Documentation ¶
Overview ¶
Package adt represents partially and fully evaluated CUE types.
This package introduces several categories of types that indicate some set of values that may be used in a certain situation. Concrete types may belong to multiple categories.
Abstract Types ¶
The following types describe the a place where a value may be used:
Decl a value than can be used as a StructLit element. Elem a value than can be used as a ListLit element. Expr represents an Expr in the CUE grammar. Value a fully evaluated value that has no references (except for children in composite values). Node any of the above values.
The following types categorize nodes by function:
Resolver a reference to position in the result tree. Evaluator evaluates to 1 value. Yielder evaluates to 0 or more values. Validator validates another value.
Reference resolution algorithm ¶
A Resolver is resolved within the context of an Environment. In CUE, a reference is evaluated by substituting it with a copy of the value to which it refers. If the copied value itself contains references we can distinguish two different cases. References that refer to values within the copied reference (not regarding selectors) will henceforth point to the copied node. References that point to outside the referenced value will keep referring to their original value.
a: b: { c: int d: c e: f } f: 4 g: a.b { // d.c points to inside the referred value, e.f, not. c: 3 }
The implementation doesn't actually copy referred values, but rather resolves references with the aid of an Environment. During compile time, each references is associated with the label and a number indicating in which parent scope (offset from the current) this label needs to be looked up. An Environment keeps track of the point at which a value was referenced, providing enough information to look up the labeled value. This Environment is the identical for all references within a fields conjunct. Often, an Environment can even be shared among conjuncts.
Values ¶
Values are fully evaluated expressions. As this means that all references will have been eliminated, Values are fully defined without the need for an Environment. Additionally, Values represent a fully evaluated form, stripped of any comprehensions, optional fields or embeddings.
Package eval contains the high level CUE evaluation strategy.
CUE allows for a significant amount of freedom in order of evaluation due to the commutativity of the unification operation. This package implements one of the possible strategies.
Index ¶
- Constants
- Variables
- func Accept(ctx *OpContext, n *Vertex, f Feature) (found, required bool)
- func AddStats(ctx *OpContext)
- func AssertConcreteIsPossible(op Op, x Expr) bool
- func Assertf(b bool, format string, args ...interface{})
- func DebugSortArcs(c *OpContext, n *Vertex)
- func DebugSortFields(c *OpContext, a []Feature)
- func Equal(ctx *OpContext, v, w Value, flags Flag) bool
- func HiddenKey(s, pkgPath string) string
- func IsConcrete(v Value) bool
- func IsDef(x Expr) bool
- func Pos(n Node) token.Pos
- func TotalStats() stats.Counts
- type ArcType
- type BaseValue
- type BasicType
- type BinaryExpr
- type Bool
- type Bottom
- type BoundExpr
- type BoundValue
- type Builtin
- type BuiltinValidator
- type BulkOptionalField
- type Bytes
- type CallExpr
- type CloseInfo
- func (c *CloseInfo) AddPositions(ctx *OpContext)
- func (c CloseInfo) IsInOneOf(t SpanType) bool
- func (c CloseInfo) Location() Node
- func (c CloseInfo) RootSpanType() SpanType
- func (c CloseInfo) SpawnEmbed(x Node) CloseInfo
- func (c CloseInfo) SpawnGroup(x Expr) CloseInfo
- func (c CloseInfo) SpawnRef(arc *Vertex, isDef bool, x Expr) CloseInfo
- func (c CloseInfo) SpawnSpan(x Node, t SpanType) CloseInfo
- type Comprehension
- type Concreteness
- type Config
- type Conjunct
- type ConjunctGroup
- type Conjunction
- type Constraints
- type CycleInfo
- type Decl
- type Disjunct
- type Disjunction
- type DisjunctionExpr
- type DynamicField
- type DynamicReference
- type Elem
- type Ellipsis
- type Environment
- type ErrorCode
- type Evaluator
- type Expr
- type Feature
- func LabelFromValue(c *OpContext, src Expr, v Value) Feature
- func MakeIdentLabel(r StringIndexer, s, pkgpath string) Feature
- func MakeIntLabel(t FeatureType, i int64) Feature
- func MakeLabel(src ast.Node, index int64, f FeatureType) (Feature, errors.Error)
- func MakeLetLabel(r StringIndexer, s string) Feature
- func MakeNamedLabel(r StringIndexer, t FeatureType, s string) Feature
- func MakeStringLabel(r StringIndexer, s string) Feature
- func (f Feature) IdentString(index StringIndexer) string
- func (f Feature) Index() int
- func (f Feature) IsDef() bool
- func (f Feature) IsHidden() bool
- func (f Feature) IsInt() bool
- func (f Feature) IsLet() bool
- func (f Feature) IsRegular() bool
- func (f Feature) IsString() bool
- func (f Feature) IsValid() bool
- func (f Feature) PkgID(index StringIndexer) string
- func (f Feature) RawString(index StringIndexer) string
- func (f Feature) SelectorString(index StringIndexer) string
- func (f Feature) StringValue(index StringIndexer) string
- func (f Feature) ToValue(ctx *OpContext) Value
- func (f Feature) Typ() FeatureType
- type FeatureType
- type Field
- type FieldInfo
- type FieldReference
- type Flag
- type ForClause
- type ID
- type IfClause
- type ImportReference
- type IndexExpr
- type Interpolation
- type Kind
- type LabelReference
- type LetClause
- type LetField
- type LetReference
- type ListLit
- type ListMarker
- type Node
- type NodeLink
- type Null
- type Num
- type Op
- type OpContext
- func (c *OpContext) Add(a, b *Num) Value
- func (c *OpContext) AddBottom(b *Bottom)
- func (c *OpContext) AddErr(err errors.Error) *Bottom
- func (c *OpContext) AddErrf(format string, args ...interface{}) *Bottom
- func (c *OpContext) AddPosition(n Node)
- func (c *OpContext) Assertf(pos token.Pos, b bool, format string, args ...interface{})
- func (c *OpContext) BoolValue(v Value) bool
- func (c *OpContext) CloseInfo() CloseInfo
- func (c *OpContext) Elems(v Value) []*Vertex
- func (c *OpContext) Env(upCount int32) *Environment
- func (c *OpContext) Err() *Bottom
- func (c *OpContext) Evaluate(env *Environment, x Expr) (result Value, complete bool)
- func (c *OpContext) HasErr() bool
- func (c *OpContext) Impl() Runtime
- func (c *OpContext) Int64(v Value) int64
- func (c *OpContext) IntDiv(a, b *Num) Value
- func (c *OpContext) IntMod(a, b *Num) Value
- func (c *OpContext) IntQuo(a, b *Num) Value
- func (c *OpContext) IntRem(a, b *Num) Value
- func (c *OpContext) Label(src Expr, x Value) Feature
- func (c *OpContext) Logf(v *Vertex, format string, args ...interface{})
- func (c *OpContext) Lookup(env *Environment, r Resolver) (*Vertex, *Bottom)
- func (c *OpContext) MarkPositions() int
- func (c *OpContext) Mul(a, b *Num) Value
- func (c *OpContext) NewErrf(format string, args ...interface{}) *Bottom
- func (c *OpContext) NewInt64(n int64, sources ...Node) Value
- func (c *OpContext) NewList(values ...Value) *Vertex
- func (c *OpContext) NewPosf(p token.Pos, format string, args ...interface{}) *ValueError
- func (c *OpContext) NewString(s string) Value
- func (c *OpContext) Newf(format string, args ...interface{}) *ValueError
- func (c *OpContext) Num(v Value, as interface{}) *Num
- func (c *OpContext) PathToString(path []Feature) string
- func (c *OpContext) PopArc(saved *Vertex)
- func (c *OpContext) PopState(s frame) *Bottom
- func (c *OpContext) Pos() token.Pos
- func (c *OpContext) Pow(a, b *Num) Value
- func (c *OpContext) PushArc(v *Vertex) (saved *Vertex)
- func (c *OpContext) PushConjunct(x Conjunct) (saved frame)
- func (c *OpContext) PushState(env *Environment, src ast.Node) (saved frame)
- func (c *OpContext) Quo(a, b *Num) Value
- func (c *OpContext) RawElems(v Value) []*Vertex
- func (c *OpContext) ReleasePositions(p int)
- func (c *OpContext) Resolve(x Conjunct, r Resolver) (*Vertex, *Bottom)
- func (c *OpContext) Source() ast.Node
- func (c *OpContext) Stats() *stats.Counts
- func (c *OpContext) Str(x Node) string
- func (c *OpContext) StringLabel(s string) Feature
- func (c *OpContext) StringValue(v Value) string
- func (c *OpContext) Sub(a, b *Num) Value
- func (c *OpContext) ToBytes(v Value) []byte
- func (c *OpContext) ToString(v Value) string
- func (c *OpContext) Validate(check Validator, value Value) *Bottom
- type OptionalType
- type Param
- type PatternConstraint
- type RefNode
- type Resolver
- type Runtime
- type SelectorExpr
- type SliceExpr
- type SpanType
- type String
- type StringIndexer
- type StructInfo
- type StructLit
- type StructMarker
- type Top
- type UnaryExpr
- type Validator
- type Value
- type ValueClause
- type ValueError
- type ValueReference
- type Vertex
- func (v *Vertex) Accept(ctx *OpContext, f Feature) bool
- func (v *Vertex) AddChildError(recursive *Bottom)
- func (v *Vertex) AddConjunct(c Conjunct) *Bottom
- func (v *Vertex) AddErr(ctx *OpContext, b *Bottom)
- func (v *Vertex) AddStruct(s *StructLit, env *Environment, ci CloseInfo) *StructInfo
- func (v *Vertex) Clone() *Vertex
- func (v *Vertex) CompleteArcs(c *OpContext)
- func (x *Vertex) Concreteness() Concreteness
- func (v *Vertex) Default() *Vertex
- func (v *Vertex) Elems() []*Vertex
- func (v *Vertex) Err(c *OpContext) *Bottom
- func (v *Vertex) Finalize(c *OpContext)
- func (v *Vertex) ForceDone()
- func (v *Vertex) GetArc(c *OpContext, f Feature, t ArcType) (arc *Vertex, isNew bool)
- func (v *Vertex) Indirect() *Vertex
- func (v *Vertex) IsClosedList() bool
- func (v *Vertex) IsClosedStruct() bool
- func (x *Vertex) IsConcrete() bool
- func (v *Vertex) IsConstraint() bool
- func (v *Vertex) IsData() bool
- func (v *Vertex) IsDefined(c *OpContext) bool
- func (v *Vertex) IsErr() bool
- func (v *Vertex) IsInOneOf(mask SpanType) bool
- func (v *Vertex) IsList() bool
- func (v *Vertex) IsOptional(label Feature) bool
- func (v *Vertex) IsRecursivelyClosed() bool
- func (v *Vertex) IsUnprocessed() bool
- func (v *Vertex) Kind() Kind
- func (v *Vertex) Lookup(f Feature) *Vertex
- func (v *Vertex) MatchAndInsert(ctx *OpContext, arc *Vertex)
- func (v *Vertex) OptionalTypes() OptionalType
- func (v *Vertex) Path() []Feature
- func (v *Vertex) Rooted() bool
- func (v *Vertex) SetValue(ctx *OpContext, value BaseValue) *Bottom
- func (v *Vertex) Source() ast.Node
- func (v *Vertex) Status() vertexStatus
- func (v *Vertex) ToDataAll(ctx *OpContext) *Vertex
- func (v *Vertex) ToDataSingle() *Vertex
- func (v *Vertex) Value() Value
- type YieldFunc
- type Yielder
Constants ¶
const ( // PARENT dependencies are used to track the completion of parent // closedContexts within the closedness tree. PARENT depKind = iota + 1 // ARC dependencies are used to track the completion of corresponding // closedContexts in parent Vertices. ARC // NOTIFY dependencies keep a note while dependent conjuncts are collected NOTIFY // root node of source // TASK dependencies are used to track the completion of a task. TASK // EVAL tracks that the conjunct associated with a closeContext has been // inserted using scheduleConjunct. A closeContext may not be deleted // as long as the conjunct has not been evaluated yet. // This prevents a node from being released if an ARC decrement happens // before a node is evaluated. EVAL // ROOT dependencies are used to track that all nodes of parents are // added to a tree. ROOT // Always refers to self. // INIT dependencies are used to hold ownership of a closeContext during // initialization and prevent it from being finalized when scheduling a // node's conjuncts. INIT // DEFER is used to track recursive processing of a node. DEFER // Always refers to self. // TEST is used for testing notifications. TEST // Always refers to self. )
Variables ¶
var Debug bool = os.Getenv("CUE_DEBUG") != "0"
Debug sets whether extra aggressive checking should be done. This should typically default to true for pre-releases and default to false otherwise.
var DebugDeps = false
DebugDeps enables dependency tracking for debugging purposes. It is off by default, as it adds a significant overhead.
TODO: hook this init CUE_DEBUG, once we have set this up as a single environment variable. For instance, CUE_DEBUG=matchdeps=1.
var DebugSort int
DebugSort specifies that arcs be sorted consistently between implementations.
0: default 1: sort by Feature: this should be consistent between implementations where there is no change in the compiler and indexing code. 2: alphabetical
var Verbosity int
Verbosity sets the log level. There are currently only two levels:
0: no logging 1: logging
Functions ¶
func Accept ¶
Accept determines whether f is allowed in n. It uses the OpContext for caching administrative fields.
func AddStats ¶ added in v0.5.0
func AddStats(ctx *OpContext)
AddStats adds the stats of the given OpContext to the global counters.
func AssertConcreteIsPossible ¶
Assert that the given expression can evaluate to a concrete value.
func Assertf ¶
Assert panics if the condition is false. Assert can be used to check for conditions that are considers to break an internal variant or unexpected condition, but that nonetheless probably will be handled correctly down the line. For instance, a faulty condition could lead to error being caught down the road, but resulting in an inaccurate error message. In production code it is better to deal with the bad error message than to panic.
It is advisable for each use of Assert to document how the error is expected to be handled down the line.
func DebugSortArcs ¶ added in v0.4.3
func DebugSortFields ¶ added in v0.4.3
func HiddenKey ¶ added in v0.5.0
HiddenKey constructs the uniquely identifying string for a hidden fields and its package.
func IsDef ¶
IsDef reports whether an expressions is a reference that references a definition anywhere in its selection path.
TODO(performance): this should be merged with resolve(). But for now keeping this code isolated makes it easier to see what it is for.
func TotalStats ¶ added in v0.5.0
TotalStats returns the aggregate counts of all operations calling AddStats.
Types ¶
type ArcType ¶ added in v0.6.0
type ArcType uint8
const ( // ArcMember means that this arc is a normal non-optional field // (including regular, hidden, and definition fields). ArcMember ArcType = iota // ArcRequired is like optional, but requires that a field be specified. // Fields are of the form foo!. ArcRequired // ArcOptional represents fields of the form foo? and defines constraints // for foo in case it is defined. ArcOptional // ArcPending means that it is not known yet whether an arc exists and that // its conjuncts need to be processed to find out. This happens when an arc // is provisionally added as part of a comprehension, but when this // comprehension has not yet yielded any results. ArcPending // ArcNotPresent indicates that this arc is not present and, unlike // ArcPending, needs no further processing. ArcNotPresent )
func ConstraintFromToken ¶ added in v0.6.0
ConstraintFromToken converts a given AST constraint token to the corresponding ArcType.
type BaseValue ¶
type BaseValue interface {
Kind() Kind
}
A BaseValue is any Value or a *Marker. It indicates the type of a Vertex.
type BasicType ¶
BasicType represents all values of a certain Kind. It can be used as a Value and Expr.
string int num bool
func (*BasicType) Concreteness ¶
func (*BasicType) Concreteness() Concreteness
type BinaryExpr ¶
type BinaryExpr struct { Src *ast.BinaryExpr Op Op X Expr Y Expr }
BinaryExpr is a binary expression.
X + Y X & Y
func (*BinaryExpr) Source ¶
func (x *BinaryExpr) Source() ast.Node
type Bool ¶
Bool is a boolean value. It can be used as a Value and Expr.
func (*Bool) Concreteness ¶
func (*Bool) Concreteness() Concreteness
type Bottom ¶
type Bottom struct { Src ast.Node Err errors.Error Code ErrorCode // Permanent indicates whether an incomplete error can be // resolved later without making the configuration more specific. // This may happen when an arc isn't fully resolved yet. Permanent bool HasRecursive bool ChildError bool // Err is the error of the child NotExists bool // This error originated from a failed lookup. ForCycle bool // this is a for cycle // Value holds the computed value so far in case Value Value }
Bottom represents an error or bottom symbol.
Although a Bottom node holds control data, it should not be created until the control information already resulted in an error.
func CombineErrors ¶
CombineErrors combines two errors that originate at the same Vertex.
func NewRequiredNotPresentError ¶ added in v0.6.0
func (*Bottom) Concreteness ¶
func (*Bottom) Concreteness() Concreteness
func (*Bottom) IsIncomplete ¶
func (*Bottom) Specialize ¶
type BoundValue ¶
A BoundValue is a fully evaluated unary comparator that can be used to validate other values.
<5 =~"Name$"
func (*BoundValue) Concreteness ¶
func (*BoundValue) Concreteness() Concreteness
func (*BoundValue) Kind ¶
func (x *BoundValue) Kind() Kind
func (*BoundValue) Source ¶
func (x *BoundValue) Source() ast.Node
type Builtin ¶
type Builtin struct { // TODO: make these values for better type checking. Params []Param Result Kind Func func(c *OpContext, args []Value) Expr Package Feature Name string }
A Builtin is a value representing a native function call.
func (*Builtin) BareValidator ¶
func (x *Builtin) BareValidator() *BuiltinValidator
func (*Builtin) Concreteness ¶
func (*Builtin) Concreteness() Concreteness
func (*Builtin) IsValidator ¶
IsValidator reports whether b should be interpreted as a Validator for the given number of arguments.
type BuiltinValidator ¶
type BuiltinValidator struct { Src *CallExpr Builtin *Builtin Args []Value // any but the first value }
A BuiltinValidator is a Value that results from evaluation a partial call to a builtin (using CallExpr).
strings.MinRunes(4)
func (*BuiltinValidator) Concreteness ¶
func (*BuiltinValidator) Concreteness() Concreteness
func (*BuiltinValidator) Kind ¶
func (x *BuiltinValidator) Kind() Kind
func (*BuiltinValidator) Pos ¶
func (x *BuiltinValidator) Pos() token.Pos
func (*BuiltinValidator) Source ¶
func (x *BuiltinValidator) Source() ast.Node
type BulkOptionalField ¶
type BulkOptionalField struct { Src *ast.Field // Ellipsis or Field Filter Expr Value Expr Label Feature // for reference and formatting }
A BulkOptionalField represents a set of optional field.
[expr]: expr
func (*BulkOptionalField) Source ¶
func (x *BulkOptionalField) Source() ast.Node
type Bytes ¶
Bytes is a bytes value. It can be used as a Value and Expr.
func (*Bytes) Concreteness ¶
func (*Bytes) Concreteness() Concreteness
type CloseInfo ¶
type CloseInfo struct { // IsClosed is true if this conjunct represents a single level of closing // as indicated by the closed builtin. IsClosed bool // FromEmbed indicates whether this conjunct was inserted because of an // embedding. This flag is sticky: it will be set for conjuncts created // from fields defined by this conjunct. // NOTE: only used when using closeContext. FromEmbed bool // FromDef indicates whether this conjunct was inserted because of a // definition. This flag is sticky: it will be set for conjuncts created // from fields defined by this conjunct. // NOTE: only used when using closeContext. FromDef bool // FieldTypes indicates which kinds of fields (optional, dynamic, patterns, // etc.) are contained in this conjunct. FieldTypes OptionalType CycleInfo // contains filtered or unexported fields }
TODO: merge with closeInfo: this is a leftover of the refactoring.
func (*CloseInfo) AddPositions ¶
TODO(perf): remove: error positions should always be computed on demand in dedicated error types.
func (CloseInfo) IsInOneOf ¶
IsInOneOf reports whether c is contained within any of the span types in the given mask.
func (CloseInfo) RootSpanType ¶
func (CloseInfo) SpawnEmbed ¶
TODO(perf): use on StructInfo. Then if parent and expression are the same it is possible to use cached value.
func (CloseInfo) SpawnGroup ¶
SpawnGroup is used for structs that contain embeddings that may end up closing the struct. This is to force that `b` is not allowed in
a: {#foo} & {b: int}
type Comprehension ¶ added in v0.4.3
type Comprehension struct { Syntax ast.Node // Clauses is the list of for, if, and other clauses of a comprehension, // not including the yielded value (in curly braces). Clauses []Yielder // Value can be either a StructLit if this is a compiled expression or // a Field if this is a computed Comprehension. Value holds a Field, // rather than an Expr, in the latter case to preserve as much position // information as possible. Value Node // contains filtered or unexported fields }
func (*Comprehension) DidResolve ¶ added in v0.5.0
func (x *Comprehension) DidResolve() bool
DidResolve reports whether a comprehension was processed and resulted in at least one yielded value.
func (*Comprehension) Envs ¶ added in v0.5.0
func (c *Comprehension) Envs() []*Environment
Envs returns all Environments yielded from an evaluated comprehension. Together with the Comprehension value, each Environment represents a result value of the comprehension.
func (*Comprehension) Nest ¶ added in v0.5.0
func (c *Comprehension) Nest() int
Nest returns the nesting level of void arcs of this comprehension.
func (*Comprehension) Source ¶ added in v0.4.3
func (x *Comprehension) Source() ast.Node
type Concreteness ¶
type Concreteness int
Concreteness is a measure of the level of concreteness of a value, where lower values mean more concrete.
const ( BottomLevel Concreteness = iota // Concrete indicates a concrete scalar value, list or struct. Concrete // Constraint indicates a non-concrete scalar value that is more specific, // than a top-level type. Constraint // PrimitiveType indicates a top-level specific type, for instance, string, // bytes, number, or bool. Type // Any indicates any value, or top. Any )
type Conjunct ¶
type Conjunct struct { Env *Environment // CloseInfo is a unique number that tracks a group of conjuncts that need // belong to a single originating definition. CloseInfo CloseInfo // contains filtered or unexported fields }
An Conjunct is an Environment-Expr pair. The Environment is the starting point for reference lookup for any reference contained in X.
func MakeConjunct ¶
func MakeConjunct(env *Environment, x Node, id CloseInfo) Conjunct
func MakeRootConjunct ¶
func MakeRootConjunct(env *Environment, x Node) Conjunct
MakeRootConjunct creates a conjunct from the given environment and node. It panics if x cannot be used as an expression.
func (*Conjunct) Elem ¶ added in v0.4.3
Elem retrieves the Elem form of the contained conjunct. If it is a Field, it will return the field value.
type ConjunctGroup ¶ added in v0.8.0
type ConjunctGroup []Conjunct
A ConjunctGroup is an Elem that is used for internal grouping of Conjuncts only.
func (*ConjunctGroup) Source ¶ added in v0.8.0
func (g *ConjunctGroup) Source() ast.Node
type Conjunction ¶
A Conjunction is a conjunction of values that cannot be represented as a single value. It is the result of unification.
func (*Conjunction) Concreteness ¶
func (*Conjunction) Concreteness() Concreteness
func (*Conjunction) Kind ¶
func (x *Conjunction) Kind() Kind
func (*Conjunction) Source ¶
func (x *Conjunction) Source() ast.Node
type Constraints ¶ added in v0.7.0
type Constraints struct { // Pairs lists Pattern-Constraint pairs. Pairs []PatternConstraint // TODO(perf): move to Arcs? // Allowed is a Value that defines the set of all allowed fields. // To check if a field is allowed, its correpsonding CUE value can be // unified with this value. Allowed Value }
Constraints keeps track of pattern constraints and the set of allowed fields.
type CycleInfo ¶ added in v0.5.0
type CycleInfo struct { // IsCyclic indicates whether this conjunct, or any of its ancestors, // had a violating cycle. IsCyclic bool // Inline is used to detect expressions referencing themselves, for instance: // {x: out, out: x}.out Inline bool // TODO(perf): pack this in with CloseInfo. Make an uint32 pointing into // a buffer maintained in OpContext, using a mark-release mechanism. Refs *RefNode }
type Decl ¶
type Decl interface { Node // contains filtered or unexported methods }
A Decl represents all valid StructLit elements.
type Disjunction ¶
type Disjunction struct { Src ast.Expr // Values are the non-error disjuncts of this expression. The first // NumDefaults values are default values. Values []Value Errors *Bottom // []bottom // NumDefaults indicates the number of default values. NumDefaults int HasDefaults bool }
A disjunction is a disjunction of values. It is the result of expanding a DisjunctionExpr if the expression cannot be represented as a single value.
func (*Disjunction) Concreteness ¶
func (*Disjunction) Concreteness() Concreteness
func (*Disjunction) Default ¶
func (d *Disjunction) Default() Value
func (*Disjunction) Kind ¶
func (x *Disjunction) Kind() Kind
func (*Disjunction) Source ¶
func (x *Disjunction) Source() ast.Node
type DisjunctionExpr ¶
type DisjunctionExpr struct { Src *ast.BinaryExpr Values []Disjunct HasDefaults bool }
A Disjunction represents a disjunction, where each disjunct may or may not be marked as a default.
func (*DisjunctionExpr) Source ¶
func (x *DisjunctionExpr) Source() ast.Node
type DynamicField ¶
A DynamicField represents a regular field for which the key is computed.
"\(expr)": expr (expr): expr
func (*DynamicField) Source ¶
func (x *DynamicField) Source() ast.Node
type DynamicReference ¶
type DynamicReference struct { Src *ast.Ident UpCount int32 Label Expr // TODO: only use aliases and store the actual expression only in the scope. // The feature is unique for every instance. This will also allow dynamic // fields to be ordered among normal fields. // // This could also be used to assign labels to embedded values, if they // don't match a label. Alias Feature }
A DynamicReference is like a FieldReference, but with a computed label.
Example: an X referring to
X=(x): v X="\(x)": v X=[string]: v
func (*DynamicReference) EvaluateLabel ¶ added in v0.5.0
func (x *DynamicReference) EvaluateLabel(ctx *OpContext, env *Environment) Feature
func (*DynamicReference) Source ¶
func (x *DynamicReference) Source() ast.Node
type Elem ¶
type Elem interface { Decl // contains filtered or unexported methods }
An Elem represents all value ListLit elements.
All Elem values can be used as a Decl.
type Environment ¶
type Environment struct { Up *Environment Vertex *Vertex // DynamicLabel is only set when instantiating a field from a pattern // constraint. It is used to resolve label references. DynamicLabel Feature // contains filtered or unexported fields }
An Environment links the parent scopes for identifier lookup to a composite node. Each conjunct that make up node in the tree can be associated with a different environment (although some conjuncts may share an Environment).
type ErrorCode ¶
type ErrorCode int8
ErrorCode indicates the type of error. The type of error may influence control flow. No other aspects of an error may influence control flow.
const ( // An EvalError is a fatal evaluation error. EvalError ErrorCode = iota // A UserError is a fatal error originating from the user. UserError // StructuralCycleError means a structural cycle was found. Structural // cycles are permanent errors, but they are not passed up recursively, // as a unification of a value with a structural cycle with one that // doesn't may still give a useful result. StructuralCycleError // IncompleteError means an evaluation could not complete because of // insufficient information that may still be added later. IncompleteError // A CycleError indicates a reference error. It is considered to be // an incomplete error, as reference errors may be broken by providing // a concrete value. CycleError )
type Evaluator ¶
type Evaluator interface { Node // contains filtered or unexported methods }
An Evaluator provides a method to convert to a value.
type Expr ¶
type Expr interface { Elem // contains filtered or unexported methods }
An Expr corresponds to an ast.Expr.
All Expr values can be used as an Elem or Decl.
type Feature ¶
type Feature uint32
A Feature is an encoded form of a label which comprises a compact representation of an integer or string label as well as a label type.
const ( InvalidLabel Feature = 0 // MaxIndex indicates the maximum number of unique strings that are used for // labels within this CUE implementation. MaxIndex = 1<<(32-indexShift) - 1 )
InvalidLabel is an encoding of an erroneous label.
var ( AnyDefinition Feature = makeLabel(MaxIndex, DefinitionLabel) AnyHidden Feature = makeLabel(MaxIndex, HiddenLabel) AnyString Feature = makeLabel(MaxIndex, StringLabel) AnyIndex Feature = makeLabel(MaxIndex, IntLabel) )
These labels can be used for wildcard queries.
func MakeIdentLabel ¶
func MakeIdentLabel(r StringIndexer, s, pkgpath string) Feature
MakeIdentLabel creates a label for the given identifier.
func MakeIntLabel ¶ added in v0.5.0
func MakeIntLabel(t FeatureType, i int64) Feature
MakeIntLabel creates an integer label.
func MakeLetLabel ¶ added in v0.5.0
func MakeLetLabel(r StringIndexer, s string) Feature
MakeLetLabel creates a label for the given let identifier s.
A let declaration is always logically unique within its scope and will never unify with a let field of another struct. This is enforced by ensuring that the let identifier is unique across an entire configuration. This, in turn, is done by adding a unique number to each let identifier.
func MakeNamedLabel ¶ added in v0.5.0
func MakeNamedLabel(r StringIndexer, t FeatureType, s string) Feature
MakeNamedLabel creates a feature for the given name and feature type.
func MakeStringLabel ¶
func MakeStringLabel(r StringIndexer, s string) Feature
MakeStringLabel creates a label for the given string.
func (Feature) IdentString ¶
func (f Feature) IdentString(index StringIndexer) string
IdentString reports the identifier of f. The result is undefined if f is not an identifier label.
func (Feature) IsDef ¶
IsDef reports whether the label is a definition (an identifier starting with # or _#.
func (Feature) IsHidden ¶
IsHidden reports whether this label is hidden (an identifier starting with _ or #_).
func (Feature) IsLet ¶ added in v0.5.0
IsLet reports whether this label is a let field (like `let X = value`).
func (Feature) PkgID ¶
func (f Feature) PkgID(index StringIndexer) string
PkgID returns the package identifier, composed of the module and package name, associated with this identifier. It will return "" if this is not a hidden label.
func (Feature) RawString ¶ added in v0.5.0
func (f Feature) RawString(index StringIndexer) string
RawString reports the underlying string value of f without interpretation.
func (Feature) SelectorString ¶
func (f Feature) SelectorString(index StringIndexer) string
SelectorString reports the shortest string representation of f when used as a selector.
func (Feature) StringValue ¶
func (f Feature) StringValue(index StringIndexer) string
StringValue reports the string value of f, which must be a string label.
type FeatureType ¶
type FeatureType int8
A FeatureType indicates the type of label.
const ( InvalidLabelType FeatureType = iota StringLabel IntLabel DefinitionLabel HiddenLabel HiddenDefinitionLabel LetLabel )
func (FeatureType) IsDef ¶
func (f FeatureType) IsDef() bool
func (FeatureType) IsHidden ¶
func (f FeatureType) IsHidden() bool
func (FeatureType) IsLet ¶ added in v0.5.0
func (f FeatureType) IsLet() bool
type Field ¶
Field represents a regular field or field constraint with a fixed label. The label can be a regular field, definition or hidden field.
foo: bar #foo: bar _foo: bar
Legacy:
Foo :: bar
type FieldReference ¶
A FieldReference represents a lexical reference to a field.
a
func (*FieldReference) Source ¶
func (x *FieldReference) Source() ast.Node
type Flag ¶
type Flag uint16
const ( // IgnoreOptional allows optional information to be ignored. This only // applies when CheckStructural is given. IgnoreOptional Flag = 1 << iota // CheckStructural indicates that closedness information should be // considered for equality. Equal may return false even when values are // equal. CheckStructural Flag = 1 << iota )
type ForClause ¶
A ForClause represents a for clause of a comprehension. It can be used as a struct or list element.
for k, v in src {}
type IfClause ¶
An IfClause represents an if clause of a comprehension. It can be used as a struct or list element.
if cond {}
type ImportReference ¶
type ImportReference struct { Src *ast.Ident ImportPath Feature Label Feature // for informative purposes }
An ImportReference refers to an imported package.
Example: strings in
import "strings" strings.ToLower("Upper")
func (*ImportReference) Source ¶
func (x *ImportReference) Source() ast.Node
type Interpolation ¶
type Interpolation struct { Src *ast.Interpolation K Kind // string or bytes Parts []Expr // odd: strings, even sources }
An Interpolation is a string interpolation.
"a \(b) c"
func (*Interpolation) Source ¶
func (x *Interpolation) Source() ast.Node
type Kind ¶
type Kind uint16
Kind reports the Value kind.
const ( NullKind Kind = (1 << iota) BoolKind IntKind FloatKind StringKind BytesKind FuncKind ListKind StructKind NumberKind = IntKind | FloatKind BottomKind Kind = 0 NumKind = IntKind | FloatKind TopKind Kind = (allKinds - 1) // all kinds, but not references ScalarKinds = NullKind | BoolKind | IntKind | FloatKind | StringKind | BytesKind CompositKind = StructKind | ListKind )
func (Kind) IsAnyOf ¶
IsAnyOf reports whether k is any of the given kinds.
For instances, k.IsAnyOf(String|Bytes) reports whether k overlaps with the String or Bytes kind.
func (Kind) String ¶
String returns the representation of the Kind as a CUE expression. For example:
(IntKind|ListKind).String()
will return:
(int|[...])
func (Kind) TypeString ¶
TypeString is like String, but returns a string representation of a valid CUE type.
type LabelReference ¶
A LabelReference refers to the string or integer value of a label.
Example: an X referring to
[X=Pattern]: b: a
func (*LabelReference) Source ¶
func (x *LabelReference) Source() ast.Node
type LetField ¶ added in v0.5.0
type LetField struct { Src *ast.LetClause Label Feature // IsMulti is true when this let field should be replicated for each // incarnation. This is the case when its expression refers to the // variables of a for comprehension embedded within a struct. IsMulti bool Value Expr }
A LetField represents a field that is only visible in the local scope.
let X = expr
type LetReference ¶
type LetReference struct { Src *ast.Ident UpCount int32 Label Feature // for informative purposes X Expr }
A LetReference evaluates a let expression in its original environment.
Example: an X referring to
let X = x
func (*LetReference) Source ¶
func (x *LetReference) Source() ast.Node
type ListLit ¶
type ListLit struct { Src *ast.ListLit // scalars, comprehensions, ...T Elems []Elem // contains filtered or unexported fields }
A ListLit represents an unevaluated list literal.
[a, for x in src { ... }, b, ...T]
type ListMarker ¶
func (*ListMarker) Kind ¶
func (x *ListMarker) Kind() Kind
func (*ListMarker) Source ¶
func (x *ListMarker) Source() ast.Node
type NodeLink ¶
type NodeLink struct {
Node *Vertex
}
A NodeLink is used during computation to refer to an existing Vertex. It is used to signal a potential cycle or reference. Note that a NodeLink may be used as a value. This should be taken into account.
func (*NodeLink) Concreteness ¶
func (x *NodeLink) Concreteness() Concreteness
type Null ¶
Null represents null. It can be used as a Value and Expr.
func (*Null) Concreteness ¶
func (*Null) Concreteness() Concreteness
type Num ¶
type Num struct { Src ast.Node K Kind // needed? X apd.Decimal // Is integer if the apd.Decimal is an integer. }
Num is a numeric value. It can be used as a Value and Expr.
func (*Num) Concreteness ¶
func (*Num) Concreteness() Concreteness
type Op ¶
type Op int
Op indicates the operation at the top of an expression tree of the expression use to evaluate a value.
const ( NoOp Op = iota AndOp OrOp SelectorOp IndexOp SliceOp CallOp BoolAndOp BoolOrOp EqualOp NotOp NotEqualOp LessThanOp LessEqualOp GreaterThanOp GreaterEqualOp MatchOp NotMatchOp AddOp SubtractOp MultiplyOp FloatQuotientOp IntQuotientOp IntRemainderOp IntDivideOp IntModuloOp InterpolationOp )
Values of Op.
type OpContext ¶
type OpContext struct { Runtime Format func(Node) string Version internal.EvaluatorVersion // Copied from Runtime // The current call is a validator. A builtin may return a boolean false // along with an error message describing a validation error. If the latter // is wrapped in an internal.ValidationError, it will only be interpreted // as an error if this is true. // TODO: strictly separate validators and functions. IsValidator bool // contains filtered or unexported fields }
An OpContext implements CUE's unification operation. It only operates on values that are created with the Runtime with which an OpContext is associated. An OpContext is not goroutine safe and only one goroutine may use an OpContext at a time.
func NewContext ¶
NewContext creates an operation context.
func (*OpContext) AddErr ¶
AddErr records an error in OpContext. It returns errors collected so far.
func (*OpContext) AddErrf ¶
AddErrf records an error in OpContext. It returns errors collected so far.
func (*OpContext) AddPosition ¶
func (*OpContext) Assertf ¶
Assertf either panics or reports an error to c if the condition is not met.
func (*OpContext) Env ¶
func (c *OpContext) Env(upCount int32) *Environment
func (*OpContext) Evaluate ¶
func (c *OpContext) Evaluate(env *Environment, x Expr) (result Value, complete bool)
Evaluate evaluates an expression within the given environment and indicates whether the result is complete. It will always return a non-nil result.
func (*OpContext) HasErr ¶
HasErr reports whether any error was reported, including whether value was incomplete.
func (*OpContext) Lookup ¶ added in v0.5.0
func (c *OpContext) Lookup(env *Environment, r Resolver) (*Vertex, *Bottom)
Lookup looks up r in env without further resolving the value.
func (*OpContext) MarkPositions ¶
MarkPositions marks the current position stack.
func (*OpContext) NewErrf ¶
NewErrf creates a *Bottom value and returns it. The returned uses the current source as the point of origin of the error.
func (*OpContext) NewPosf ¶
func (c *OpContext) NewPosf(p token.Pos, format string, args ...interface{}) *ValueError
func (*OpContext) Newf ¶
func (c *OpContext) Newf(format string, args ...interface{}) *ValueError
func (*OpContext) PathToString ¶ added in v0.5.0
PathToString creates a pretty-printed path of the given list of features.
func (*OpContext) PushArc ¶
PushArc signals c that arc v is currently being processed for the purpose of error reporting. PopArc should be called with the returned value once processing of v is completed.
func (*OpContext) PushConjunct ¶ added in v0.5.0
func (*OpContext) PushState ¶
func (c *OpContext) PushState(env *Environment, src ast.Node) (saved frame)
func (*OpContext) RawElems ¶ added in v0.5.0
RawElems returns the elements of the list without evaluating them.
func (*OpContext) ReleasePositions ¶
ReleasePositions sets the position state to one from a call to MarkPositions.
func (*OpContext) Resolve ¶
Resolve finds a node in the tree.
Should only be used to insert Conjuncts. TODO: perhaps only return Conjuncts and error.
func (*OpContext) StringLabel ¶
StringLabel converts s to a string label.
func (*OpContext) StringValue ¶
type OptionalType ¶
type OptionalType int8
OptionalType is a bit field of the type of optional constraints in use by an Acceptor.
const ( HasField OptionalType = 1 << iota // X: T HasDynamic // (X): T or "\(X)": T HasPattern // [X]: T HasComplexPattern // anything but a basic type HasAdditional // ...T IsOpen // Defined for all fields )
type Param ¶
type Param struct { Name Feature // name of the argument; mostly for documentation Value Value // Could become Value later, using disjunctions for defaults. }
type PatternConstraint ¶ added in v0.7.0
A PatternConstraint represents a single
[pattern]: T.
The Vertex holds a list of conjuncts to represent the constraints. We use a Vertex so that these can be evaluated and compared for equality. Unlike for regular Vertex values, CloseInfo.closeContext is set for constraints: it is needed when matching subfields to ensure that conjuncts get inserted into the proper groups.
type RefNode ¶ added in v0.5.0
type RefNode struct { Ref Resolver Arc *Vertex // Ref points to this Vertex // Node is the Vertex of which Ref is evaluated as a conjunct. // If there is a cyclic reference (not structural cycle), then // the reference will have the same node. This allows detecting reference // cycles for nodes referring to nodes with an evaluation cycle // (mode tracked to Evaluating status). Examples: // // a: x // Y: x // x: {Y} // // and // // Y: x.b // a: x // x: b: {Y} | null // // In both cases there are not structural cycles and thus need to be // distinguished from regular structural cycles. Node *Vertex Next *RefNode Depth int32 }
A RefNode is a linked list of associated references.
type Resolver ¶
type Resolver interface { Node // contains filtered or unexported methods }
A Resolver represents a reference somewhere else within a tree that resolves a value.
type Runtime ¶
type Runtime interface { // StringIndexer allows for converting string labels to and from a // canonical numeric representation. StringIndexer // LoadImport loads a unique Vertex associated with a given import path. It // returns nil if no import for this package could be found. LoadImport(importPath string) *Vertex // StoreType associates a CUE expression with a Go type. StoreType(t reflect.Type, src ast.Expr, expr Expr) // LoadType retrieves a previously stored CUE expression for a given Go // type if available. LoadType(t reflect.Type) (src ast.Expr, expr Expr, ok bool) EvaluatorVersion() internal.EvaluatorVersion }
Runtime defines an interface for low-level representation conversion and lookup.
type SelectorExpr ¶
type SelectorExpr struct { Src *ast.SelectorExpr X Expr Sel Feature }
A SelectorExpr looks up a fixed field in an expression.
a.sel
func (*SelectorExpr) Source ¶
func (x *SelectorExpr) Source() ast.Node
type SpanType ¶
type SpanType uint8
A SpanType is used to indicate whether a CUE value is within the scope of a certain CUE language construct, the span type.
type String ¶
String is a string value. It can be used as a Value and Expr.
func (*String) Concreteness ¶
func (*String) Concreteness() Concreteness
type StringIndexer ¶
type StringIndexer interface { // ToIndex returns a unique positive index for s (0 < index < 2^28-1). // // For each pair of strings s and t it must return the same index if and // only if s == t. StringToIndex(s string) (index int64) // ToString returns a string s for index such that ToIndex(s) == index. IndexToString(index int64) string // NextUniqueID returns a new unique identifier. NextUniqueID() uint64 }
A StringIndexer coverts strings to and from an index that is unique for a given string.
type StructInfo ¶
type StructInfo struct { *StructLit Env *Environment CloseInfo // Embed indicates the struct in which this struct is embedded (originally), // or nil if this is a root structure. // Embed *StructInfo // Context *RefInfo // the location from which this struct originates. Disable bool Embedding bool }
func (*StructInfo) MatchAndInsert ¶
func (o *StructInfo) MatchAndInsert(c *OpContext, arc *Vertex)
MatchAndInsert finds matching optional parts for a given Arc and adds its conjuncts. Bulk fields are only applied if no fields match, and additional constraints are only added if neither regular nor bulk fields match.
type StructLit ¶
type StructLit struct { Src ast.Node // ast.File or ast.StructLit Decls []Decl // field marks the optional conjuncts of all explicit Fields. // Required Fields are marked as empty Fields []FieldInfo Dynamic []*DynamicField // excluded are all literal fields that already exist. Bulk []*BulkOptionalField Additional []*Ellipsis HasEmbed bool IsOpen bool // has a ... // contains filtered or unexported fields }
A StructLit represents an unevaluated struct literal or file body.
func (*StructLit) HasOptional ¶
func (*StructLit) OptionalTypes ¶
func (o *StructLit) OptionalTypes() OptionalType
type StructMarker ¶
type StructMarker struct { // NeedClose is used to signal that the evaluator should close this struct. // It is only set by the close builtin. NeedClose bool }
func (*StructMarker) Kind ¶
func (x *StructMarker) Kind() Kind
func (*StructMarker) Source ¶
func (x *StructMarker) Source() ast.Node
type Top ¶
Top represents all possible values. It can be used as a Value and Expr.
func (*Top) Concreteness ¶
func (*Top) Concreteness() Concreteness
type Validator ¶
type Validator interface { Value // contains filtered or unexported methods }
A Validator validates a Value. All Validators are Values.
func SimplifyValidator ¶
SimplifyValidator simplifies non-bound validators.
Currently this only checks for pure equality. In the future this can be used to simplify certain builtin validators analogously to how we simplify bounds now.
type Value ¶
type Value interface { Expr Concreteness() Concreteness Kind() Kind }
A Value represents a node in the evaluated data graph.
All Values values can also be used as a Expr.
func BinOp ¶
BinOp handles all operations except AndOp and OrOp. This includes processing unary comparators such as '<4' and '=~"foo"'.
BinOp returns nil if not both left and right are concrete.
func SimplifyBounds ¶
func SimplifyBounds(ctx *OpContext, k Kind, x, y *BoundValue) Value
SimplifyBounds collapses bounds if possible. The bound values must be concrete. It returns nil if the bound values cannot be collapsed.
k represents additional type constraints, such as `int`.
type ValueClause ¶
type ValueClause struct { Node // contains filtered or unexported fields }
ValueClause represents a wrapper Environment in a chained clause list to account for the unwrapped struct. It is never created by the compiler and serves as a dynamic element only.
type ValueError ¶
A ValueError is returned as a result of evaluating a value.
func (*ValueError) AddClosedPositions ¶
func (v *ValueError) AddClosedPositions(c CloseInfo)
func (*ValueError) AddPosition ¶
func (v *ValueError) AddPosition(n Node)
func (*ValueError) Error ¶
func (e *ValueError) Error() string
func (*ValueError) InputPositions ¶
func (e *ValueError) InputPositions() (a []token.Pos)
func (*ValueError) Path ¶
func (e *ValueError) Path() (a []string)
func (*ValueError) Position ¶
func (e *ValueError) Position() token.Pos
type ValueReference ¶ added in v0.4.0
type ValueReference struct { Src *ast.Ident UpCount int32 Label Feature // for informative purposes }
A ValueReference represents a lexical reference to a value.
Example: an X referring to
a: X=b
func (*ValueReference) Source ¶ added in v0.4.0
func (x *ValueReference) Source() ast.Node
type Vertex ¶
type Vertex struct { // Parent links to a parent Vertex. This parent should only be used to // access the parent's Label field to find the relative location within a // tree. Parent *Vertex // Label is the feature leading to this vertex. Label Feature // Closed indicates whether this Vertex is recursively closed. This is the // case, for instance, if it is a node in a definition or if one of the // conjuncts, or ancestor conjuncts, is a definition. Closed bool // MultiLet indicates whether multiple let fields were added from // different sources. If true, a LetReference must be resolved using // the per-Environment value cache. MultiLet bool // After this is set, no more arcs may be added during evaluation. This is // set, for instance, after a Vertex is used as a source for comprehensions, // or any other operation that relies on the set of arcs being constant. LockArcs bool // IsDynamic signifies whether this struct is computed as part of an // expression and not part of the static evaluation tree. // Used for cycle detection. IsDynamic bool // ArcType indicates the level of optionality of this arc. ArcType ArcType // BaseValue is the value associated with this vertex. For lists and structs // this is a sentinel value indicating its kind. BaseValue BaseValue // ChildErrors is the collection of all errors of children. ChildErrors *Bottom // The parent of nodes can be followed to determine the path within the // configuration of this node. // Value Value Arcs []*Vertex // arcs are sorted in display order. // PatternConstraints are additional constraints that match more nodes. // Constraints that match existing Arcs already have their conjuncts // mixed in. // TODO: either put in StructMarker/ListMarker or integrate with Arcs // so that this pointer is unnecessary. PatternConstraints *Constraints // Conjuncts lists the structs that ultimately formed this Composite value. // This includes all selected disjuncts. // // This value may be nil, in which case the Arcs are considered to define // the final value of this Vertex. Conjuncts []Conjunct // Structs is a slice of struct literals that contributed to this value. // This information is used to compute the topological sort of arcs. Structs []*StructInfo // contains filtered or unexported fields }
A Vertex is a node in the value tree. It may be a leaf or internal node. It may have arcs to represent elements of a fully evaluated struct or list.
For structs, it only contains definitions and concrete fields. optional fields are dropped.
It maintains source information such as a list of conjuncts that contributed to the value.
func (*Vertex) Accept ¶
TODO: return error instead of boolean? (or at least have version that does.)
func (*Vertex) AddChildError ¶
AddChildError updates x to record an error that occurred in one of its descendent arcs. The resulting error will record the worst error code of the current error or recursive error.
If x is not already an error, the value is recorded in the error for reference.
func (*Vertex) AddConjunct ¶
AddConjunct adds the given Conjuncts to v if it doesn't already exist.
func (*Vertex) AddStruct ¶
func (v *Vertex) AddStruct(s *StructLit, env *Environment, ci CloseInfo) *StructInfo
func (*Vertex) CompleteArcs ¶ added in v0.6.0
CompleteArcs ensures the set of arcs has been computed.
func (*Vertex) Concreteness ¶
func (x *Vertex) Concreteness() Concreteness
func (*Vertex) Default ¶
Default returns the default value or itself if there is no default.
It also closes a list, representing its default value.
func (*Vertex) ForceDone ¶ added in v0.6.0
func (v *Vertex) ForceDone()
ForceDone prevents v from being evaluated.
func (*Vertex) GetArc ¶
GetArc returns a Vertex for the outgoing arc with label f. It creates and ads one if it doesn't yet exist.
func (*Vertex) Indirect ¶ added in v0.4.2
Indirect unrolls indirections of Vertex values. These may be introduced, for instance, by temporary bindings such as comprehension values. It returns v itself if v does not point to another Vertex.
func (*Vertex) IsClosedList ¶ added in v0.3.1
func (*Vertex) IsClosedStruct ¶ added in v0.3.1
func (*Vertex) IsConcrete ¶
func (*Vertex) IsConstraint ¶ added in v0.6.0
IsConstraint reports whether the Vertex is an optional or required field.
func (*Vertex) IsData ¶
IsData reports whether v should be interpreted in data mode. In other words, it tells whether optional field matching and non-regular fields, like definitions and hidden fields, should be ignored.
func (*Vertex) IsDefined ¶ added in v0.5.0
IsDefined indicates whether this arc is defined meaning it is not a required or optional constraint and not a "void" arc. It will evaluate the arc, and thus evaluate any comprehension, to make this determination.
func (*Vertex) IsInOneOf ¶ added in v0.4.0
IsInOneOf reports whether any of the Structs associated with v is contained within any of the span types in the given mask.
func (*Vertex) IsOptional ¶
IsOptional reports whether a field is explicitly defined as optional, as opposed to whether it is allowed by a pattern constraint.
func (*Vertex) IsRecursivelyClosed ¶ added in v0.4.0
IsRecursivelyClosed returns true if this value is either a definition or unified with a definition.
func (*Vertex) IsUnprocessed ¶ added in v0.6.0
IsUnprocessed reports whether v is unprocessed.
func (*Vertex) MatchAndInsert ¶
MatchAndInsert finds the conjuncts for optional fields, pattern constraints, and additional constraints that match f and inserts them in arc. Use f is 0 to match all additional constraints only.
func (*Vertex) OptionalTypes ¶
func (v *Vertex) OptionalTypes() OptionalType
func (*Vertex) Path ¶
Path computes the sequence of Features leading from the root to of the instance to this Vertex.
NOTE: this is for debugging purposes only.
func (*Vertex) Rooted ¶ added in v0.6.0
Rooted reports whether there is a path from the root of the tree to this Vertex.
func (*Vertex) ToDataAll ¶
ToDataAll returns a new v where v and all its descendents contain only the regular fields.
func (*Vertex) ToDataSingle ¶
ToDataSingle creates a new Vertex that represents just the regular fields of this vertex. Arcs are left untouched. It is used by cue.Eval to convert nodes to data on per-node basis.
type YieldFunc ¶
type YieldFunc func(env *Environment)