terraform/internal/plans/objchange/normalize_obj.go

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package objchange
import (
"github.com/hashicorp/terraform/internal/configs/configschema"
"github.com/zclconf/go-cty/cty"
)
// NormalizeObjectFromLegacySDK takes an object that may have been generated
// by the legacy Terraform SDK (i.e. returned from a provider with the
// LegacyTypeSystem opt-out set) and does its best to normalize it for the
// assumptions we would normally enforce if the provider had not opted out.
//
// In particular, this function guarantees that a value representing a nested
// block will never itself be unknown or null, instead representing that as
// a non-null value that may contain null/unknown values.
//
// The input value must still conform to the implied type of the given schema,
// or else this function may produce garbage results or panic. This is usually
// okay because type consistency is enforced when deserializing the value
// returned from the provider over the RPC wire protocol anyway.
func NormalizeObjectFromLegacySDK(val cty.Value, schema *configschema.Block) cty.Value {
val, valMarks := val.UnmarkDeepWithPaths()
val = normalizeObjectFromLegacySDK(val, schema)
return val.MarkWithPaths(valMarks)
}
func normalizeObjectFromLegacySDK(val cty.Value, schema *configschema.Block) cty.Value {
if val == cty.NilVal || val.IsNull() {
// This should never happen in reasonable use, but we'll allow it
// and normalize to a null of the expected type rather than panicking
// below.
return cty.NullVal(schema.ImpliedType())
}
vals := make(map[string]cty.Value)
for name := range schema.Attributes {
// No normalization for attributes, since them being type-conformant
// is all that we require.
vals[name] = val.GetAttr(name)
}
for name, blockS := range schema.BlockTypes {
lv := val.GetAttr(name)
// Legacy SDK never generates dynamically-typed attributes and so our
// normalization code doesn't deal with them, but we need to make sure
// we still pass them through properly so that we don't interfere with
// objects generated by other SDKs.
if ty := blockS.Block.ImpliedType(); ty.HasDynamicTypes() {
vals[name] = lv
continue
}
switch blockS.Nesting {
configs/configschema: Introduce the NestingGroup mode for blocks In study of existing providers we've found a pattern we werent previously accounting for of using a nested block type to represent a group of arguments that relate to a particular feature that is always enabled but where it improves configuration readability to group all of its settings together in a nested block. The existing NestingSingle was not a good fit for this because it is designed under the assumption that the presence or absence of the block has some significance in enabling or disabling the relevant feature, and so for these always-active cases we'd generate a misleading plan where the settings for the feature appear totally absent, rather than showing the default values that will be selected. NestingGroup is, therefore, a slight variation of NestingSingle where presence vs. absence of the block is not distinguishable (it's never null) and instead its contents are treated as unset when the block is absent. This then in turn causes any default values associated with the nested arguments to be honored and displayed in the plan whenever the block is not explicitly configured. The current SDK cannot activate this mode, but that's okay because its "legacy type system" opt-out flag allows it to force a block to be processed in this way anyway. We're adding this now so that we can introduce the feature in a future SDK without causing a breaking change to the protocol, since the set of possible block nesting modes is not extensible.
2019-04-09 00:32:53 +02:00
case configschema.NestingSingle, configschema.NestingGroup:
if lv.IsKnown() {
configs/configschema: Introduce the NestingGroup mode for blocks In study of existing providers we've found a pattern we werent previously accounting for of using a nested block type to represent a group of arguments that relate to a particular feature that is always enabled but where it improves configuration readability to group all of its settings together in a nested block. The existing NestingSingle was not a good fit for this because it is designed under the assumption that the presence or absence of the block has some significance in enabling or disabling the relevant feature, and so for these always-active cases we'd generate a misleading plan where the settings for the feature appear totally absent, rather than showing the default values that will be selected. NestingGroup is, therefore, a slight variation of NestingSingle where presence vs. absence of the block is not distinguishable (it's never null) and instead its contents are treated as unset when the block is absent. This then in turn causes any default values associated with the nested arguments to be honored and displayed in the plan whenever the block is not explicitly configured. The current SDK cannot activate this mode, but that's okay because its "legacy type system" opt-out flag allows it to force a block to be processed in this way anyway. We're adding this now so that we can introduce the feature in a future SDK without causing a breaking change to the protocol, since the set of possible block nesting modes is not extensible.
2019-04-09 00:32:53 +02:00
if lv.IsNull() && blockS.Nesting == configschema.NestingGroup {
vals[name] = blockS.EmptyValue()
} else {
vals[name] = normalizeObjectFromLegacySDK(lv, &blockS.Block)
configs/configschema: Introduce the NestingGroup mode for blocks In study of existing providers we've found a pattern we werent previously accounting for of using a nested block type to represent a group of arguments that relate to a particular feature that is always enabled but where it improves configuration readability to group all of its settings together in a nested block. The existing NestingSingle was not a good fit for this because it is designed under the assumption that the presence or absence of the block has some significance in enabling or disabling the relevant feature, and so for these always-active cases we'd generate a misleading plan where the settings for the feature appear totally absent, rather than showing the default values that will be selected. NestingGroup is, therefore, a slight variation of NestingSingle where presence vs. absence of the block is not distinguishable (it's never null) and instead its contents are treated as unset when the block is absent. This then in turn causes any default values associated with the nested arguments to be honored and displayed in the plan whenever the block is not explicitly configured. The current SDK cannot activate this mode, but that's okay because its "legacy type system" opt-out flag allows it to force a block to be processed in this way anyway. We're adding this now so that we can introduce the feature in a future SDK without causing a breaking change to the protocol, since the set of possible block nesting modes is not extensible.
2019-04-09 00:32:53 +02:00
}
} else {
vals[name] = unknownBlockStub(&blockS.Block)
}
case configschema.NestingList:
switch {
case !lv.IsKnown():
vals[name] = cty.ListVal([]cty.Value{unknownBlockStub(&blockS.Block)})
case lv.IsNull() || lv.LengthInt() == 0:
vals[name] = cty.ListValEmpty(blockS.Block.ImpliedType())
default:
subVals := make([]cty.Value, 0, lv.LengthInt())
for it := lv.ElementIterator(); it.Next(); {
_, subVal := it.Element()
subVals = append(subVals, normalizeObjectFromLegacySDK(subVal, &blockS.Block))
}
vals[name] = cty.ListVal(subVals)
}
case configschema.NestingSet:
switch {
case !lv.IsKnown():
vals[name] = cty.SetVal([]cty.Value{unknownBlockStub(&blockS.Block)})
case lv.IsNull() || lv.LengthInt() == 0:
vals[name] = cty.SetValEmpty(blockS.Block.ImpliedType())
default:
subVals := make([]cty.Value, 0, lv.LengthInt())
for it := lv.ElementIterator(); it.Next(); {
_, subVal := it.Element()
subVals = append(subVals, normalizeObjectFromLegacySDK(subVal, &blockS.Block))
}
vals[name] = cty.SetVal(subVals)
}
default:
// The legacy SDK doesn't support NestingMap, so we just assume
// maps are always okay. (If not, we would've detected and returned
// an error to the user before we got here.)
vals[name] = lv
}
}
return cty.ObjectVal(vals)
}
// unknownBlockStub constructs an object value that approximates an unknown
// block by producing a known block object with all of its leaf attribute
// values set to unknown.
//
// Blocks themselves cannot be unknown, so if the legacy SDK tries to return
// such a thing, we'll use this result instead. This convention mimics how
// the dynamic block feature deals with being asked to iterate over an unknown
// value, because our value-checking functions already accept this convention
// as a special case.
func unknownBlockStub(schema *configschema.Block) cty.Value {
vals := make(map[string]cty.Value)
for name, attrS := range schema.Attributes {
vals[name] = cty.UnknownVal(attrS.Type)
}
for name, blockS := range schema.BlockTypes {
switch blockS.Nesting {
configs/configschema: Introduce the NestingGroup mode for blocks In study of existing providers we've found a pattern we werent previously accounting for of using a nested block type to represent a group of arguments that relate to a particular feature that is always enabled but where it improves configuration readability to group all of its settings together in a nested block. The existing NestingSingle was not a good fit for this because it is designed under the assumption that the presence or absence of the block has some significance in enabling or disabling the relevant feature, and so for these always-active cases we'd generate a misleading plan where the settings for the feature appear totally absent, rather than showing the default values that will be selected. NestingGroup is, therefore, a slight variation of NestingSingle where presence vs. absence of the block is not distinguishable (it's never null) and instead its contents are treated as unset when the block is absent. This then in turn causes any default values associated with the nested arguments to be honored and displayed in the plan whenever the block is not explicitly configured. The current SDK cannot activate this mode, but that's okay because its "legacy type system" opt-out flag allows it to force a block to be processed in this way anyway. We're adding this now so that we can introduce the feature in a future SDK without causing a breaking change to the protocol, since the set of possible block nesting modes is not extensible.
2019-04-09 00:32:53 +02:00
case configschema.NestingSingle, configschema.NestingGroup:
vals[name] = unknownBlockStub(&blockS.Block)
case configschema.NestingList:
// In principle we may be expected to produce a tuple value here,
// if there are any dynamically-typed attributes in our nested block,
// but the legacy SDK doesn't support that, so we just assume it'll
// never be necessary to normalize those. (Incorrect usage in any
// other SDK would be caught and returned as an error before we
// get here.)
vals[name] = cty.ListVal([]cty.Value{unknownBlockStub(&blockS.Block)})
case configschema.NestingSet:
vals[name] = cty.SetVal([]cty.Value{unknownBlockStub(&blockS.Block)})
case configschema.NestingMap:
// A nesting map can never be unknown since we then wouldn't know
// what the keys are. (Legacy SDK doesn't support NestingMap anyway,
// so this should never arise.)
vals[name] = cty.MapValEmpty(blockS.Block.ImpliedType())
}
}
return cty.ObjectVal(vals)
}