Delease
/
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							use std::collections::{HashMap, HashSet};

use crate::parsing::{Message, Transition};
use btrun::{Activate, End};

use super::Protocol;
use proc_macro2::{Ident, TokenStream};
use quote::{format_ident, quote, ToTokens};

impl ToTokens for Protocol {
    fn to_tokens(&self, tokens: &mut TokenStream) {
        tokens.extend(self.generate_message_enum());
        tokens.extend(self.generate_state_traits());
    }
}

impl Protocol {
    fn generate_message_enum(&self) -> TokenStream {
        let mut msgs: HashSet<&Message> = HashSet::new();
        for transition in self.transitions.iter() {
            // We only need to insert received messages because every sent message has a
            // corresponding receiver thanks to the validator.
            if let Some(msg) = transition.in_msg() {
                msgs.insert(msg);
            }
        }
        let variants = msgs.iter().map(|msg| msg.ident());
        let msg_types = msgs.iter().map(|msg| msg.type_tokens());
        let enum_name = format_ident!("{}Msgs", self.name_def.name);
        quote! {
            pub enum #enum_name {
                #( #variants(#msg_types) ),*
            }
        }
    }

    fn generate_state_traits(&self) -> TokenStream {
        let mut traits: HashMap<&Ident, Vec<&Transition>> = HashMap::new();
        for transition in self.transitions.iter() {
            let vec = traits
                .entry(&transition.in_state.state_trait)
                .or_insert_with(Vec::new);
            vec.push(transition);
        }
        let mut tokens = TokenStream::new();
        for (trait_ident, transitions) in traits {
            let transition_tokens = transitions.iter().map(|x| x.generate_tokens());
            quote! {
                pub trait #trait_ident {
                    #( #transition_tokens )*
                }
            }
            .to_tokens(&mut tokens);
        }
        tokens
    }
}

impl Message {
    /// Returns the tokens which represent the type of this message.
    fn type_tokens(&self) -> TokenStream {
        // We generate a fully-qualified path to the Activate message so that it doesn't need to be
        // imported for every protocol definition.
        let msg_type = if self.msg_type == Activate::ident() {
            quote! { ::btrun::Activate }
        } else {
            let msg_type = &self.msg_type;
            quote! { #msg_type }
        };
        if self.is_reply() {
            quote! {
                <#msg_type as ::btrun::CallMsg>::Reply
            }
        } else {
            quote! {
                #msg_type
            }
        }
    }
}

impl Transition {
    /// Generates the tokens for the code which implements this transition.
    fn generate_tokens(&self) -> TokenStream {
        let (msg_arg, method_ident) = if let Some(msg) = self.in_msg() {
            let msg_type = if msg.msg_type == Activate::ident() {
                quote! { ::btrun::Activate }
            } else {
                msg.msg_type.to_token_stream()
            };
            let method_ident = format_ident!("handle_{}", msg.ident().pascal_to_snake());
            let msg_arg = quote! { , msg: #msg_type };
            (msg_arg, method_ident)
        } else {
            let msg_arg = quote! {};
            let msg_names = self
                .out_msgs
                .as_ref()
                .iter()
                .fold(Option::<String>::None, |accum, curr| {
                    let msg_name = curr.msg.ident().pascal_to_snake();
                    if let Some(mut accum) = accum {
                        accum.push('_');
                        accum.push_str(&msg_name);
                        Some(accum)
                    } else {
                        Some(msg_name)
                    }
                })
                // Since no message is being handled, the validator ensures that at least one
                // message is being sent. Hence this unwrap will not panic.
                .unwrap();
            let method_ident = format_ident!("send_{}", msg_names);
            (msg_arg, method_ident)
        };
        let method_type_prefix = method_ident.snake_to_pascal();
        let output_pairs: Vec<_> = self
            .out_states
            .as_ref()
            .iter()
            .map(|state| {
                let state_trait = &state.state_trait;
                if state_trait == End::ident() {
                    (quote! {}, quote! { ::btrun::End })
                } else {
                    let assoc_type = format_ident!("{}{}", method_type_prefix, state_trait);
                    let output_decl = quote! { type #assoc_type: #state_trait; };
                    let output_type = quote! { Self::#assoc_type };
                    (output_decl, output_type)
                }
            })
            .collect();
        let output_decls = output_pairs.iter().map(|(decl, _)| decl);
        let output_types = output_pairs.iter().map(|(_, output_type)| output_type);
        let future_name = format_ident!("{}Fut", method_type_prefix);
        quote! {
            #( #output_decls )*
            type #future_name: ::std::future::Future<Output = Result<( #( #output_types ),* )>>;
            fn #method_ident(self #msg_arg) -> Self::#future_name;
        }
    }
}

trait CaseConvert {
    /// Converts a name in snake_case to PascalCase.
    fn snake_to_pascal(&self) -> String;
    /// Converts a name in PascalCase to snake_case.
    fn pascal_to_snake(&self) -> String;
}

impl CaseConvert for String {
    fn snake_to_pascal(&self) -> String {
        let mut pascal = String::with_capacity(self.len());
        let mut prev_underscore = true;
        for c in self.chars() {
            if '_' == c {
                prev_underscore = true;
            } else {
                if prev_underscore {
                    pascal.extend(c.to_uppercase());
                } else {
                    pascal.push(c);
                }
                prev_underscore = false;
            }
        }
        pascal
    }

    fn pascal_to_snake(&self) -> String {
        let mut snake = String::with_capacity(self.len());
        let mut prev_lower = false;
        for c in self.chars() {
            if c.is_uppercase() {
                if prev_lower {
                    snake.push('_');
                }
                snake.extend(c.to_lowercase());
                prev_lower = false;
            } else {
                prev_lower = true;
                snake.push(c);
            }
        }
        snake
    }
}

impl CaseConvert for Ident {
    fn snake_to_pascal(&self) -> String {
        self.to_string().snake_to_pascal()
    }

    fn pascal_to_snake(&self) -> String {
        self.to_string().pascal_to_snake()
    }
}

#[cfg(test)]
mod tests {
    use super::*;

    #[test]
    fn string_snake_to_pascal_multiple_segments() {
        const EXPECTED: &str = "FirstSecondThird";
        let input = String::from("first_second_third");

        let actual = input.snake_to_pascal();

        assert_eq!(EXPECTED, actual);
    }

    #[test]
    fn string_snake_to_pascal_single_segment() {
        const EXPECTED: &str = "First";
        let input = String::from("first");

        let actual = input.snake_to_pascal();

        assert_eq!(EXPECTED, actual);
    }

    #[test]
    fn string_snake_to_pascal_empty_string() {
        const EXPECTED: &str = "";
        let input = String::from(EXPECTED);

        let actual = input.snake_to_pascal();

        assert_eq!(EXPECTED, actual);
    }

    #[test]
    fn string_snake_to_pascal_leading_underscore() {
        const EXPECTED: &str = "First";
        let input = String::from("_first");

        let actual = input.snake_to_pascal();

        assert_eq!(EXPECTED, actual);
    }

    #[test]
    fn string_snake_to_pascal_leading_underscores() {
        const EXPECTED: &str = "First";
        let input = String::from("__first");

        let actual = input.snake_to_pascal();

        assert_eq!(EXPECTED, actual);
    }

    #[test]
    fn string_snake_to_pascal_multiple_underscores() {
        const EXPECTED: &str = "FirstSecondThird";
        let input = String::from("first__second___third");

        let actual = input.snake_to_pascal();

        assert_eq!(EXPECTED, actual);
    }

    #[test]
    fn string_pascal_to_snake_multiple_segments() {
        const EXPECTED: &str = "first_second_third";
        let input = String::from("FirstSecondThird");

        let actual = input.pascal_to_snake();

        assert_eq!(EXPECTED, actual);
    }

    #[test]
    fn string_pascal_to_snake_single_segment() {
        let input = String::from("First");
        const EXPECTED: &str = "first";

        let actual = input.pascal_to_snake();

        assert_eq!(EXPECTED, actual);
    }

    #[test]
    fn string_pascal_to_snake_empty_string() {
        const EXPECTED: &str = "";
        let input = String::from(EXPECTED);

        let actual = input.pascal_to_snake();

        assert_eq!(EXPECTED, actual);
    }

    #[test]
    fn string_pascal_to_snake_consecutive_uppercase() {
        const EXPECTED: &str = "kernel_mc";
        let input = String::from("KernelMC");

        let actual = input.pascal_to_snake();

        assert_eq!(EXPECTED, actual);
    }
}