[−][src]Macro quote::quote
The whole point.
Performs variable interpolation against the input and produces it as
TokenStream
. For returning tokens to the compiler in a procedural macro, use
into()
to build a TokenStream
.
Interpolation
Variable interpolation is done with #var
(similar to $var
in
macro_rules!
macros). This grabs the var
variable that is currently in
scope and inserts it in that location in the output tokens. Any type
implementing the ToTokens
trait can be interpolated. This includes most
Rust primitive types as well as most of the syntax tree types from the Syn
crate.
Repetition is done using #(...)*
or #(...),*
again similar to
macro_rules!
. This iterates through the elements of any variable
interpolated within the repetition and inserts a copy of the repetition body
for each one. The variables in an interpolation may be anything that
implements IntoIterator
, including Vec
or a pre-existing iterator.
#(#var)*
— no separators#(#var),*
— the character before the asterisk is used as a separator#( struct #var; )*
— the repetition can contain other tokens#( #k => println!("{}", #v), )*
— even multiple interpolations
There are two limitations around interpolations in a repetition:
-
Every interpolation inside of a repetition must be a distinct variable. That is,
#(#a #a)*
is not allowed. Work around this by collectinga
into a vector and taking referencesa1 = &a
anda2 = &a
which you use inside the repetition:#(#a1 #a2)*
. Where possible, use meaningful names that indicate the distinct role of each copy. -
Every interpolation inside of a repetition must be iterable. If we have
vec
which is a vector andident
which is a single identifier,#(#ident #vec)*
is not allowed. Work around this by usingstd::iter::repeat(ident)
to produce an iterable that can be used from within the repetition.
Hygiene
Any interpolated tokens preserve the Span
information provided by their
ToTokens
implementation. Tokens that originate within the quote!
invocation are spanned with Span::call_site()
.
A different span can be provided through the quote_spanned!
macro.
Return type
The macro evaluates to an expression of type proc_macro2::TokenStream
.
Meanwhile Rust procedural macros are expected to return the type
proc_macro::TokenStream
.
The difference between the two types is that proc_macro
types are entirely
specific to procedural macros and cannot ever exist in code outside of a
procedural macro, while proc_macro2
types may exist anywhere including
tests and non-macro code like main.rs and build.rs. This is why even the
procedural macro ecosystem is largely built around proc_macro2
, because
that ensures the libraries are unit testable and accessible in non-macro
contexts.
There is a From
-conversion in both directions so returning the output of
quote!
from a procedural macro usually looks like tokens.into()
or
proc_macro::TokenStream::from(tokens)
.
Examples
Procedural macro
The structure of a basic procedural macro is as follows. Refer to the Syn
crate for further useful guidance on using quote!
as part of a procedural
macro.
# #[cfg(any())]
extern crate proc_macro;
# use proc_macro2 as proc_macro;
use proc_macro::TokenStream;
use quote::quote;
# const IGNORE_TOKENS: &'static str = stringify! {
#[proc_macro_derive(HeapSize)]
# };
pub fn derive_heap_size(input: TokenStream) -> TokenStream {
// Parse the input and figure out what implementation to generate...
# const IGNORE_TOKENS: &'static str = stringify! {
let name = /* ... */;
let expr = /* ... */;
# };
#
# let name = 0;
# let expr = 0;
let expanded = quote! {
// The generated impl.
impl heapsize::HeapSize for #name {
fn heap_size_of_children(&self) -> usize {
#expr
}
}
};
// Hand the output tokens back to the compiler.
TokenStream::from(expanded)
}
Combining quoted fragments
Usually you don't end up constructing an entire final TokenStream
in one
piece. Different parts may come from different helper functions. The tokens
produced by quote!
themselves implement ToTokens
and so can be
interpolated into later quote!
invocations to build up a final result.
# use quote::quote;
#
let type_definition = quote! {...};
let methods = quote! {...};
let tokens = quote! {
#type_definition
#methods
};
Constructing identifiers
Suppose we have an identifier ident
which came from somewhere in a macro
input and we need to modify it in some way for the macro output. Let's
consider prepending the identifier with an underscore.
Simply interpolating the identifier next to an underscore will not have the
behavior of concatenating them. The underscore and the identifier will
continue to be two separate tokens as if you had written _ x
.
# use proc_macro2::{self as syn, Span};
# use quote::quote;
#
# let ident = syn::Ident::new("i", Span::call_site());
#
// incorrect
quote! {
let mut _#ident = 0;
}
# ;
The solution is to perform token-level manipulations using the APIs provided by Syn and proc-macro2.
# use proc_macro2::{self as syn, Span};
# use quote::quote;
#
# let ident = syn::Ident::new("i", Span::call_site());
#
let concatenated = format!("_{}", ident);
let varname = syn::Ident::new(&concatenated, ident.span());
quote! {
let mut #varname = 0;
}
# ;
Making method calls
Let's say our macro requires some type specified in the macro input to have
a constructor called new
. We have the type in a variable called
field_type
of type syn::Type
and want to invoke the constructor.
# use quote::quote;
#
# let field_type = quote!(...);
#
// incorrect
quote! {
let value = #field_type::new();
}
# ;
This works only sometimes. If field_type
is String
, the expanded code
contains String::new()
which is fine. But if field_type
is something
like Vec<i32>
then the expanded code is Vec<i32>::new()
which is invalid
syntax. Ordinarily in handwritten Rust we would write Vec::<i32>::new()
but for macros often the following is more convenient.
# use quote::quote;
#
# let field_type = quote!(...);
#
quote! {
let value = <#field_type>::new();
}
# ;
This expands to <Vec<i32>>::new()
which behaves correctly.
A similar pattern is appropriate for trait methods.
# use quote::quote;
#
# let field_type = quote!(...);
#
quote! {
let value = <#field_type as core::default::Default>::default();
}
# ;