metropolis/pkg/logtree/logtree.go - monogon - Gitiles

 // Copyright 2020 The Monogon Project Authors.
 //
 // SPDX-License-Identifier: Apache-2.0
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 package logtree

 import (
 	"fmt"
 	"strings"
 	"sync"

 	"source.monogon.dev/metropolis/pkg/logbuffer"
 )

 // LogTree is a tree-shaped logging system. For more information, see the package-level documentation.
 type LogTree struct {
 	// journal is the tree's journal, storing all log data and managing subscribers.
 	journal *journal
 	// root is the root node of the actual tree of the log tree. The nodes contain per-DN configuration options, notably
 	// the current verbosity level of that DN.
 	root *node
 }

 func New() *LogTree {
 	lt := &LogTree{
 		journal: newJournal(),
 	}
 	lt.root = newNode(lt, "")
 	return lt
 }

 // node represents a given DN as a discrete 'logger'. It implements the LeveledLogger interface for log publishing,
 // entries from which it passes over to the logtree's journal.
 type node struct {
 	// dn is the DN which this node represents (or "" if this is the root node).
 	dn DN
 	// tree is the LogTree to which this node belongs.
 	tree *LogTree
 	// verbosity is the current verbosity level of this DN/node, affecting .V(n) LeveledLogger calls
 	verbosity     VerbosityLevel
 	rawLineBuffer *logbuffer.LineBuffer

 	// mu guards children.
 	mu sync.Mutex
 	// children is a map of DN-part to a children node in the logtree. A DN-part is a string representing a part of the
 	// DN between the deliming dots, as returned by DN.Path.
 	children map[string]*node
 }

 // newNode returns a node at a given DN in the LogTree - but doesn't set up the LogTree to insert it accordingly.
 func newNode(tree *LogTree, dn DN) *node {
 	n := &node{
 		dn:       dn,
 		tree:     tree,
 		children: make(map[string]*node),
 	}
 	// TODO(q3k): make this limit configurable. If this happens, or the default (1024) gets changes, max chunk size
 	// calculations when serving the logs (eg. in NodeDebugService) must reflect this.
 	n.rawLineBuffer = logbuffer.NewLineBuffer(1024, n.logRaw)
 	return n
 }

 // nodeByDN returns the LogTree node corresponding to a given DN. If either the node or some of its parents do not
 // exist they will be created as needed.
 func (l *LogTree) nodeByDN(dn DN) (*node, error) {
 	traversal, err := newTraversal(dn)
 	if err != nil {
 		return nil, fmt.Errorf("traversal failed: %w", err)
 	}
 	return traversal.execute(l.root), nil
 }

 // nodeTraversal represents a request to traverse the LogTree in search of a given node by DN.
 type nodeTraversal struct {
 	// want is the DN of the node's that requested to be found.
 	want DN
 	// current is the path already taken to find the node, in the form of DN parts. It starts out as want.Parts() and
 	// progresses to become empty as the traversal continues.
 	current []string
 	// left is the path that's still needed to be taken in order to find the node, in the form of DN parts. It starts
 	// out empty and progresses to become wants.Parts() as the traversal continues.
 	left []string
 }

 // next adjusts the traversal's current/left slices to the next element of the traversal, returns the part that's now
 // being looked for (or "" if the traveral is done) and the full DN of the element that's being looked for.
 //
 // For example, a traversal of foo.bar.baz will cause .next() to return the following on each invocation:
 //  - part: foo, full: foo
 //  - part: bar, full: foo.bar
 //  - part: baz, full: foo.bar.baz
 //  - part: "",  full: foo.bar.baz
 func (t *nodeTraversal) next() (part string, full DN) {
 	if len(t.left) == 0 {
 		return "", t.want
 	}
 	part = t.left[0]
 	t.current = append(t.current, part)
 	t.left = t.left[1:]
 	full = DN(strings.Join(t.current, "."))
 	return
 }

 // newTraversal returns a nodeTraversal fora a given wanted DN.
 func newTraversal(dn DN) (*nodeTraversal, error) {
 	parts, err := dn.Path()
 	if err != nil {
 		return nil, err
 	}
 	return &nodeTraversal{
 		want: dn,
 		left: parts,
 	}, nil
 }

 // execute the traversal in order to find the node. This can only be called once per traversal.
 // Nodes will be created within the tree until the target node is reached. Existing nodes will be reused.
 // This is effectively an idempotent way of accessing a node in the tree based on a traversal.
 func (t *nodeTraversal) execute(n *node) *node {
 	cur := n
 	for {
 		part, full := t.next()
 		if part == "" {
 			return cur
 		}

 		mu := &cur.mu
 		mu.Lock()
 		if _, ok := cur.children[part]; !ok {
 			cur.children[part] = newNode(n.tree, DN(full))
 		}
 		cur = cur.children[part]
 		mu.Unlock()
 	}
 }
	// Copyright 2020 The Monogon Project Authors.
	//
	// SPDX-License-Identifier: Apache-2.0
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	package logtree

	import (
	"fmt"
	"strings"
	"sync"

	"source.monogon.dev/metropolis/pkg/logbuffer"
	)

	// LogTree is a tree-shaped logging system. For more information, see the package-level documentation.
	type LogTree struct {
	// journal is the tree's journal, storing all log data and managing subscribers.
	journal *journal
	// root is the root node of the actual tree of the log tree. The nodes contain per-DN configuration options, notably
	// the current verbosity level of that DN.
	root *node
	}

	func New() *LogTree {
	lt := &LogTree{
	journal: newJournal(),
	}
	lt.root = newNode(lt, "")
	return lt
	}

	// node represents a given DN as a discrete 'logger'. It implements the LeveledLogger interface for log publishing,
	// entries from which it passes over to the logtree's journal.
	type node struct {
	// dn is the DN which this node represents (or "" if this is the root node).
	dn DN
	// tree is the LogTree to which this node belongs.
	tree *LogTree
	// verbosity is the current verbosity level of this DN/node, affecting .V(n) LeveledLogger calls
	verbosity VerbosityLevel
	rawLineBuffer *logbuffer.LineBuffer

	// mu guards children.
	mu sync.Mutex
	// children is a map of DN-part to a children node in the logtree. A DN-part is a string representing a part of the
	// DN between the deliming dots, as returned by DN.Path.
	children map[string]*node
	}

	// newNode returns a node at a given DN in the LogTree - but doesn't set up the LogTree to insert it accordingly.
	func newNode(tree LogTree, dn DN) node {
	n := &node{
	dn: dn,
	tree: tree,
	children: make(map[string]*node),
	}
	// TODO(q3k): make this limit configurable. If this happens, or the default (1024) gets changes, max chunk size
	// calculations when serving the logs (eg. in NodeDebugService) must reflect this.
	n.rawLineBuffer = logbuffer.NewLineBuffer(1024, n.logRaw)
	return n
	}

	// nodeByDN returns the LogTree node corresponding to a given DN. If either the node or some of its parents do not
	// exist they will be created as needed.
	func (l LogTree) nodeByDN(dn DN) (node, error) {
	traversal, err := newTraversal(dn)
	if err != nil {
	return nil, fmt.Errorf("traversal failed: %w", err)
	}
	return traversal.execute(l.root), nil
	}

	// nodeTraversal represents a request to traverse the LogTree in search of a given node by DN.
	type nodeTraversal struct {
	// want is the DN of the node's that requested to be found.
	want DN
	// current is the path already taken to find the node, in the form of DN parts. It starts out as want.Parts() and
	// progresses to become empty as the traversal continues.
	current []string
	// left is the path that's still needed to be taken in order to find the node, in the form of DN parts. It starts
	// out empty and progresses to become wants.Parts() as the traversal continues.
	left []string
	}

	// next adjusts the traversal's current/left slices to the next element of the traversal, returns the part that's now
	// being looked for (or "" if the traveral is done) and the full DN of the element that's being looked for.
	//
	// For example, a traversal of foo.bar.baz will cause .next() to return the following on each invocation:
	// - part: foo, full: foo
	// - part: bar, full: foo.bar
	// - part: baz, full: foo.bar.baz
	// - part: "", full: foo.bar.baz
	func (t *nodeTraversal) next() (part string, full DN) {
	if len(t.left) == 0 {
	return "", t.want
	}
	part = t.left[0]
	t.current = append(t.current, part)
	t.left = t.left[1:]
	full = DN(strings.Join(t.current, "."))
	return
	}

	// newTraversal returns a nodeTraversal fora a given wanted DN.
	func newTraversal(dn DN) (*nodeTraversal, error) {
	parts, err := dn.Path()
	if err != nil {
	return nil, err
	}
	return &nodeTraversal{
	want: dn,
	left: parts,
	}, nil
	}

	// execute the traversal in order to find the node. This can only be called once per traversal.
	// Nodes will be created within the tree until the target node is reached. Existing nodes will be reused.
	// This is effectively an idempotent way of accessing a node in the tree based on a traversal.
	func (t nodeTraversal) execute(n node) *node {
	cur := n
	for {
	part, full := t.next()
	if part == "" {
	return cur
	}

	mu := &cur.mu
	mu.Lock()
	if _, ok := cur.children[part]; !ok {
	cur.children[part] = newNode(n.tree, DN(full))
	}
	cur = cur.children[part]
	mu.Unlock()
	}
	}