* Fix `LimitReader`'s `Buffer::consume` impl to avoid limit underflow
* Make `MultiWriter` fail fast instead of always running through each
`Writer`. This may or may not be what we want, but it at least
doesn't throw any errors encountered in later `Writer`s into oblivion.
* Prevent `IterReader`'s `Reader::read` impl from returning EOF if given
an empty buffer.
[breaking-change]
Rename io::timer::sleep, Timer::sleep, Timer::oneshot,
Timer::periodic, to sleep_ms, oneshot_ms, periodic_ms. These functions
all take an integer and interpret it as milliseconds.
Replacement functions will be added that take Duration.
[breaking-change]
This required some contortions because importing both raw::Slice
and slice::Slice makes rustc crash.
Since `Slice` is in the prelude, this renaming is unlikely to
casue breakage.
[breaking-change]
ImmutableVector -> ImmutableSlice
ImmutableEqVector -> ImmutableEqSlice
ImmutableOrdVector -> ImmutableOrdSlice
MutableVector -> MutableSlice
MutableVectorAllocating -> MutableSliceAllocating
MutableCloneableVector -> MutableCloneableSlice
MutableOrdVector -> MutableOrdSlice
These are all in the prelude so most code will not break.
[breaking-change]
* The caller should be responsible for cleaning up file descriptors
* If a caller safely creates a file descriptor (via
native::io::file::open) the returned structure (FileDesc) will try to
clean up the file, failing in the process and writing error messages
to the screen.
* This should not happen as the caller has no public interface for
telling the FileDesc structure to NOT free the underlying fd.
* Alternatively, if another file is opened under the same fd held by
the FileDesc structure returned by native::io::file::open, it will
close the wrong file upon destruction.
This commit stabilizes the `std::sync::atomics` module, renaming it to
`std::sync::atomic` to match library precedent elsewhere, and tightening
up behavior around incorrect memory ordering annotations.
The vast majority of the module is now `stable`. However, the
`AtomicOption` type has been deprecated, since it is essentially unused
and is not truly a primitive atomic type. It will eventually be replaced
by a higher-level abstraction like MVars.
Due to deprecations, this is a:
[breaking-change]
This commit stabilizes the `std::sync::atomics` module, renaming it to
`std::sync::atomic` to match library precedent elsewhere, and tightening
up behavior around incorrect memory ordering annotations.
The vast majority of the module is now `stable`. However, the
`AtomicOption` type has been deprecated, since it is essentially unused
and is not truly a primitive atomic type. It will eventually be replaced
by a higher-level abstraction like MVars.
Due to deprecations, this is a:
[breaking-change]
This was motivated by a desire to remove allocation in the common
pattern of
let old = key.replace(None)
do_something();
key.replace(old);
This also switched the map representation from a Vec to a TreeMap. A Vec
may be reasonable if there's only a couple TLD keys, but a TreeMap
provides better behavior as the number of keys increases.
Like the Vec, this TreeMap implementation does not shrink the container
when a value is removed. Unlike Vec, this TreeMap implementation cannot
reuse an empty node for a different key. Therefore any key that has been
inserted into the TLD at least once will continue to take up space in
the Map until the task ends. The expectation is that the majority of
keys that are inserted into TLD will be expected to have a value for
most of the rest of the task's lifetime. If this assumption is wrong,
there are two reasonable ways to fix this that could be implemented in
the future:
1. Provide an API call to either remove a specific key from the TLD and
destruct its node (e.g. `remove()`), or instead to explicitly clean
up all currently-empty nodes in the map (e.g. `compact()`). This is
simple, but requires the user to explicitly call it.
2. Keep track of the number of empty nodes in the map and when the map
is mutated (via `replace()`), if the number of empty nodes passes
some threshold, compact it automatically. Alternatively, whenever a
new key is inserted that hasn't been used before, compact the map at
that point.
---
Benchmarks:
I ran 3 benchmarks. tld_replace_none just replaces the tld key with None
repeatedly. tld_replace_some replaces it with Some repeatedly. And
tld_replace_none_some simulates the common behavior of replacing with
None, then replacing with the previous value again (which was a Some).
Old implementation:
test tld_replace_none ... bench: 20 ns/iter (+/- 0)
test tld_replace_none_some ... bench: 77 ns/iter (+/- 4)
test tld_replace_some ... bench: 57 ns/iter (+/- 2)
New implementation:
test tld_replace_none ... bench: 11 ns/iter (+/- 0)
test tld_replace_none_some ... bench: 23 ns/iter (+/- 0)
test tld_replace_some ... bench: 12 ns/iter (+/- 0)
Errors can be printed with {}, printing with {:?} does not work very
well.
Not actually related to this PR, but it came up when running the tests
and now is as good a time to fix it as any.
I wanted to add an implementation of `Default` inside the bitflags macro, but `Default` isn't in the prelude, which means anyone who wants to use `bitflags!` needs to import it. This seems not nice, so I've just implemented for `FilePermission` instead.
In order to prevent users from having to manually implement Hash and Ord for
bitflags types, this commit derives these traits automatically.
This breaks code that has manually implemented any of these traits for types
created by the bitflags! macro. Change this code by removing implementations
of these traits.
[breaking-change]
This makes edge cases in which the `Iterator` trait was not in scope
and/or `Option` or its variants were not in scope work properly.
This breaks code that looks like:
struct MyStruct { ... }
impl MyStruct {
fn next(&mut self) -> Option<int> { ... }
}
for x in MyStruct { ... } { ... }
Change ad-hoc `next` methods like the above to implementations of the
`Iterator` trait. For example:
impl Iterator<int> for MyStruct {
fn next(&mut self) -> Option<int> { ... }
}
Closes#15392.
[breaking-change]
Implement for Vec, DList, RingBuf. Add MutableSeq to the prelude.
Since the collections traits are in the prelude most consumers of
these methods will continue to work without change.
[breaking-change]
- `width()` computes the displayed width of a string, ignoring the width of control characters.
- arguably we might do *something* else for control characters, but the question is, what?
- users who want to do something else can iterate over chars()
- `graphemes()` returns a `Graphemes` struct, which implements an iterator over the grapheme clusters of a &str.
- fully compliant with [UAX#29](http://www.unicode.org/reports/tr29/#Grapheme_Cluster_Boundaries)
- passes all [Unicode-supplied tests](http://www.unicode.org/reports/tr41/tr41-15.html#Tests29)
- added code to generate additionial categories in `unicode.py`
- `Cn` aka `Not_Assigned`
- categories necessary for grapheme cluster breaking
- tidied up the exports from libunicode
- all exports are exposed through a module rather than directly at crate root.
- std::prelude imports UnicodeChar and UnicodeStrSlice from std::char and std::str rather than directly from libunicode
closes#7043
- Graphemes and GraphemeIndices structs implement iterators over
grapheme clusters analogous to the Chars and CharOffsets for chars in
a string. Iterator and DoubleEndedIterator are available for both.
- tidied up the exports for libunicode. crate root exports are now moved
into more appropriate module locations:
- UnicodeStrSlice, Words, Graphemes, GraphemeIndices are in str module
- UnicodeChar exported from char instead of crate root
- canonical_combining_class is exported from str rather than crate root
Since libunicode's exports have changed, programs that previously relied
on the old export locations will need to change their `use` statements
to reflect the new ones. See above for more information on where the new
exports live.
closes#7043
[breaking-change]
Currently when a read-only file has unlink() invoked on it on windows, the call
will fail. On unix, however, the call will succeed. In order to have a more
consistent behavior across platforms, this error is recognized on windows and
the file is changed to read-write before removal is attempted.
