src/cmd/compile/internal/types2/context.go - go - Git at Google

 // Copyright 2021 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package types2

 import (
 	"bytes"
 	"fmt"
 	"strconv"
 	"strings"
 	"sync"
 )

 // This file contains a definition of the type-checking context; an opaque type
 // that may be supplied by users during instantiation.
 //
 // Contexts serve two purposes:
 //  - reduce the duplication of identical instances
 //  - short-circuit instantiation cycles
 //
 // For the latter purpose, we must always have a context during instantiation,
 // whether or not it is supplied by the user. For both purposes, it must be the
 // case that hashing a pointer-identical type produces consistent results
 // (somewhat obviously).
 //
 // However, neither of these purposes require that our hash is perfect, and so
 // this was not an explicit design goal of the context type. In fact, due to
 // concurrent use it is convenient not to guarantee de-duplication.
 //
 // Nevertheless, in the future it could be helpful to allow users to leverage
 // contexts to canonicalize instances, and it would probably be possible to
 // achieve such a guarantee.

 // A Context is an opaque type checking context. It may be used to share
 // identical type instances across type-checked packages or calls to
 // Instantiate. Contexts are safe for concurrent use.
 //
 // The use of a shared context does not guarantee that identical instances are
 // deduplicated in all cases.
 type Context struct {
 	mu        sync.Mutex
 	typeMap   map[string][]ctxtEntry // type hash -> instances entries
 	nextID    int                    // next unique ID
 	originIDs map[Type]int           // origin type -> unique ID
 }

 type ctxtEntry struct {
 	orig     Type
 	targs    []Type
 	instance Type // = orig[targs]
 }

 // NewContext creates a new Context.
 func NewContext() *Context {
 	return &Context{
 		typeMap:   make(map[string][]ctxtEntry),
 		originIDs: make(map[Type]int),
 	}
 }

 // instanceHash returns a string representation of typ instantiated with targs.
 // The hash should be a perfect hash, though out of caution the type checker
 // does not assume this. The result is guaranteed to not contain blanks.
 func (ctxt *Context) instanceHash(orig Type, targs []Type) string {
 	assert(ctxt != nil)
 	assert(orig != nil)
 	var buf bytes.Buffer

 	h := newTypeHasher(&buf, ctxt)
 	h.string(strconv.Itoa(ctxt.getID(orig)))
 	// Because we've already written the unique origin ID this call to h.typ is
 	// unnecessary, but we leave it for hash readability. It can be removed later
 	// if performance is an issue.
 	h.typ(orig)
 	if len(targs) > 0 {
 		// TODO(rfindley): consider asserting on isGeneric(typ) here, if and when
 		// isGeneric handles *Signature types.
 		h.typeList(targs)
 	}

 	return strings.ReplaceAll(buf.String(), " ", "#")
 }

 // lookup returns an existing instantiation of orig with targs, if it exists.
 // Otherwise, it returns nil.
 func (ctxt *Context) lookup(h string, orig Type, targs []Type) Type {
 	ctxt.mu.Lock()
 	defer ctxt.mu.Unlock()

 	for _, e := range ctxt.typeMap[h] {
 		if identicalInstance(orig, targs, e.orig, e.targs) {
 			return e.instance
 		}
 		if debug {
 			// Panic during development to surface any imperfections in our hash.
 			panic(fmt.Sprintf("non-identical instances: (orig: %s, targs: %v) and %s", orig, targs, e.instance))
 		}
 	}

 	return nil
 }

 // update de-duplicates n against previously seen types with the hash h.  If an
 // identical type is found with the type hash h, the previously seen type is
 // returned. Otherwise, n is returned, and recorded in the Context for the hash
 // h.
 func (ctxt *Context) update(h string, orig Type, targs []Type, inst Type) Type {
 	assert(inst != nil)

 	ctxt.mu.Lock()
 	defer ctxt.mu.Unlock()

 	for _, e := range ctxt.typeMap[h] {
 		if inst == nil || Identical(inst, e.instance) {
 			return e.instance
 		}
 		if debug {
 			// Panic during development to surface any imperfections in our hash.
 			panic(fmt.Sprintf("%s and %s are not identical", inst, e.instance))
 		}
 	}

 	ctxt.typeMap[h] = append(ctxt.typeMap[h], ctxtEntry{
 		orig:     orig,
 		targs:    targs,
 		instance: inst,
 	})

 	return inst
 }

 // getID returns a unique ID for the type t.
 func (ctxt *Context) getID(t Type) int {
 	ctxt.mu.Lock()
 	defer ctxt.mu.Unlock()
 	id, ok := ctxt.originIDs[t]
 	if !ok {
 		id = ctxt.nextID
 		ctxt.originIDs[t] = id
 		ctxt.nextID++
 	}
 	return id
 }
	// Copyright 2021 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package types2

	import (
	"bytes"
	"fmt"
	"strconv"
	"strings"
	"sync"
	)

	// This file contains a definition of the type-checking context; an opaque type
	// that may be supplied by users during instantiation.
	//
	// Contexts serve two purposes:
	// - reduce the duplication of identical instances
	// - short-circuit instantiation cycles
	//
	// For the latter purpose, we must always have a context during instantiation,
	// whether or not it is supplied by the user. For both purposes, it must be the
	// case that hashing a pointer-identical type produces consistent results
	// (somewhat obviously).
	//
	// However, neither of these purposes require that our hash is perfect, and so
	// this was not an explicit design goal of the context type. In fact, due to
	// concurrent use it is convenient not to guarantee de-duplication.
	//
	// Nevertheless, in the future it could be helpful to allow users to leverage
	// contexts to canonicalize instances, and it would probably be possible to
	// achieve such a guarantee.

	// A Context is an opaque type checking context. It may be used to share
	// identical type instances across type-checked packages or calls to
	// Instantiate. Contexts are safe for concurrent use.
	//
	// The use of a shared context does not guarantee that identical instances are
	// deduplicated in all cases.
	type Context struct {
	mu sync.Mutex
	typeMap map[string][]ctxtEntry // type hash -> instances entries
	nextID int // next unique ID
	originIDs map[Type]int // origin type -> unique ID
	}

	type ctxtEntry struct {
	orig Type
	targs []Type
	instance Type // = orig[targs]
	}

	// NewContext creates a new Context.
	func NewContext() *Context {
	return &Context{
	typeMap: make(map[string][]ctxtEntry),
	originIDs: make(map[Type]int),
	}
	}

	// instanceHash returns a string representation of typ instantiated with targs.
	// The hash should be a perfect hash, though out of caution the type checker
	// does not assume this. The result is guaranteed to not contain blanks.
	func (ctxt *Context) instanceHash(orig Type, targs []Type) string {
	assert(ctxt != nil)
	assert(orig != nil)
	var buf bytes.Buffer

	h := newTypeHasher(&buf, ctxt)
	h.string(strconv.Itoa(ctxt.getID(orig)))
	// Because we've already written the unique origin ID this call to h.typ is
	// unnecessary, but we leave it for hash readability. It can be removed later
	// if performance is an issue.
	h.typ(orig)
	if len(targs) > 0 {
	// TODO(rfindley): consider asserting on isGeneric(typ) here, if and when
	// isGeneric handles *Signature types.
	h.typeList(targs)
	}

	return strings.ReplaceAll(buf.String(), " ", "#")
	}

	// lookup returns an existing instantiation of orig with targs, if it exists.
	// Otherwise, it returns nil.
	func (ctxt *Context) lookup(h string, orig Type, targs []Type) Type {
	ctxt.mu.Lock()
	defer ctxt.mu.Unlock()

	for _, e := range ctxt.typeMap[h] {
	if identicalInstance(orig, targs, e.orig, e.targs) {
	return e.instance
	}
	if debug {
	// Panic during development to surface any imperfections in our hash.
	panic(fmt.Sprintf("non-identical instances: (orig: %s, targs: %v) and %s", orig, targs, e.instance))
	}
	}

	return nil
	}

	// update de-duplicates n against previously seen types with the hash h. If an
	// identical type is found with the type hash h, the previously seen type is
	// returned. Otherwise, n is returned, and recorded in the Context for the hash
	// h.
	func (ctxt *Context) update(h string, orig Type, targs []Type, inst Type) Type {
	assert(inst != nil)

	ctxt.mu.Lock()
	defer ctxt.mu.Unlock()

	for _, e := range ctxt.typeMap[h] {
	if inst == nil \|\| Identical(inst, e.instance) {
	return e.instance
	}
	if debug {
	// Panic during development to surface any imperfections in our hash.
	panic(fmt.Sprintf("%s and %s are not identical", inst, e.instance))
	}
	}

	ctxt.typeMap[h] = append(ctxt.typeMap[h], ctxtEntry{
	orig: orig,
	targs: targs,
	instance: inst,
	})

	return inst
	}

	// getID returns a unique ID for the type t.
	func (ctxt *Context) getID(t Type) int {
	ctxt.mu.Lock()
	defer ctxt.mu.Unlock()
	id, ok := ctxt.originIDs[t]
	if !ok {
	id = ctxt.nextID
	ctxt.originIDs[t] = id
	ctxt.nextID++
	}
	return id
	}