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chromium / external / github.com / rust-lang / rust / 0f02309e4b0ea05ee905205278fb6d131341c41f / . / src / libterm / terminfo / parm.rs
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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.
//! Parameterized string expansion
use self::Param::*;
use self::States::*;
use self::FormatState::*;
use self::FormatOp::*;
use std::iter::repeat;
#[derive(Clone, Copy, PartialEq)]
enum States {
Nothing,
Percent,
SetVar,
GetVar,
PushParam,
CharConstant,
CharClose,
IntConstant(i32),
FormatPattern(Flags, FormatState),
SeekIfElse(usize),
SeekIfElsePercent(usize),
SeekIfEnd(usize),
SeekIfEndPercent(usize),
}
#[derive(Copy, PartialEq, Clone)]
enum FormatState {
FormatStateFlags,
FormatStateWidth,
FormatStatePrecision,
}
/// Types of parameters a capability can use
#[allow(missing_docs)]
#[derive(Clone)]
pub enum Param {
Words(String),
Number(i32),
}
/// Container for static and dynamic variable arrays
pub struct Variables {
/// Static variables A-Z
sta: [Param; 26],
/// Dynamic variables a-z
dyn: [Param; 26],
}
impl Variables {
/// Return a new zero-initialized Variables
pub fn new() -> Variables {
Variables {
sta: [Number(0), Number(0), Number(0), Number(0), Number(0), Number(0), Number(0),
Number(0), Number(0), Number(0), Number(0), Number(0), Number(0), Number(0),
Number(0), Number(0), Number(0), Number(0), Number(0), Number(0), Number(0),
Number(0), Number(0), Number(0), Number(0), Number(0)],
dyn: [Number(0), Number(0), Number(0), Number(0), Number(0), Number(0), Number(0),
Number(0), Number(0), Number(0), Number(0), Number(0), Number(0), Number(0),
Number(0), Number(0), Number(0), Number(0), Number(0), Number(0), Number(0),
Number(0), Number(0), Number(0), Number(0), Number(0)],
}
}
}
/// Expand a parameterized capability
///
/// # Arguments
/// * `cap` - string to expand
/// * `params` - vector of params for %p1 etc
/// * `vars` - Variables struct for %Pa etc
///
/// To be compatible with ncurses, `vars` should be the same between calls to `expand` for
/// multiple capabilities for the same terminal.
pub fn expand(cap: &[u8], params: &[Param], vars: &mut Variables) -> Result<Vec<u8>, String> {
let mut state = Nothing;
// expanded cap will only rarely be larger than the cap itself
let mut output = Vec::with_capacity(cap.len());
let mut stack: Vec<Param> = Vec::new();
// Copy parameters into a local vector for mutability
let mut mparams = [Number(0), Number(0), Number(0), Number(0), Number(0), Number(0),
Number(0), Number(0), Number(0)];
for (dst, src) in mparams.iter_mut().zip(params.iter()) {
*dst = (*src).clone();
}
for &c in cap.iter() {
let cur = c as char;
let mut old_state = state;
match state {
Nothing => {
if cur == '%' {
state = Percent;
} else {
output.push(c);
}
}
Percent => {
match cur {
'%' => {
output.push(c);
state = Nothing
}
'c' => {
match stack.pop() {
// if c is 0, use 0200 (128) for ncurses compatibility
Some(Number(0)) => output.push(128u8),
// Don't check bounds. ncurses just casts and truncates.
Some(Number(c)) => output.push(c as u8),
Some(_) => return Err("a non-char was used with %c".to_string()),
None => return Err("stack is empty".to_string()),
}
}
'p' => state = PushParam,
'P' => state = SetVar,
'g' => state = GetVar,
'\'' => state = CharConstant,
'{' => state = IntConstant(0),
'l' => {
match stack.pop() {
Some(Words(s)) => stack.push(Number(s.len() as i32)),
Some(_) => return Err("a non-str was used with %l".to_string()),
None => return Err("stack is empty".to_string()),
}
}
'+' | '-' | '/' | '*' | '^' | '&' | '|' | 'm' => {
match (stack.pop(), stack.pop()) {
(Some(Number(y)), Some(Number(x))) => {
stack.push(Number(match cur {
'+' => x + y,
'-' => x - y,
'*' => x * y,
'/' => x / y,
'|' => x | y,
'&' => x & y,
'^' => x ^ y,
'm' => x % y,
_ => unreachable!("All cases handled"),
}))
}
(Some(_), Some(_)) => {
return Err(format!("non-numbers on stack with {}", cur))
}
_ => return Err("stack is empty".to_string()),
}
}
'=' | '>' | '<' | 'A' | 'O' => {
match (stack.pop(), stack.pop()) {
(Some(Number(y)), Some(Number(x))) => {
stack.push(Number(if match cur {
'=' => x == y,
'<' => x < y,
'>' => x > y,
'A' => x > 0 && y > 0,
'O' => x > 0 || y > 0,
_ => unreachable!(),
} {
1
} else {
0
}))
}
(Some(_), Some(_)) => {
return Err(format!("non-numbers on stack with {}", cur))
}
_ => return Err("stack is empty".to_string()),
}
}
'!' | '~' => {
match stack.pop() {
Some(Number(x)) => {
stack.push(Number(match cur {
'!' if x > 0 => 0,
'!' => 1,
'~' => !x,
_ => unreachable!(),
}))
}
Some(_) => return Err(format!("non-numbers on stack with {}", cur)),
None => return Err("stack is empty".to_string()),
}
}
'i' => {
match (&mparams[0], &mparams[1]) {
(&Number(x), &Number(y)) => {
mparams[0] = Number(x + 1);
mparams[1] = Number(y + 1);
}
(_, _) => {
return Err("first two params not numbers with %i".to_string())
}
}
}
// printf-style support for %doxXs
'd' | 'o' | 'x' | 'X' | 's' => {
if let Some(arg) = stack.pop() {
let flags = Flags::new();
let res = format(arg, FormatOp::from_char(cur), flags)?;
output.extend(res.iter().map(|x| *x));
} else {
return Err("stack is empty".to_string());
}
}
':' | '#' | ' ' | '.' | '0'...'9' => {
let mut flags = Flags::new();
let mut fstate = FormatStateFlags;
match cur {
':' => (),
'#' => flags.alternate = true,
' ' => flags.space = true,
'.' => fstate = FormatStatePrecision,
'0'...'9' => {
flags.width = cur as usize - '0' as usize;
fstate = FormatStateWidth;
}
_ => unreachable!(),
}
state = FormatPattern(flags, fstate);
}
// conditionals
'?' => (),
't' => {
match stack.pop() {
Some(Number(0)) => state = SeekIfElse(0),
Some(Number(_)) => (),
Some(_) => {
return Err("non-number on stack with conditional".to_string())
}
None => return Err("stack is empty".to_string()),
}
}
'e' => state = SeekIfEnd(0),
';' => (),
_ => return Err(format!("unrecognized format option {}", cur)),
}
}
PushParam => {
// params are 1-indexed
stack.push(mparams[match cur.to_digit(10) {
Some(d) => d as usize - 1,
None => return Err("bad param number".to_string()),
}]
.clone());
}
SetVar => {
if cur >= 'A' && cur <= 'Z' {
if let Some(arg) = stack.pop() {
let idx = (cur as u8) - b'A';
vars.sta[idx as usize] = arg;
} else {
return Err("stack is empty".to_string());
}
} else if cur >= 'a' && cur <= 'z' {
if let Some(arg) = stack.pop() {
let idx = (cur as u8) - b'a';
vars.dyn[idx as usize] = arg;
} else {
return Err("stack is empty".to_string());
}
} else {
return Err("bad variable name in %P".to_string());
}
}
GetVar => {
if cur >= 'A' && cur <= 'Z' {
let idx = (cur as u8) - b'A';
stack.push(vars.sta[idx as usize].clone());
} else if cur >= 'a' && cur <= 'z' {
let idx = (cur as u8) - b'a';
stack.push(vars.dyn[idx as usize].clone());
} else {
return Err("bad variable name in %g".to_string());
}
}
CharConstant => {
stack.push(Number(c as i32));
state = CharClose;
}
CharClose => {
if cur != '\'' {
return Err("malformed character constant".to_string());
}
}
IntConstant(i) => {
if cur == '}' {
stack.push(Number(i));
state = Nothing;
} else if let Some(digit) = cur.to_digit(10) {
match i.checked_mul(10).and_then(|i_ten| i_ten.checked_add(digit as i32)) {
Some(i) => {
state = IntConstant(i);
old_state = Nothing;
}
None => return Err("int constant too large".to_string()),
}
} else {
return Err("bad int constant".to_string());
}
}
FormatPattern(ref mut flags, ref mut fstate) => {
old_state = Nothing;
match (*fstate, cur) {
(_, 'd') | (_, 'o') | (_, 'x') | (_, 'X') | (_, 's') => {
if let Some(arg) = stack.pop() {
let res = format(arg, FormatOp::from_char(cur), *flags)?;
output.extend(res.iter().map(|x| *x));
// will cause state to go to Nothing
old_state = FormatPattern(*flags, *fstate);
} else {
return Err("stack is empty".to_string());
}
}
(FormatStateFlags, '#') => {
flags.alternate = true;
}
(FormatStateFlags, '-') => {
flags.left = true;
}
(FormatStateFlags, '+') => {
flags.sign = true;
}
(FormatStateFlags, ' ') => {
flags.space = true;
}
(FormatStateFlags, '0'...'9') => {
flags.width = cur as usize - '0' as usize;
*fstate = FormatStateWidth;
}
(FormatStateFlags, '.') => {
*fstate = FormatStatePrecision;
}
(FormatStateWidth, '0'...'9') => {
let old = flags.width;
flags.width = flags.width * 10 + (cur as usize - '0' as usize);
if flags.width < old {
return Err("format width overflow".to_string());
}
}
(FormatStateWidth, '.') => {
*fstate = FormatStatePrecision;
}
(FormatStatePrecision, '0'...'9') => {
let old = flags.precision;
flags.precision = flags.precision * 10 + (cur as usize - '0' as usize);
if flags.precision < old {
return Err("format precision overflow".to_string());
}
}
_ => return Err("invalid format specifier".to_string()),
}
}
SeekIfElse(level) => {
if cur == '%' {
state = SeekIfElsePercent(level);
}
old_state = Nothing;
}
SeekIfElsePercent(level) => {
if cur == ';' {
if level == 0 {
state = Nothing;
} else {
state = SeekIfElse(level - 1);
}
} else if cur == 'e' && level == 0 {
state = Nothing;
} else if cur == '?' {
state = SeekIfElse(level + 1);
} else {
state = SeekIfElse(level);
}
}
SeekIfEnd(level) => {
if cur == '%' {
state = SeekIfEndPercent(level);
}
old_state = Nothing;
}
SeekIfEndPercent(level) => {
if cur == ';' {
if level == 0 {
state = Nothing;
} else {
state = SeekIfEnd(level - 1);
}
} else if cur == '?' {
state = SeekIfEnd(level + 1);
} else {
state = SeekIfEnd(level);
}
}
}
if state == old_state {
state = Nothing;
}
}
Ok(output)
}
#[derive(Copy, PartialEq, Clone)]
struct Flags {
width: usize,
precision: usize,
alternate: bool,
left: bool,
sign: bool,
space: bool,
}
impl Flags {
fn new() -> Flags {
Flags {
width: 0,
precision: 0,
alternate: false,
left: false,
sign: false,
space: false,
}
}
}
#[derive(Copy, Clone)]
enum FormatOp {
FormatDigit,
FormatOctal,
FormatHex,
FormatHEX,
FormatString,
}
impl FormatOp {
fn from_char(c: char) -> FormatOp {
match c {
'd' => FormatDigit,
'o' => FormatOctal,
'x' => FormatHex,
'X' => FormatHEX,
's' => FormatString,
_ => panic!("bad FormatOp char"),
}
}
fn to_char(self) -> char {
match self {
FormatDigit => 'd',
FormatOctal => 'o',
FormatHex => 'x',
FormatHEX => 'X',
FormatString => 's',
}
}
}
fn format(val: Param, op: FormatOp, flags: Flags) -> Result<Vec<u8>, String> {
let mut s = match val {
Number(d) => {
match op {
FormatDigit => {
if flags.sign {
format!("{:+01$}", d, flags.precision)
} else if d < 0 {
// C doesn't take sign into account in precision calculation.
format!("{:01$}", d, flags.precision + 1)
} else if flags.space {
format!(" {:01$}", d, flags.precision)
} else {
format!("{:01$}", d, flags.precision)
}
}
FormatOctal => {
if flags.alternate {
// Leading octal zero counts against precision.
format!("0{:01$o}", d, flags.precision.saturating_sub(1))
} else {
format!("{:01$o}", d, flags.precision)
}
}
FormatHex => {
if flags.alternate && d != 0 {
format!("0x{:01$x}", d, flags.precision)
} else {
format!("{:01$x}", d, flags.precision)
}
}
FormatHEX => {
if flags.alternate && d != 0 {
format!("0X{:01$X}", d, flags.precision)
} else {
format!("{:01$X}", d, flags.precision)
}
}
FormatString => return Err("non-number on stack with %s".to_string()),
}
.into_bytes()
}
Words(s) => {
match op {
FormatString => {
let mut s = s.into_bytes();
if flags.precision > 0 && flags.precision < s.len() {
s.truncate(flags.precision);
}
s
}
_ => return Err(format!("non-string on stack with %{}", op.to_char())),
}
}
};
if flags.width > s.len() {
let n = flags.width - s.len();
if flags.left {
s.extend(repeat(b' ').take(n));
} else {
let mut s_ = Vec::with_capacity(flags.width);
s_.extend(repeat(b' ').take(n));
s_.extend(s.into_iter());
s = s_;
}
}
Ok(s)
}
#[cfg(test)]
mod test {
use super::{expand, Variables};
use super::Param::{self, Words, Number};
use std::result::Result::Ok;
#[test]
fn test_basic_setabf() {
let s = b"\\E[48;5;%p1%dm";
assert_eq!(expand(s, &[Number(1)], &mut Variables::new()).unwrap(),
"\\E[48;5;1m".bytes().collect::<Vec<_>>());
}
#[test]
fn test_multiple_int_constants() {
assert_eq!(expand(b"%{1}%{2}%d%d", &[], &mut Variables::new()).unwrap(),
"21".bytes().collect::<Vec<_>>());
}
#[test]
fn test_op_i() {
let mut vars = Variables::new();
assert_eq!(expand(b"%p1%d%p2%d%p3%d%i%p1%d%p2%d%p3%d",
&[Number(1), Number(2), Number(3)],
&mut vars),
Ok("123233".bytes().collect::<Vec<_>>()));
assert_eq!(expand(b"%p1%d%p2%d%i%p1%d%p2%d", &[], &mut vars),
Ok("0011".bytes().collect::<Vec<_>>()));
}
#[test]
fn test_param_stack_failure_conditions() {
let mut varstruct = Variables::new();
let vars = &mut varstruct;
fn get_res(fmt: &str,
cap: &str,
params: &[Param],
vars: &mut Variables)
-> Result<Vec<u8>, String> {
let mut u8v: Vec<_> = fmt.bytes().collect();
u8v.extend(cap.as_bytes().iter().map(|&b| b));
expand(&u8v, params, vars)
}
let caps = ["%d", "%c", "%s", "%Pa", "%l", "%!", "%~"];
for &cap in caps.iter() {
let res = get_res("", cap, &[], vars);
assert!(res.is_err(),
"Op {} succeeded incorrectly with 0 stack entries",
cap);
let p = if cap == "%s" || cap == "%l" {
Words("foo".to_string())
} else {
Number(97)
};
let res = get_res("%p1", cap, &[p], vars);
assert!(res.is_ok(),
"Op {} failed with 1 stack entry: {}",
cap,
res.err().unwrap());
}
let caps = ["%+", "%-", "%*", "%/", "%m", "%&", "%|", "%A", "%O"];
for &cap in caps.iter() {
let res = expand(cap.as_bytes(), &[], vars);
assert!(res.is_err(),
"Binop {} succeeded incorrectly with 0 stack entries",
cap);
let res = get_res("%{1}", cap, &[], vars);
assert!(res.is_err(),
"Binop {} succeeded incorrectly with 1 stack entry",
cap);
let res = get_res("%{1}%{2}", cap, &[], vars);
assert!(res.is_ok(),
"Binop {} failed with 2 stack entries: {}",
cap,
res.err().unwrap());
}
}
#[test]
fn test_push_bad_param() {
assert!(expand(b"%pa", &[], &mut Variables::new()).is_err());
}
#[test]
fn test_comparison_ops() {
let v = [('<', [1u8, 0u8, 0u8]), ('=', [0u8, 1u8, 0u8]), ('>', [0u8, 0u8, 1u8])];
for &(op, bs) in v.iter() {
let s = format!("%{{1}}%{{2}}%{}%d", op);
let res = expand(s.as_bytes(), &[], &mut Variables::new());
assert!(res.is_ok(), res.err().unwrap());
assert_eq!(res.unwrap(), vec![b'0' + bs[0]]);
let s = format!("%{{1}}%{{1}}%{}%d", op);
let res = expand(s.as_bytes(), &[], &mut Variables::new());
assert!(res.is_ok(), res.err().unwrap());
assert_eq!(res.unwrap(), vec![b'0' + bs[1]]);
let s = format!("%{{2}}%{{1}}%{}%d", op);
let res = expand(s.as_bytes(), &[], &mut Variables::new());
assert!(res.is_ok(), res.err().unwrap());
assert_eq!(res.unwrap(), vec![b'0' + bs[2]]);
}
}
#[test]
fn test_conditionals() {
let mut vars = Variables::new();
let s = b"\\E[%?%p1%{8}%<%t3%p1%d%e%p1%{16}%<%t9%p1%{8}%-%d%e38;5;%p1%d%;m";
let res = expand(s, &[Number(1)], &mut vars);
assert!(res.is_ok(), res.err().unwrap());
assert_eq!(res.unwrap(), "\\E[31m".bytes().collect::<Vec<_>>());
let res = expand(s, &[Number(8)], &mut vars);
assert!(res.is_ok(), res.err().unwrap());
assert_eq!(res.unwrap(), "\\E[90m".bytes().collect::<Vec<_>>());
let res = expand(s, &[Number(42)], &mut vars);
assert!(res.is_ok(), res.err().unwrap());
assert_eq!(res.unwrap(), "\\E[38;5;42m".bytes().collect::<Vec<_>>());
}
#[test]
fn test_format() {
let mut varstruct = Variables::new();
let vars = &mut varstruct;
assert_eq!(expand(b"%p1%s%p2%2s%p3%2s%p4%.2s",
&[Words("foo".to_string()),
Words("foo".to_string()),
Words("f".to_string()),
Words("foo".to_string())],
vars),
Ok("foofoo ffo".bytes().collect::<Vec<_>>()));
assert_eq!(expand(b"%p1%:-4.2s", &[Words("foo".to_string())], vars),
Ok("fo ".bytes().collect::<Vec<_>>()));
assert_eq!(expand(b"%p1%d%p1%.3d%p1%5d%p1%:+d", &[Number(1)], vars),
Ok("1001 1+1".bytes().collect::<Vec<_>>()));
assert_eq!(expand(b"%p1%o%p1%#o%p2%6.4x%p2%#6.4X",
&[Number(15), Number(27)],
vars),
Ok("17017 001b0X001B".bytes().collect::<Vec<_>>()));
}
}