tools/flow/tasks.go - cue - Git at Google

 // Copyright 2020 CUE Authors
 //
 // 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 flow

 // This file contains functionality for identifying tasks in the configuration
 // and annotating the dependencies between them.

 import (
 	"cuelang.org/go/cue"
 	"cuelang.org/go/cue/errors"
 	"cuelang.org/go/internal"
 	"cuelang.org/go/internal/core/adt"
 	"cuelang.org/go/internal/core/dep"
 )

 // initTasks takes the current configuration and adds tasks to the list of
 // tasks. It can be run multiple times on increasingly more concrete
 // configurations to add more tasks, whereby the task pointers of previously
 // found tasks are preserved.
 func (c *Controller) initTasks() {
 	// Clear previous cache.
 	c.nodes = map[*adt.Vertex]*Task{}

 	v := c.inst.LookupPath(c.cfg.Root)
 	if err := v.Err(); err != nil {
 		c.addErr(err, "invalid root")
 		c.cancel()
 		return
 	}

 	// Mark any task that is located under the root.
 	c.findRootTasks(v)

 	// Mark any tasks that are implied by dependencies.
 	// Note that the list of tasks may grow as this loop progresses.
 	for i := 0; i < len(c.tasks); i++ {
 		t := c.tasks[i]
 		c.markTaskDependencies(t, t.vertex())
 	}

 	// Check if there are cycles in the task dependencies.
 	if err := checkCycle(c.tasks); err != nil {
 		c.addErr(err, "cyclic task")
 	}

 	if c.errs != nil {
 		c.cancel()
 	}
 }

 // findRootTasks finds tasks under the root.
 func (c *Controller) findRootTasks(v cue.Value) {
 	t := c.getTask(nil, v)

 	if t != nil {
 		return
 	}

 	for iter, _ := v.Fields(); iter.Next(); {
 		c.findRootTasks(iter.Value())
 	}
 }

 // This file contains the functionality to locate and record the tasks of
 // a configuration. It:
 //   - create Task struct for each node that is a task
 //   - associate nodes in a configuration with a Task, if applicable.
 // The node-to-task map is used to determine task dependencies.

 // getTask finds and marks tasks that are descendents of v.
 func (c *Controller) getTask(scope *Task, v cue.Value) *Task {
 	// Look up cached node.
 	_, n := internal.CoreValue(v)
 	w := n.(*adt.Vertex)
 	if t, ok := c.nodes[w]; ok {
 		return t
 	}

 	// Look up cached task from previous evaluation.
 	p := v.Path()
 	key := p.String()

 	t := c.keys[key]

 	if t == nil {
 		r, err := c.isTask(v)

 		var errs errors.Error
 		if err != nil {
 			if !c.inRoot(w) {
 				// Must be in InferTask mode. In this case we ignore the error.
 				r = nil
 			} else {
 				c.addErr(err, "invalid task")
 				errs = errors.Promote(err, "create task")
 			}
 		}

 		if r != nil {
 			index := len(c.tasks)
 			t = &Task{
 				v:      v,
 				c:      c,
 				r:      r,
 				path:   p,
 				labels: w.Path(),
 				key:    key,
 				index:  index,
 				err:    errs,
 			}
 			c.tasks = append(c.tasks, t)
 			c.keys[key] = t
 		}
 	}

 	// Process nodes of task for this evaluation.
 	if t != nil {
 		scope = t
 		if t.state <= Ready {
 			// Don't set the value if the task is currently running as this may
 			// result in all kinds of inconsistency issues.
 			t.v = v
 		}

 		c.tagChildren(w, t)
 	}

 	c.nodes[w] = scope

 	return t
 }

 func (c *Controller) tagChildren(n *adt.Vertex, t *Task) {
 	for _, a := range n.Arcs {
 		c.nodes[a] = t
 		c.tagChildren(a, t)
 	}
 }

 // findImpliedTask determines the task of corresponding to node n, if any. If n
 // is not already associated with a task, it tries to determine whether n is
 // part of a task by checking if any of the parent nodes is a task.
 //
 // TODO: it is actually more accurate to check for tasks from top down. TODO:
 // What should be done if a subtasks is referenced that is embedded in another
 // task. Should the surrounding tasks be added as well?
 func (c *Controller) findImpliedTask(d dep.Dependency) *Task {
 	// Ignore references into packages. Fill will fundamentally not work for
 	// packages, and packages cannot point back to the main package as cycles
 	// are not allowed.
 	if d.Import() != nil {
 		return nil
 	}

 	n := d.Node

 	// This Finalize should not be necessary, as the input to dep is already
 	// finalized. However, cue cmd uses some legacy instance stitching code
 	// where some of the backlink Environments are not properly initialized.
 	// Finalizing should patch those up at the expense of doing some duplicate
 	// work. The plan is to replace `cue cmd` with a much more clean
 	// implementation (probably a separate tool called `cuerun`) where this
 	// issue is fixed. For now we leave this patch.
 	//
 	// Note that this issue predates package flow, but that it just surfaced in
 	// flow and having a different evaluation order.
 	//
 	// Note: this call is cheap if n is already Finalized.
 	n.Finalize(c.opCtx)

 	for ; n != nil; n = n.Parent {
 		if c.cfg.IgnoreConcrete && n.IsConcrete() {
 			if k := n.BaseValue.Kind(); k != adt.StructKind && k != adt.ListKind {
 				return nil
 			}
 		}

 		t, ok := c.nodes[n]
 		if ok || !c.cfg.InferTasks {
 			return t
 		}

 		if !d.IsRoot() {
 			v := cue.MakeValue(c.opCtx, n)

 			if t := c.getTask(nil, v); t != nil {
 				return t
 			}
 		}
 	}

 	return nil
 }

 // markTaskDependencies traces through all conjuncts of a Task and marks
 // any dependencies on other tasks.
 //
 // The dependencies for a node by traversing the nodes of a task and then
 // traversing the dependencies of the conjuncts.
 //
 // This terminates because:
 //
 //  - traversing all nodes of all tasks is guaranteed finite (CUE does not
 //    evaluate to infinite structure).
 //
 //  - traversing conjuncts of all nodes is finite, as the input syntax is
 //    inherently finite.
 //
 //  - as regular nodes are traversed recursively they are marked with a cycle
 //    marker to detect cycles, ensuring a finite traversal as well.
 //
 func (c *Controller) markTaskDependencies(t *Task, n *adt.Vertex) {
 	dep.VisitFields(c.opCtx, n, func(d dep.Dependency) error {
 		depTask := c.findImpliedTask(d)
 		if depTask != nil {
 			if depTask != cycleMarker {
 				v := cue.MakeValue(c.opCtx, d.Node)
 				t.addDep(v.Path().String(), depTask)
 			}
 			return nil
 		}

 		// If this points to a non-task node, it may itself point to a task.
 		// Handling this allows for dynamic references. For instance, such a
 		// value may reference the result value of a task, or even create
 		// new tasks based on the result of another task.
 		if d.Import() == nil {
 			c.nodes[d.Node] = cycleMarker
 			c.markTaskDependencies(t, d.Node)
 			c.nodes[d.Node] = nil
 		}
 		return nil
 	})
 }

 func (c *Controller) inRoot(n *adt.Vertex) bool {
 	path := cue.MakeValue(c.opCtx, n).Path().Selectors()
 	root := c.cfg.Root.Selectors()
 	if len(path) < len(root) {
 		return false
 	}
 	for i, sel := range root {
 		if path[i] != sel {
 			return false
 		}
 	}
 	return true
 }

 var cycleMarker = &Task{}
	// Copyright 2020 CUE Authors
	//
	// 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 flow

	// This file contains functionality for identifying tasks in the configuration
	// and annotating the dependencies between them.

	import (
	"cuelang.org/go/cue"
	"cuelang.org/go/cue/errors"
	"cuelang.org/go/internal"
	"cuelang.org/go/internal/core/adt"
	"cuelang.org/go/internal/core/dep"
	)

	// initTasks takes the current configuration and adds tasks to the list of
	// tasks. It can be run multiple times on increasingly more concrete
	// configurations to add more tasks, whereby the task pointers of previously
	// found tasks are preserved.
	func (c *Controller) initTasks() {
	// Clear previous cache.
	c.nodes = map[adt.Vertex]Task{}

	v := c.inst.LookupPath(c.cfg.Root)
	if err := v.Err(); err != nil {
	c.addErr(err, "invalid root")
	c.cancel()
	return
	}

	// Mark any task that is located under the root.
	c.findRootTasks(v)

	// Mark any tasks that are implied by dependencies.
	// Note that the list of tasks may grow as this loop progresses.
	for i := 0; i < len(c.tasks); i++ {
	t := c.tasks[i]
	c.markTaskDependencies(t, t.vertex())
	}

	// Check if there are cycles in the task dependencies.
	if err := checkCycle(c.tasks); err != nil {
	c.addErr(err, "cyclic task")
	}

	if c.errs != nil {
	c.cancel()
	}
	}

	// findRootTasks finds tasks under the root.
	func (c *Controller) findRootTasks(v cue.Value) {
	t := c.getTask(nil, v)

	if t != nil {
	return
	}

	for iter, _ := v.Fields(); iter.Next(); {
	c.findRootTasks(iter.Value())
	}
	}

	// This file contains the functionality to locate and record the tasks of
	// a configuration. It:
	// - create Task struct for each node that is a task
	// - associate nodes in a configuration with a Task, if applicable.
	// The node-to-task map is used to determine task dependencies.

	// getTask finds and marks tasks that are descendents of v.
	func (c Controller) getTask(scope Task, v cue.Value) *Task {
	// Look up cached node.
	_, n := internal.CoreValue(v)
	w := n.(*adt.Vertex)
	if t, ok := c.nodes[w]; ok {
	return t
	}

	// Look up cached task from previous evaluation.
	p := v.Path()
	key := p.String()

	t := c.keys[key]

	if t == nil {
	r, err := c.isTask(v)

	var errs errors.Error
	if err != nil {
	if !c.inRoot(w) {
	// Must be in InferTask mode. In this case we ignore the error.
	r = nil
	} else {
	c.addErr(err, "invalid task")
	errs = errors.Promote(err, "create task")
	}
	}

	if r != nil {
	index := len(c.tasks)
	t = &Task{
	v: v,
	c: c,
	r: r,
	path: p,
	labels: w.Path(),
	key: key,
	index: index,
	err: errs,
	}
	c.tasks = append(c.tasks, t)
	c.keys[key] = t
	}
	}

	// Process nodes of task for this evaluation.
	if t != nil {
	scope = t
	if t.state <= Ready {
	// Don't set the value if the task is currently running as this may
	// result in all kinds of inconsistency issues.
	t.v = v
	}

	c.tagChildren(w, t)
	}

	c.nodes[w] = scope

	return t
	}

	func (c Controller) tagChildren(n adt.Vertex, t *Task) {
	for _, a := range n.Arcs {
	c.nodes[a] = t
	c.tagChildren(a, t)
	}
	}

	// findImpliedTask determines the task of corresponding to node n, if any. If n
	// is not already associated with a task, it tries to determine whether n is
	// part of a task by checking if any of the parent nodes is a task.
	//
	// TODO: it is actually more accurate to check for tasks from top down. TODO:
	// What should be done if a subtasks is referenced that is embedded in another
	// task. Should the surrounding tasks be added as well?
	func (c Controller) findImpliedTask(d dep.Dependency) Task {
	// Ignore references into packages. Fill will fundamentally not work for
	// packages, and packages cannot point back to the main package as cycles
	// are not allowed.
	if d.Import() != nil {
	return nil
	}

	n := d.Node

	// This Finalize should not be necessary, as the input to dep is already
	// finalized. However, cue cmd uses some legacy instance stitching code
	// where some of the backlink Environments are not properly initialized.
	// Finalizing should patch those up at the expense of doing some duplicate
	// work. The plan is to replace `cue cmd` with a much more clean
	// implementation (probably a separate tool called `cuerun`) where this
	// issue is fixed. For now we leave this patch.
	//
	// Note that this issue predates package flow, but that it just surfaced in
	// flow and having a different evaluation order.
	//
	// Note: this call is cheap if n is already Finalized.
	n.Finalize(c.opCtx)

	for ; n != nil; n = n.Parent {
	if c.cfg.IgnoreConcrete && n.IsConcrete() {
	if k := n.BaseValue.Kind(); k != adt.StructKind && k != adt.ListKind {
	return nil
	}
	}

	t, ok := c.nodes[n]
	if ok \|\| !c.cfg.InferTasks {
	return t
	}

	if !d.IsRoot() {
	v := cue.MakeValue(c.opCtx, n)

	if t := c.getTask(nil, v); t != nil {
	return t
	}
	}
	}

	return nil
	}

	// markTaskDependencies traces through all conjuncts of a Task and marks
	// any dependencies on other tasks.
	//
	// The dependencies for a node by traversing the nodes of a task and then
	// traversing the dependencies of the conjuncts.
	//
	// This terminates because:
	//
	// - traversing all nodes of all tasks is guaranteed finite (CUE does not
	// evaluate to infinite structure).
	//
	// - traversing conjuncts of all nodes is finite, as the input syntax is
	// inherently finite.
	//
	// - as regular nodes are traversed recursively they are marked with a cycle
	// marker to detect cycles, ensuring a finite traversal as well.
	//
	func (c Controller) markTaskDependencies(t Task, n *adt.Vertex) {
	dep.VisitFields(c.opCtx, n, func(d dep.Dependency) error {
	depTask := c.findImpliedTask(d)
	if depTask != nil {
	if depTask != cycleMarker {
	v := cue.MakeValue(c.opCtx, d.Node)
	t.addDep(v.Path().String(), depTask)
	}
	return nil
	}

	// If this points to a non-task node, it may itself point to a task.
	// Handling this allows for dynamic references. For instance, such a
	// value may reference the result value of a task, or even create
	// new tasks based on the result of another task.
	if d.Import() == nil {
	c.nodes[d.Node] = cycleMarker
	c.markTaskDependencies(t, d.Node)
	c.nodes[d.Node] = nil
	}
	return nil
	})
	}

	func (c Controller) inRoot(n adt.Vertex) bool {
	path := cue.MakeValue(c.opCtx, n).Path().Selectors()
	root := c.cfg.Root.Selectors()
	if len(path) < len(root) {
	return false
	}
	for i, sel := range root {
	if path[i] != sel {
	return false
	}
	}
	return true
	}

	var cycleMarker = &Task{}