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#![deny(elided_lifetimes_in_paths)]
#![deny(unreachable_pub)]
use askama_shared::heritage::{Context, Heritage};
use askama_shared::input::{Print, Source, TemplateInput};
use askama_shared::parser::{parse, Expr, Node};
use askama_shared::{
generator, get_template_source, read_config_file, CompileError, Config, Integrations,
};
use proc_macro::TokenStream;
use proc_macro2::Span;
use std::collections::HashMap;
use std::path::PathBuf;
#[proc_macro_derive(Template, attributes(template))]
pub fn derive_template(input: TokenStream) -> TokenStream {
let ast: syn::DeriveInput = syn::parse(input).unwrap();
match build_template(&ast) {
Ok(source) => source.parse().unwrap(),
Err(e) => syn::Error::new(Span::call_site(), e)
.to_compile_error()
.into(),
}
}
/// Takes a `syn::DeriveInput` and generates source code for it
///
/// Reads the metadata from the `template()` attribute to get the template
/// metadata, then fetches the source from the filesystem. The source is
/// parsed, and the parse tree is fed to the code generator. Will print
/// the parse tree and/or generated source according to the `print` key's
/// value as passed to the `template()` attribute.
fn build_template(ast: &syn::DeriveInput) -> Result<String, CompileError> {
let config_toml = read_config_file()?;
let config = Config::new(&config_toml)?;
let input = TemplateInput::new(ast, &config)?;
let source: String = match input.source {
Source::Source(ref s) => s.clone(),
Source::Path(_) => get_template_source(&input.path)?,
};
let mut sources = HashMap::new();
find_used_templates(&input, &mut sources, source)?;
let mut parsed = HashMap::new();
for (path, src) in &sources {
parsed.insert(path, parse(src, input.syntax)?);
}
let mut contexts = HashMap::new();
for (path, nodes) in &parsed {
contexts.insert(*path, Context::new(input.config, path, nodes)?);
}
let ctx = &contexts[&input.path];
let heritage = if !ctx.blocks.is_empty() || ctx.extends.is_some() {
Some(Heritage::new(ctx, &contexts))
} else {
None
};
if input.print == Print::Ast || input.print == Print::All {
eprintln!("{:?}", parsed[&input.path]);
}
let code = generator::generate(&input, &contexts, &heritage, INTEGRATIONS)?;
if input.print == Print::Code || input.print == Print::All {
eprintln!("{}", code);
}
Ok(code)
}
fn find_used_templates(
input: &TemplateInput<'_>,
map: &mut HashMap<PathBuf, String>,
source: String,
) -> Result<(), CompileError> {
let mut dependency_graph = Vec::new();
let mut check = vec![(input.path.clone(), source)];
while let Some((path, source)) = check.pop() {
for n in parse(&source, input.syntax)? {
match n {
Node::Extends(Expr::StrLit(extends)) => {
let extends = input.config.find_template(extends, Some(&path))?;
let dependency_path = (path.clone(), extends.clone());
if dependency_graph.contains(&dependency_path) {
return Err(CompileError::String(format!(
"cyclic dependecy in graph {:#?}",
dependency_graph
.iter()
.map(|e| format!("{:#?} --> {:#?}", e.0, e.1))
.collect::<Vec<String>>()
)));
}
dependency_graph.push(dependency_path);
let source = get_template_source(&extends)?;
check.push((extends, source));
}
Node::Import(_, import, _) => {
let import = input.config.find_template(import, Some(&path))?;
let source = get_template_source(&import)?;
check.push((import, source));
}
_ => {}
}
}
map.insert(path, source);
}
Ok(())
}
const INTEGRATIONS: Integrations = Integrations {
actix: cfg!(feature = "actix-web"),
axum: cfg!(feature = "axum"),
gotham: cfg!(feature = "gotham"),
iron: cfg!(feature = "iron"),
mendes: cfg!(feature = "mendes"),
rocket: cfg!(feature = "rocket"),
tide: cfg!(feature = "tide"),
warp: cfg!(feature = "warp"),
};
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