opentofu/internal/command/format/diff.go
Alisdair McDiarmid 5fc3ba37a6 cli: Improve sensitivity change warning output
When an attribute value changes in sensitivity, we previously rendered
this in the diff with a `~` update action and a note about the
consequence of the sensitivity change. Since we also suppress the
attribute value, this made it impossible to know if the underlying value
was changing, too, which has significant consequences on the meaning of
the plan.

This commit adds an equality check of the old/new underlying values. If
these are unchanged, we add a note to the sensitivity warning to clarify
that only sensitivity is changing.
2021-05-18 10:33:25 -04:00

1997 lines
60 KiB
Go

package format
import (
"bufio"
"bytes"
"fmt"
"log"
"sort"
"strings"
"github.com/mitchellh/colorstring"
"github.com/zclconf/go-cty/cty"
ctyjson "github.com/zclconf/go-cty/cty/json"
"github.com/hashicorp/terraform/internal/addrs"
"github.com/hashicorp/terraform/internal/configs/configschema"
"github.com/hashicorp/terraform/internal/plans"
"github.com/hashicorp/terraform/internal/plans/objchange"
"github.com/hashicorp/terraform/internal/states"
)
// ResourceChange returns a string representation of a change to a particular
// resource, for inclusion in user-facing plan output.
//
// The resource schema must be provided along with the change so that the
// formatted change can reflect the configuration structure for the associated
// resource.
//
// If "color" is non-nil, it will be used to color the result. Otherwise,
// no color codes will be included.
func ResourceChange(
change *plans.ResourceInstanceChangeSrc,
schema *configschema.Block,
color *colorstring.Colorize,
) string {
addr := change.Addr
var buf bytes.Buffer
if color == nil {
color = &colorstring.Colorize{
Colors: colorstring.DefaultColors,
Disable: true,
Reset: false,
}
}
dispAddr := addr.String()
if change.DeposedKey != states.NotDeposed {
dispAddr = fmt.Sprintf("%s (deposed object %s)", dispAddr, change.DeposedKey)
}
switch change.Action {
case plans.Create:
buf.WriteString(color.Color(fmt.Sprintf("[bold] # %s[reset] will be created", dispAddr)))
case plans.Read:
buf.WriteString(color.Color(fmt.Sprintf("[bold] # %s[reset] will be read during apply\n # (config refers to values not yet known)", dispAddr)))
case plans.Update:
buf.WriteString(color.Color(fmt.Sprintf("[bold] # %s[reset] will be updated in-place", dispAddr)))
case plans.CreateThenDelete, plans.DeleteThenCreate:
switch change.ActionReason {
case plans.ResourceInstanceReplaceBecauseTainted:
buf.WriteString(color.Color(fmt.Sprintf("[bold] # %s[reset] is tainted, so must be [bold][red]replaced", dispAddr)))
case plans.ResourceInstanceReplaceByRequest:
buf.WriteString(color.Color(fmt.Sprintf("[bold] # %s[reset] will be [bold][red]replaced[reset], as requested", dispAddr)))
default:
buf.WriteString(color.Color(fmt.Sprintf("[bold] # %s[reset] must be [bold][red]replaced", dispAddr)))
}
case plans.Delete:
buf.WriteString(color.Color(fmt.Sprintf("[bold] # %s[reset] will be [bold][red]destroyed", dispAddr)))
if change.DeposedKey != states.NotDeposed {
// Some extra context about this unusual situation.
buf.WriteString(color.Color(fmt.Sprint("\n # (left over from a partially-failed replacement of this instance)")))
}
default:
// should never happen, since the above is exhaustive
buf.WriteString(fmt.Sprintf("%s has an action the plan renderer doesn't support (this is a bug)", dispAddr))
}
buf.WriteString(color.Color("[reset]\n"))
buf.WriteString(color.Color(DiffActionSymbol(change.Action)) + " ")
switch addr.Resource.Resource.Mode {
case addrs.ManagedResourceMode:
buf.WriteString(fmt.Sprintf(
"resource %q %q",
addr.Resource.Resource.Type,
addr.Resource.Resource.Name,
))
case addrs.DataResourceMode:
buf.WriteString(fmt.Sprintf(
"data %q %q ",
addr.Resource.Resource.Type,
addr.Resource.Resource.Name,
))
default:
// should never happen, since the above is exhaustive
buf.WriteString(addr.String())
}
buf.WriteString(" {")
p := blockBodyDiffPrinter{
buf: &buf,
color: color,
action: change.Action,
requiredReplace: change.RequiredReplace,
}
// Most commonly-used resources have nested blocks that result in us
// going at least three traversals deep while we recurse here, so we'll
// start with that much capacity and then grow as needed for deeper
// structures.
path := make(cty.Path, 0, 3)
changeV, err := change.Decode(schema.ImpliedType())
if err != nil {
// Should never happen in here, since we've already been through
// loads of layers of encode/decode of the planned changes before now.
panic(fmt.Sprintf("failed to decode plan for %s while rendering diff: %s", addr, err))
}
// We currently have an opt-out that permits the legacy SDK to return values
// that defy our usual conventions around handling of nesting blocks. To
// avoid the rendering code from needing to handle all of these, we'll
// normalize first.
// (Ideally we'd do this as part of the SDK opt-out implementation in core,
// but we've added it here for now to reduce risk of unexpected impacts
// on other code in core.)
changeV.Change.Before = objchange.NormalizeObjectFromLegacySDK(changeV.Change.Before, schema)
changeV.Change.After = objchange.NormalizeObjectFromLegacySDK(changeV.Change.After, schema)
result := p.writeBlockBodyDiff(schema, changeV.Before, changeV.After, 6, path)
if result.bodyWritten {
buf.WriteString("\n")
buf.WriteString(strings.Repeat(" ", 4))
}
buf.WriteString("}\n")
return buf.String()
}
// ResourceInstanceDrift returns a string representation of a change to a
// particular resource instance that was made outside of Terraform, for
// reporting a change that has already happened rather than one that is planned.
//
// The the two resource instances have equal current objects then the result
// will be an empty string to indicate that there is no drift to render.
//
// The resource schema must be provided along with the change so that the
// formatted change can reflect the configuration structure for the associated
// resource.
//
// If "color" is non-nil, it will be used to color the result. Otherwise,
// no color codes will be included.
func ResourceInstanceDrift(
addr addrs.AbsResourceInstance,
before, after *states.ResourceInstance,
schema *configschema.Block,
color *colorstring.Colorize,
) string {
var buf bytes.Buffer
if color == nil {
color = &colorstring.Colorize{
Colors: colorstring.DefaultColors,
Disable: true,
Reset: false,
}
}
dispAddr := addr.String()
action := plans.Update
switch {
case after == nil || after.Current == nil:
// The object was deleted
buf.WriteString(color.Color(fmt.Sprintf("[bold] # %s[reset] has been deleted", dispAddr)))
action = plans.Delete
default:
// The object was changed
buf.WriteString(color.Color(fmt.Sprintf("[bold] # %s[reset] has been changed", dispAddr)))
}
buf.WriteString(color.Color("[reset]\n"))
buf.WriteString(color.Color(DiffActionSymbol(action)) + " ")
switch addr.Resource.Resource.Mode {
case addrs.ManagedResourceMode:
buf.WriteString(fmt.Sprintf(
"resource %q %q",
addr.Resource.Resource.Type,
addr.Resource.Resource.Name,
))
case addrs.DataResourceMode:
buf.WriteString(fmt.Sprintf(
"data %q %q ",
addr.Resource.Resource.Type,
addr.Resource.Resource.Name,
))
default:
// should never happen, since the above is exhaustive
buf.WriteString(addr.String())
}
buf.WriteString(" {")
p := blockBodyDiffPrinter{
buf: &buf,
color: color,
action: action,
}
// Most commonly-used resources have nested blocks that result in us
// going at least three traversals deep while we recurse here, so we'll
// start with that much capacity and then grow as needed for deeper
// structures.
path := make(cty.Path, 0, 3)
ty := schema.ImpliedType()
var err error
var oldObj, newObj *states.ResourceInstanceObject
oldObj, err = before.Current.Decode(ty)
if err != nil {
// We shouldn't encounter errors here because Terraform Core should've
// made sure that the previous run object conforms to the current
// schema by having the provider upgrade it, but we'll be robust here
// in case there are some edges we didn't find yet.
return fmt.Sprintf(" # %s previous run state doesn't conform to current schema; this is a Terraform bug\n # %s\n", addr, err)
}
if after != nil && after.Current != nil {
newObj, err = after.Current.Decode(ty)
if err != nil {
// We shouldn't encounter errors here because Terraform Core should've
// made sure that the prior state object conforms to the current
// schema by having the provider upgrade it, even if we skipped
// refreshing on this run, but we'll be robust here in case there are
// some edges we didn't find yet.
return fmt.Sprintf(" # %s refreshed state doesn't conform to current schema; this is a Terraform bug\n # %s\n", addr, err)
}
}
oldVal := oldObj.Value
var newVal cty.Value
if newObj != nil {
newVal = newObj.Value
} else {
newVal = cty.NullVal(ty)
}
if newVal.RawEquals(oldVal) {
// Nothing to show, then.
return ""
}
// We currently have an opt-out that permits the legacy SDK to return values
// that defy our usual conventions around handling of nesting blocks. To
// avoid the rendering code from needing to handle all of these, we'll
// normalize first.
// (Ideally we'd do this as part of the SDK opt-out implementation in core,
// but we've added it here for now to reduce risk of unexpected impacts
// on other code in core.)
oldVal = objchange.NormalizeObjectFromLegacySDK(oldVal, schema)
newVal = objchange.NormalizeObjectFromLegacySDK(newVal, schema)
result := p.writeBlockBodyDiff(schema, oldVal, newVal, 6, path)
if result.bodyWritten {
buf.WriteString("\n")
buf.WriteString(strings.Repeat(" ", 4))
}
buf.WriteString("}\n")
return buf.String()
}
// OutputChanges returns a string representation of a set of changes to output
// values for inclusion in user-facing plan output.
//
// If "color" is non-nil, it will be used to color the result. Otherwise,
// no color codes will be included.
func OutputChanges(
changes []*plans.OutputChangeSrc,
color *colorstring.Colorize,
) string {
var buf bytes.Buffer
p := blockBodyDiffPrinter{
buf: &buf,
color: color,
action: plans.Update, // not actually used in this case, because we're not printing a containing block
}
// We're going to reuse the codepath we used for printing resource block
// diffs, by pretending that the set of defined outputs are the attributes
// of some resource. It's a little forced to do this, but it gives us all
// the same formatting heuristics as we normally use for resource
// attributes.
oldVals := make(map[string]cty.Value, len(changes))
newVals := make(map[string]cty.Value, len(changes))
synthSchema := &configschema.Block{
Attributes: make(map[string]*configschema.Attribute, len(changes)),
}
for _, changeSrc := range changes {
name := changeSrc.Addr.OutputValue.Name
change, err := changeSrc.Decode()
if err != nil {
// It'd be weird to get a decoding error here because that would
// suggest that Terraform itself just produced an invalid plan, and
// we don't have any good way to ignore it in this codepath, so
// we'll just log it and ignore it.
log.Printf("[ERROR] format.OutputChanges: Failed to decode planned change for output %q: %s", name, err)
continue
}
synthSchema.Attributes[name] = &configschema.Attribute{
Type: cty.DynamicPseudoType, // output types are decided dynamically based on the given value
Optional: true,
Sensitive: change.Sensitive,
}
oldVals[name] = change.Before
newVals[name] = change.After
}
p.writeBlockBodyDiff(synthSchema, cty.ObjectVal(oldVals), cty.ObjectVal(newVals), 2, nil)
return buf.String()
}
type blockBodyDiffPrinter struct {
buf *bytes.Buffer
color *colorstring.Colorize
action plans.Action
requiredReplace cty.PathSet
// verbose is set to true when using the "diff" printer to format state
verbose bool
}
type blockBodyDiffResult struct {
bodyWritten bool
skippedAttributes int
skippedBlocks int
}
const forcesNewResourceCaption = " [red]# forces replacement[reset]"
// writeBlockBodyDiff writes attribute or block differences
// and returns true if any differences were found and written
func (p *blockBodyDiffPrinter) writeBlockBodyDiff(schema *configschema.Block, old, new cty.Value, indent int, path cty.Path) blockBodyDiffResult {
path = ctyEnsurePathCapacity(path, 1)
result := blockBodyDiffResult{}
// write the attributes diff
blankBeforeBlocks := p.writeAttrsDiff(schema.Attributes, old, new, indent, path, &result)
p.writeSkippedAttr(result.skippedAttributes, indent+2)
{
blockTypeNames := make([]string, 0, len(schema.BlockTypes))
for name := range schema.BlockTypes {
blockTypeNames = append(blockTypeNames, name)
}
sort.Strings(blockTypeNames)
for _, name := range blockTypeNames {
blockS := schema.BlockTypes[name]
oldVal := ctyGetAttrMaybeNull(old, name)
newVal := ctyGetAttrMaybeNull(new, name)
result.bodyWritten = true
skippedBlocks := p.writeNestedBlockDiffs(name, blockS, oldVal, newVal, blankBeforeBlocks, indent, path)
if skippedBlocks > 0 {
result.skippedBlocks += skippedBlocks
}
// Always include a blank for any subsequent block types.
blankBeforeBlocks = true
}
if result.skippedBlocks > 0 {
noun := "blocks"
if result.skippedBlocks == 1 {
noun = "block"
}
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent+2))
p.buf.WriteString(p.color.Color(fmt.Sprintf("[dark_gray]# (%d unchanged %s hidden)[reset]", result.skippedBlocks, noun)))
}
}
return result
}
func (p *blockBodyDiffPrinter) writeAttrsDiff(
attrsS map[string]*configschema.Attribute,
old, new cty.Value,
indent int,
path cty.Path,
result *blockBodyDiffResult) bool {
blankBeforeBlocks := false
attrNames := make([]string, 0, len(attrsS))
attrNameLen := 0
for name := range attrsS {
oldVal := ctyGetAttrMaybeNull(old, name)
newVal := ctyGetAttrMaybeNull(new, name)
if oldVal.IsNull() && newVal.IsNull() {
// Skip attributes where both old and new values are null
// (we do this early here so that we'll do our value alignment
// based on the longest attribute name that has a change, rather
// than the longest attribute name in the full set.)
continue
}
attrNames = append(attrNames, name)
if len(name) > attrNameLen {
attrNameLen = len(name)
}
}
sort.Strings(attrNames)
if len(attrNames) > 0 {
blankBeforeBlocks = true
}
for _, name := range attrNames {
attrS := attrsS[name]
oldVal := ctyGetAttrMaybeNull(old, name)
newVal := ctyGetAttrMaybeNull(new, name)
result.bodyWritten = true
skipped := p.writeAttrDiff(name, attrS, oldVal, newVal, attrNameLen, indent, path)
if skipped {
result.skippedAttributes++
}
}
return blankBeforeBlocks
}
// getPlanActionAndShow returns the action value
// and a boolean for showJustNew. In this function we
// modify the old and new values to remove any possible marks
func getPlanActionAndShow(old cty.Value, new cty.Value) (plans.Action, bool) {
var action plans.Action
showJustNew := false
switch {
case old.IsNull():
action = plans.Create
showJustNew = true
case new.IsNull():
action = plans.Delete
case ctyEqualWithUnknown(old, new):
action = plans.NoOp
showJustNew = true
default:
action = plans.Update
}
return action, showJustNew
}
func (p *blockBodyDiffPrinter) writeAttrDiff(name string, attrS *configschema.Attribute, old, new cty.Value, nameLen, indent int, path cty.Path) bool {
path = append(path, cty.GetAttrStep{Name: name})
action, showJustNew := getPlanActionAndShow(old, new)
if action == plans.NoOp && !p.verbose && !identifyingAttribute(name, attrS) {
return true
}
if attrS.NestedType != nil {
p.writeNestedAttrDiff(name, attrS.NestedType, old, new, nameLen, indent, path, action, showJustNew)
return false
}
p.buf.WriteString("\n")
p.writeSensitivityWarning(old, new, indent, action, false)
p.buf.WriteString(strings.Repeat(" ", indent))
p.writeActionSymbol(action)
p.buf.WriteString(p.color.Color("[bold]"))
p.buf.WriteString(name)
p.buf.WriteString(p.color.Color("[reset]"))
p.buf.WriteString(strings.Repeat(" ", nameLen-len(name)))
p.buf.WriteString(" = ")
if attrS.Sensitive {
p.buf.WriteString("(sensitive value)")
if p.pathForcesNewResource(path) {
p.buf.WriteString(p.color.Color(forcesNewResourceCaption))
}
} else {
switch {
case showJustNew:
p.writeValue(new, action, indent+2)
if p.pathForcesNewResource(path) {
p.buf.WriteString(p.color.Color(forcesNewResourceCaption))
}
default:
// We show new even if it is null to emphasize the fact
// that it is being unset, since otherwise it is easy to
// misunderstand that the value is still set to the old value.
p.writeValueDiff(old, new, indent+2, path)
}
}
return false
}
// writeNestedAttrDiff is responsible for formatting Attributes with NestedTypes
// in the diff.
func (p *blockBodyDiffPrinter) writeNestedAttrDiff(
name string, objS *configschema.Object, old, new cty.Value,
nameLen, indent int, path cty.Path, action plans.Action, showJustNew bool) {
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent))
p.writeActionSymbol(action)
p.buf.WriteString(p.color.Color("[bold]"))
p.buf.WriteString(name)
p.buf.WriteString(p.color.Color("[reset]"))
p.buf.WriteString(strings.Repeat(" ", nameLen-len(name)))
result := &blockBodyDiffResult{}
switch objS.Nesting {
case configschema.NestingSingle:
p.buf.WriteString(" = {")
if action != plans.NoOp && (p.pathForcesNewResource(path) || p.pathForcesNewResource(path[:len(path)-1])) {
p.buf.WriteString(p.color.Color(forcesNewResourceCaption))
}
p.writeAttrsDiff(objS.Attributes, old, new, indent+2, path, result)
p.writeSkippedAttr(result.skippedAttributes, indent+4)
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent))
p.buf.WriteString("}")
case configschema.NestingList:
p.buf.WriteString(" = [")
if action != plans.NoOp && (p.pathForcesNewResource(path) || p.pathForcesNewResource(path[:len(path)-1])) {
p.buf.WriteString(p.color.Color(forcesNewResourceCaption))
}
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent+4))
p.writeActionSymbol(action)
p.buf.WriteString("{")
oldItems := ctyCollectionValues(old)
newItems := ctyCollectionValues(new)
// Here we intentionally preserve the index-based correspondance
// between old and new, rather than trying to detect insertions
// and removals in the list, because this more accurately reflects
// how Terraform Core and providers will understand the change,
// particularly when the nested block contains computed attributes
// that will themselves maintain correspondance by index.
// commonLen is number of elements that exist in both lists, which
// will be presented as updates (~). Any additional items in one
// of the lists will be presented as either creates (+) or deletes (-)
// depending on which list they belong to.
var commonLen int
// unchanged is the number of unchanged elements
var unchanged int
switch {
case len(oldItems) < len(newItems):
commonLen = len(oldItems)
default:
commonLen = len(newItems)
}
for i := 0; i < commonLen; i++ {
path := append(path, cty.IndexStep{Key: cty.NumberIntVal(int64(i))})
oldItem := oldItems[i]
newItem := newItems[i]
if oldItem.RawEquals(newItem) {
action = plans.NoOp
unchanged++
}
if action != plans.NoOp {
p.writeAttrsDiff(objS.Attributes, oldItem, newItem, indent+6, path, result)
p.writeSkippedAttr(result.skippedAttributes, indent+8)
p.buf.WriteString("\n")
}
}
for i := commonLen; i < len(oldItems); i++ {
path := append(path, cty.IndexStep{Key: cty.NumberIntVal(int64(i))})
oldItem := oldItems[i]
newItem := cty.NullVal(oldItem.Type())
p.writeAttrsDiff(objS.Attributes, oldItem, newItem, indent+6, path, result)
p.buf.WriteString("\n")
}
for i := commonLen; i < len(newItems); i++ {
path := append(path, cty.IndexStep{Key: cty.NumberIntVal(int64(i))})
newItem := newItems[i]
oldItem := cty.NullVal(newItem.Type())
p.writeAttrsDiff(objS.Attributes, oldItem, newItem, indent+6, path, result)
p.buf.WriteString("\n")
}
p.buf.WriteString(strings.Repeat(" ", indent+4))
p.buf.WriteString("},\n")
p.writeSkippedElems(unchanged, indent+4)
p.buf.WriteString(strings.Repeat(" ", indent+2))
p.buf.WriteString("]")
case configschema.NestingSet:
oldItems := ctyCollectionValues(old)
newItems := ctyCollectionValues(new)
allItems := make([]cty.Value, 0, len(oldItems)+len(newItems))
allItems = append(allItems, oldItems...)
allItems = append(allItems, newItems...)
all := cty.SetVal(allItems)
p.buf.WriteString(" = [")
for it := all.ElementIterator(); it.Next(); {
_, val := it.Element()
var action plans.Action
var oldValue, newValue cty.Value
switch {
case !val.IsKnown():
action = plans.Update
newValue = val
case !old.HasElement(val).True():
action = plans.Create
oldValue = cty.NullVal(val.Type())
newValue = val
case !new.HasElement(val).True():
action = plans.Delete
oldValue = val
newValue = cty.NullVal(val.Type())
default:
action = plans.NoOp
oldValue = val
newValue = val
}
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent+4))
p.writeActionSymbol(action)
p.buf.WriteString("{")
if action != plans.NoOp && (p.pathForcesNewResource(path) || p.pathForcesNewResource(path[:len(path)-1])) {
p.buf.WriteString(p.color.Color(forcesNewResourceCaption))
}
path := append(path, cty.IndexStep{Key: val})
p.writeAttrsDiff(objS.Attributes, oldValue, newValue, indent+6, path, result)
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent+4))
p.buf.WriteString("},")
}
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent+2))
p.buf.WriteString("]")
case configschema.NestingMap:
oldItems := old.AsValueMap()
newItems := new.AsValueMap()
allKeys := make(map[string]bool)
for k := range oldItems {
allKeys[k] = true
}
for k := range newItems {
allKeys[k] = true
}
allKeysOrder := make([]string, 0, len(allKeys))
for k := range allKeys {
allKeysOrder = append(allKeysOrder, k)
}
sort.Strings(allKeysOrder)
p.buf.WriteString(" = {\n")
// unchanged tracks the number of unchanged elements
unchanged := 0
for _, k := range allKeysOrder {
var action plans.Action
oldValue := oldItems[k]
newValue := newItems[k]
switch {
case oldValue == cty.NilVal:
oldValue = cty.NullVal(newValue.Type())
action = plans.Create
case newValue == cty.NilVal:
newValue = cty.NullVal(oldValue.Type())
action = plans.Delete
case !newValue.RawEquals(oldValue):
action = plans.Update
default:
action = plans.NoOp
unchanged++
}
if action != plans.NoOp {
p.buf.WriteString(strings.Repeat(" ", indent+4))
p.writeActionSymbol(action)
fmt.Fprintf(p.buf, "%q = {", k)
if p.pathForcesNewResource(path) || p.pathForcesNewResource(path[:len(path)-1]) {
p.buf.WriteString(p.color.Color(forcesNewResourceCaption))
}
path := append(path, cty.IndexStep{Key: cty.StringVal(k)})
p.writeAttrsDiff(objS.Attributes, oldValue, newValue, indent+6, path, result)
p.writeSkippedAttr(result.skippedAttributes, indent+8)
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent+4))
p.buf.WriteString("},\n")
}
}
p.writeSkippedElems(unchanged, indent+4)
p.buf.WriteString(strings.Repeat(" ", indent+2))
p.buf.WriteString("}")
}
return
}
func (p *blockBodyDiffPrinter) writeNestedBlockDiffs(name string, blockS *configschema.NestedBlock, old, new cty.Value, blankBefore bool, indent int, path cty.Path) int {
skippedBlocks := 0
path = append(path, cty.GetAttrStep{Name: name})
if old.IsNull() && new.IsNull() {
// Nothing to do if both old and new is null
return skippedBlocks
}
// If either the old or the new value is marked,
// Display a special diff because it is irrelevant
// to list all obfuscated attributes as (sensitive)
if old.IsMarked() || new.IsMarked() {
p.writeSensitiveNestedBlockDiff(name, old, new, indent, blankBefore, path)
return 0
}
// Where old/new are collections representing a nesting mode other than
// NestingSingle, we assume the collection value can never be unknown
// since we always produce the container for the nested objects, even if
// the objects within are computed.
switch blockS.Nesting {
case configschema.NestingSingle, configschema.NestingGroup:
var action plans.Action
eqV := new.Equals(old)
switch {
case old.IsNull():
action = plans.Create
case new.IsNull():
action = plans.Delete
case !new.IsWhollyKnown() || !old.IsWhollyKnown():
// "old" should actually always be known due to our contract
// that old values must never be unknown, but we'll allow it
// anyway to be robust.
action = plans.Update
case !eqV.IsKnown() || !eqV.True():
action = plans.Update
}
if blankBefore {
p.buf.WriteRune('\n')
}
skipped := p.writeNestedBlockDiff(name, nil, &blockS.Block, action, old, new, indent, path)
if skipped {
return 1
}
case configschema.NestingList:
// For the sake of handling nested blocks, we'll treat a null list
// the same as an empty list since the config language doesn't
// distinguish these anyway.
old = ctyNullBlockListAsEmpty(old)
new = ctyNullBlockListAsEmpty(new)
oldItems := ctyCollectionValues(old)
newItems := ctyCollectionValues(new)
// Here we intentionally preserve the index-based correspondance
// between old and new, rather than trying to detect insertions
// and removals in the list, because this more accurately reflects
// how Terraform Core and providers will understand the change,
// particularly when the nested block contains computed attributes
// that will themselves maintain correspondance by index.
// commonLen is number of elements that exist in both lists, which
// will be presented as updates (~). Any additional items in one
// of the lists will be presented as either creates (+) or deletes (-)
// depending on which list they belong to.
var commonLen int
switch {
case len(oldItems) < len(newItems):
commonLen = len(oldItems)
default:
commonLen = len(newItems)
}
if blankBefore && (len(oldItems) > 0 || len(newItems) > 0) {
p.buf.WriteRune('\n')
}
for i := 0; i < commonLen; i++ {
path := append(path, cty.IndexStep{Key: cty.NumberIntVal(int64(i))})
oldItem := oldItems[i]
newItem := newItems[i]
action := plans.Update
if oldItem.RawEquals(newItem) {
action = plans.NoOp
}
skipped := p.writeNestedBlockDiff(name, nil, &blockS.Block, action, oldItem, newItem, indent, path)
if skipped {
skippedBlocks++
}
}
for i := commonLen; i < len(oldItems); i++ {
path := append(path, cty.IndexStep{Key: cty.NumberIntVal(int64(i))})
oldItem := oldItems[i]
newItem := cty.NullVal(oldItem.Type())
skipped := p.writeNestedBlockDiff(name, nil, &blockS.Block, plans.Delete, oldItem, newItem, indent, path)
if skipped {
skippedBlocks++
}
}
for i := commonLen; i < len(newItems); i++ {
path := append(path, cty.IndexStep{Key: cty.NumberIntVal(int64(i))})
newItem := newItems[i]
oldItem := cty.NullVal(newItem.Type())
skipped := p.writeNestedBlockDiff(name, nil, &blockS.Block, plans.Create, oldItem, newItem, indent, path)
if skipped {
skippedBlocks++
}
}
case configschema.NestingSet:
// For the sake of handling nested blocks, we'll treat a null set
// the same as an empty set since the config language doesn't
// distinguish these anyway.
old = ctyNullBlockSetAsEmpty(old)
new = ctyNullBlockSetAsEmpty(new)
oldItems := ctyCollectionValues(old)
newItems := ctyCollectionValues(new)
if (len(oldItems) + len(newItems)) == 0 {
// Nothing to do if both sets are empty
return 0
}
allItems := make([]cty.Value, 0, len(oldItems)+len(newItems))
allItems = append(allItems, oldItems...)
allItems = append(allItems, newItems...)
all := cty.SetVal(allItems)
if blankBefore {
p.buf.WriteRune('\n')
}
for it := all.ElementIterator(); it.Next(); {
_, val := it.Element()
var action plans.Action
var oldValue, newValue cty.Value
switch {
case !val.IsKnown():
action = plans.Update
newValue = val
case !old.HasElement(val).True():
action = plans.Create
oldValue = cty.NullVal(val.Type())
newValue = val
case !new.HasElement(val).True():
action = plans.Delete
oldValue = val
newValue = cty.NullVal(val.Type())
default:
action = plans.NoOp
oldValue = val
newValue = val
}
path := append(path, cty.IndexStep{Key: val})
skipped := p.writeNestedBlockDiff(name, nil, &blockS.Block, action, oldValue, newValue, indent, path)
if skipped {
skippedBlocks++
}
}
case configschema.NestingMap:
// For the sake of handling nested blocks, we'll treat a null map
// the same as an empty map since the config language doesn't
// distinguish these anyway.
old = ctyNullBlockMapAsEmpty(old)
new = ctyNullBlockMapAsEmpty(new)
oldItems := old.AsValueMap()
newItems := new.AsValueMap()
if (len(oldItems) + len(newItems)) == 0 {
// Nothing to do if both maps are empty
return 0
}
allKeys := make(map[string]bool)
for k := range oldItems {
allKeys[k] = true
}
for k := range newItems {
allKeys[k] = true
}
allKeysOrder := make([]string, 0, len(allKeys))
for k := range allKeys {
allKeysOrder = append(allKeysOrder, k)
}
sort.Strings(allKeysOrder)
if blankBefore {
p.buf.WriteRune('\n')
}
for _, k := range allKeysOrder {
var action plans.Action
oldValue := oldItems[k]
newValue := newItems[k]
switch {
case oldValue == cty.NilVal:
oldValue = cty.NullVal(newValue.Type())
action = plans.Create
case newValue == cty.NilVal:
newValue = cty.NullVal(oldValue.Type())
action = plans.Delete
case !newValue.RawEquals(oldValue):
action = plans.Update
default:
action = plans.NoOp
}
path := append(path, cty.IndexStep{Key: cty.StringVal(k)})
skipped := p.writeNestedBlockDiff(name, &k, &blockS.Block, action, oldValue, newValue, indent, path)
if skipped {
skippedBlocks++
}
}
}
return skippedBlocks
}
func (p *blockBodyDiffPrinter) writeSensitiveNestedBlockDiff(name string, old, new cty.Value, indent int, blankBefore bool, path cty.Path) {
var action plans.Action
switch {
case old.IsNull():
action = plans.Create
case new.IsNull():
action = plans.Delete
case !new.IsWhollyKnown() || !old.IsWhollyKnown():
// "old" should actually always be known due to our contract
// that old values must never be unknown, but we'll allow it
// anyway to be robust.
action = plans.Update
case !ctyEqualValueAndMarks(old, new):
action = plans.Update
}
if blankBefore {
p.buf.WriteRune('\n')
}
// New line before warning printing
p.buf.WriteRune('\n')
p.writeSensitivityWarning(old, new, indent, action, true)
p.buf.WriteString(strings.Repeat(" ", indent))
p.writeActionSymbol(action)
fmt.Fprintf(p.buf, "%s {", name)
if action != plans.NoOp && p.pathForcesNewResource(path) {
p.buf.WriteString(p.color.Color(forcesNewResourceCaption))
}
p.buf.WriteRune('\n')
p.buf.WriteString(strings.Repeat(" ", indent+4))
p.buf.WriteString("# At least one attribute in this block is (or was) sensitive,\n")
p.buf.WriteString(strings.Repeat(" ", indent+4))
p.buf.WriteString("# so its contents will not be displayed.")
p.buf.WriteRune('\n')
p.buf.WriteString(strings.Repeat(" ", indent+2))
p.buf.WriteString("}")
}
func (p *blockBodyDiffPrinter) writeNestedBlockDiff(name string, label *string, blockS *configschema.Block, action plans.Action, old, new cty.Value, indent int, path cty.Path) bool {
if action == plans.NoOp && !p.verbose {
return true
}
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent))
p.writeActionSymbol(action)
if label != nil {
fmt.Fprintf(p.buf, "%s %q {", name, *label)
} else {
fmt.Fprintf(p.buf, "%s {", name)
}
if action != plans.NoOp && (p.pathForcesNewResource(path) || p.pathForcesNewResource(path[:len(path)-1])) {
p.buf.WriteString(p.color.Color(forcesNewResourceCaption))
}
result := p.writeBlockBodyDiff(blockS, old, new, indent+4, path)
if result.bodyWritten {
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent+2))
}
p.buf.WriteString("}")
return false
}
func (p *blockBodyDiffPrinter) writeValue(val cty.Value, action plans.Action, indent int) {
// Could check specifically for the sensitivity marker
if val.IsMarked() {
p.buf.WriteString("(sensitive)")
return
}
if !val.IsKnown() {
p.buf.WriteString("(known after apply)")
return
}
if val.IsNull() {
p.buf.WriteString(p.color.Color("[dark_gray]null[reset]"))
return
}
ty := val.Type()
switch {
case ty.IsPrimitiveType():
switch ty {
case cty.String:
{
// Special behavior for JSON strings containing array or object
src := []byte(val.AsString())
ty, err := ctyjson.ImpliedType(src)
// check for the special case of "null", which decodes to nil,
// and just allow it to be printed out directly
if err == nil && !ty.IsPrimitiveType() && strings.TrimSpace(val.AsString()) != "null" {
jv, err := ctyjson.Unmarshal(src, ty)
if err == nil {
p.buf.WriteString("jsonencode(")
if jv.LengthInt() == 0 {
p.writeValue(jv, action, 0)
} else {
p.buf.WriteByte('\n')
p.buf.WriteString(strings.Repeat(" ", indent+4))
p.writeValue(jv, action, indent+4)
p.buf.WriteByte('\n')
p.buf.WriteString(strings.Repeat(" ", indent))
}
p.buf.WriteByte(')')
break // don't *also* do the normal behavior below
}
}
}
if strings.Contains(val.AsString(), "\n") {
// It's a multi-line string, so we want to use the multi-line
// rendering so it'll be readable. Rather than re-implement
// that here, we'll just re-use the multi-line string diff
// printer with no changes, which ends up producing the
// result we want here.
// The path argument is nil because we don't track path
// information into strings and we know that a string can't
// have any indices or attributes that might need to be marked
// as (requires replacement), which is what that argument is for.
p.writeValueDiff(val, val, indent, nil)
break
}
fmt.Fprintf(p.buf, "%q", val.AsString())
case cty.Bool:
if val.True() {
p.buf.WriteString("true")
} else {
p.buf.WriteString("false")
}
case cty.Number:
bf := val.AsBigFloat()
p.buf.WriteString(bf.Text('f', -1))
default:
// should never happen, since the above is exhaustive
fmt.Fprintf(p.buf, "%#v", val)
}
case ty.IsListType() || ty.IsSetType() || ty.IsTupleType():
p.buf.WriteString("[")
it := val.ElementIterator()
for it.Next() {
_, val := it.Element()
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent+2))
p.writeActionSymbol(action)
p.writeValue(val, action, indent+4)
p.buf.WriteString(",")
}
if val.LengthInt() > 0 {
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent))
}
p.buf.WriteString("]")
case ty.IsMapType():
p.buf.WriteString("{")
keyLen := 0
for it := val.ElementIterator(); it.Next(); {
key, _ := it.Element()
if keyStr := key.AsString(); len(keyStr) > keyLen {
keyLen = len(keyStr)
}
}
for it := val.ElementIterator(); it.Next(); {
key, val := it.Element()
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent+2))
p.writeActionSymbol(action)
p.writeValue(key, action, indent+4)
p.buf.WriteString(strings.Repeat(" ", keyLen-len(key.AsString())))
p.buf.WriteString(" = ")
p.writeValue(val, action, indent+4)
}
if val.LengthInt() > 0 {
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent))
}
p.buf.WriteString("}")
case ty.IsObjectType():
p.buf.WriteString("{")
atys := ty.AttributeTypes()
attrNames := make([]string, 0, len(atys))
nameLen := 0
for attrName := range atys {
attrNames = append(attrNames, attrName)
if len(attrName) > nameLen {
nameLen = len(attrName)
}
}
sort.Strings(attrNames)
for _, attrName := range attrNames {
val := val.GetAttr(attrName)
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent+2))
p.writeActionSymbol(action)
p.buf.WriteString(attrName)
p.buf.WriteString(strings.Repeat(" ", nameLen-len(attrName)))
p.buf.WriteString(" = ")
p.writeValue(val, action, indent+4)
}
if len(attrNames) > 0 {
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent))
}
p.buf.WriteString("}")
}
}
func (p *blockBodyDiffPrinter) writeValueDiff(old, new cty.Value, indent int, path cty.Path) {
ty := old.Type()
typesEqual := ctyTypesEqual(ty, new.Type())
// We have some specialized diff implementations for certain complex
// values where it's useful to see a visualization of the diff of
// the nested elements rather than just showing the entire old and
// new values verbatim.
// However, these specialized implementations can apply only if both
// values are known and non-null.
if old.IsKnown() && new.IsKnown() && !old.IsNull() && !new.IsNull() && typesEqual {
if old.IsMarked() || new.IsMarked() {
p.buf.WriteString("(sensitive)")
if p.pathForcesNewResource(path) {
p.buf.WriteString(p.color.Color(forcesNewResourceCaption))
}
return
}
switch {
case ty == cty.String:
// We have special behavior for both multi-line strings in general
// and for strings that can parse as JSON. For the JSON handling
// to apply, both old and new must be valid JSON.
// For single-line strings that don't parse as JSON we just fall
// out of this switch block and do the default old -> new rendering.
oldS := old.AsString()
newS := new.AsString()
{
// Special behavior for JSON strings containing object or
// list values.
oldBytes := []byte(oldS)
newBytes := []byte(newS)
oldType, oldErr := ctyjson.ImpliedType(oldBytes)
newType, newErr := ctyjson.ImpliedType(newBytes)
if oldErr == nil && newErr == nil && !(oldType.IsPrimitiveType() && newType.IsPrimitiveType()) {
oldJV, oldErr := ctyjson.Unmarshal(oldBytes, oldType)
newJV, newErr := ctyjson.Unmarshal(newBytes, newType)
if oldErr == nil && newErr == nil {
if !oldJV.RawEquals(newJV) { // two JSON values may differ only in insignificant whitespace
p.buf.WriteString("jsonencode(")
p.buf.WriteByte('\n')
p.buf.WriteString(strings.Repeat(" ", indent+2))
p.writeActionSymbol(plans.Update)
p.writeValueDiff(oldJV, newJV, indent+4, path)
p.buf.WriteByte('\n')
p.buf.WriteString(strings.Repeat(" ", indent))
p.buf.WriteByte(')')
} else {
// if they differ only in insignificant whitespace
// then we'll note that but still expand out the
// effective value.
if p.pathForcesNewResource(path) {
p.buf.WriteString(p.color.Color("jsonencode( [red]# whitespace changes force replacement[reset]"))
} else {
p.buf.WriteString(p.color.Color("jsonencode( [dim]# whitespace changes[reset]"))
}
p.buf.WriteByte('\n')
p.buf.WriteString(strings.Repeat(" ", indent+4))
p.writeValue(oldJV, plans.NoOp, indent+4)
p.buf.WriteByte('\n')
p.buf.WriteString(strings.Repeat(" ", indent))
p.buf.WriteByte(')')
}
return
}
}
}
if !strings.Contains(oldS, "\n") && !strings.Contains(newS, "\n") {
break
}
p.buf.WriteString("<<-EOT")
if p.pathForcesNewResource(path) {
p.buf.WriteString(p.color.Color(forcesNewResourceCaption))
}
p.buf.WriteString("\n")
var oldLines, newLines []cty.Value
{
r := strings.NewReader(oldS)
sc := bufio.NewScanner(r)
for sc.Scan() {
oldLines = append(oldLines, cty.StringVal(sc.Text()))
}
}
{
r := strings.NewReader(newS)
sc := bufio.NewScanner(r)
for sc.Scan() {
newLines = append(newLines, cty.StringVal(sc.Text()))
}
}
// Optimization for strings which are exactly equal: just print
// directly without calculating the sequence diff. This makes a
// significant difference when this code path is reached via a
// writeValue call with a large multi-line string.
if oldS == newS {
for _, line := range newLines {
p.buf.WriteString(strings.Repeat(" ", indent+4))
p.buf.WriteString(line.AsString())
p.buf.WriteString("\n")
}
} else {
diffLines := ctySequenceDiff(oldLines, newLines)
for _, diffLine := range diffLines {
p.buf.WriteString(strings.Repeat(" ", indent+2))
p.writeActionSymbol(diffLine.Action)
switch diffLine.Action {
case plans.NoOp, plans.Delete:
p.buf.WriteString(diffLine.Before.AsString())
case plans.Create:
p.buf.WriteString(diffLine.After.AsString())
default:
// Should never happen since the above covers all
// actions that ctySequenceDiff can return for strings
p.buf.WriteString(diffLine.After.AsString())
}
p.buf.WriteString("\n")
}
}
p.buf.WriteString(strings.Repeat(" ", indent)) // +4 here because there's no symbol
p.buf.WriteString("EOT")
return
case ty.IsSetType():
p.buf.WriteString("[")
if p.pathForcesNewResource(path) {
p.buf.WriteString(p.color.Color(forcesNewResourceCaption))
}
p.buf.WriteString("\n")
var addedVals, removedVals, allVals []cty.Value
for it := old.ElementIterator(); it.Next(); {
_, val := it.Element()
allVals = append(allVals, val)
if new.HasElement(val).False() {
removedVals = append(removedVals, val)
}
}
for it := new.ElementIterator(); it.Next(); {
_, val := it.Element()
allVals = append(allVals, val)
if val.IsKnown() && old.HasElement(val).False() {
addedVals = append(addedVals, val)
}
}
var all, added, removed cty.Value
if len(allVals) > 0 {
all = cty.SetVal(allVals)
} else {
all = cty.SetValEmpty(ty.ElementType())
}
if len(addedVals) > 0 {
added = cty.SetVal(addedVals)
} else {
added = cty.SetValEmpty(ty.ElementType())
}
if len(removedVals) > 0 {
removed = cty.SetVal(removedVals)
} else {
removed = cty.SetValEmpty(ty.ElementType())
}
suppressedElements := 0
for it := all.ElementIterator(); it.Next(); {
_, val := it.Element()
var action plans.Action
switch {
case !val.IsKnown():
action = plans.Update
case added.HasElement(val).True():
action = plans.Create
case removed.HasElement(val).True():
action = plans.Delete
default:
action = plans.NoOp
}
if action == plans.NoOp && !p.verbose {
suppressedElements++
continue
}
p.buf.WriteString(strings.Repeat(" ", indent+2))
p.writeActionSymbol(action)
p.writeValue(val, action, indent+4)
p.buf.WriteString(",\n")
}
if suppressedElements > 0 {
p.writeActionSymbol(plans.NoOp)
p.buf.WriteString(strings.Repeat(" ", indent+2))
noun := "elements"
if suppressedElements == 1 {
noun = "element"
}
p.buf.WriteString(p.color.Color(fmt.Sprintf("[dark_gray]# (%d unchanged %s hidden)[reset]", suppressedElements, noun)))
p.buf.WriteString("\n")
}
p.buf.WriteString(strings.Repeat(" ", indent))
p.buf.WriteString("]")
return
case ty.IsListType() || ty.IsTupleType():
p.buf.WriteString("[")
if p.pathForcesNewResource(path) {
p.buf.WriteString(p.color.Color(forcesNewResourceCaption))
}
p.buf.WriteString("\n")
elemDiffs := ctySequenceDiff(old.AsValueSlice(), new.AsValueSlice())
// Maintain a stack of suppressed lines in the diff for later
// display or elision
var suppressedElements []*plans.Change
var changeShown bool
for i := 0; i < len(elemDiffs); i++ {
if !p.verbose {
for i < len(elemDiffs) && elemDiffs[i].Action == plans.NoOp {
suppressedElements = append(suppressedElements, elemDiffs[i])
i++
}
}
// If we have some suppressed elements on the stack…
if len(suppressedElements) > 0 {
// If we've just rendered a change, display the first
// element in the stack as context
if changeShown {
elemDiff := suppressedElements[0]
p.buf.WriteString(strings.Repeat(" ", indent+4))
p.writeValue(elemDiff.After, elemDiff.Action, indent+4)
p.buf.WriteString(",\n")
suppressedElements = suppressedElements[1:]
}
hidden := len(suppressedElements)
// If we're not yet at the end of the list, capture the
// last element on the stack as context for the upcoming
// change to be rendered
var nextContextDiff *plans.Change
if hidden > 0 && i < len(elemDiffs) {
hidden--
nextContextDiff = suppressedElements[hidden]
}
// If there are still hidden elements, show an elision
// statement counting them
if hidden > 0 {
p.writeActionSymbol(plans.NoOp)
p.buf.WriteString(strings.Repeat(" ", indent+2))
noun := "elements"
if hidden == 1 {
noun = "element"
}
p.buf.WriteString(p.color.Color(fmt.Sprintf("[dark_gray]# (%d unchanged %s hidden)[reset]", hidden, noun)))
p.buf.WriteString("\n")
}
// Display the next context diff if it was captured above
if nextContextDiff != nil {
p.buf.WriteString(strings.Repeat(" ", indent+4))
p.writeValue(nextContextDiff.After, nextContextDiff.Action, indent+4)
p.buf.WriteString(",\n")
}
// Suppressed elements have now been handled so clear them again
suppressedElements = nil
}
if i >= len(elemDiffs) {
break
}
elemDiff := elemDiffs[i]
p.buf.WriteString(strings.Repeat(" ", indent+2))
p.writeActionSymbol(elemDiff.Action)
switch elemDiff.Action {
case plans.NoOp, plans.Delete:
p.writeValue(elemDiff.Before, elemDiff.Action, indent+4)
case plans.Update:
p.writeValueDiff(elemDiff.Before, elemDiff.After, indent+4, path)
case plans.Create:
p.writeValue(elemDiff.After, elemDiff.Action, indent+4)
default:
// Should never happen since the above covers all
// actions that ctySequenceDiff can return.
p.writeValue(elemDiff.After, elemDiff.Action, indent+4)
}
p.buf.WriteString(",\n")
changeShown = true
}
p.buf.WriteString(strings.Repeat(" ", indent))
p.buf.WriteString("]")
return
case ty.IsMapType():
p.buf.WriteString("{")
if p.pathForcesNewResource(path) {
p.buf.WriteString(p.color.Color(forcesNewResourceCaption))
}
p.buf.WriteString("\n")
var allKeys []string
keyLen := 0
for it := old.ElementIterator(); it.Next(); {
k, _ := it.Element()
keyStr := k.AsString()
allKeys = append(allKeys, keyStr)
if len(keyStr) > keyLen {
keyLen = len(keyStr)
}
}
for it := new.ElementIterator(); it.Next(); {
k, _ := it.Element()
keyStr := k.AsString()
allKeys = append(allKeys, keyStr)
if len(keyStr) > keyLen {
keyLen = len(keyStr)
}
}
sort.Strings(allKeys)
suppressedElements := 0
lastK := ""
for i, k := range allKeys {
if i > 0 && lastK == k {
continue // skip duplicates (list is sorted)
}
lastK = k
kV := cty.StringVal(k)
var action plans.Action
if old.HasIndex(kV).False() {
action = plans.Create
} else if new.HasIndex(kV).False() {
action = plans.Delete
}
if old.HasIndex(kV).True() && new.HasIndex(kV).True() {
if ctyEqualValueAndMarks(old.Index(kV), new.Index(kV)) {
action = plans.NoOp
} else {
action = plans.Update
}
}
if action == plans.NoOp && !p.verbose {
suppressedElements++
continue
}
path := append(path, cty.IndexStep{Key: kV})
oldV := old.Index(kV)
newV := new.Index(kV)
p.writeSensitivityWarning(oldV, newV, indent+2, action, false)
p.buf.WriteString(strings.Repeat(" ", indent+2))
p.writeActionSymbol(action)
p.writeValue(kV, action, indent+4)
p.buf.WriteString(strings.Repeat(" ", keyLen-len(k)))
p.buf.WriteString(" = ")
switch action {
case plans.Create, plans.NoOp:
v := new.Index(kV)
if v.IsMarked() {
p.buf.WriteString("(sensitive)")
} else {
p.writeValue(v, action, indent+4)
}
case plans.Delete:
oldV := old.Index(kV)
newV := cty.NullVal(oldV.Type())
p.writeValueDiff(oldV, newV, indent+4, path)
default:
if oldV.IsMarked() || newV.IsMarked() {
p.buf.WriteString("(sensitive)")
} else {
p.writeValueDiff(oldV, newV, indent+4, path)
}
}
p.buf.WriteByte('\n')
}
if suppressedElements > 0 {
p.writeActionSymbol(plans.NoOp)
p.buf.WriteString(strings.Repeat(" ", indent+2))
noun := "elements"
if suppressedElements == 1 {
noun = "element"
}
p.buf.WriteString(p.color.Color(fmt.Sprintf("[dark_gray]# (%d unchanged %s hidden)[reset]", suppressedElements, noun)))
p.buf.WriteString("\n")
}
p.buf.WriteString(strings.Repeat(" ", indent))
p.buf.WriteString("}")
return
case ty.IsObjectType():
p.buf.WriteString("{")
p.buf.WriteString("\n")
forcesNewResource := p.pathForcesNewResource(path)
var allKeys []string
keyLen := 0
for it := old.ElementIterator(); it.Next(); {
k, _ := it.Element()
keyStr := k.AsString()
allKeys = append(allKeys, keyStr)
if len(keyStr) > keyLen {
keyLen = len(keyStr)
}
}
for it := new.ElementIterator(); it.Next(); {
k, _ := it.Element()
keyStr := k.AsString()
allKeys = append(allKeys, keyStr)
if len(keyStr) > keyLen {
keyLen = len(keyStr)
}
}
sort.Strings(allKeys)
suppressedElements := 0
lastK := ""
for i, k := range allKeys {
if i > 0 && lastK == k {
continue // skip duplicates (list is sorted)
}
lastK = k
kV := k
var action plans.Action
if !old.Type().HasAttribute(kV) {
action = plans.Create
} else if !new.Type().HasAttribute(kV) {
action = plans.Delete
} else if ctyEqualValueAndMarks(old.GetAttr(kV), new.GetAttr(kV)) {
action = plans.NoOp
} else {
action = plans.Update
}
if action == plans.NoOp && !p.verbose {
suppressedElements++
continue
}
path := append(path, cty.GetAttrStep{Name: kV})
p.buf.WriteString(strings.Repeat(" ", indent+2))
p.writeActionSymbol(action)
p.buf.WriteString(k)
p.buf.WriteString(strings.Repeat(" ", keyLen-len(k)))
p.buf.WriteString(" = ")
switch action {
case plans.Create, plans.NoOp:
v := new.GetAttr(kV)
p.writeValue(v, action, indent+4)
case plans.Delete:
oldV := old.GetAttr(kV)
newV := cty.NullVal(oldV.Type())
p.writeValueDiff(oldV, newV, indent+4, path)
default:
oldV := old.GetAttr(kV)
newV := new.GetAttr(kV)
p.writeValueDiff(oldV, newV, indent+4, path)
}
p.buf.WriteString("\n")
}
if suppressedElements > 0 {
p.writeActionSymbol(plans.NoOp)
p.buf.WriteString(strings.Repeat(" ", indent+2))
noun := "elements"
if suppressedElements == 1 {
noun = "element"
}
p.buf.WriteString(p.color.Color(fmt.Sprintf("[dark_gray]# (%d unchanged %s hidden)[reset]", suppressedElements, noun)))
p.buf.WriteString("\n")
}
p.buf.WriteString(strings.Repeat(" ", indent))
p.buf.WriteString("}")
if forcesNewResource {
p.buf.WriteString(p.color.Color(forcesNewResourceCaption))
}
return
}
}
// In all other cases, we just show the new and old values as-is
p.writeValue(old, plans.Delete, indent)
if new.IsNull() {
p.buf.WriteString(p.color.Color(" [dark_gray]->[reset] "))
} else {
p.buf.WriteString(p.color.Color(" [yellow]->[reset] "))
}
p.writeValue(new, plans.Create, indent)
if p.pathForcesNewResource(path) {
p.buf.WriteString(p.color.Color(forcesNewResourceCaption))
}
}
// writeActionSymbol writes a symbol to represent the given action, followed
// by a space.
//
// It only supports the actions that can be represented with a single character:
// Create, Delete, Update and NoAction.
func (p *blockBodyDiffPrinter) writeActionSymbol(action plans.Action) {
switch action {
case plans.Create:
p.buf.WriteString(p.color.Color("[green]+[reset] "))
case plans.Delete:
p.buf.WriteString(p.color.Color("[red]-[reset] "))
case plans.Update:
p.buf.WriteString(p.color.Color("[yellow]~[reset] "))
case plans.NoOp:
p.buf.WriteString(" ")
default:
// Should never happen
p.buf.WriteString(p.color.Color("? "))
}
}
func (p *blockBodyDiffPrinter) writeSensitivityWarning(old, new cty.Value, indent int, action plans.Action, isBlock bool) {
// Dont' show this warning for create or delete
if action == plans.Create || action == plans.Delete {
return
}
// Customize the warning based on if it is an attribute or block
diffType := "attribute value"
if isBlock {
diffType = "block"
}
// If only attribute sensitivity is changing, clarify that the value is unchanged
var valueUnchangedSuffix string
if !isBlock {
oldUnmarked, _ := old.UnmarkDeep()
newUnmarked, _ := new.UnmarkDeep()
if oldUnmarked.RawEquals(newUnmarked) {
valueUnchangedSuffix = " The value is unchanged."
}
}
if new.IsMarked() && !old.IsMarked() {
p.buf.WriteString(strings.Repeat(" ", indent))
p.buf.WriteString(p.color.Color(fmt.Sprintf("# [yellow]Warning:[reset] this %s will be marked as sensitive and will not\n", diffType)))
p.buf.WriteString(strings.Repeat(" ", indent))
p.buf.WriteString(fmt.Sprintf("# display in UI output after applying this change.%s\n", valueUnchangedSuffix))
}
// Note if changing this attribute will change its sensitivity
if old.IsMarked() && !new.IsMarked() {
p.buf.WriteString(strings.Repeat(" ", indent))
p.buf.WriteString(p.color.Color(fmt.Sprintf("# [yellow]Warning:[reset] this %s will no longer be marked as sensitive\n", diffType)))
p.buf.WriteString(strings.Repeat(" ", indent))
p.buf.WriteString(fmt.Sprintf("# after applying this change.%s\n", valueUnchangedSuffix))
}
}
func (p *blockBodyDiffPrinter) pathForcesNewResource(path cty.Path) bool {
if !p.action.IsReplace() || p.requiredReplace.Empty() {
// "requiredReplace" only applies when the instance is being replaced,
// and we should only inspect that set if it is not empty
return false
}
return p.requiredReplace.Has(path)
}
func ctyEmptyString(value cty.Value) bool {
if !value.IsNull() && value.IsKnown() {
valueType := value.Type()
if valueType == cty.String && value.AsString() == "" {
return true
}
}
return false
}
func ctyGetAttrMaybeNull(val cty.Value, name string) cty.Value {
attrType := val.Type().AttributeType(name)
if val.IsNull() {
return cty.NullVal(attrType)
}
// We treat "" as null here
// as existing SDK doesn't support null yet.
// This allows us to avoid spurious diffs
// until we introduce null to the SDK.
attrValue := val.GetAttr(name)
// If the value is marked, the ctyEmptyString function will fail
if !val.ContainsMarked() && ctyEmptyString(attrValue) {
return cty.NullVal(attrType)
}
return attrValue
}
func ctyCollectionValues(val cty.Value) []cty.Value {
if !val.IsKnown() || val.IsNull() {
return nil
}
ret := make([]cty.Value, 0, val.LengthInt())
for it := val.ElementIterator(); it.Next(); {
_, value := it.Element()
ret = append(ret, value)
}
return ret
}
// ctySequenceDiff returns differences between given sequences of cty.Value(s)
// in the form of Create, Delete, or Update actions (for objects).
func ctySequenceDiff(old, new []cty.Value) []*plans.Change {
var ret []*plans.Change
lcs := objchange.LongestCommonSubsequence(old, new)
var oldI, newI, lcsI int
for oldI < len(old) || newI < len(new) || lcsI < len(lcs) {
for oldI < len(old) && (lcsI >= len(lcs) || !old[oldI].RawEquals(lcs[lcsI])) {
isObjectDiff := old[oldI].Type().IsObjectType() && newI < len(new) && new[newI].Type().IsObjectType() && (lcsI >= len(lcs) || !new[newI].RawEquals(lcs[lcsI]))
if isObjectDiff {
ret = append(ret, &plans.Change{
Action: plans.Update,
Before: old[oldI],
After: new[newI],
})
oldI++
newI++ // we also consume the next "new" in this case
continue
}
ret = append(ret, &plans.Change{
Action: plans.Delete,
Before: old[oldI],
After: cty.NullVal(old[oldI].Type()),
})
oldI++
}
for newI < len(new) && (lcsI >= len(lcs) || !new[newI].RawEquals(lcs[lcsI])) {
ret = append(ret, &plans.Change{
Action: plans.Create,
Before: cty.NullVal(new[newI].Type()),
After: new[newI],
})
newI++
}
if lcsI < len(lcs) {
ret = append(ret, &plans.Change{
Action: plans.NoOp,
Before: lcs[lcsI],
After: lcs[lcsI],
})
// All of our indexes advance together now, since the line
// is common to all three sequences.
lcsI++
oldI++
newI++
}
}
return ret
}
// ctyEqualValueAndMarks checks equality of two possibly-marked values,
// considering partially-unknown values and equal values with different marks
// as inequal
func ctyEqualWithUnknown(old, new cty.Value) bool {
if !old.IsWhollyKnown() || !new.IsWhollyKnown() {
return false
}
return ctyEqualValueAndMarks(old, new)
}
// ctyEqualValueAndMarks checks equality of two possibly-marked values,
// considering equal values with different marks as inequal
func ctyEqualValueAndMarks(old, new cty.Value) bool {
oldUnmarked, oldMarks := old.UnmarkDeep()
newUnmarked, newMarks := new.UnmarkDeep()
sameValue := oldUnmarked.Equals(newUnmarked)
return sameValue.IsKnown() && sameValue.True() && oldMarks.Equal(newMarks)
}
// ctyTypesEqual checks equality of two types more loosely
// by avoiding checks of object/tuple elements
// as we render differences on element-by-element basis anyway
func ctyTypesEqual(oldT, newT cty.Type) bool {
if oldT.IsObjectType() && newT.IsObjectType() {
return true
}
if oldT.IsTupleType() && newT.IsTupleType() {
return true
}
return oldT.Equals(newT)
}
func ctyEnsurePathCapacity(path cty.Path, minExtra int) cty.Path {
if cap(path)-len(path) >= minExtra {
return path
}
newCap := cap(path) * 2
if newCap < (len(path) + minExtra) {
newCap = len(path) + minExtra
}
newPath := make(cty.Path, len(path), newCap)
copy(newPath, path)
return newPath
}
// ctyNullBlockListAsEmpty either returns the given value verbatim if it is non-nil
// or returns an empty value of a suitable type to serve as a placeholder for it.
//
// In particular, this function handles the special situation where a "list" is
// actually represented as a tuple type where nested blocks contain
// dynamically-typed values.
func ctyNullBlockListAsEmpty(in cty.Value) cty.Value {
if !in.IsNull() {
return in
}
if ty := in.Type(); ty.IsListType() {
return cty.ListValEmpty(ty.ElementType())
}
return cty.EmptyTupleVal // must need a tuple, then
}
// ctyNullBlockMapAsEmpty either returns the given value verbatim if it is non-nil
// or returns an empty value of a suitable type to serve as a placeholder for it.
//
// In particular, this function handles the special situation where a "map" is
// actually represented as an object type where nested blocks contain
// dynamically-typed values.
func ctyNullBlockMapAsEmpty(in cty.Value) cty.Value {
if !in.IsNull() {
return in
}
if ty := in.Type(); ty.IsMapType() {
return cty.MapValEmpty(ty.ElementType())
}
return cty.EmptyObjectVal // must need an object, then
}
// ctyNullBlockSetAsEmpty either returns the given value verbatim if it is non-nil
// or returns an empty value of a suitable type to serve as a placeholder for it.
func ctyNullBlockSetAsEmpty(in cty.Value) cty.Value {
if !in.IsNull() {
return in
}
// Dynamically-typed attributes are not supported inside blocks backed by
// sets, so our result here is always a set.
return cty.SetValEmpty(in.Type().ElementType())
}
// DiffActionSymbol returns a string that, once passed through a
// colorstring.Colorize, will produce a result that can be written
// to a terminal to produce a symbol made of three printable
// characters, possibly interspersed with VT100 color codes.
func DiffActionSymbol(action plans.Action) string {
switch action {
case plans.DeleteThenCreate:
return "[red]-[reset]/[green]+[reset]"
case plans.CreateThenDelete:
return "[green]+[reset]/[red]-[reset]"
case plans.Create:
return " [green]+[reset]"
case plans.Delete:
return " [red]-[reset]"
case plans.Read:
return " [cyan]<=[reset]"
case plans.Update:
return " [yellow]~[reset]"
default:
return " ?"
}
}
// Extremely coarse heuristic for determining whether or not a given attribute
// name is important for identifying a resource. In the future, this may be
// replaced by a flag in the schema, but for now this is likely to be good
// enough.
func identifyingAttribute(name string, attrSchema *configschema.Attribute) bool {
return name == "id" || name == "tags" || name == "name"
}
func (p *blockBodyDiffPrinter) writeSkippedAttr(skipped, indent int) {
if skipped > 0 {
noun := "attributes"
if skipped == 1 {
noun = "attribute"
}
p.buf.WriteString("\n")
p.buf.WriteString(strings.Repeat(" ", indent))
p.buf.WriteString(p.color.Color(fmt.Sprintf("[dark_gray]# (%d unchanged %s hidden)[reset]", skipped, noun)))
}
}
func (p *blockBodyDiffPrinter) writeSkippedElems(skipped, indent int) {
if skipped > 0 {
noun := "elements"
if skipped == 1 {
noun = "element"
}
p.buf.WriteString(strings.Repeat(" ", indent))
p.buf.WriteString(p.color.Color(fmt.Sprintf("[dark_gray]# (%d unchanged %s hidden)[reset]", skipped, noun)))
p.buf.WriteString("\n")
}
}