cmd/signature-fuzzer/internal/fuzz-generator/parm.go - tools - 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 generator

 import (
 	"bytes"
 	"fmt"
 	"os"
 	"sort"
 )

 // parm is an interface describing an abstract parameter var or return
 // var; there will be concrete types of various sorts that implement
 // this interface.
 type parm interface {

 	// Declare emits text containing a declaration of this param
 	// or return var into the specified buffer. Prefix is a tag to
 	// prepend before the declaration (for example a variable
 	// name) followed by a space; suffix is an arbitrary string to
 	// tack onto the end of the param's type text. Here 'caller'
 	// is set to true if we're emitting the caller part of a test
 	// pair as opposed to the checker.
 	Declare(b *bytes.Buffer, prefix string, suffix string, caller bool)

 	// GenElemRef returns a pair [X,Y] corresponding to a
 	// component piece of some composite parm, where X is a string
 	// forming the reference (ex: ".field" if we're picking out a
 	// struct field) and Y is a parm object corresponding to the
 	// type of the element.
 	GenElemRef(elidx int, path string) (string, parm)

 	// GenValue constructs a new concrete random value appropriate
 	// for the type in question and returns it, along with a
 	// sequence number indicating how many random decisions we had
 	// to make. Here "s" is the current generator state, "f" is
 	// the current function we're emitting, value is a sequence
 	// number indicating how many random decisions have been made
 	// up until this point, and 'caller' is set to true if we're
 	// emitting the caller part of a test pair as opposed to the
 	// checker.  Return value is a pair [V,I] where V is the text
 	// if the value, and I is a new sequence number reflecting any
 	// additional random choices we had to make.  For example, if
 	// the parm is something like "type Foo struct { f1 int32; f2
 	// float64 }" then we might expect GenValue to emit something
 	// like "Foo{int32(-9), float64(123.123)}".
 	GenValue(s *genstate, f *funcdef, value int, caller bool) (string, int)

 	// IsControl returns true if this specific param has been marked
 	// as the single param that controls recursion for a recursive
 	// checker function. The test code doesn't check this param for a specific
 	// value, but instead returns early if it has value 0 or decrements it
 	// on a recursive call.
 	IsControl() bool

 	// NumElements returns the total number of discrete elements contained
 	// in this parm. For non-composite types, this will always be 1.
 	NumElements() int

 	// String returns a descriptive string for this parm.
 	String() string

 	// TypeName returns the non-qualified type name for this parm.
 	TypeName() string

 	// QualName returns a package-qualified type name for this parm.
 	QualName() string

 	// HasPointer returns true if this parm is of pointer type, or
 	// if it is a composite that has a pointer element somewhere inside.
 	// Strings and slices return true for this hook.
 	HasPointer() bool

 	// IsBlank() returns true if the name of this parm is "_" (that is,
 	// if we randomly chose to make it a blank). SetBlank() is used
 	// to set the 'blank' property for this parm.
 	IsBlank() bool
 	SetBlank(v bool)

 	// AddrTaken() return a token indicating whether this parm should
 	// be address taken or not, the nature of the address-taken-ness (see
 	// below at the def of addrTakenHow). SetAddrTaken is used to set
 	// the address taken property of the parm.
 	AddrTaken() addrTakenHow
 	SetAddrTaken(val addrTakenHow)

 	// IsGenVal() returns true if the values of this type should
 	// be obtained by calling a helper func, as opposed to
 	// emitting code inline (as one would for things like numeric
 	// types). SetIsGenVal is used to set the gen-val property of
 	// the parm.
 	IsGenVal() bool
 	SetIsGenVal(val bool)

 	// SkipCompare() returns true if we've randomly decided that
 	// we don't want to compare the value for this param or
 	// return.  SetSkipCompare is used to set the skip-compare
 	// property of the parm.
 	SkipCompare() skipCompare
 	SetSkipCompare(val skipCompare)
 }

 type addrTakenHow uint8

 const (
 	// Param not address taken.
 	notAddrTaken addrTakenHow = 0

 	// Param address is taken and used for simple reads/writes.
 	addrTakenSimple addrTakenHow = 1

 	// Param address is taken and passed to a well-behaved function.
 	addrTakenPassed addrTakenHow = 2

 	// Param address is taken and stored to a global var.
 	addrTakenHeap addrTakenHow = 3
 )

 func (a *addrTakenHow) AddrTaken() addrTakenHow {
 	return *a
 }

 func (a *addrTakenHow) SetAddrTaken(val addrTakenHow) {
 	*a = val
 }

 type isBlank bool

 func (b *isBlank) IsBlank() bool {
 	return bool(*b)
 }

 func (b *isBlank) SetBlank(val bool) {
 	*b = isBlank(val)
 }

 type isGenValFunc bool

 func (g *isGenValFunc) IsGenVal() bool {
 	return bool(*g)
 }

 func (g *isGenValFunc) SetIsGenVal(val bool) {
 	*g = isGenValFunc(val)
 }

 type skipCompare int

 const (
 	// Param not address taken.
 	SkipAll     = -1
 	SkipNone    = 0
 	SkipPayload = 1
 )

 func (s *skipCompare) SkipCompare() skipCompare {
 	return skipCompare(*s)
 }

 func (s *skipCompare) SetSkipCompare(val skipCompare) {
 	*s = skipCompare(val)
 }

 // containedParms takes an arbitrary param 'p' and returns a slice
 // with 'p' itself plus any component parms contained within 'p'.
 func containedParms(p parm) []parm {
 	visited := make(map[string]parm)
 	worklist := []parm{p}

 	addToWork := func(p parm) {
 		if p == nil {
 			panic("not expected")
 		}
 		if _, ok := visited[p.TypeName()]; !ok {
 			worklist = append(worklist, p)
 		}
 	}

 	for len(worklist) != 0 {
 		cp := worklist[0]
 		worklist = worklist[1:]
 		if _, ok := visited[cp.TypeName()]; ok {
 			continue
 		}
 		visited[cp.TypeName()] = cp
 		switch x := cp.(type) {
 		case *mapparm:
 			addToWork(x.keytype)
 			addToWork(x.valtype)
 		case *structparm:
 			for _, fld := range x.fields {
 				addToWork(fld)
 			}
 		case *arrayparm:
 			addToWork(x.eltype)
 		case *pointerparm:
 			addToWork(x.totype)
 		case *typedefparm:
 			addToWork(x.target)
 		}
 	}
 	rv := []parm{}
 	for _, v := range visited {
 		rv = append(rv, v)
 	}
 	sort.Slice(rv, func(i, j int) bool {
 		if rv[i].TypeName() == rv[j].TypeName() {
 			fmt.Fprintf(os.Stderr, "%d %d %+v %+v %s %s\n", i, j, rv[i], rv[i].String(), rv[j], rv[j].String())
 			panic("unexpected")
 		}
 		return rv[i].TypeName() < rv[j].TypeName()
 	})
 	return rv
 }
	// 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 generator

	import (
	"bytes"
	"fmt"
	"os"
	"sort"
	)

	// parm is an interface describing an abstract parameter var or return
	// var; there will be concrete types of various sorts that implement
	// this interface.
	type parm interface {

	// Declare emits text containing a declaration of this param
	// or return var into the specified buffer. Prefix is a tag to
	// prepend before the declaration (for example a variable
	// name) followed by a space; suffix is an arbitrary string to
	// tack onto the end of the param's type text. Here 'caller'
	// is set to true if we're emitting the caller part of a test
	// pair as opposed to the checker.
	Declare(b *bytes.Buffer, prefix string, suffix string, caller bool)

	// GenElemRef returns a pair [X,Y] corresponding to a
	// component piece of some composite parm, where X is a string
	// forming the reference (ex: ".field" if we're picking out a
	// struct field) and Y is a parm object corresponding to the
	// type of the element.
	GenElemRef(elidx int, path string) (string, parm)

	// GenValue constructs a new concrete random value appropriate
	// for the type in question and returns it, along with a
	// sequence number indicating how many random decisions we had
	// to make. Here "s" is the current generator state, "f" is
	// the current function we're emitting, value is a sequence
	// number indicating how many random decisions have been made
	// up until this point, and 'caller' is set to true if we're
	// emitting the caller part of a test pair as opposed to the
	// checker. Return value is a pair [V,I] where V is the text
	// if the value, and I is a new sequence number reflecting any
	// additional random choices we had to make. For example, if
	// the parm is something like "type Foo struct { f1 int32; f2
	// float64 }" then we might expect GenValue to emit something
	// like "Foo{int32(-9), float64(123.123)}".
	GenValue(s genstate, f funcdef, value int, caller bool) (string, int)

	// IsControl returns true if this specific param has been marked
	// as the single param that controls recursion for a recursive
	// checker function. The test code doesn't check this param for a specific
	// value, but instead returns early if it has value 0 or decrements it
	// on a recursive call.
	IsControl() bool

	// NumElements returns the total number of discrete elements contained
	// in this parm. For non-composite types, this will always be 1.
	NumElements() int

	// String returns a descriptive string for this parm.
	String() string

	// TypeName returns the non-qualified type name for this parm.
	TypeName() string

	// QualName returns a package-qualified type name for this parm.
	QualName() string

	// HasPointer returns true if this parm is of pointer type, or
	// if it is a composite that has a pointer element somewhere inside.
	// Strings and slices return true for this hook.
	HasPointer() bool

	// IsBlank() returns true if the name of this parm is "_" (that is,
	// if we randomly chose to make it a blank). SetBlank() is used
	// to set the 'blank' property for this parm.
	IsBlank() bool
	SetBlank(v bool)

	// AddrTaken() return a token indicating whether this parm should
	// be address taken or not, the nature of the address-taken-ness (see
	// below at the def of addrTakenHow). SetAddrTaken is used to set
	// the address taken property of the parm.
	AddrTaken() addrTakenHow
	SetAddrTaken(val addrTakenHow)

	// IsGenVal() returns true if the values of this type should
	// be obtained by calling a helper func, as opposed to
	// emitting code inline (as one would for things like numeric
	// types). SetIsGenVal is used to set the gen-val property of
	// the parm.
	IsGenVal() bool
	SetIsGenVal(val bool)

	// SkipCompare() returns true if we've randomly decided that
	// we don't want to compare the value for this param or
	// return. SetSkipCompare is used to set the skip-compare
	// property of the parm.
	SkipCompare() skipCompare
	SetSkipCompare(val skipCompare)
	}

	type addrTakenHow uint8

	const (
	// Param not address taken.
	notAddrTaken addrTakenHow = 0

	// Param address is taken and used for simple reads/writes.
	addrTakenSimple addrTakenHow = 1

	// Param address is taken and passed to a well-behaved function.
	addrTakenPassed addrTakenHow = 2

	// Param address is taken and stored to a global var.
	addrTakenHeap addrTakenHow = 3
	)

	func (a *addrTakenHow) AddrTaken() addrTakenHow {
	return *a
	}

	func (a *addrTakenHow) SetAddrTaken(val addrTakenHow) {
	*a = val
	}

	type isBlank bool

	func (b *isBlank) IsBlank() bool {
	return bool(*b)
	}

	func (b *isBlank) SetBlank(val bool) {
	*b = isBlank(val)
	}

	type isGenValFunc bool

	func (g *isGenValFunc) IsGenVal() bool {
	return bool(*g)
	}

	func (g *isGenValFunc) SetIsGenVal(val bool) {
	*g = isGenValFunc(val)
	}

	type skipCompare int

	const (
	// Param not address taken.
	SkipAll = -1
	SkipNone = 0
	SkipPayload = 1
	)

	func (s *skipCompare) SkipCompare() skipCompare {
	return skipCompare(*s)
	}

	func (s *skipCompare) SetSkipCompare(val skipCompare) {
	*s = skipCompare(val)
	}

	// containedParms takes an arbitrary param 'p' and returns a slice
	// with 'p' itself plus any component parms contained within 'p'.
	func containedParms(p parm) []parm {
	visited := make(map[string]parm)
	worklist := []parm{p}

	addToWork := func(p parm) {
	if p == nil {
	panic("not expected")
	}
	if _, ok := visited[p.TypeName()]; !ok {
	worklist = append(worklist, p)
	}
	}

	for len(worklist) != 0 {
	cp := worklist[0]
	worklist = worklist[1:]
	if _, ok := visited[cp.TypeName()]; ok {
	continue
	}
	visited[cp.TypeName()] = cp
	switch x := cp.(type) {
	case *mapparm:
	addToWork(x.keytype)
	addToWork(x.valtype)
	case *structparm:
	for _, fld := range x.fields {
	addToWork(fld)
	}
	case *arrayparm:
	addToWork(x.eltype)
	case *pointerparm:
	addToWork(x.totype)
	case *typedefparm:
	addToWork(x.target)
	}
	}
	rv := []parm{}
	for _, v := range visited {
	rv = append(rv, v)
	}
	sort.Slice(rv, func(i, j int) bool {
	if rv[i].TypeName() == rv[j].TypeName() {
	fmt.Fprintf(os.Stderr, "%d %d %+v %+v %s %s\n", i, j, rv[i], rv[i].String(), rv[j], rv[j].String())
	panic("unexpected")
	}
	return rv[i].TypeName() < rv[j].TypeName()
	})
	return rv
	}