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use super::Layer;
use std::fmt;
/// Two middlewares chained together.
#[derive(Clone)]
pub struct Stack<Inner, Outer> {
inner: Inner,
outer: Outer,
}
impl<Inner, Outer> Stack<Inner, Outer> {
/// Create a new `Stack`.
pub fn new(inner: Inner, outer: Outer) -> Self {
Stack { inner, outer }
}
}
impl<S, Inner, Outer> Layer<S> for Stack<Inner, Outer>
where
Inner: Layer<S>,
Outer: Layer<Inner::Service>,
{
type Service = Outer::Service;
fn layer(&self, service: S) -> Self::Service {
let inner = self.inner.layer(service);
self.outer.layer(inner)
}
}
impl<Inner, Outer> fmt::Debug for Stack<Inner, Outer>
where
Inner: fmt::Debug,
Outer: fmt::Debug,
{
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
// The generated output of nested `Stack`s is very noisy and makes
// it harder to understand what is in a `ServiceBuilder`.
//
// Instead, this output is designed assuming that a `Stack` is
// usually quite nested, and inside a `ServiceBuilder`. Therefore,
// this skips using `f.debug_struct()`, since each one would force
// a new layer of indentation.
//
// - In compact mode, a nested stack ends up just looking like a flat
// list of layers.
//
// - In pretty mode, while a newline is inserted between each layer,
// the `DebugStruct` used in the `ServiceBuilder` will inject padding
// to that each line is at the same indentation level.
//
// Also, the order of [outer, inner] is important, since it reflects
// the order that the layers were added to the stack.
if f.alternate() {
// pretty
write!(f, "{:#?},\n{:#?}", self.outer, self.inner)
} else {
write!(f, "{:?}, {:?}", self.outer, self.inner)
}
}
}