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rust/src/libsyntax/ext/format.rs

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Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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// Copyright 2012 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
use ast;
Modernized a few type names in rustc and syntax
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use codemap::{Span, respan};
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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use ext::base::*;
use ext::base;
use ext::build::AstBuilder;
use rsparse = parse;
use parse::token;
use std::fmt::parse;
use std::hashmap::{HashMap, HashSet};
use std::vec;
#[deriving(Eq)]
enum ArgumentType {
Known(@str),
Unsigned,
String,
}
struct Context {
ecx: @ExtCtxt,
Modernized a few type names in rustc and syntax
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fmtsp: Span,
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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// Parsed argument expressions and the types that we've found so far for
// them.
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args: ~[@ast::Expr],
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arg_types: ~[Option<ArgumentType>],
// Parsed named expressions and the types that we've found for them so far
Modernized a few more types in syntax::ast
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names: HashMap<@str, @ast::Expr>,
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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name_types: HashMap<@str, ArgumentType>,
// Collection of the compiled `rt::Piece` structures
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pieces: ~[@ast::Expr],
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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name_positions: HashMap<@str, uint>,
method_statics: ~[@ast::item],
// Updated as arguments are consumed or methods are entered
nest_level: uint,
next_arg: uint,
}
impl Context {
/// Parses the arguments from the given list of tokens, returning None if
syntax: Remove usage of fmt!
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/// there's a parse error so we can continue parsing other format! expressions.
Modernized a few type names in rustc and syntax
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fn parse_args(&mut self, sp: Span,
Reduce the amount of complexity in format! This renames the syntax-extension file to format from ifmt, and it also reduces the amount of complexity inside by defining all other macros in terms of format_args!
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tts: &[ast::token_tree]) -> (@ast::Expr, Option<@ast::Expr>) {
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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let p = rsparse::new_parser_from_tts(self.ecx.parse_sess(),
self.ecx.cfg(),
tts.to_owned());
Reduce the amount of complexity in format! This renames the syntax-extension file to format from ifmt, and it also reduces the amount of complexity inside by defining all other macros in terms of format_args!
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// Parse the leading function expression (maybe a block, maybe a path)
let extra = p.parse_expr();
if !p.eat(&token::COMMA) {
self.ecx.span_err(sp, "expected token: `,`");
return (extra, None);
}
Implement a wrapper macro around fprintf -- ifmtf
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Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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if *p.token == token::EOF {
Implement a wrapper macro around fprintf -- ifmtf
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self.ecx.span_err(sp, "requires at least a format string argument");
return (extra, None);
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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}
let fmtstr = p.parse_expr();
let mut named = false;
while *p.token != token::EOF {
if !p.eat(&token::COMMA) {
self.ecx.span_err(sp, "expected token: `,`");
Implement a wrapper macro around fprintf -- ifmtf
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return (extra, None);
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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}
Allow trailing commas in format! This is more consistent with other parts of the language and it also makes it easier to use in situations where format string is massive.
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if *p.token == token::EOF { break } // accept trailing commas
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if named || (token::is_ident(p.token) &&
p.look_ahead(1, |t| *t == token::EQ)) {
named = true;
let ident = match *p.token {
token::IDENT(i, _) => {
p.bump();
i
}
_ if named => {
self.ecx.span_err(*p.span,
"expected ident, positional arguments \
cannot follow named arguments");
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return (extra, None);
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}
_ => {
self.ecx.span_err(*p.span,
syntax: Remove usage of fmt!
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format!("expected ident for named \
argument, but found `{}`",
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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p.this_token_to_str()));
Implement a wrapper macro around fprintf -- ifmtf
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return (extra, None);
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}
};
let name = self.ecx.str_of(ident);
p.expect(&token::EQ);
let e = p.parse_expr();
match self.names.find(&name) {
None => {}
Some(prev) => {
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self.ecx.span_err(e.span, format!("duplicate argument \
named `{}`", name));
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self.ecx.parse_sess.span_diagnostic.span_note(
prev.span, "previously here");
loop
}
}
self.names.insert(name, e);
} else {
self.args.push(p.parse_expr());
self.arg_types.push(None);
}
}
Implement a wrapper macro around fprintf -- ifmtf
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return (extra, Some(fmtstr));
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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}
/// Verifies one piece of a parse string. All errors are not emitted as
/// fatal so we can continue giving errors about this and possibly other
/// format strings.
fn verify_piece(&mut self, p: &parse::Piece) {
match *p {
parse::String(*) => {}
parse::CurrentArgument => {
if self.nest_level == 0 {
self.ecx.span_err(self.fmtsp,
"`#` reference used with nothing to \
reference back to");
}
}
parse::Argument(ref arg) => {
Implement formatting arguments for strings and integers Closes #1651
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// width/precision first, if they have implicit positional
// parameters it makes more sense to consume them first.
self.verify_count(arg.format.width);
self.verify_count(arg.format.precision);
// argument second, if it's an implicit positional parameter
// it's written second, so it should come after width/precision.
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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let pos = match arg.position {
parse::ArgumentNext => {
let i = self.next_arg;
if self.check_positional_ok() {
self.next_arg += 1;
}
Left(i)
}
parse::ArgumentIs(i) => Left(i),
parse::ArgumentNamed(s) => Right(s.to_managed()),
};
// and finally the method being applied
match arg.method {
Remove the notion of an "unknown format" As mentioned in #9456, the format! syntax extension would previously consider an empty format as a 'Unknown' format which could then also get coerced into a different style of format on another argument. This is unusual behavior because `{}` is a very common format and if you have `{0} {0:?}` you wouldn't expect them both to be coereced to the `Poly` formatter. This commit removes this coercion, but still retains the requirement that each argument has exactly one format specified for it (an empty format now counts as well). Perhaps at a later date we can add support for multiple formats of one argument, but this puts us in at least a backwards-compatible situation if we decide to do that.
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None => {
let ty = Known(arg.format.ty.to_managed());
self.verify_arg_type(pos, ty);
}
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Some(ref method) => { self.verify_method(pos, *method); }
}
}
}
}
fn verify_pieces(&mut self, pieces: &[parse::Piece]) {
for piece in pieces.iter() {
self.verify_piece(piece);
}
}
fn verify_count(&mut self, c: parse::Count) {
match c {
parse::CountImplied | parse::CountIs(*) => {}
parse::CountIsParam(i) => {
self.verify_arg_type(Left(i), Unsigned);
}
parse::CountIsNextParam => {
if self.check_positional_ok() {
self.verify_arg_type(Left(self.next_arg), Unsigned);
self.next_arg += 1;
}
}
}
}
fn check_positional_ok(&mut self) -> bool {
if self.nest_level != 0 {
self.ecx.span_err(self.fmtsp, "cannot use implicit positional \
arguments nested inside methods");
false
} else {
true
}
}
fn verify_method(&mut self, pos: Either<uint, @str>, m: &parse::Method) {
self.nest_level += 1;
match *m {
parse::Plural(_, ref arms, ref default) => {
let mut seen_cases = HashSet::new();
self.verify_arg_type(pos, Unsigned);
for arm in arms.iter() {
if !seen_cases.insert(arm.selector) {
match arm.selector {
Left(name) => {
self.ecx.span_err(self.fmtsp,
syntax: Remove usage of fmt!
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format!("duplicate selector \
`{:?}`", name));
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}
Right(idx) => {
self.ecx.span_err(self.fmtsp,
syntax: Remove usage of fmt!
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format!("duplicate selector \
`={}`", idx));
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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}
}
}
self.verify_pieces(arm.result);
}
self.verify_pieces(*default);
}
parse::Select(ref arms, ref default) => {
self.verify_arg_type(pos, String);
let mut seen_cases = HashSet::new();
for arm in arms.iter() {
if !seen_cases.insert(arm.selector) {
self.ecx.span_err(self.fmtsp,
syntax: Remove usage of fmt!
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format!("duplicate selector `{}`",
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arm.selector));
} else if arm.selector == "" {
self.ecx.span_err(self.fmtsp,
"empty selector in `select`");
}
self.verify_pieces(arm.result);
}
self.verify_pieces(*default);
}
}
self.nest_level -= 1;
}
fn verify_arg_type(&mut self, arg: Either<uint, @str>, ty: ArgumentType) {
match arg {
Left(arg) => {
if arg < 0 || self.args.len() <= arg {
syntax: Remove usage of fmt!
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let msg = format!("invalid reference to argument `{}` (there \
are {} arguments)", arg, self.args.len());
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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self.ecx.span_err(self.fmtsp, msg);
return;
}
self.verify_same(self.args[arg].span, ty, self.arg_types[arg]);
Remove the notion of an "unknown format" As mentioned in #9456, the format! syntax extension would previously consider an empty format as a 'Unknown' format which could then also get coerced into a different style of format on another argument. This is unusual behavior because `{}` is a very common format and if you have `{0} {0:?}` you wouldn't expect them both to be coereced to the `Poly` formatter. This commit removes this coercion, but still retains the requirement that each argument has exactly one format specified for it (an empty format now counts as well). Perhaps at a later date we can add support for multiple formats of one argument, but this puts us in at least a backwards-compatible situation if we decide to do that.
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if self.arg_types[arg].is_none() {
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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self.arg_types[arg] = Some(ty);
}
}
Right(name) => {
let span = match self.names.find(&name) {
Some(e) => e.span,
None => {
syntax: Remove usage of fmt!
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let msg = format!("there is no argument named `{}`", name);
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self.ecx.span_err(self.fmtsp, msg);
return;
}
};
self.verify_same(span, ty,
self.name_types.find(&name).map(|&x| *x));
Remove the notion of an "unknown format" As mentioned in #9456, the format! syntax extension would previously consider an empty format as a 'Unknown' format which could then also get coerced into a different style of format on another argument. This is unusual behavior because `{}` is a very common format and if you have `{0} {0:?}` you wouldn't expect them both to be coereced to the `Poly` formatter. This commit removes this coercion, but still retains the requirement that each argument has exactly one format specified for it (an empty format now counts as well). Perhaps at a later date we can add support for multiple formats of one argument, but this puts us in at least a backwards-compatible situation if we decide to do that.
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if !self.name_types.contains_key(&name) {
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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self.name_types.insert(name, ty);
}
// Assign this named argument a slot in the arguments array if
// it hasn't already been assigned a slot.
if !self.name_positions.contains_key(&name) {
let slot = self.name_positions.len();
self.name_positions.insert(name, slot);
}
}
}
}
/// When we're keeping track of the types that are declared for certain
/// arguments, we assume that `None` means we haven't seen this argument
/// yet, `Some(None)` means that we've seen the argument, but no format was
/// specified, and `Some(Some(x))` means that the argument was declared to
/// have type `x`.
///
/// Obviously `Some(Some(x)) != Some(Some(y))`, but we consider it true
/// that: `Some(None) == Some(Some(x))`
Modernized a few type names in rustc and syntax
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fn verify_same(&self, sp: Span, ty: ArgumentType,
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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before: Option<ArgumentType>) {
let cur = match before {
Remove the notion of an "unknown format" As mentioned in #9456, the format! syntax extension would previously consider an empty format as a 'Unknown' format which could then also get coerced into a different style of format on another argument. This is unusual behavior because `{}` is a very common format and if you have `{0} {0:?}` you wouldn't expect them both to be coereced to the `Poly` formatter. This commit removes this coercion, but still retains the requirement that each argument has exactly one format specified for it (an empty format now counts as well). Perhaps at a later date we can add support for multiple formats of one argument, but this puts us in at least a backwards-compatible situation if we decide to do that.
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None => return,
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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Some(t) => t,
};
if ty == cur { return }
match (cur, ty) {
(Known(cur), Known(ty)) => {
self.ecx.span_err(sp,
syntax: Remove usage of fmt!
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format!("argument redeclared with type `{}` when \
it was previously `{}`", ty, cur));
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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}
(Known(cur), _) => {
self.ecx.span_err(sp,
syntax: Remove usage of fmt!
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format!("argument used to format with `{}` was \
attempted to not be used for formatting",
cur));
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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}
(_, Known(ty)) => {
self.ecx.span_err(sp,
syntax: Remove usage of fmt!
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format!("argument previously used as a format \
argument attempted to be used as `{}`",
ty));
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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}
(_, _) => {
self.ecx.span_err(sp, "argument declared with multiple formats");
}
}
}
/// Translate a `parse::Piece` to a static `rt::Piece`
Modernized a few more types in syntax::ast
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fn trans_piece(&mut self, piece: &parse::Piece) -> @ast::Expr {
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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let sp = self.fmtsp;
Correct the padding on integer types for formatting
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let parsepath = |s: &str| {
~[self.ecx.ident_of("std"), self.ecx.ident_of("fmt"),
self.ecx.ident_of("parse"), self.ecx.ident_of(s)]
};
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let rtpath = |s: &str| {
~[self.ecx.ident_of("std"), self.ecx.ident_of("fmt"),
self.ecx.ident_of("rt"), self.ecx.ident_of(s)]
};
let ctpath = |s: &str| {
~[self.ecx.ident_of("std"), self.ecx.ident_of("fmt"),
self.ecx.ident_of("parse"), self.ecx.ident_of(s)]
};
Implement a format_args!() macro The purpose of this macro is to further reduce the number of allocations which occur when dealing with formatting strings. This macro will perform all of the static analysis necessary to validate that a format string is safe, and then it will wrap up the "format string" into an opaque struct which can then be passed around. Two safe functions are added (write/format) which take this opaque argument structure, unwrap it, and then call the unsafe version of write/format (in an unsafe block). Other than these two functions, it is not intended for anyone to ever look inside this opaque struct. The macro looks a bit odd, but mostly because of rvalue lifetimes this is the only way for it to be safe that I know of. Example use-cases of this are: * third-party libraries can use the default formatting syntax without any forced allocations * the fail!() macro can avoid allocating the format string * the logging macros can avoid allocation any strings
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let none = self.ecx.path_global(sp, ~[
self.ecx.ident_of("std"),
self.ecx.ident_of("option"),
self.ecx.ident_of("None")]);
let none = self.ecx.expr_path(none);
Modernized a few more types in syntax::ast
2013-09-01 20:45:37 -05:00
let some = |e: @ast::Expr| {
Implement a format_args!() macro The purpose of this macro is to further reduce the number of allocations which occur when dealing with formatting strings. This macro will perform all of the static analysis necessary to validate that a format string is safe, and then it will wrap up the "format string" into an opaque struct which can then be passed around. Two safe functions are added (write/format) which take this opaque argument structure, unwrap it, and then call the unsafe version of write/format (in an unsafe block). Other than these two functions, it is not intended for anyone to ever look inside this opaque struct. The macro looks a bit odd, but mostly because of rvalue lifetimes this is the only way for it to be safe that I know of. Example use-cases of this are: * third-party libraries can use the default formatting syntax without any forced allocations * the fail!() macro can avoid allocating the format string * the logging macros can avoid allocation any strings
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let p = self.ecx.path_global(sp, ~[
self.ecx.ident_of("std"),
self.ecx.ident_of("option"),
self.ecx.ident_of("Some")]);
let p = self.ecx.expr_path(p);
self.ecx.expr_call(sp, p, ~[e])
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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};
let trans_count = |c: parse::Count| {
match c {
parse::CountIs(i) => {
self.ecx.expr_call_global(sp, ctpath("CountIs"),
~[self.ecx.expr_uint(sp, i)])
}
parse::CountIsParam(i) => {
self.ecx.expr_call_global(sp, ctpath("CountIsParam"),
~[self.ecx.expr_uint(sp, i)])
}
parse::CountImplied => {
let path = self.ecx.path_global(sp, ctpath("CountImplied"));
self.ecx.expr_path(path)
}
parse::CountIsNextParam => {
let path = self.ecx.path_global(sp, ctpath("CountIsNextParam"));
self.ecx.expr_path(path)
}
}
};
let trans_method = |method: &parse::Method| {
let method = match *method {
parse::Select(ref arms, ref default) => {
std: Rename Iterator.transform -> .map cc #5898
2013-08-09 22:09:47 -05:00
let arms = arms.iter().map(|arm| {
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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let p = self.ecx.path_global(sp, rtpath("SelectArm"));
std: Rename Iterator.transform -> .map cc #5898
2013-08-09 22:09:47 -05:00
let result = arm.result.iter().map(|p| {
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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self.trans_piece(p)
}).collect();
let s = arm.selector.to_managed();
let selector = self.ecx.expr_str(sp, s);
self.ecx.expr_struct(sp, p, ~[
self.ecx.field_imm(sp,
self.ecx.ident_of("selector"),
selector),
self.ecx.field_imm(sp, self.ecx.ident_of("result"),
self.ecx.expr_vec_slice(sp, result)),
])
}).collect();
std: Rename Iterator.transform -> .map cc #5898
2013-08-09 22:09:47 -05:00
let default = default.iter().map(|p| {
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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self.trans_piece(p)
}).collect();
self.ecx.expr_call_global(sp, rtpath("Select"), ~[
self.ecx.expr_vec_slice(sp, arms),
self.ecx.expr_vec_slice(sp, default),
])
}
parse::Plural(offset, ref arms, ref default) => {
let offset = match offset {
Some(i) => { some(self.ecx.expr_uint(sp, i)) }
Implement a format_args!() macro The purpose of this macro is to further reduce the number of allocations which occur when dealing with formatting strings. This macro will perform all of the static analysis necessary to validate that a format string is safe, and then it will wrap up the "format string" into an opaque struct which can then be passed around. Two safe functions are added (write/format) which take this opaque argument structure, unwrap it, and then call the unsafe version of write/format (in an unsafe block). Other than these two functions, it is not intended for anyone to ever look inside this opaque struct. The macro looks a bit odd, but mostly because of rvalue lifetimes this is the only way for it to be safe that I know of. Example use-cases of this are: * third-party libraries can use the default formatting syntax without any forced allocations * the fail!() macro can avoid allocating the format string * the logging macros can avoid allocation any strings
2013-08-28 04:22:45 -05:00
None => { none.clone() }
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
};
std: Rename Iterator.transform -> .map cc #5898
2013-08-09 22:09:47 -05:00
let arms = arms.iter().map(|arm| {
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
let p = self.ecx.path_global(sp, rtpath("PluralArm"));
std: Rename Iterator.transform -> .map cc #5898
2013-08-09 22:09:47 -05:00
let result = arm.result.iter().map(|p| {
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
self.trans_piece(p)
}).collect();
let (lr, selarg) = match arm.selector {
Left(t) => {
syntax: Remove usage of fmt!
2013-09-27 23:01:58 -05:00
let p = ctpath(format!("{:?}", t));
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
let p = self.ecx.path_global(sp, p);
(self.ecx.ident_of("Left"),
self.ecx.expr_path(p))
}
Right(i) => {
(self.ecx.ident_of("Right"),
self.ecx.expr_uint(sp, i))
}
};
let selector = self.ecx.expr_call_ident(sp,
lr, ~[selarg]);
self.ecx.expr_struct(sp, p, ~[
self.ecx.field_imm(sp,
self.ecx.ident_of("selector"),
selector),
self.ecx.field_imm(sp, self.ecx.ident_of("result"),
self.ecx.expr_vec_slice(sp, result)),
])
}).collect();
std: Rename Iterator.transform -> .map cc #5898
2013-08-09 22:09:47 -05:00
let default = default.iter().map(|p| {
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
self.trans_piece(p)
}).collect();
self.ecx.expr_call_global(sp, rtpath("Plural"), ~[
offset,
self.ecx.expr_vec_slice(sp, arms),
self.ecx.expr_vec_slice(sp, default),
])
}
};
let life = self.ecx.lifetime(sp, self.ecx.ident_of("static"));
let ty = self.ecx.ty_path(self.ecx.path_all(
sp,
true,
rtpath("Method"),
Some(life),
~[]
), None);
Modernized a few more types in syntax::ast
2013-09-01 20:45:37 -05:00
let st = ast::item_static(ty, ast::MutImmutable, method);
syntax: Remove usage of fmt!
2013-09-27 23:01:58 -05:00
let static_name = self.ecx.ident_of(format!("__static_method_{}",
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
self.method_statics.len()));
Implement an `address_insignificant` attribute This can be applied to statics and it will indicate that LLVM will attempt to merge the constant in .data with other statics. I have preliminarily applied this to all of the statics generated by the new `ifmt!` syntax extension. I compiled a file with 1000 calls to `ifmt!` and a separate file with 1000 calls to `fmt!` to compare the sizes, and the results were: fmt 310k ifmt (before) 529k ifmt (after) 202k This now means that ifmt! is both faster and smaller than fmt!, yay!
2013-08-09 15:47:00 -05:00
// Flag these statics as `address_insignificant` so LLVM can
// merge duplicate globals as much as possible (which we're
// generating a whole lot of).
let unnamed = self.ecx.meta_word(self.fmtsp, @"address_insignificant");
let unnamed = self.ecx.attribute(self.fmtsp, unnamed);
let item = self.ecx.item(sp, static_name, ~[unnamed], st);
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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self.method_statics.push(item);
self.ecx.expr_ident(sp, static_name)
};
match *piece {
parse::String(s) => {
self.ecx.expr_call_global(sp, rtpath("String"),
~[self.ecx.expr_str(sp, s.to_managed())])
}
parse::CurrentArgument => {
let nil = self.ecx.expr_lit(sp, ast::lit_nil);
self.ecx.expr_call_global(sp, rtpath("CurrentArgument"), ~[nil])
}
parse::Argument(ref arg) => {
// Translate the position
let pos = match arg.position {
// These two have a direct mapping
parse::ArgumentNext => {
let path = self.ecx.path_global(sp,
rtpath("ArgumentNext"));
self.ecx.expr_path(path)
}
parse::ArgumentIs(i) => {
self.ecx.expr_call_global(sp, rtpath("ArgumentIs"),
~[self.ecx.expr_uint(sp, i)])
}
// Named arguments are converted to positional arguments at
// the end of the list of arguments
parse::ArgumentNamed(n) => {
let n = n.to_managed();
let i = match self.name_positions.find_copy(&n) {
Some(i) => i,
None => 0, // error already emitted elsewhere
};
let i = i + self.args.len();
self.ecx.expr_call_global(sp, rtpath("ArgumentIs"),
~[self.ecx.expr_uint(sp, i)])
}
};
// Translate the format
let fill = match arg.format.fill { Some(c) => c, None => ' ' };
stop treating char as an integer type Closes #7609
2013-09-03 18:24:12 -05:00
let fill = self.ecx.expr_lit(sp, ast::lit_char(fill as u32));
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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let align = match arg.format.align {
Correct the padding on integer types for formatting
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parse::AlignLeft => {
self.ecx.path_global(sp, parsepath("AlignLeft"))
}
parse::AlignRight => {
self.ecx.path_global(sp, parsepath("AlignRight"))
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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}
Correct the padding on integer types for formatting
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parse::AlignUnknown => {
self.ecx.path_global(sp, parsepath("AlignUnknown"))
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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}
};
Correct the padding on integer types for formatting
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let align = self.ecx.expr_path(align);
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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let flags = self.ecx.expr_uint(sp, arg.format.flags);
let prec = trans_count(arg.format.precision);
let width = trans_count(arg.format.width);
let path = self.ecx.path_global(sp, rtpath("FormatSpec"));
let fmt = self.ecx.expr_struct(sp, path, ~[
self.ecx.field_imm(sp, self.ecx.ident_of("fill"), fill),
Correct the padding on integer types for formatting
2013-08-10 18:50:42 -05:00
self.ecx.field_imm(sp, self.ecx.ident_of("align"), align),
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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self.ecx.field_imm(sp, self.ecx.ident_of("flags"), flags),
self.ecx.field_imm(sp, self.ecx.ident_of("precision"), prec),
self.ecx.field_imm(sp, self.ecx.ident_of("width"), width),
]);
// Translate the method (if any)
let method = match arg.method {
Implement a format_args!() macro The purpose of this macro is to further reduce the number of allocations which occur when dealing with formatting strings. This macro will perform all of the static analysis necessary to validate that a format string is safe, and then it will wrap up the "format string" into an opaque struct which can then be passed around. Two safe functions are added (write/format) which take this opaque argument structure, unwrap it, and then call the unsafe version of write/format (in an unsafe block). Other than these two functions, it is not intended for anyone to ever look inside this opaque struct. The macro looks a bit odd, but mostly because of rvalue lifetimes this is the only way for it to be safe that I know of. Example use-cases of this are: * third-party libraries can use the default formatting syntax without any forced allocations * the fail!() macro can avoid allocating the format string * the logging macros can avoid allocation any strings
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None => { none.clone() }
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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Some(ref m) => {
let m = trans_method(*m);
some(self.ecx.expr_addr_of(sp, m))
}
};
let path = self.ecx.path_global(sp, rtpath("Argument"));
let s = self.ecx.expr_struct(sp, path, ~[
self.ecx.field_imm(sp, self.ecx.ident_of("position"), pos),
self.ecx.field_imm(sp, self.ecx.ident_of("format"), fmt),
self.ecx.field_imm(sp, self.ecx.ident_of("method"), method),
]);
self.ecx.expr_call_global(sp, rtpath("Argument"), ~[s])
}
}
}
syntax: Remove usage of fmt!
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/// Actually builds the expression which the iformat! block will be expanded
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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/// to
Reduce the amount of complexity in format! This renames the syntax-extension file to format from ifmt, and it also reduces the amount of complexity inside by defining all other macros in terms of format_args!
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fn to_expr(&self, extra: @ast::Expr) -> @ast::Expr {
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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let mut lets = ~[];
let mut locals = ~[];
let mut names = vec::from_fn(self.name_positions.len(), |_| None);
// First, declare all of our methods that are statics
for &method in self.method_statics.iter() {
Modernized a few more types in syntax::ast
2013-09-01 20:45:37 -05:00
let decl = respan(self.fmtsp, ast::DeclItem(method));
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
lets.push(@respan(self.fmtsp,
Delay assignment of node ids until after expansion. Ensures that each AST node has a unique id. Fixes numerous bugs in macro expansion and deriving. Add two representative tests. Fixes #7971 Fixes #6304 Fixes #8367 Fixes #8754 Fixes #8852 Fixes #2543 Fixes #7654
2013-09-06 21:11:55 -05:00
ast::StmtDecl(@decl, ast::DUMMY_NODE_ID)));
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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}
// Next, build up the static array which will become our precompiled
// format "string"
let fmt = self.ecx.expr_vec(self.fmtsp, self.pieces.clone());
Implement a format_args!() macro The purpose of this macro is to further reduce the number of allocations which occur when dealing with formatting strings. This macro will perform all of the static analysis necessary to validate that a format string is safe, and then it will wrap up the "format string" into an opaque struct which can then be passed around. Two safe functions are added (write/format) which take this opaque argument structure, unwrap it, and then call the unsafe version of write/format (in an unsafe block). Other than these two functions, it is not intended for anyone to ever look inside this opaque struct. The macro looks a bit odd, but mostly because of rvalue lifetimes this is the only way for it to be safe that I know of. Example use-cases of this are: * third-party libraries can use the default formatting syntax without any forced allocations * the fail!() macro can avoid allocating the format string * the logging macros can avoid allocation any strings
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let piece_ty = self.ecx.ty_path(self.ecx.path_all(
self.fmtsp,
true, ~[
self.ecx.ident_of("std"),
self.ecx.ident_of("fmt"),
self.ecx.ident_of("rt"),
self.ecx.ident_of("Piece"),
],
Some(self.ecx.lifetime(self.fmtsp, self.ecx.ident_of("static"))),
~[]
), None);
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
let ty = ast::ty_fixed_length_vec(
Implement a format_args!() macro The purpose of this macro is to further reduce the number of allocations which occur when dealing with formatting strings. This macro will perform all of the static analysis necessary to validate that a format string is safe, and then it will wrap up the "format string" into an opaque struct which can then be passed around. Two safe functions are added (write/format) which take this opaque argument structure, unwrap it, and then call the unsafe version of write/format (in an unsafe block). Other than these two functions, it is not intended for anyone to ever look inside this opaque struct. The macro looks a bit odd, but mostly because of rvalue lifetimes this is the only way for it to be safe that I know of. Example use-cases of this are: * third-party libraries can use the default formatting syntax without any forced allocations * the fail!() macro can avoid allocating the format string * the logging macros can avoid allocation any strings
2013-08-28 04:22:45 -05:00
self.ecx.ty_mt(piece_ty.clone(), ast::MutImmutable),
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
self.ecx.expr_uint(self.fmtsp, self.pieces.len())
);
let ty = self.ecx.ty(self.fmtsp, ty);
Modernized a few more types in syntax::ast
2013-09-01 20:45:37 -05:00
let st = ast::item_static(ty, ast::MutImmutable, fmt);
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
let static_name = self.ecx.ident_of("__static_fmtstr");
Implement an `address_insignificant` attribute This can be applied to statics and it will indicate that LLVM will attempt to merge the constant in .data with other statics. I have preliminarily applied this to all of the statics generated by the new `ifmt!` syntax extension. I compiled a file with 1000 calls to `ifmt!` and a separate file with 1000 calls to `fmt!` to compare the sizes, and the results were: fmt 310k ifmt (before) 529k ifmt (after) 202k This now means that ifmt! is both faster and smaller than fmt!, yay!
2013-08-09 15:47:00 -05:00
// see above comment for `address_insignificant` and why we do it
let unnamed = self.ecx.meta_word(self.fmtsp, @"address_insignificant");
let unnamed = self.ecx.attribute(self.fmtsp, unnamed);
let item = self.ecx.item(self.fmtsp, static_name, ~[unnamed], st);
Modernized a few more types in syntax::ast
2013-09-01 20:45:37 -05:00
let decl = respan(self.fmtsp, ast::DeclItem(item));
Delay assignment of node ids until after expansion. Ensures that each AST node has a unique id. Fixes numerous bugs in macro expansion and deriving. Add two representative tests. Fixes #7971 Fixes #6304 Fixes #8367 Fixes #8754 Fixes #8852 Fixes #2543 Fixes #7654
2013-09-06 21:11:55 -05:00
lets.push(@respan(self.fmtsp, ast::StmtDecl(@decl, ast::DUMMY_NODE_ID)));
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
// Right now there is a bug such that for the expression:
// foo(bar(&1))
// the lifetime of `1` doesn't outlast the call to `bar`, so it's not
// vald for the call to `foo`. To work around this all arguments to the
syntax: Remove usage of fmt!
2013-09-27 23:01:58 -05:00
// format! string are shoved into locals. Furthermore, we shove the address
Don't have format! move out of local variables
2013-09-03 01:53:13 -05:00
// of each variable because we don't want to move out of the arguments
// passed to this function.
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
for (i, &e) in self.args.iter().enumerate() {
if self.arg_types[i].is_none() { loop } // error already generated
syntax: Remove usage of fmt!
2013-09-27 23:01:58 -05:00
let name = self.ecx.ident_of(format!("__arg{}", i));
Don't have format! move out of local variables
2013-09-03 01:53:13 -05:00
let e = self.ecx.expr_addr_of(e.span, e);
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
lets.push(self.ecx.stmt_let(e.span, false, name, e));
Implement a format_args!() macro The purpose of this macro is to further reduce the number of allocations which occur when dealing with formatting strings. This macro will perform all of the static analysis necessary to validate that a format string is safe, and then it will wrap up the "format string" into an opaque struct which can then be passed around. Two safe functions are added (write/format) which take this opaque argument structure, unwrap it, and then call the unsafe version of write/format (in an unsafe block). Other than these two functions, it is not intended for anyone to ever look inside this opaque struct. The macro looks a bit odd, but mostly because of rvalue lifetimes this is the only way for it to be safe that I know of. Example use-cases of this are: * third-party libraries can use the default formatting syntax without any forced allocations * the fail!() macro can avoid allocating the format string * the logging macros can avoid allocation any strings
2013-08-28 04:22:45 -05:00
locals.push(self.format_arg(e.span, Left(i),
self.ecx.expr_ident(e.span, name)));
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
}
for (&name, &e) in self.names.iter() {
if !self.name_types.contains_key(&name) { loop }
syntax: Remove usage of fmt!
2013-09-27 23:01:58 -05:00
let lname = self.ecx.ident_of(format!("__arg{}", name));
Don't have format! move out of local variables
2013-09-03 01:53:13 -05:00
let e = self.ecx.expr_addr_of(e.span, e);
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
lets.push(self.ecx.stmt_let(e.span, false, lname, e));
names[*self.name_positions.get(&name)] =
Implement a format_args!() macro The purpose of this macro is to further reduce the number of allocations which occur when dealing with formatting strings. This macro will perform all of the static analysis necessary to validate that a format string is safe, and then it will wrap up the "format string" into an opaque struct which can then be passed around. Two safe functions are added (write/format) which take this opaque argument structure, unwrap it, and then call the unsafe version of write/format (in an unsafe block). Other than these two functions, it is not intended for anyone to ever look inside this opaque struct. The macro looks a bit odd, but mostly because of rvalue lifetimes this is the only way for it to be safe that I know of. Example use-cases of this are: * third-party libraries can use the default formatting syntax without any forced allocations * the fail!() macro can avoid allocating the format string * the logging macros can avoid allocation any strings
2013-08-28 04:22:45 -05:00
Some(self.format_arg(e.span, Right(name),
self.ecx.expr_ident(e.span, lname)));
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
}
Reduce the amount of complexity in format! This renames the syntax-extension file to format from ifmt, and it also reduces the amount of complexity inside by defining all other macros in terms of format_args!
2013-09-12 21:36:58 -05:00
// Now create the fmt::Arguments struct with all our locals we created.
std: Rename Iterator.transform -> .map cc #5898
2013-08-09 22:09:47 -05:00
let args = names.move_iter().map(|a| a.unwrap());
std: Iterator.chain_ -> .chain
2013-08-09 22:22:59 -05:00
let mut args = locals.move_iter().chain(args);
Reduce the amount of complexity in format! This renames the syntax-extension file to format from ifmt, and it also reduces the amount of complexity inside by defining all other macros in terms of format_args!
2013-09-12 21:36:58 -05:00
let fmt = self.ecx.expr_ident(self.fmtsp, static_name);
let args = self.ecx.expr_vec_slice(self.fmtsp, args.collect());
let result = self.ecx.expr_call_global(self.fmtsp, ~[
self.ecx.ident_of("std"),
self.ecx.ident_of("fmt"),
self.ecx.ident_of("Arguments"),
self.ecx.ident_of("new"),
], ~[fmt, args]);
// We did all the work of making sure that the arguments
// structure is safe, so we can safely have an unsafe block.
let result = self.ecx.expr_block(ast::Block {
view_items: ~[],
stmts: ~[],
expr: Some(result),
id: ast::DUMMY_NODE_ID,
rules: ast::UnsafeBlock(ast::CompilerGenerated),
span: self.fmtsp,
});
let resname = self.ecx.ident_of("__args");
lets.push(self.ecx.stmt_let(self.fmtsp, false, resname, result));
let res = self.ecx.expr_ident(self.fmtsp, resname);
let result = self.ecx.expr_call(extra.span, extra, ~[
self.ecx.expr_addr_of(extra.span, res)]);
Implement a format_args!() macro The purpose of this macro is to further reduce the number of allocations which occur when dealing with formatting strings. This macro will perform all of the static analysis necessary to validate that a format string is safe, and then it will wrap up the "format string" into an opaque struct which can then be passed around. Two safe functions are added (write/format) which take this opaque argument structure, unwrap it, and then call the unsafe version of write/format (in an unsafe block). Other than these two functions, it is not intended for anyone to ever look inside this opaque struct. The macro looks a bit odd, but mostly because of rvalue lifetimes this is the only way for it to be safe that I know of. Example use-cases of this are: * third-party libraries can use the default formatting syntax without any forced allocations * the fail!() macro can avoid allocating the format string * the logging macros can avoid allocation any strings
2013-08-28 04:22:45 -05:00
self.ecx.expr_block(self.ecx.block(self.fmtsp, lets,
Some(result)))
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
}
Implement a format_args!() macro The purpose of this macro is to further reduce the number of allocations which occur when dealing with formatting strings. This macro will perform all of the static analysis necessary to validate that a format string is safe, and then it will wrap up the "format string" into an opaque struct which can then be passed around. Two safe functions are added (write/format) which take this opaque argument structure, unwrap it, and then call the unsafe version of write/format (in an unsafe block). Other than these two functions, it is not intended for anyone to ever look inside this opaque struct. The macro looks a bit odd, but mostly because of rvalue lifetimes this is the only way for it to be safe that I know of. Example use-cases of this are: * third-party libraries can use the default formatting syntax without any forced allocations * the fail!() macro can avoid allocating the format string * the logging macros can avoid allocation any strings
2013-08-28 04:22:45 -05:00
fn format_arg(&self, sp: Span, argno: Either<uint, @str>,
arg: @ast::Expr) -> @ast::Expr {
let ty = match argno {
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
Left(i) => self.arg_types[i].unwrap(),
Right(s) => *self.name_types.get(&s)
};
Implement an `address_insignificant` attribute This can be applied to statics and it will indicate that LLVM will attempt to merge the constant in .data with other statics. I have preliminarily applied this to all of the statics generated by the new `ifmt!` syntax extension. I compiled a file with 1000 calls to `ifmt!` and a separate file with 1000 calls to `fmt!` to compare the sizes, and the results were: fmt 310k ifmt (before) 529k ifmt (after) 202k This now means that ifmt! is both faster and smaller than fmt!, yay!
2013-08-09 15:47:00 -05:00
Delegate `{}` to Default instead of Poly By using a separate trait this is overridable on a per-type basis and makes room for the possibility of even more arguments passed in for the future.
2013-08-14 22:40:15 -05:00
let fmt_trait = match ty {
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
Known(tyname) => {
Delegate `{}` to Default instead of Poly By using a separate trait this is overridable on a per-type basis and makes room for the possibility of even more arguments passed in for the future.
2013-08-14 22:40:15 -05:00
match tyname.as_slice() {
Remove the notion of an "unknown format" As mentioned in #9456, the format! syntax extension would previously consider an empty format as a 'Unknown' format which could then also get coerced into a different style of format on another argument. This is unusual behavior because `{}` is a very common format and if you have `{0} {0:?}` you wouldn't expect them both to be coereced to the `Poly` formatter. This commit removes this coercion, but still retains the requirement that each argument has exactly one format specified for it (an empty format now counts as well). Perhaps at a later date we can add support for multiple formats of one argument, but this puts us in at least a backwards-compatible situation if we decide to do that.
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"" => "Default",
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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"?" => "Poly",
"b" => "Bool",
"c" => "Char",
Add `f` formats to `ifmt!` Currently the work just the same as the old `extfmt` versions
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"d" | "i" => "Signed",
"f" => "Float",
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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"o" => "Octal",
"p" => "Pointer",
Add `f` formats to `ifmt!` Currently the work just the same as the old `extfmt` versions
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"s" => "String",
Define integer formats for all widths Closes #1653
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"t" => "Binary",
Add `f` formats to `ifmt!` Currently the work just the same as the old `extfmt` versions
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"u" => "Unsigned",
"x" => "LowerHex",
"X" => "UpperHex",
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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_ => {
syntax: Remove usage of fmt!
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self.ecx.span_err(sp, format!("unknown format trait \
`{}`", tyname));
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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"Dummy"
}
Delegate `{}` to Default instead of Poly By using a separate trait this is overridable on a per-type basis and makes room for the possibility of even more arguments passed in for the future.
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}
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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}
String => {
Delegate `{}` to Default instead of Poly By using a separate trait this is overridable on a per-type basis and makes room for the possibility of even more arguments passed in for the future.
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return self.ecx.expr_call_global(sp, ~[
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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self.ecx.ident_of("std"),
self.ecx.ident_of("fmt"),
self.ecx.ident_of("argumentstr"),
Implement a format_args!() macro The purpose of this macro is to further reduce the number of allocations which occur when dealing with formatting strings. This macro will perform all of the static analysis necessary to validate that a format string is safe, and then it will wrap up the "format string" into an opaque struct which can then be passed around. Two safe functions are added (write/format) which take this opaque argument structure, unwrap it, and then call the unsafe version of write/format (in an unsafe block). Other than these two functions, it is not intended for anyone to ever look inside this opaque struct. The macro looks a bit odd, but mostly because of rvalue lifetimes this is the only way for it to be safe that I know of. Example use-cases of this are: * third-party libraries can use the default formatting syntax without any forced allocations * the fail!() macro can avoid allocating the format string * the logging macros can avoid allocation any strings
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], ~[arg])
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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}
Unsigned => {
Delegate `{}` to Default instead of Poly By using a separate trait this is overridable on a per-type basis and makes room for the possibility of even more arguments passed in for the future.
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return self.ecx.expr_call_global(sp, ~[
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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self.ecx.ident_of("std"),
self.ecx.ident_of("fmt"),
self.ecx.ident_of("argumentuint"),
Implement a format_args!() macro The purpose of this macro is to further reduce the number of allocations which occur when dealing with formatting strings. This macro will perform all of the static analysis necessary to validate that a format string is safe, and then it will wrap up the "format string" into an opaque struct which can then be passed around. Two safe functions are added (write/format) which take this opaque argument structure, unwrap it, and then call the unsafe version of write/format (in an unsafe block). Other than these two functions, it is not intended for anyone to ever look inside this opaque struct. The macro looks a bit odd, but mostly because of rvalue lifetimes this is the only way for it to be safe that I know of. Example use-cases of this are: * third-party libraries can use the default formatting syntax without any forced allocations * the fail!() macro can avoid allocating the format string * the logging macros can avoid allocation any strings
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], ~[arg])
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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}
Delegate `{}` to Default instead of Poly By using a separate trait this is overridable on a per-type basis and makes room for the possibility of even more arguments passed in for the future.
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};
let format_fn = self.ecx.path_global(sp, ~[
self.ecx.ident_of("std"),
self.ecx.ident_of("fmt"),
self.ecx.ident_of(fmt_trait),
self.ecx.ident_of("fmt"),
]);
self.ecx.expr_call_global(sp, ~[
self.ecx.ident_of("std"),
self.ecx.ident_of("fmt"),
self.ecx.ident_of("argument"),
Implement a format_args!() macro The purpose of this macro is to further reduce the number of allocations which occur when dealing with formatting strings. This macro will perform all of the static analysis necessary to validate that a format string is safe, and then it will wrap up the "format string" into an opaque struct which can then be passed around. Two safe functions are added (write/format) which take this opaque argument structure, unwrap it, and then call the unsafe version of write/format (in an unsafe block). Other than these two functions, it is not intended for anyone to ever look inside this opaque struct. The macro looks a bit odd, but mostly because of rvalue lifetimes this is the only way for it to be safe that I know of. Example use-cases of this are: * third-party libraries can use the default formatting syntax without any forced allocations * the fail!() macro can avoid allocating the format string * the logging macros can avoid allocation any strings
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], ~[self.ecx.expr_path(format_fn), arg])
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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}
}
Reduce the amount of complexity in format! This renames the syntax-extension file to format from ifmt, and it also reduces the amount of complexity inside by defining all other macros in terms of format_args!
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pub fn expand_args(ecx: @ExtCtxt, sp: Span,
tts: &[ast::token_tree]) -> base::MacResult {
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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let mut cx = Context {
ecx: ecx,
args: ~[],
arg_types: ~[],
names: HashMap::new(),
name_positions: HashMap::new(),
name_types: HashMap::new(),
nest_level: 0,
next_arg: 0,
pieces: ~[],
method_statics: ~[],
fmtsp: sp,
};
Reduce the amount of complexity in format! This renames the syntax-extension file to format from ifmt, and it also reduces the amount of complexity inside by defining all other macros in terms of format_args!
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let (extra, efmt) = match cx.parse_args(sp, tts) {
Implement a wrapper macro around fprintf -- ifmtf
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(extra, Some(e)) => (extra, e),
(_, None) => { return MRExpr(ecx.expr_uint(sp, 2)); }
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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};
cx.fmtsp = efmt.span;
let fmt = expr_to_str(ecx, efmt,
Implement a wrapper macro around fprintf -- ifmtf
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"format argument must be a string literal.");
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
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let mut err = false;
do parse::parse_error::cond.trap(|m| {
if !err {
err = true;
ecx.span_err(efmt.span, m);
}
}).inside {
for piece in parse::Parser::new(fmt) {
if !err {
cx.verify_piece(&piece);
let piece = cx.trans_piece(&piece);
cx.pieces.push(piece);
}
}
}
if err { return MRExpr(efmt) }
// Make sure that all arguments were used and all arguments have types.
for (i, ty) in cx.arg_types.iter().enumerate() {
if ty.is_none() {
ecx.span_err(cx.args[i].span, "argument never used");
}
}
for (name, e) in cx.names.iter() {
if !cx.name_types.contains_key(name) {
ecx.span_err(e.span, "named argument never used");
}
}
Reduce the amount of complexity in format! This renames the syntax-extension file to format from ifmt, and it also reduces the amount of complexity inside by defining all other macros in terms of format_args!
2013-09-12 21:36:58 -05:00
MRExpr(cx.to_expr(extra))
Add initial support for a new formatting syntax The new macro is available under the name ifmt! (only an intermediate name)
2013-07-29 03:12:41 -05:00
}
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