Rust Project Developers # This file is distributed under the same license as the Rust package. # Automatically generated, 2013. # msgid "" msgstr "" "Project-Id-Version: Rust 0.8\n" "POT-Creation-Date: 2013-08-05 19:40+0900\n" "PO-Revision-Date: 2013-07-28 20:32+0900\n" "Last-Translator: Automatically generated\n" "Language-Team: none\n" "Language: ja\n" "MIME-Version: 1.0\n" "Content-Type: text/plain; charset=UTF-8\n" "Content-Transfer-Encoding: 8bit\n" "Plural-Forms: nplurals=1; plural=0;\n" #. type: Plain text #: doc/tutorial-container.md:2 msgid "% Containers and iterators" msgstr "" #. type: Plain text #: doc/tutorial-container.md:4 msgid "# Containers" msgstr "" #. type: Plain text #: doc/tutorial-container.md:6 msgid "The container traits are defined in the `std::container` module." msgstr "" #. type: Plain text #: doc/tutorial-container.md:8 msgid "## Unique and managed vectors" msgstr "" #. type: Plain text #: doc/tutorial-container.md:12 msgid "" "Vectors have `O(1)` indexing and removal from the end, along with `O(1)` " "amortized insertion. Vectors are the most common container in Rust, and are " "flexible enough to fit many use cases." msgstr "" #. type: Plain text #: doc/tutorial-container.md:16 msgid "" "Vectors can also be sorted and used as efficient lookup tables with the " "`std::vec::bsearch` function, if all the elements are inserted at one time " "and deletions are unnecessary." msgstr "" #. type: Plain text #: doc/tutorial-container.md:18 msgid "## Maps and sets" msgstr "" #. type: Plain text #: doc/tutorial-container.md:22 msgid "" "Maps are collections of unique keys with corresponding values, and sets are " "just unique keys without a corresponding value. The `Map` and `Set` traits " "in `std::container` define the basic interface." msgstr "" #. type: Plain text #: doc/tutorial-container.md:24 msgid "The standard library provides three owned map/set types:" msgstr "" #. type: Bullet: '* ' #: doc/tutorial-container.md:30 msgid "" "`std::hashmap::HashMap` and `std::hashmap::HashSet`, requiring the keys to " "implement `Eq` and `Hash`" msgstr "" #. type: Bullet: '* ' #: doc/tutorial-container.md:30 msgid "" "`std::trie::TrieMap` and `std::trie::TrieSet`, requiring the keys to be " "`uint`" msgstr "" #. type: Bullet: '* ' #: doc/tutorial-container.md:30 msgid "" "`extra::treemap::TreeMap` and `extra::treemap::TreeSet`, requiring the keys " "to implement `TotalOrd`" msgstr "" #. type: Plain text #: doc/tutorial-container.md:34 msgid "" "These maps do not use managed pointers so they can be sent between tasks as " "long as the key and value types are sendable. Neither the key or value type " "has to be copyable." msgstr "" #. type: Plain text #: doc/tutorial-container.md:37 msgid "" "The `TrieMap` and `TreeMap` maps are ordered, while `HashMap` uses an " "arbitrary order." msgstr "" #. type: Plain text #: doc/tutorial-container.md:42 msgid "" "Each `HashMap` instance has a random 128-bit key to use with a keyed hash, " "making the order of a set of keys in a given hash table randomized. Rust " "provides a [SipHash](https://131002.net/siphash/) implementation for any " "type implementing the `IterBytes` trait." msgstr "" #. type: Plain text #: doc/tutorial-container.md:44 msgid "## Double-ended queues" msgstr "" #. type: Plain text #: doc/tutorial-container.md:49 msgid "" "The `extra::deque` module implements a double-ended queue with `O(1)` " "amortized inserts and removals from both ends of the container. It also has " "`O(1)` indexing like a vector. The contained elements are not required to be " "copyable, and the queue will be sendable if the contained type is sendable." msgstr "" #. type: Plain text #: doc/tutorial-container.md:51 msgid "## Priority queues" msgstr "" #. type: Plain text #: doc/tutorial-container.md:55 msgid "" "The `extra::priority_queue` module implements a queue ordered by a key. The " "contained elements are not required to be copyable, and the queue will be " "sendable if the contained type is sendable." msgstr "" #. type: Plain text #: doc/tutorial-container.md:61 msgid "" "Insertions have `O(log n)` time complexity and checking or popping the " "largest element is `O(1)`. Converting a vector to a priority queue can be " "done in-place, and has `O(n)` complexity. A priority queue can also be " "converted to a sorted vector in-place, allowing it to be used for an `O(n " "log n)` in-place heapsort." msgstr "" #. type: Plain text #: doc/tutorial-container.md:63 msgid "# Iterators" msgstr "" #. type: Plain text #: doc/tutorial-container.md:65 msgid "## Iteration protocol" msgstr "" #. type: Plain text #: doc/tutorial-container.md:69 msgid "" "The iteration protocol is defined by the `Iterator` trait in the `std::" "iterator` module. The minimal implementation of the trait is a `next` " "method, yielding the next element from an iterator object:" msgstr "" #. type: Plain text #: doc/tutorial-container.md:73 msgid "~~~ /// An infinite stream of zeroes struct ZeroStream;" msgstr "" #. type: Plain text #: doc/tutorial-container.md:80 #, no-wrap msgid "" "impl Iterator for ZeroStream {\n" " fn next(&mut self) -> Option {\n" " Some(0)\n" " }\n" "}\n" "~~~~\n" msgstr "" #. type: Plain text #: doc/tutorial-container.md:83 msgid "" "Reaching the end of the iterator is signalled by returning `None` instead of " "`Some(item)`:" msgstr "" #. type: Plain text #: doc/tutorial-container.md:89 doc/tutorial-container.md:262 #, no-wrap msgid "" "~~~\n" "/// A stream of N zeroes\n" "struct ZeroStream {\n" " priv remaining: uint\n" "}\n" msgstr "" #. type: Plain text #: doc/tutorial-container.md:95 #, no-wrap msgid "" "impl ZeroStream {\n" " fn new(n: uint) -> ZeroStream {\n" " ZeroStream { remaining: n }\n" " }\n" "}\n" msgstr "" #. type: Plain text #: doc/tutorial-container.md:107 doc/tutorial-container.md:284 #, no-wrap msgid "" "impl Iterator for ZeroStream {\n" " fn next(&mut self) -> Option {\n" " if self.remaining == 0 {\n" " None\n" " } else {\n" " self.remaining -= 1;\n" " Some(0)\n" " }\n" " }\n" "}\n" "~~~\n" msgstr "" #. type: Plain text #: doc/tutorial-container.md:109 msgid "## Container iterators" msgstr "" #. type: Plain text #: doc/tutorial-container.md:112 msgid "" "Containers implement iteration over the contained elements by returning an " "iterator object. For example, vector slices several iterators available:" msgstr "" #. type: Bullet: '* ' #: doc/tutorial-container.md:116 msgid "`iter()` and `rev_iter()`, for immutable references to the elements" msgstr "" #. type: Bullet: '* ' #: doc/tutorial-container.md:116 msgid "" "`mut_iter()` and `mut_rev_iter()`, for mutable references to the elements" msgstr "" #. type: Bullet: '* ' #: doc/tutorial-container.md:116 msgid "" "`consume_iter()` and `consume_rev_iter`, to move the elements out by-value" msgstr "" #. type: Plain text #: doc/tutorial-container.md:119 msgid "" "A typical mutable container will implement at least `iter()`, `mut_iter()` " "and `consume_iter()` along with the reverse variants if it maintains an " "order." msgstr "" #. type: Plain text #: doc/tutorial-container.md:121 msgid "### Freezing" msgstr "" #. type: Plain text #: doc/tutorial-container.md:125 msgid "" "Unlike most other languages with external iterators, Rust has no *iterator " "invalidation*. As long an iterator is still in scope, the compiler will " "prevent modification of the container through another handle." msgstr "" #. type: Plain text #: doc/tutorial-container.md:130 #, no-wrap msgid "" "~~~\n" "let mut xs = [1, 2, 3];\n" "{\n" " let _it = xs.iter();\n" msgstr "" #. type: Plain text #: doc/tutorial-container.md:136 #, no-wrap msgid "" " // the vector is frozen for this scope, the compiler will statically\n" " // prevent modification\n" "}\n" "// the vector becomes unfrozen again at the end of the scope\n" "~~~\n" msgstr "" #. type: Plain text #: doc/tutorial-container.md:139 msgid "" "These semantics are due to most container iterators being implemented with " "`&` and `&mut`." msgstr "" #. type: Plain text #: doc/tutorial-container.md:141 msgid "## Iterator adaptors" msgstr "" #. type: Plain text #: doc/tutorial-container.md:145 msgid "" "The `IteratorUtil` trait implements common algorithms as methods extending " "every `Iterator` implementation. For example, the `fold` method will " "accumulate the items yielded by an `Iterator` into a single value:" msgstr "" #. type: Plain text #: doc/tutorial-container.md:151 msgid "" "~~~ let xs = [1, 9, 2, 3, 14, 12]; let result = xs.iter().fold(0, |" "accumulator, item| accumulator - *item); assert_eq!(result, -41); ~~~" msgstr "" #. type: Plain text #: doc/tutorial-container.md:153 msgid "" "Some adaptors return an adaptor object implementing the `Iterator` trait " "itself:" msgstr "" #. type: Plain text #: doc/tutorial-container.md:160 msgid "" "~~~ let xs = [1, 9, 2, 3, 14, 12]; let ys = [5, 2, 1, 8]; let sum = xs." "iter().chain_(ys.iter()).fold(0, |a, b| a + *b); assert_eq!(sum, 57); ~~~" msgstr "" #. type: Plain text #: doc/tutorial-container.md:164 msgid "" "Note that some adaptors like the `chain_` method above use a trailing " "underscore to work around an issue with method resolve. The underscores will " "be dropped when they become unnecessary." msgstr "" #. type: Plain text #: doc/tutorial-container.md:166 msgid "## For loops" msgstr "" #. type: Plain text #: doc/tutorial-container.md:168 msgid "" "The `for` keyword can be used as sugar for iterating through any iterator:" msgstr "" #. type: Plain text #: doc/tutorial-container.md:171 msgid "~~~ let xs = [2, 3, 5, 7, 11, 13, 17];" msgstr "" #. type: Plain text #: doc/tutorial-container.md:176 #, no-wrap msgid "" "// print out all the elements in the vector\n" "for x in xs.iter() {\n" " println(x.to_str())\n" "}\n" msgstr "" #. type: Plain text #: doc/tutorial-container.md:182 #, no-wrap msgid "" "// print out all but the first 3 elements in the vector\n" "for x in xs.iter().skip(3) {\n" " println(x.to_str())\n" "}\n" "~~~\n" msgstr "" #. type: Plain text #: doc/tutorial-container.md:185 msgid "" "For loops are *often* used with a temporary iterator object, as above. They " "can also advance the state of an iterator in a mutable location:" msgstr "" #. type: Plain text #: doc/tutorial-container.md:189 msgid "" "~~~ let xs = [1, 2, 3, 4, 5]; let ys = [\"foo\", \"bar\", \"baz\", \"foobar" "\"];" msgstr "" #. type: Plain text #: doc/tutorial-container.md:192 msgid "" "// create an iterator yielding tuples of elements from both vectors let mut " "it = xs.iter().zip(ys.iter());" msgstr "" #. type: Plain text #: doc/tutorial-container.md:196 #, no-wrap msgid "" "// print out the pairs of elements up to (&3, &\"baz\")\n" "for (x, y) in it {\n" " printfln!(\"%d %s\", *x, *y);\n" msgstr "" #. type: Plain text #: doc/tutorial-container.md:201 #, no-wrap msgid "" " if *x == 3 {\n" " break;\n" " }\n" "}\n" msgstr "" #. type: Plain text #: doc/tutorial-container.md:204 msgid "" "// yield and print the last pair from the iterator printfln!(\"last: %?\", " "it.next());" msgstr "" #. type: Plain text #: doc/tutorial-container.md:208 msgid "// the iterator is now fully consumed assert!(it.next().is_none()); ~~~" msgstr "" #. type: Plain text #: doc/tutorial-container.md:210 msgid "## Conversion" msgstr "" #. type: Plain text #: doc/tutorial-container.md:212 msgid "" "Iterators offer generic conversion to containers with the `collect` adaptor:" msgstr "" #. type: Plain text #: doc/tutorial-container.md:218 msgid "" "~~~ let xs = [0, 1, 1, 2, 3, 5, 8]; let ys = xs.rev_iter().skip(1)." "transform(|&x| x * 2).collect::<~[int]>(); assert_eq!(ys, ~[10, 6, 4, 2, 2, " "0]); ~~~" msgstr "" #. type: Plain text #: doc/tutorial-container.md:221 msgid "" "The method requires a type hint for the container type, if the surrounding " "code does not provide sufficient information." msgstr "" #. type: Plain text #: doc/tutorial-container.md:225 msgid "" "Containers can provide conversion from iterators through `collect` by " "implementing the `FromIterator` trait. For example, the implementation for " "vectors is as follows:" msgstr "" #. type: Plain text #: doc/tutorial-container.md:238 #, no-wrap msgid "" "~~~\n" "impl> FromIterator for ~[A] {\n" " pub fn from_iterator(iterator: &mut T) -> ~[A] {\n" " let (lower, _) = iterator.size_hint();\n" " let mut xs = with_capacity(lower);\n" " for x in iterator {\n" " xs.push(x);\n" " }\n" " xs\n" " }\n" "}\n" "~~~\n" msgstr "" #. type: Plain text #: doc/tutorial-container.md:240 msgid "### Size hints" msgstr "" #. type: Plain text #: doc/tutorial-container.md:243 msgid "" "The `Iterator` trait provides a `size_hint` default method, returning a " "lower bound and optionally on upper bound on the length of the iterator:" msgstr "" #. type: Plain text #: doc/tutorial-container.md:247 msgid "~~~ fn size_hint(&self) -> (uint, Option) { (0, None) } ~~~" msgstr "" #. type: Plain text #: doc/tutorial-container.md:251 msgid "" "The vector implementation of `FromIterator` from above uses the lower bound " "to pre-allocate enough space to hold the minimum number of elements the " "iterator will yield." msgstr "" #. type: Plain text #: doc/tutorial-container.md:254 msgid "" "The default implementation is always correct, but it should be overridden if " "the iterator can provide better information." msgstr "" #. type: Plain text #: doc/tutorial-container.md:256 msgid "" "The `ZeroStream` from earlier can provide an exact lower and upper bound:" msgstr "" #. type: Plain text #: doc/tutorial-container.md:267 #, no-wrap msgid "" "impl ZeroStream {\n" " fn new(n: uint) -> ZeroStream {\n" " ZeroStream { remaining: n }\n" " }\n" msgstr "" #. type: Plain text #: doc/tutorial-container.md:272 #, no-wrap msgid "" " fn size_hint(&self) -> (uint, Option) {\n" " (self.remaining, Some(self.remaining))\n" " }\n" "}\n" msgstr "" #. type: Plain text #: doc/tutorial-container.md:286 msgid "## Double-ended iterators" msgstr "" #. type: Plain text #: doc/tutorial-container.md:290 msgid "" "The `DoubleEndedIterator` trait represents an iterator able to yield " "elements from either end of a range. It inherits from the `Iterator` trait " "and extends it with the `next_back` function." msgstr "" #. type: Plain text #: doc/tutorial-container.md:293 msgid "" "A `DoubleEndedIterator` can be flipped with the `invert` adaptor, returning " "another `DoubleEndedIterator` with `next` and `next_back` exchanged." msgstr "" #. type: Plain text #: doc/tutorial-container.md:300 msgid "" "~~~ let xs = [1, 2, 3, 4, 5, 6]; let mut it = xs.iter(); printfln!(\"%?\", " "it.next()); // prints `Some(&1)` printfln!(\"%?\", it.next()); // prints " "`Some(&2)` printfln!(\"%?\", it.next_back()); // prints `Some(&6)`" msgstr "" #. type: Plain text #: doc/tutorial-container.md:306 #, no-wrap msgid "" "// prints `5`, `4` and `3`\n" "for &x in it.invert() {\n" " printfln!(\"%?\", x)\n" "}\n" "~~~\n" msgstr "" #. type: Plain text #: doc/tutorial-container.md:309 msgid "" "The `rev_iter` and `mut_rev_iter` methods on vectors just return an inverted " "version of the standard immutable and mutable vector iterators." msgstr "" #. type: Plain text #: doc/tutorial-container.md:312 msgid "" "The `chain_`, `transform`, `filter`, `filter_map` and `peek` adaptors are " "`DoubleEndedIterator` implementations if the underlying iterators are." msgstr "" #. type: Plain text #: doc/tutorial-container.md:317 msgid "" "~~~ let xs = [1, 2, 3, 4]; let ys = [5, 6, 7, 8]; let mut it = xs.iter()." "chain_(ys.iter()).transform(|&x| x * 2);" msgstr "" #. type: Plain text #: doc/tutorial-container.md:319 msgid "printfln!(\"%?\", it.next()); // prints `Some(2)`" msgstr "" #. type: Plain text #: doc/tutorial-container.md:325 #, no-wrap msgid "" "// prints `16`, `14`, `12`, `10`, `8`, `6`, `4`\n" "for x in it.invert() {\n" " printfln!(\"%?\", x);\n" "}\n" "~~~\n" msgstr "" #. type: Plain text #: doc/tutorial-container.md:327 msgid "## Random-access iterators" msgstr "" #. type: Plain text #: doc/tutorial-container.md:331 msgid "" "The `RandomAccessIterator` trait represents an iterator offering random " "access to the whole range. The `indexable` method retrieves the number of " "elements accessible with the `idx` method." msgstr "" #. type: Plain text #: doc/tutorial-container.md:334 msgid "" "The `chain_` adaptor is an implementation of `RandomAccessIterator` if the " "underlying iterators are." msgstr "" #. type: Plain text #: doc/tutorial-container.md:343 msgid "" "~~~ let xs = [1, 2, 3, 4, 5]; let ys = ~[7, 9, 11]; let mut it = xs.iter()." "chain_(ys.iter()); printfln!(\"%?\", it.idx(0)); // prints `Some(&1)` " "printfln!(\"%?\", it.idx(5)); // prints `Some(&7)` printfln!(\"%?\", it." "idx(7)); // prints `Some(&11)` printfln!(\"%?\", it.idx(8)); // prints `None`" msgstr "" #. type: Plain text #: doc/tutorial-container.md:348 msgid "" "// yield two elements from the beginning, and one from the end it.next(); it." "next(); it.next_back();" msgstr "" #. type: Plain text #: doc/tutorial-container.md:352 msgid "" "printfln!(\"%?\", it.idx(0)); // prints `Some(&3)` printfln!(\"%?\", it." "idx(4)); // prints `Some(&9)` printfln!(\"%?\", it.idx(6)); // prints `None` " "~~~" msgstr ""