src/net/http/routing_tree.go - toolchain/go - Git at Google

 // Copyright 2023 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 // This file implements a decision tree for fast matching of requests to
 // patterns.
 //
 // The root of the tree branches on the host of the request.
 // The next level branches on the method.
 // The remaining levels branch on consecutive segments of the path.
 //
 // The "more specific wins" precedence rule can result in backtracking.
 // For example, given the patterns
 //     /a/b/z
 //     /a/{x}/c
 // we will first try to match the path "/a/b/c" with /a/b/z, and
 // when that fails we will try against /a/{x}/c.

 package http

 import (
 	"strings"
 )

 // A routingNode is a node in the decision tree.
 // The same struct is used for leaf and interior nodes.
 type routingNode struct {
 	// A leaf node holds a single pattern and the Handler it was registered
 	// with.
 	pattern *pattern
 	handler Handler

 	// An interior node maps parts of the incoming request to child nodes.
 	// special children keys:
 	//     "/"	trailing slash (resulting from {$})
 	//	   ""   single wildcard
 	//	   "*"  multi wildcard
 	children   mapping[string, *routingNode]
 	emptyChild *routingNode // optimization: child with key ""
 }

 // addPattern adds a pattern and its associated Handler to the tree
 // at root.
 func (root *routingNode) addPattern(p *pattern, h Handler) {
 	// First level of tree is host.
 	n := root.addChild(p.host)
 	// Second level of tree is method.
 	n = n.addChild(p.method)
 	// Remaining levels are path.
 	n.addSegments(p.segments, p, h)
 }

 // addSegments adds the given segments to the tree rooted at n.
 // If there are no segments, then n is a leaf node that holds
 // the given pattern and handler.
 func (n *routingNode) addSegments(segs []segment, p *pattern, h Handler) {
 	if len(segs) == 0 {
 		n.set(p, h)
 		return
 	}
 	seg := segs[0]
 	if seg.multi {
 		if len(segs) != 1 {
 			panic("multi wildcard not last")
 		}
 		n.addChild("*").set(p, h)
 	} else if seg.wild {
 		n.addChild("").addSegments(segs[1:], p, h)
 	} else {
 		n.addChild(seg.s).addSegments(segs[1:], p, h)
 	}
 }

 // set sets the pattern and handler for n, which
 // must be a leaf node.
 func (n *routingNode) set(p *pattern, h Handler) {
 	if n.pattern != nil || n.handler != nil {
 		panic("non-nil leaf fields")
 	}
 	n.pattern = p
 	n.handler = h
 }

 // addChild adds a child node with the given key to n
 // if one does not exist, and returns the child.
 func (n *routingNode) addChild(key string) *routingNode {
 	if key == "" {
 		if n.emptyChild == nil {
 			n.emptyChild = &routingNode{}
 		}
 		return n.emptyChild
 	}
 	if c := n.findChild(key); c != nil {
 		return c
 	}
 	c := &routingNode{}
 	n.children.add(key, c)
 	return c
 }

 // findChild returns the child of n with the given key, or nil
 // if there is no child with that key.
 func (n *routingNode) findChild(key string) *routingNode {
 	if key == "" {
 		return n.emptyChild
 	}
 	r, _ := n.children.find(key)
 	return r
 }

 // match returns the leaf node under root that matches the arguments, and a list
 // of values for pattern wildcards in the order that the wildcards appear.
 // For example, if the request path is "/a/b/c" and the pattern is "/{x}/b/{y}",
 // then the second return value will be []string{"a", "c"}.
 func (root *routingNode) match(host, method, path string) (*routingNode, []string) {
 	if host != "" {
 		// There is a host. If there is a pattern that specifies that host and it
 		// matches, we are done. If the pattern doesn't match, fall through to
 		// try patterns with no host.
 		if l, m := root.findChild(host).matchMethodAndPath(method, path); l != nil {
 			return l, m
 		}
 	}
 	return root.emptyChild.matchMethodAndPath(method, path)
 }

 // matchMethodAndPath matches the method and path.
 // Its return values are the same as [routingNode.match].
 // The receiver should be a child of the root.
 func (n *routingNode) matchMethodAndPath(method, path string) (*routingNode, []string) {
 	if n == nil {
 		return nil, nil
 	}
 	if l, m := n.findChild(method).matchPath(path, nil); l != nil {
 		// Exact match of method name.
 		return l, m
 	}
 	if method == "HEAD" {
 		// GET matches HEAD too.
 		if l, m := n.findChild("GET").matchPath(path, nil); l != nil {
 			return l, m
 		}
 	}
 	// No exact match; try patterns with no method.
 	return n.emptyChild.matchPath(path, nil)
 }

 // matchPath matches a path.
 // Its return values are the same as [routingNode.match].
 // matchPath calls itself recursively. The matches argument holds the wildcard matches
 // found so far.
 func (n *routingNode) matchPath(path string, matches []string) (*routingNode, []string) {
 	if n == nil {
 		return nil, nil
 	}
 	// If path is empty, then we are done.
 	// If n is a leaf node, we found a match; return it.
 	// If n is an interior node (which means it has a nil pattern),
 	// then we failed to match.
 	if path == "" {
 		if n.pattern == nil {
 			return nil, nil
 		}
 		return n, matches
 	}
 	// Get the first segment of path.
 	seg, rest := firstSegment(path)
 	// First try matching against patterns that have a literal for this position.
 	// We know by construction that such patterns are more specific than those
 	// with a wildcard at this position (they are either more specific, equivalent,
 	// or overlap, and we ruled out the first two when the patterns were registered).
 	if n, m := n.findChild(seg).matchPath(rest, matches); n != nil {
 		return n, m
 	}
 	// If matching a literal fails, try again with patterns that have a single
 	// wildcard (represented by an empty string in the child mapping).
 	// Again, by construction, patterns with a single wildcard must be more specific than
 	// those with a multi wildcard.
 	// We skip this step if the segment is a trailing slash, because single wildcards
 	// don't match trailing slashes.
 	if seg != "/" {
 		if n, m := n.emptyChild.matchPath(rest, append(matches, seg)); n != nil {
 			return n, m
 		}
 	}
 	// Lastly, match the pattern (there can be at most one) that has a multi
 	// wildcard in this position to the rest of the path.
 	if c := n.findChild("*"); c != nil {
 		// Don't record a match for a nameless wildcard (which arises from a
 		// trailing slash in the pattern).
 		if c.pattern.lastSegment().s != "" {
 			matches = append(matches, pathUnescape(path[1:])) // remove initial slash
 		}
 		return c, matches
 	}
 	return nil, nil
 }

 // firstSegment splits path into its first segment, and the rest.
 // The path must begin with "/".
 // If path consists of only a slash, firstSegment returns ("/", "").
 // The segment is returned unescaped, if possible.
 func firstSegment(path string) (seg, rest string) {
 	if path == "/" {
 		return "/", ""
 	}
 	path = path[1:] // drop initial slash
 	i := strings.IndexByte(path, '/')
 	if i < 0 {
 		i = len(path)
 	}
 	return pathUnescape(path[:i]), path[i:]
 }

 // matchingMethods adds to methodSet all the methods that would result in a
 // match if passed to routingNode.match with the given host and path.
 func (root *routingNode) matchingMethods(host, path string, methodSet map[string]bool) {
 	if host != "" {
 		root.findChild(host).matchingMethodsPath(path, methodSet)
 	}
 	root.emptyChild.matchingMethodsPath(path, methodSet)
 	if methodSet["GET"] {
 		methodSet["HEAD"] = true
 	}
 }

 func (n *routingNode) matchingMethodsPath(path string, set map[string]bool) {
 	if n == nil {
 		return
 	}
 	n.children.eachPair(func(method string, c *routingNode) bool {
 		if p, _ := c.matchPath(path, nil); p != nil {
 			set[method] = true
 		}
 		return true
 	})
 	// Don't look at the empty child. If there were an empty
 	// child, it would match on any method, but we only
 	// call this when we fail to match on a method.
 }
	// Copyright 2023 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	// This file implements a decision tree for fast matching of requests to
	// patterns.
	//
	// The root of the tree branches on the host of the request.
	// The next level branches on the method.
	// The remaining levels branch on consecutive segments of the path.
	//
	// The "more specific wins" precedence rule can result in backtracking.
	// For example, given the patterns
	// /a/b/z
	// /a/{x}/c
	// we will first try to match the path "/a/b/c" with /a/b/z, and
	// when that fails we will try against /a/{x}/c.

	package http

	import (
	"strings"
	)

	// A routingNode is a node in the decision tree.
	// The same struct is used for leaf and interior nodes.
	type routingNode struct {
	// A leaf node holds a single pattern and the Handler it was registered
	// with.
	pattern *pattern
	handler Handler

	// An interior node maps parts of the incoming request to child nodes.
	// special children keys:
	// "/" trailing slash (resulting from {$})
	// "" single wildcard
	// "*" multi wildcard
	children mapping[string, *routingNode]
	emptyChild *routingNode // optimization: child with key ""
	}

	// addPattern adds a pattern and its associated Handler to the tree
	// at root.
	func (root routingNode) addPattern(p pattern, h Handler) {
	// First level of tree is host.
	n := root.addChild(p.host)
	// Second level of tree is method.
	n = n.addChild(p.method)
	// Remaining levels are path.
	n.addSegments(p.segments, p, h)
	}

	// addSegments adds the given segments to the tree rooted at n.
	// If there are no segments, then n is a leaf node that holds
	// the given pattern and handler.
	func (n routingNode) addSegments(segs []segment, p pattern, h Handler) {
	if len(segs) == 0 {
	n.set(p, h)
	return
	}
	seg := segs[0]
	if seg.multi {
	if len(segs) != 1 {
	panic("multi wildcard not last")
	}
	n.addChild("*").set(p, h)
	} else if seg.wild {
	n.addChild("").addSegments(segs[1:], p, h)
	} else {
	n.addChild(seg.s).addSegments(segs[1:], p, h)
	}
	}

	// set sets the pattern and handler for n, which
	// must be a leaf node.
	func (n routingNode) set(p pattern, h Handler) {
	if n.pattern != nil \|\| n.handler != nil {
	panic("non-nil leaf fields")
	}
	n.pattern = p
	n.handler = h
	}

	// addChild adds a child node with the given key to n
	// if one does not exist, and returns the child.
	func (n routingNode) addChild(key string) routingNode {
	if key == "" {
	if n.emptyChild == nil {
	n.emptyChild = &routingNode{}
	}
	return n.emptyChild
	}
	if c := n.findChild(key); c != nil {
	return c
	}
	c := &routingNode{}
	n.children.add(key, c)
	return c
	}

	// findChild returns the child of n with the given key, or nil
	// if there is no child with that key.
	func (n routingNode) findChild(key string) routingNode {
	if key == "" {
	return n.emptyChild
	}
	r, _ := n.children.find(key)
	return r
	}

	// match returns the leaf node under root that matches the arguments, and a list
	// of values for pattern wildcards in the order that the wildcards appear.
	// For example, if the request path is "/a/b/c" and the pattern is "/{x}/b/{y}",
	// then the second return value will be []string{"a", "c"}.
	func (root routingNode) match(host, method, path string) (routingNode, []string) {
	if host != "" {
	// There is a host. If there is a pattern that specifies that host and it
	// matches, we are done. If the pattern doesn't match, fall through to
	// try patterns with no host.
	if l, m := root.findChild(host).matchMethodAndPath(method, path); l != nil {
	return l, m
	}
	}
	return root.emptyChild.matchMethodAndPath(method, path)
	}

	// matchMethodAndPath matches the method and path.
	// Its return values are the same as [routingNode.match].
	// The receiver should be a child of the root.
	func (n routingNode) matchMethodAndPath(method, path string) (routingNode, []string) {
	if n == nil {
	return nil, nil
	}
	if l, m := n.findChild(method).matchPath(path, nil); l != nil {
	// Exact match of method name.
	return l, m
	}
	if method == "HEAD" {
	// GET matches HEAD too.
	if l, m := n.findChild("GET").matchPath(path, nil); l != nil {
	return l, m
	}
	}
	// No exact match; try patterns with no method.
	return n.emptyChild.matchPath(path, nil)
	}

	// matchPath matches a path.
	// Its return values are the same as [routingNode.match].
	// matchPath calls itself recursively. The matches argument holds the wildcard matches
	// found so far.
	func (n routingNode) matchPath(path string, matches []string) (routingNode, []string) {
	if n == nil {
	return nil, nil
	}
	// If path is empty, then we are done.
	// If n is a leaf node, we found a match; return it.
	// If n is an interior node (which means it has a nil pattern),
	// then we failed to match.
	if path == "" {
	if n.pattern == nil {
	return nil, nil
	}
	return n, matches
	}
	// Get the first segment of path.
	seg, rest := firstSegment(path)
	// First try matching against patterns that have a literal for this position.
	// We know by construction that such patterns are more specific than those
	// with a wildcard at this position (they are either more specific, equivalent,
	// or overlap, and we ruled out the first two when the patterns were registered).
	if n, m := n.findChild(seg).matchPath(rest, matches); n != nil {
	return n, m
	}
	// If matching a literal fails, try again with patterns that have a single
	// wildcard (represented by an empty string in the child mapping).
	// Again, by construction, patterns with a single wildcard must be more specific than
	// those with a multi wildcard.
	// We skip this step if the segment is a trailing slash, because single wildcards
	// don't match trailing slashes.
	if seg != "/" {
	if n, m := n.emptyChild.matchPath(rest, append(matches, seg)); n != nil {
	return n, m
	}
	}
	// Lastly, match the pattern (there can be at most one) that has a multi
	// wildcard in this position to the rest of the path.
	if c := n.findChild("*"); c != nil {
	// Don't record a match for a nameless wildcard (which arises from a
	// trailing slash in the pattern).
	if c.pattern.lastSegment().s != "" {
	matches = append(matches, pathUnescape(path[1:])) // remove initial slash
	}
	return c, matches
	}
	return nil, nil
	}

	// firstSegment splits path into its first segment, and the rest.
	// The path must begin with "/".
	// If path consists of only a slash, firstSegment returns ("/", "").
	// The segment is returned unescaped, if possible.
	func firstSegment(path string) (seg, rest string) {
	if path == "/" {
	return "/", ""
	}
	path = path[1:] // drop initial slash
	i := strings.IndexByte(path, '/')
	if i < 0 {
	i = len(path)
	}
	return pathUnescape(path[:i]), path[i:]
	}

	// matchingMethods adds to methodSet all the methods that would result in a
	// match if passed to routingNode.match with the given host and path.
	func (root *routingNode) matchingMethods(host, path string, methodSet map[string]bool) {
	if host != "" {
	root.findChild(host).matchingMethodsPath(path, methodSet)
	}
	root.emptyChild.matchingMethodsPath(path, methodSet)
	if methodSet["GET"] {
	methodSet["HEAD"] = true
	}
	}

	func (n *routingNode) matchingMethodsPath(path string, set map[string]bool) {
	if n == nil {
	return
	}
	n.children.eachPair(func(method string, c *routingNode) bool {
	if p, _ := c.matchPath(path, nil); p != nil {
	set[method] = true
	}
	return true
	})
	// Don't look at the empty child. If there were an empty
	// child, it would match on any method, but we only
	// call this when we fail to match on a method.
	}