use parser::{self, Cond, Expr, Node, Target, WS}; use path; use quote::{Tokens, ToTokens}; use std::{cmp, hash, str}; use std::path::PathBuf; use std::collections::HashSet; use syn; pub fn generate(ast: &syn::DeriveInput, path: &str, mut nodes: Vec) -> String { let mut base: Option = None; let mut blocks = Vec::new(); let mut block_names = Vec::new(); let mut content = Vec::new(); for n in nodes.drain(..) { match n { Node::Extends(path) => { match base { Some(_) => panic!("multiple extend blocks found"), None => { base = Some(path); }, } }, Node::BlockDef(ws1, name, _, ws2) => { blocks.push(n); block_names.push(name); content.push(Node::Block(ws1, name, ws2)); }, _ => { content.push(n); }, } } let mut gen = Generator::default(); if !blocks.is_empty() { let trait_name = trait_name_for_path(&base, path); if base.is_none() { gen.define_trait(&trait_name, &block_names); } else { let parent_type = get_parent_type(ast) .expect("expected field '_parent' in extending template struct"); gen.deref_to_parent(ast, &parent_type); } let trait_nodes = if base.is_none() { Some(&content[..]) } else { None }; gen.impl_trait(ast, &trait_name, &blocks, trait_nodes); gen.impl_template_for_trait(ast, base.is_some()); } else { gen.impl_template(ast, &content); } gen.impl_display(ast); gen.result() } fn trait_name_for_path(base: &Option, path: &str) -> String { let rooted_path = match *base { Some(Expr::StrLit(user_path)) => { path::find_template_from_path(user_path, Some(path)) }, _ => { let mut path_buf = PathBuf::new(); path_buf.push(&path); path_buf }, }; let mut res = String::new(); res.push_str("TraitFrom"); for c in rooted_path.to_string_lossy().chars() { if c.is_alphanumeric() { res.push(c); } else { res.push_str(&format!("{:x}", c as u32)); } } res } fn get_parent_type(ast: &syn::DeriveInput) -> Option<&syn::Ty> { match ast.body { syn::Body::Struct(ref data) => { data.fields().iter().filter_map(|f| { f.ident.as_ref().and_then(|name| { if name.as_ref() == "_parent" { Some(&f.ty) } else { None } }) }) }, _ => panic!("derive(Template) only works for struct items"), }.next() } struct Generator<'a> { buf: String, indent: u8, start: bool, locals: SetChain<'a, &'a str>, next_ws: Option<&'a str>, skip_ws: bool, } impl<'a> Generator<'a> { fn new<'n>(locals: SetChain<'n, &'n str>, indent: u8) -> Generator<'n> { Generator { buf: String::new(), indent: indent, start: true, locals: locals, next_ws: None, skip_ws: false, } } fn default<'n>() -> Generator<'n> { Self::new(SetChain::new(), 0) } fn child<'n>(&'n mut self) -> Generator<'n> { let locals = SetChain::with_parent(&self.locals); Self::new(locals, self.indent) } /* Helper methods for writing to internal buffer */ fn indent(&mut self) { self.indent += 1; } fn dedent(&mut self) { self.indent -= 1; } fn write(&mut self, s: &str) { if self.start { for _ in 0..(self.indent * 4) { self.buf.push(' '); } self.start = false; } self.buf.push_str(s); } fn writeln(&mut self, s: &str) { if s.is_empty() { return; } if s == "}" { self.dedent(); } self.write(s); if s.ends_with('{') { self.indent(); } self.buf.push('\n'); self.start = true; } /* Helper methods for dealing with whitespace nodes */ fn flush_ws(&mut self, ws: &WS) { if self.next_ws.is_some() && !ws.0 { let val = self.next_ws.unwrap(); if !val.is_empty() { self.writeln(&format!("writer.write_str({:#?})?;", val)); } } self.next_ws = None; } fn prepare_ws(&mut self, ws: &WS) { self.skip_ws = ws.1; } fn handle_ws(&mut self, ws: &WS) { self.flush_ws(ws); self.prepare_ws(ws); } /* Visitor methods for expression types */ fn visit_num_lit(&mut self, s: &str) { self.write(s); } fn visit_str_lit(&mut self, s: &str) { self.write(&format!("\"{}\"", s)); } fn visit_var(&mut self, s: &str) { if self.locals.contains(s) { self.write(s); } else { self.write(&format!("self.{}", s)); } } fn visit_attr(&mut self, obj: &Expr, attr: &str) { if let Expr::Var(name) = *obj { if name == "loop" { self.write("_loop_index"); if attr == "index" { self.write(" + 1"); return; } else if attr == "index0" { return; } else { panic!("unknown loop variable"); } } } self.visit_expr(obj); self.write(&format!(".{}", attr)); } fn visit_filter(&mut self, name: &str, args: &[Expr]) { if name == "format" { self.write("format!("); } else { self.write(&format!("::askama::filters::{}(&", name)); } for (i, arg) in args.iter().enumerate() { if i > 0 { self.write(", &"); } self.visit_expr(arg); } self.write(")"); } fn visit_binop(&mut self, op: &str, left: &Expr, right: &Expr) { self.visit_expr(left); self.write(&format!(" {} ", op)); self.visit_expr(right); } fn visit_group(&mut self, inner: &Expr) { self.write("("); self.visit_expr(inner); self.write(")"); } fn visit_call(&mut self, obj: &Expr, method: &str, args: &[Expr]) { self.visit_expr(obj); self.write(&format!(".{}(", method)); for (i, arg) in args.iter().enumerate() { if i > 0 { self.write(", "); } self.visit_expr(arg); } self.write(")"); } fn visit_expr(&mut self, expr: &Expr) { match *expr { Expr::NumLit(s) => self.visit_num_lit(s), Expr::StrLit(s) => self.visit_str_lit(s), Expr::Var(s) => self.visit_var(s), Expr::Attr(ref obj, name) => self.visit_attr(obj, name), Expr::Filter(name, ref args) => self.visit_filter(name, args), Expr::BinOp(op, ref left, ref right) => self.visit_binop(op, left, right), Expr::Group(ref inner) => self.visit_group(inner), Expr::Call(ref obj, method, ref args) => self.visit_call(obj, method, args), } } fn visit_target_single<'t>(&mut self, name: &'t str) -> Vec<&'t str> { vec![name] } fn visit_target<'t>(&mut self, target: &'t Target) -> Vec<&'t str> { match *target { Target::Name(s) => { self.visit_target_single(s) }, } } /* Helper methods for handling node types */ fn write_lit(&mut self, lws: &'a str, val: &str, rws: &'a str) { assert!(self.next_ws.is_none()); if !lws.is_empty() { if self.skip_ws { self.skip_ws = false; } else if val.is_empty() { assert!(rws.is_empty()); self.next_ws = Some(lws); } else { self.writeln(&format!("writer.write_str({:#?})?;", lws)); } } if !val.is_empty() { self.writeln(&format!("writer.write_str({:#?})?;", val)); } if !rws.is_empty() { self.next_ws = Some(rws); } } fn write_expr(&mut self, ws: &WS, s: &Expr) { self.handle_ws(ws); self.write("writer.write_fmt(format_args!(\"{}\", "); self.visit_expr(s); self.writeln("))?;"); } fn write_cond(&mut self, conds: &'a [Cond], ws: &WS) { for (i, &(ref cws, ref cond, ref nodes)) in conds.iter().enumerate() { self.handle_ws(cws); match *cond { Some(ref expr) => { if i == 0 { self.write("if "); } else { self.dedent(); self.write("} else if "); } self.visit_expr(expr); }, None => { self.dedent(); self.write("} else"); }, } self.writeln(" {"); self.handle(nodes); } self.handle_ws(ws); self.writeln("}"); } fn write_loop(&mut self, ws1: &WS, var: &'a Target, iter: &Expr, body: &'a [Node], ws2: &WS) { self.handle_ws(ws1); self.locals.push(); self.write("for (_loop_index, "); let targets = self.visit_target(var); for name in &targets { self.locals.insert(name); self.write(name); } self.write(") in (&"); self.visit_expr(iter); self.writeln(").into_iter().enumerate() {"); self.handle(body); self.handle_ws(ws2); self.writeln("}"); self.locals.pop(); } fn write_block(&mut self, ws1: &WS, name: &str, ws2: &WS) { self.flush_ws(ws1); self.writeln(&format!("timpl.render_block_{}_into(writer)?;", name)); self.prepare_ws(ws2); } fn write_block_def(&mut self, ws1: &WS, name: &str, nodes: &'a [Node], ws2: &WS) { self.writeln("#[allow(unused_variables)]"); self.writeln(&format!( "fn render_block_{}_into(&self, writer: &mut ::std::fmt::Write) \ -> ::askama::Result<()> {{", name)); self.prepare_ws(ws1); self.handle(nodes); self.flush_ws(ws2); self.writeln("Ok(())"); self.writeln("}"); } fn handle_include(&mut self, ws: &WS, path: &str) { self.prepare_ws(ws); let path = path::find_template_from_path(&path, None); let src = path::get_template_source(&path); let nodes = parser::parse(&src); let nested = { let mut gen = self.child(); gen.handle(&nodes); gen.result() }; self.buf.push_str(&nested); self.flush_ws(ws); } fn handle(&mut self, nodes: &'a [Node]) { for n in nodes { match *n { Node::Lit(lws, val, rws) => { self.write_lit(lws, val, rws); } Node::Comment() => {}, Node::Expr(ref ws, ref val) => { self.write_expr(ws, val); }, Node::Cond(ref conds, ref ws) => { self.write_cond(conds, ws); }, Node::Loop(ref ws1, ref var, ref iter, ref body, ref ws2) => { self.write_loop(ws1, var, iter, body, ws2); }, Node::Block(ref ws1, name, ref ws2) => { self.write_block(ws1, name, ws2); }, Node::BlockDef(ref ws1, name, ref block_nodes, ref ws2) => { self.write_block_def(ws1, name, block_nodes, ws2); } Node::Include(ref ws, ref path) => { self.handle_include(ws, path); }, Node::Extends(_) => { panic!("no extends or block definition allowed in content"); }, } } } // Writes header for the `impl` for `TraitFromPathName` or `Template` // for the given context struct. fn write_header(&mut self, ast: &syn::DeriveInput, target: &str) { let mut full_anno = Tokens::new(); let mut orig_anno = Tokens::new(); let need_anno = ast.generics.lifetimes.len() > 0 || ast.generics.ty_params.len() > 0; if need_anno { full_anno.append("<"); orig_anno.append("<"); } let mut sep = false; for lt in &ast.generics.lifetimes { if sep { full_anno.append(","); orig_anno.append(","); } lt.to_tokens(&mut full_anno); lt.to_tokens(&mut orig_anno); sep = true; } for param in &ast.generics.ty_params { if sep { full_anno.append(","); orig_anno.append(","); } let mut impl_param = param.clone(); impl_param.default = None; impl_param.to_tokens(&mut full_anno); param.ident.to_tokens(&mut orig_anno); sep = true; } if need_anno { full_anno.append(">"); orig_anno.append(">"); } let mut where_clause = Tokens::new(); ast.generics.where_clause.to_tokens(&mut where_clause); self.writeln(&format!("impl{} {} for {}{}{} {{", full_anno.as_str(), target, ast.ident.as_ref(), orig_anno.as_str(), where_clause.as_str())); } // Implement `Template` for the given context struct. fn impl_template(&mut self, ast: &syn::DeriveInput, nodes: &'a [Node]) { self.write_header(ast, "::askama::Template"); self.writeln("fn render_into(&self, writer: &mut ::std::fmt::Write) -> \ ::askama::Result<()> {"); self.handle(nodes); self.flush_ws(&WS(false, false)); self.writeln("Ok(())"); self.writeln("}"); self.writeln("}"); } // Implement `Display` for the given context struct. fn impl_display(&mut self, ast: &syn::DeriveInput) { self.write_header(ast, "::std::fmt::Display"); self.writeln("fn fmt(&self, f: &mut ::std::fmt::Formatter) -> ::askama::Result<()> {"); self.writeln("self.render_into(f)"); self.writeln("}"); self.writeln("}"); } // Implement `Deref` for an inheriting context struct. fn deref_to_parent(&mut self, ast: &syn::DeriveInput, parent_type: &syn::Ty) { self.write_header(ast, "::std::ops::Deref"); let mut tokens = Tokens::new(); parent_type.to_tokens(&mut tokens); self.writeln(&format!("type Target = {};", tokens.as_str())); self.writeln("fn deref(&self) -> &Self::Target {"); self.writeln("&self._parent"); self.writeln("}"); self.writeln("}"); } // Implement `TraitFromPathName` for the given context struct. fn impl_trait(&mut self, ast: &syn::DeriveInput, trait_name: &str, blocks: &'a [Node], nodes: Option<&'a [Node]>) { self.write_header(ast, &trait_name); self.handle(blocks); self.writeln("#[allow(unused_variables)]"); self.writeln(&format!( "fn render_trait_into(&self, timpl: &{}, writer: &mut ::std::fmt::Write) \ -> ::askama::Result<()> {{", trait_name)); if let Some(nodes) = nodes { self.handle(nodes); self.flush_ws(&WS(false, false)); } else { self.writeln("self._parent.render_trait_into(self, writer)?;"); } self.writeln("Ok(())"); self.writeln("}"); self.flush_ws(&WS(false, false)); self.writeln("}"); } // Implement `Template` for templates that implement a template trait. fn impl_template_for_trait(&mut self, ast: &syn::DeriveInput, derived: bool) { self.write_header(ast, "::askama::Template"); self.writeln("fn render_into(&self, writer: &mut ::std::fmt::Write) \ -> ::askama::Result<()> {"); if derived { self.writeln("self._parent.render_trait_into(self, writer)?;"); } else { self.writeln("self.render_trait_into(self, writer)?;"); } self.writeln("Ok(())"); self.writeln("}"); self.writeln("}"); } // Defines the `TraitFromPathName` trait. fn define_trait(&mut self, trait_name: &str, block_names: &[&str]) { self.writeln(&format!("trait {} {{", &trait_name)); for bname in block_names { self.writeln(&format!( "fn render_block_{}_into(&self, writer: &mut ::std::fmt::Write) \ -> ::askama::Result<()>;", bname)); } self.writeln(&format!( "fn render_trait_into(&self, timpl: &{}, writer: &mut ::std::fmt::Write) \ -> ::askama::Result<()>;", trait_name)); self.writeln("}"); } fn result(self) -> String { self.buf } } struct SetChain<'a, T: 'a> where T: cmp::Eq + hash::Hash { parent: Option<&'a SetChain<'a, T>>, scopes: Vec>, } impl<'a, T: 'a> SetChain<'a, T> where T: cmp::Eq + hash::Hash { fn new() -> SetChain<'a, T> { SetChain { parent: None, scopes: vec![HashSet::new()] } } fn with_parent<'p>(parent: &'p SetChain) -> SetChain<'p, T> { SetChain { parent: Some(parent), scopes: vec![HashSet::new()] } } fn contains(&self, val: T) -> bool { self.scopes.iter().rev().any(|set| set.contains(&val)) || match self.parent { Some(set) => set.contains(val), None => false, } } fn insert(&mut self, val: T) { self.scopes.last_mut().unwrap().insert(val); } fn push(&mut self) { self.scopes.push(HashSet::new()); } fn pop(&mut self) { self.scopes.pop().unwrap(); } }