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terraform/terraform/context.go

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package terraform
import (
"fmt"
"log"
"sort"
"sync"
"github.com/hashicorp/go-multierror"
"github.com/hashicorp/terraform/config"
"github.com/hashicorp/terraform/config/module"
)
// InputMode defines what sort of input will be asked for when Input
// is called on Context.
type InputMode byte
const (
// InputModeVar asks for all variables
InputModeVar InputMode = 1 << iota
// InputModeVarUnset asks for variables which are not set yet
InputModeVarUnset
// InputModeProvider asks for provider variables
InputModeProvider
// InputModeStd is the standard operating mode and asks for both variables
// and providers.
InputModeStd = InputModeVar | InputModeProvider
)
// ContextOpts are the user-configurable options to create a context with
// NewContext.
type ContextOpts struct {
Destroy bool
Diff *Diff
Hooks []Hook
Module *module.Tree
Parallelism int
State *State
Providers map[string]ResourceProviderFactory
Provisioners map[string]ResourceProvisionerFactory
Targets []string
Variables map[string]string
UIInput UIInput
}
// Context represents all the context that Terraform needs in order to
// perform operations on infrastructure. This structure is built using
// NewContext. See the documentation for that.
type Context struct {
destroy bool
diff *Diff
diffLock sync.RWMutex
hooks []Hook
module *module.Tree
providers map[string]ResourceProviderFactory
provisioners map[string]ResourceProvisionerFactory
sh *stopHook
state *State
stateLock sync.RWMutex
targets []string
uiInput UIInput
variables map[string]string
l sync.Mutex // Lock acquired during any task
parallelSem Semaphore
providerInputConfig map[string]map[string]interface{}
runCh <-chan struct{}
}
// NewContext creates a new Context structure.
//
// Once a Context is creator, the pointer values within ContextOpts
// should not be mutated in any way, since the pointers are copied, not
// the values themselves.
func NewContext(opts *ContextOpts) *Context {
// Copy all the hooks and add our stop hook. We don't append directly
// to the Config so that we're not modifying that in-place.
sh := new(stopHook)
hooks := make([]Hook, len(opts.Hooks)+1)
copy(hooks, opts.Hooks)
hooks[len(opts.Hooks)] = sh
state := opts.State
if state == nil {
state = new(State)
state.init()
}
// Determine parallelism, default to 10. We do this both to limit
// CPU pressure but also to have an extra guard against rate throttling
// from providers.
par := opts.Parallelism
if par == 0 {
par = 10
}
return &Context{
destroy: opts.Destroy,
diff: opts.Diff,
hooks: hooks,
module: opts.Module,
providers: opts.Providers,
provisioners: opts.Provisioners,
state: state,
targets: opts.Targets,
uiInput: opts.UIInput,
variables: opts.Variables,
parallelSem: NewSemaphore(par),
providerInputConfig: make(map[string]map[string]interface{}),
sh: sh,
}
}
// Graph returns the graph for this config.
func (c *Context) Graph() (*Graph, error) {
return c.GraphBuilder().Build(RootModulePath)
}
// GraphBuilder returns the GraphBuilder that will be used to create
// the graphs for this context.
func (c *Context) GraphBuilder() GraphBuilder {
// TODO test
providers := make([]string, 0, len(c.providers))
for k, _ := range c.providers {
providers = append(providers, k)
}
provisioners := make([]string, 0, len(c.provisioners))
for k, _ := range c.provisioners {
provisioners = append(provisioners, k)
}
return &BuiltinGraphBuilder{
Root: c.module,
Diff: c.diff,
Providers: providers,
Provisioners: provisioners,
State: c.state,
Targets: c.targets,
Destroy: c.destroy,
}
}
// Input asks for input to fill variables and provider configurations.
// This modifies the configuration in-place, so asking for Input twice
// may result in different UI output showing different current values.
func (c *Context) Input(mode InputMode) error {
v := c.acquireRun()
defer c.releaseRun(v)
if mode&InputModeVar != 0 {
// Walk the variables first for the root module. We walk them in
// alphabetical order for UX reasons.
rootConf := c.module.Config()
names := make([]string, len(rootConf.Variables))
m := make(map[string]*config.Variable)
for i, v := range rootConf.Variables {
names[i] = v.Name
m[v.Name] = v
}
sort.Strings(names)
for _, n := range names {
// If we only care about unset variables, then if the variabel
// is set, continue on.
if mode&InputModeVarUnset != 0 {
if _, ok := c.variables[n]; ok {
continue
}
}
v := m[n]
switch v.Type() {
case config.VariableTypeMap:
continue
case config.VariableTypeString:
// Good!
default:
panic(fmt.Sprintf("Unknown variable type: %#v", v.Type()))
}
var defaultString string
if v.Default != nil {
defaultString = v.Default.(string)
}
// Ask the user for a value for this variable
var value string
for {
var err error
value, err = c.uiInput.Input(&InputOpts{
Id: fmt.Sprintf("var.%s", n),
Query: fmt.Sprintf("var.%s", n),
Default: defaultString,
Description: v.Description,
})
if err != nil {
return fmt.Errorf(
"Error asking for %s: %s", n, err)
}
if value == "" && v.Required() {
// Redo if it is required.
continue
}
if value == "" {
// No value, just exit the loop. With no value, we just
// use whatever is currently set in variables.
break
}
break
}
if value != "" {
c.variables[n] = value
}
}
}
if mode&InputModeProvider != 0 {
// Do the walk
if _, err := c.walk(walkInput); err != nil {
return err
}
}
return nil
}
// Apply applies the changes represented by this context and returns
// the resulting state.
//
// In addition to returning the resulting state, this context is updated
// with the latest state.
func (c *Context) Apply() (*State, error) {
v := c.acquireRun()
defer c.releaseRun(v)
// Copy our own state
c.state = c.state.DeepCopy()
// Do the walk
_, err := c.walk(walkApply)
// Clean out any unused things
c.state.prune()
return c.state, err
}
// Plan generates an execution plan for the given context.
//
// The execution plan encapsulates the context and can be stored
// in order to reinstantiate a context later for Apply.
//
// Plan also updates the diff of this context to be the diff generated
// by the plan, so Apply can be called after.
func (c *Context) Plan() (*Plan, error) {
v := c.acquireRun()
defer c.releaseRun(v)
p := &Plan{
Module: c.module,
Vars: c.variables,
State: c.state,
}
var operation walkOperation
if c.destroy {
operation = walkPlanDestroy
} else {
// Set our state to be something temporary. We do this so that
// the plan can update a fake state so that variables work, then
// we replace it back with our old state.
old := c.state
if old == nil {
c.state = &State{}
c.state.init()
} else {
c.state = old.DeepCopy()
}
defer func() {
c.state = old
}()
operation = walkPlan
}
// Setup our diff
c.diffLock.Lock()
c.diff = new(Diff)
c.diff.init()
c.diffLock.Unlock()
// Do the walk
if _, err := c.walk(operation); err != nil {
return nil, err
}
p.Diff = c.diff
return p, nil
}
// Refresh goes through all the resources in the state and refreshes them
// to their latest state. This will update the state that this context
// works with, along with returning it.
//
// Even in the case an error is returned, the state will be returned and
// will potentially be partially updated.
func (c *Context) Refresh() (*State, error) {
v := c.acquireRun()
defer c.releaseRun(v)
// Copy our own state
c.state = c.state.DeepCopy()
// Do the walk
if _, err := c.walk(walkRefresh); err != nil {
return nil, err
}
// Clean out any unused things
c.state.prune()
return c.state, nil
}
// Stop stops the running task.
//
// Stop will block until the task completes.
func (c *Context) Stop() {
c.l.Lock()
ch := c.runCh
// If we aren't running, then just return
if ch == nil {
c.l.Unlock()
return
}
// Tell the hook we want to stop
c.sh.Stop()
// Wait for us to stop
c.l.Unlock()
<-ch
}
// Validate validates the configuration and returns any warnings or errors.
func (c *Context) Validate() ([]string, []error) {
v := c.acquireRun()
defer c.releaseRun(v)
var errs error
// Validate the configuration itself
if err := c.module.Validate(); err != nil {
errs = multierror.Append(errs, err)
}
// This only needs to be done for the root module, since inter-module
// variables are validated in the module tree.
if config := c.module.Config(); config != nil {
// Validate the user variables
if err := smcUserVariables(config, c.variables); len(err) > 0 {
errs = multierror.Append(errs, err...)
}
}
// Walk
walker, err := c.walk(walkValidate)
if err != nil {
return nil, multierror.Append(errs, err).Errors
}
// Return the result
rerrs := multierror.Append(errs, walker.ValidationErrors...)
return walker.ValidationWarnings, rerrs.Errors
}
// Module returns the module tree associated with this context.
func (c *Context) Module() *module.Tree {
return c.module
}
// Variables will return the mapping of variables that were defined
// for this Context. If Input was called, this mapping may be different
// than what was given.
func (c *Context) Variables() map[string]string {
return c.variables
}
// SetVariable sets a variable after a context has already been built.
func (c *Context) SetVariable(k, v string) {
c.variables[k] = v
}
func (c *Context) acquireRun() chan<- struct{} {
c.l.Lock()
defer c.l.Unlock()
// Wait for no channel to exist
for c.runCh != nil {
c.l.Unlock()
ch := c.runCh
<-ch
c.l.Lock()
}
ch := make(chan struct{})
c.runCh = ch
return ch
}
func (c *Context) releaseRun(ch chan<- struct{}) {
c.l.Lock()
defer c.l.Unlock()
close(ch)
c.runCh = nil
c.sh.Reset()
}
func (c *Context) walk(operation walkOperation) (*ContextGraphWalker, error) {
// Build the graph
graph, err := c.GraphBuilder().Build(RootModulePath)
if err != nil {
return nil, err
}
// Walk the graph
log.Printf("[INFO] Starting graph walk: %s", operation.String())
walker := &ContextGraphWalker{Context: c, Operation: operation}
return walker, graph.Walk(walker)
}
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