core: allow messages in unimplemented!() macro
This makes `unimplemented!()` match `unreachable!()`, allowing a message and possible formatting to be provided to better explain what and/or why something is not implemented.
I've used this myself in hyper for a while, include the type and method name, to better help while prototyping new modules, like `unimplemented!("Conn::poll_complete")`, or `unimplemented!("Conn::poll; state={:?}", state)`.
speed up mem::swap
I would have thought that the mem::swap code didn't need an intermediate variable precisely because the pointers are guaranteed never to alias. And.. it doesn't! It seems that llvm will also auto-vectorize this case for large structs, but alas it doesn't seem to have all the aliasing info it needs and so will add redundant checks (and even not bother with autovectorizing for small types). Looks like a lot of performance could still be gained here, so this might be a good test case for future optimizer improvements.
Here are the current benchmarks for the simd version of mem::swap; the timings are in cycles (code below) measured with 10 iterations. The timings for sizes > 32 which are not a multiple of 8 tend to be ever so slightly faster in the old code, but not always. For large struct sizes (> 1024) the new code shows a marked improvement.
\* = latest commit
† = subtracted from other measurements
| arr_length | noop<sup>†</sup> | rust_stdlib | simd_u64x4\* | simd_u64x8
|------------------|------------|-------------------|-------------------|-------------------
8|80|90|90|90
16|72|177|177|177
24|32|76|76|76
32|68|188|112|188
40|32|80|60|80
48|32|84|56|84
56|32|108|72|108
64|32|108|72|76
72|80|350|220|230
80|80|350|220|230
88|80|420|270|270
96|80|420|270|270
104|80|500|320|320
112|80|490|320|320
120|72|528|342|342
128|48|360|234|234
136|72|987|387|387
144|80|1070|420|420
152|64|856|376|376
160|68|804|400|400
168|80|1060|520|520
176|80|1070|520|520
184|32|464|228|228
192|32|504|228|228
200|32|440|248|248
208|72|987|573|573
216|80|1464|220|220
224|48|852|450|450
232|72|1182|666|666
240|32|428|288|288
248|32|428|308|308
256|80|860|770|770
264|80|1130|820|820
272|80|1340|820|820
280|80|1220|870|870
288|72|1227|804|804
296|72|1356|849|849
Only emit one error for `use foo::self;`
Currently `use foo::self;` would emit both E0429 and E0432. This commit silence the latter one (assuming `foo` is a valid module).
Fixes#42559
Disentangle InferCtxt, MemCategorizationContext and ExprUseVisitor.
At some point in the past, `InferCtxt` started being used to replace an old "`Typer`" abstraction, which provided access to `TypeckTables` and had optionally type inference to account for.
That didn't play so nicely with the `'gcx`/`'tcx` split and I had to introduce `borrowck_fake_infer_ctxt`.
The situation wasn't great but it wasn't too painful inside `rustc` itself.
Recently I've found that method being used in clippy, which does need EUV (before we make it plausible to run lints on HAIR or MIR), and set out to separate inference from tables, for the sake of lint authors.
Also fixes#42435 to make it trivial to compute type layout or use EUV from lints.
The remaining uses of `TypeckTables` in `InferCtxt` are for closure kinds and signatures, used in trait selection and projection normalization. The solution there is likely to add them as bounds to `ParamEnv`.
r? @nikomatsakis
cc @mcarton @llogiq @Manishearth
Get LLVM to stop generating dead assembly in next_power_of_two
It turns out that LLVM can turn `@llvm.ctlz.i64(_, true)` into `@llvm.ctlz.i64(_, false)` ([`ctlz`](http://llvm.org/docs/LangRef.html#llvm-ctlz-intrinsic)) where valuable, but never does the opposite. That leads to some silly assembly getting generated in certain cases.
A contrived-but-clear example https://is.gd/VAIKuC:
```rust
fn foo(x:u64) -> u32 {
if x == 0 { return !0; }
x.leading_zeros()
}
```
Generates
```asm
testq %rdi, %rdi
je .LBB0_1
je .LBB0_3 ; <-- wha?
bsrq %rdi, %rax
xorq $63, %rax
retq
.LBB0_1:
movl $-1, %eax
retq
.LBB0_3:
movl $64, %eax ; <-- dead
retq
```
I noticed this in `next_power_of_two`, which without this PR generates the following:
```asm
cmpq $2, %rcx
jae .LBB1_2
movl $1, %eax
retq
.LBB1_2:
decq %rcx
je .LBB1_3
bsrq %rcx, %rcx
xorq $63, %rcx
jmp .LBB1_5
.LBB1_3:
movl $64, %ecx ; <-- dead
.LBB1_5:
movq $-1, %rax
shrq %cl, %rax
incq %rax
retq
```
And with this PR becomes
```asm
cmpq $2, %rcx
jae .LBB0_2
movl $1, %eax
retq
.LBB0_2:
decq %rcx
bsrq %rcx, %rcx
xorl $63, %ecx
movq $-1, %rax
shrq %cl, %rax
incq %rax
retq
```
Speed up expansion
This reduces duplication, thereby increasing expansion speed. Based on tests with rust-uinput, this produces a 29x performance win (440 seconds to 15 seconds). I want to land this first, since it's a minimal patch, but with more changes to the macro parsing I can get down to 12 seconds locally.
There is one FIXME added to the code that I'll keep for now since changing it will spread outward and increase the patch size, I think.
Fixes#37074.
r? @jseyfried
cc @oberien
Ignore variadic FFI test on AArch64
I've cross compiled Rust to `aarch64-linux-gnu`, and tried to run the compile-fail tests, but `variadic-ffi.rs` fails with the following error:
```
The ABI `"stdcall"` is not supported for the current target [E0570]
```
The test seems to be ignored on (32-bit) ARM, so I turned it off for AArch64 too.
Vec<T> is pronounced 'vec'
I've never heard it pronounced "vector". Is this an outdated recommendation?
(or have I been doing it wrong all this time)
r? @steveklabnik
Fix GDB pretty-printer for tuples and pointers
Names of children should not be the same, because GDB uses them to distinguish the children.
|Before|After|
|---|---|
|![tuples_before](https://cloud.githubusercontent.com/assets/1297574/26527639/5d6cf10e-43a0-11e7-9498-abfcddb08055.png)|![tuples_after](https://cloud.githubusercontent.com/assets/1297574/26527655/9699233a-43a0-11e7-83c6-f58f713b51a0.png)|
`main.rs`
```rust
enum Test {
Zero,
One(i32),
Two(i32, String),
Three(i32, String, Vec<String>),
}
fn main() {
let tuple = (1, 2, "Asdfgh");
let zero = Test::Zero;
let one = Test::One(10);
let two = Test::Two(42, "Qwerty".to_owned());
let three = Test::Three(9000,
"Zxcvbn".to_owned(),
vec!["lorem".to_owned(), "ipsum".to_owned(), "dolor".to_owned()]);
println!(""); // breakpoint here
}
```
`launch.json`
```json
{
"version": "0.2.0",
"configurations": [
{
"type": "gdb",
"request": "launch",
"gdbpath": "rust-gdb",
"name": "Launch Program",
"valuesFormatting": "prettyPrinters", //this requires plugin Native Debug >= 0.20.0
"target": "./target/debug/test_pretty_printers",
"cwd": "${workspaceRoot}"
}
]
}
```
Fix translation of external spans
Previously, I noticed that spans from external crates don't generate any output. This limitation is problematic if analysis is performed on one or more external crates, as is the case with [rust-semverver](https://github.com/ibabushkin/rust-semverver). This change should address this behaviour, with the potential drawback that a minor performance hit is to be expected, as spans from potentially large crates have to be translated now.
Some preparatory refactorings for hash-based DepNodes
This PR collects some changes that turn out to be necessary for implementing `DepNodes` based on stable hashes (see #42294). The commits are self-contained and mostly straightforward.
The most interesting change here is the introduction of `DefIndices` for things that are not part of the AST: Some pieces of crate metadata now have a `DefIndex` too.
cc @eddyb
r? @nikomatsakis
LLVM currently doesn't remove the "bypass if argument is zero" assembly inside branches where the value is known to be non-zero, pessimizing code that uses uN::leading_zeros
Document direct implementations on type aliases.
This improves #32077, but is not a complete fix.
For a type alias `type NewType = AliasedType`, it will include any `impl NewType` and `impl
Trait for NewType` blocks in the documentation for `NewType`.
A complete fix would include the implementations from the aliased type in the type alias' documentation, so that users have a complete picture of methods that are available on the alias. However, to do this properly would require a fix for #14072, as the alias may affect the type parameters of the type alias, making the documentation difficult to understand. (That is, for `type Result = std::result::Result<(), ()>` we would ideally show documentation for `impl Result<(), ()>`, rather than generic documentation for `impl<T, E> Result<T, E>`).
I think this improvement is worthwhile, as it exposes implementations which are not currently documented by rustdoc. The documentation for the implementations on the aliased type are still accessible by clicking through to the docs for that type. (Although perhaps it's now less obvious to the user that they should click-through to get there).
This improves #32077, but is not a complete fix. For a type alias `type
NewType = AliasedType`, it will include any `impl NewType` and `impl
Trait for NewType` blocks in the documentation for `NewType`.
A complete fix would include the implementations from the aliased type
in the type alias' documentation, so that users have a complete
picture of methods that are available on the alias. However, to do this
properly would require a fix for #14072, as the alias may affect the
type parameters of the type alias, making the documentation difficult to
understand. (That is, for `type Result = std::result::Result<(), ()>` we
would ideally show documentation for `impl Result<(), ()>`, rather than
generic documentation for `impl<T, E> Result<T, E>`).
I think this improvement is worthwhile, as it exposes implementations
which are not currently documented by rustdoc. The documentation for the
implementations on the aliased type are still accessible by clicking
through to the docs for that type. (Although perhaps it's now less
obvious to the user that they should click-through to get there).
bootstrap: improve 'build --help' by explaining what exactly the last example does
I recently found myself confused about what exactly gets built how often when I run which command; I think this would have helped me.
One thing I did not touch, but I feel could also be improved, is the wording just above: "For a quick build with a usable compile, you can pass". I am not a native speaker, but this sounds odd to me. Do you mean "For a quick build of a usable compiler" (but then it should say where the usable compiler is produced)? Or do you mean "For a quick build testing if the compiler is usable"? I can reword this, but I'd like to make sure I understand the intent of the message.
What about
```
For a quick build of a usable compiler, you can pass:
./x.py build --stage 1 src/libtest
This will first build everything once (like --stage 0 without further
arguments would), and then use the compiler built in stage 0 to build
src/libtest and its dependencies.
Once this is done, build/$ARCH/stage1 contains a usable compiler.
```
However, I am not sure this is actually true. In particular, why even bother building the libstd in stage 1? AFAIK that ends up in `build/*/stage1-std`, not in `build/*/stage1` (which is filled from `build/*/stage0-*`).
std: Avoid panics in rust_eh_personality
This commit removes a few calls to panic and/or assert in `rust_eh_personality`.
This function definitely can't itself panic (that'd probably segfault or do
something else weird) and I was also noticing that a `pub extern fn foo() {}`
cdylib was abnormally large. Turns out all that size was the panicking machinery
brought in by the personality function!
The change here is to return a `Result` internally so we can bubble up the fatal
error, eventually translating to the appropriate error code for the libunwind
ABI.
This commit removes a few calls to panic and/or assert in `rust_eh_personality`.
This function definitely can't itself panic (that'd probably segfault or do
something else weird) and I was also noticing that a `pub extern fn foo() {}`
cdylib was abnormally large. Turns out all that size was the panicking machinery
brought in by the personality function!
The change here is to return a `Result` internally so we can bubble up the fatal
error, eventually translating to the appropriate error code for the libunwind
ABI.
Change `llvm.neon.*` to `llvm.arm.neon.*` in the mapping for platform intrinsics
This avoids linker errors when using platform intrinsics on 32-bit ARM with
NEON.
Fixesrust-lang-nursery/simd#10.
I don't have an explanation why the old code might have worked when the `simd` crate was written, since the new LLVM intrinsic naming seems to have existed as early as 2012. Maybe LLVM accepted two naming schemes for a few years and dropped the `llvm.neon.*` version recently? I don't know.
Also, I don't know how to write a unit test for this.