Documentation ¶
Overview ¶
Package typeutil defines various utilities for types, such as Map, a mapping from types.Type to interface{} values.
Index ¶
- func Dependencies(pkgs ...*types.Package) []*types.Package
- func IntuitiveMethodSet(T types.Type, msets *MethodSetCache) []*types.Selection
- type Hasher
- type Map
- func (m *Map) At(key types.Type) interface{}
- func (m *Map) Delete(key types.Type) bool
- func (m *Map) Iterate(f func(key types.Type, value interface{}))
- func (m *Map) Keys() []types.Type
- func (m *Map) KeysString() string
- func (m *Map) Len() int
- func (m *Map) Set(key types.Type, value interface{}) (prev interface{})
- func (m *Map) SetHasher(hasher Hasher)
- func (m *Map) String() string
- type MethodSetCache
Examples ¶
Constants ¶
This section is empty.
Variables ¶
This section is empty.
Functions ¶
func Dependencies ¶
Dependencies returns all dependencies of the specified packages.
Dependent packages appear in topological order: if package P imports package Q, Q appears earlier than P in the result. The algorithm follows import statements in the order they appear in the source code, so the result is a total order.
func IntuitiveMethodSet ¶
func IntuitiveMethodSet(T types.Type, msets *MethodSetCache) []*types.Selection
IntuitiveMethodSet returns the intuitive method set of a type T, which is the set of methods you can call on an addressable value of that type.
The result always contains MethodSet(T), and is exactly MethodSet(T) for interface types and for pointer-to-concrete types. For all other concrete types T, the result additionally contains each method belonging to *T if there is no identically named method on T itself.
This corresponds to user intuition about method sets; this function is intended only for user interfaces.
The order of the result is as for types.MethodSet(T).
Types ¶
type Hasher ¶
type Hasher struct {
// contains filtered or unexported fields
}
A Hasher maps each type to its hash value. For efficiency, a hasher uses memoization; thus its memory footprint grows monotonically over time. Hashers are not thread-safe. Hashers have reference semantics. Call MakeHasher to create a Hasher.
type Map ¶
type Map struct {
// contains filtered or unexported fields
}
Map is a hash-table-based mapping from types (types.Type) to arbitrary interface{} values. The concrete types that implement the Type interface are pointers. Since they are not canonicalized, == cannot be used to check for equivalence, and thus we cannot simply use a Go map.
Just as with map[K]V, a nil *Map is a valid empty map.
Not thread-safe.
Example ¶
package main import ( "fmt" "go/ast" "go/parser" "go/token" "go/types" "sort" "golang.org/x/tools/go/types/typeutil" ) func main() { const source = `package P var X []string var Y []string const p, q = 1.0, 2.0 func f(offset int32) (value byte, ok bool) func g(rune) (uint8, bool) ` // Parse and type-check the package. fset := token.NewFileSet() f, err := parser.ParseFile(fset, "P.go", source, 0) if err != nil { panic(err) } pkg, err := new(types.Config).Check("P", fset, []*ast.File{f}, nil) if err != nil { panic(err) } scope := pkg.Scope() // Group names of package-level objects by their type. var namesByType typeutil.Map // value is []string for _, name := range scope.Names() { T := scope.Lookup(name).Type() names, _ := namesByType.At(T).([]string) names = append(names, name) namesByType.Set(T, names) } // Format, sort, and print the map entries. var lines []string namesByType.Iterate(func(T types.Type, names interface{}) { lines = append(lines, fmt.Sprintf("%s %s", names, T)) }) sort.Strings(lines) for _, line := range lines { fmt.Println(line) } }
Output: [X Y] []string [f g] func(offset int32) (value byte, ok bool) [p q] untyped float
func (*Map) At ¶
At returns the map entry for the given key. The result is nil if the entry is not present.
func (*Map) Delete ¶
Delete removes the entry with the given key, if any. It returns true if the entry was found.
func (*Map) Iterate ¶
Iterate calls function f on each entry in the map in unspecified order.
If f should mutate the map, Iterate provides the same guarantees as Go maps: if f deletes a map entry that Iterate has not yet reached, f will not be invoked for it, but if f inserts a map entry that Iterate has not yet reached, whether or not f will be invoked for it is unspecified.
func (*Map) Keys ¶
Keys returns a new slice containing the set of map keys. The order is unspecified.
func (*Map) KeysString ¶
KeysString returns a string representation of the map's key set. Order is unspecified.
func (*Map) SetHasher ¶
SetHasher sets the hasher used by Map.
All Hashers are functionally equivalent but contain internal state used to cache the results of hashing previously seen types.
A single Hasher created by MakeHasher() may be shared among many Maps. This is recommended if the instances have many keys in common, as it will amortize the cost of hash computation.
A Hasher may grow without bound as new types are seen. Even when a type is deleted from the map, the Hasher never shrinks, since other types in the map may reference the deleted type indirectly.
Hashers are not thread-safe, and read-only operations such as Map.Lookup require updates to the hasher, so a full Mutex lock (not a read-lock) is require around all Map operations if a shared hasher is accessed from multiple threads.
If SetHasher is not called, the Map will create a private hasher at the first call to Insert.
type MethodSetCache ¶
type MethodSetCache struct {
// contains filtered or unexported fields
}
A MethodSetCache records the method set of each type T for which MethodSet(T) is called so that repeat queries are fast. The zero value is a ready-to-use cache instance.
func (*MethodSetCache) MethodSet ¶
func (cache *MethodSetCache) MethodSet(T types.Type) *types.MethodSet
MethodSet returns the method set of type T. It is thread-safe.
If cache is nil, this function is equivalent to types.NewMethodSet(T). Utility functions can thus expose an optional *MethodSetCache parameter to clients that care about performance.