// Copyright © 2020 Intel Corporation // // SPDX-License-Identifier: Apache-2.0 // use std::collections::HashMap; use std::fmt; use std::str::FromStr; #[derive(Default)] pub struct OptionParser { options: HashMap, } struct OptionParserValue { value: Option, requires_value: bool, } #[derive(Debug)] pub enum OptionParserError { UnknownOption(String), InvalidSyntax(String), Conversion(String, String), } impl fmt::Display for OptionParserError { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match self { OptionParserError::UnknownOption(s) => write!(f, "unknown option: {}", s), OptionParserError::InvalidSyntax(s) => write!(f, "invalid syntax:{}", s), OptionParserError::Conversion(field, value) => { write!(f, "unable to parse {} for {}", value, field) } } } } type OptionParserResult = std::result::Result; impl OptionParser { pub fn new() -> Self { Self { options: HashMap::new(), } } pub fn parse(&mut self, input: &str) -> OptionParserResult<()> { if input.trim().is_empty() { return Ok(()); } let options_list: Vec<&str> = input.trim().split(',').collect(); for option in options_list.iter() { let parts: Vec<&str> = option.split('=').collect(); match self.options.get_mut(parts[0]) { None => return Err(OptionParserError::UnknownOption(parts[0].to_owned())), Some(value) => { if value.requires_value { if parts.len() != 2 { return Err(OptionParserError::InvalidSyntax((*option).to_owned())); } value.value = Some(parts[1].trim().to_owned()); } else { value.value = Some(String::new()); } } } } Ok(()) } pub fn add(&mut self, option: &str) -> &mut Self { self.options.insert( option.to_owned(), OptionParserValue { value: None, requires_value: true, }, ); self } pub fn add_valueless(&mut self, option: &str) -> &mut Self { self.options.insert( option.to_owned(), OptionParserValue { value: None, requires_value: false, }, ); self } pub fn get(&self, option: &str) -> Option { self.options .get(option) .and_then(|v| v.value.clone()) .and_then(|s| if s.is_empty() { None } else { Some(s) }) } pub fn is_set(&self, option: &str) -> bool { self.options .get(option) .and_then(|v| v.value.as_ref()) .is_some() } pub fn convert(&self, option: &str) -> OptionParserResult> { match self.get(option) { None => Ok(None), Some(v) => Ok(Some(v.parse().map_err(|_| { OptionParserError::Conversion(option.to_owned(), v.to_owned()) })?)), } } } pub struct Toggle(pub bool); pub enum ToggleParseError { InvalidValue(String), } impl FromStr for Toggle { type Err = ToggleParseError; fn from_str(s: &str) -> std::result::Result { match s.to_lowercase().as_str() { "" => Ok(Toggle(false)), "on" => Ok(Toggle(true)), "off" => Ok(Toggle(false)), "true" => Ok(Toggle(true)), "false" => Ok(Toggle(false)), _ => Err(ToggleParseError::InvalidValue(s.to_owned())), } } } pub struct ByteSized(pub u64); #[derive(Debug)] pub enum ByteSizedParseError { InvalidValue(String), } impl FromStr for ByteSized { type Err = ByteSizedParseError; fn from_str(s: &str) -> std::result::Result { Ok(ByteSized({ let s = s.trim(); let shift = if s.ends_with('K') { 10 } else if s.ends_with('M') { 20 } else if s.ends_with('G') { 30 } else { 0 }; let s = s.trim_end_matches(|c| c == 'K' || c == 'M' || c == 'G'); s.parse::() .map_err(|_| ByteSizedParseError::InvalidValue(s.to_owned()))? << shift })) } } pub struct IntegerList(pub Vec); pub enum IntegerListParseError { InvalidValue(String), } impl FromStr for IntegerList { type Err = IntegerListParseError; fn from_str(s: &str) -> std::result::Result { let mut integer_list = Vec::new(); let ranges_list: Vec<&str> = s.trim().split(':').collect(); for range in ranges_list.iter() { let items: Vec<&str> = range.split('-').collect(); if items.len() > 2 { return Err(IntegerListParseError::InvalidValue(range.to_string())); } let start_range = items[0] .parse::() .map_err(|_| IntegerListParseError::InvalidValue(items[0].to_owned()))?; integer_list.push(start_range); if items.len() == 2 { let end_range = items[1] .parse::() .map_err(|_| IntegerListParseError::InvalidValue(items[1].to_owned()))?; if start_range >= end_range { return Err(IntegerListParseError::InvalidValue(range.to_string())); } for i in start_range..end_range { integer_list.push(i + 1); } } } Ok(IntegerList(integer_list)) } } pub struct TupleTwoIntegers(pub Vec<(u64, u64)>); pub enum TupleTwoIntegersParseError { InvalidValue(String), } impl FromStr for TupleTwoIntegers { type Err = TupleTwoIntegersParseError; fn from_str(s: &str) -> std::result::Result { let mut list = Vec::new(); let tuples_list: Vec<&str> = s.trim().split(':').collect(); for tuple in tuples_list.iter() { let items: Vec<&str> = tuple.split('@').collect(); if items.len() != 2 { return Err(TupleTwoIntegersParseError::InvalidValue(tuple.to_string())); } let item1 = items[0] .parse::() .map_err(|_| TupleTwoIntegersParseError::InvalidValue(items[0].to_owned()))?; let item2 = items[1] .parse::() .map_err(|_| TupleTwoIntegersParseError::InvalidValue(items[1].to_owned()))?; list.push((item1, item2)); } Ok(TupleTwoIntegers(list)) } } pub struct StringList(pub Vec); pub enum StringListParseError { InvalidValue(String), } impl FromStr for StringList { type Err = StringListParseError; fn from_str(s: &str) -> std::result::Result { let string_list: Vec = s.trim().split(':').map(|e| e.to_owned()).collect(); Ok(StringList(string_list)) } }