syzkaller/prog/rand.go
2019-09-24 20:13:37 +02:00

885 lines
23 KiB
Go

// Copyright 2015/2016 syzkaller project authors. All rights reserved.
// Use of this source code is governed by Apache 2 LICENSE that can be found in the LICENSE file.
package prog
import (
"bytes"
"fmt"
"math"
"math/rand"
"path/filepath"
"sort"
"strings"
"github.com/google/syzkaller/pkg/ifuzz"
_ "github.com/google/syzkaller/pkg/ifuzz/generated" // pull in generated instruction descriptions
)
type randGen struct {
*rand.Rand
target *Target
inCreateResource bool
recDepth map[string]int
}
func newRand(target *Target, rs rand.Source) *randGen {
return &randGen{
Rand: rand.New(rs),
target: target,
recDepth: make(map[string]int),
}
}
func (r *randGen) rand(n int) uint64 {
return uint64(r.Intn(n))
}
func (r *randGen) randRange(begin, end uint64) uint64 {
return begin + uint64(r.Intn(int(end-begin+1)))
}
func (r *randGen) bin() bool {
return r.Intn(2) == 0
}
func (r *randGen) oneOf(n int) bool {
return r.Intn(n) == 0
}
func (r *randGen) rand64() uint64 {
v := uint64(r.Int63())
if r.bin() {
v |= 1 << 63
}
return v
}
var (
// Some potentially interesting integers.
specialInts = []uint64{
0, 1, 31, 32, 63, 64, 127, 128,
129, 255, 256, 257, 511, 512,
1023, 1024, 1025, 2047, 2048, 4095, 4096,
(1 << 15) - 1, (1 << 15), (1 << 15) + 1,
(1 << 16) - 1, (1 << 16), (1 << 16) + 1,
(1 << 31) - 1, (1 << 31), (1 << 31) + 1,
(1 << 32) - 1, (1 << 32), (1 << 32) + 1,
}
// The indexes (exclusive) for the maximum specialInts values that fit in 1, 2, ... 8 bytes.
specialIntIndex [9]int
)
func init() {
sort.Slice(specialInts, func(i, j int) bool {
return specialInts[i] < specialInts[j]
})
for i := range specialIntIndex {
bitSize := uint64(8 * i)
specialIntIndex[i] = sort.Search(len(specialInts), func(i int) bool {
return specialInts[i]>>bitSize != 0
})
}
}
func (r *randGen) randInt64() uint64 {
return r.randInt(64)
}
func (r *randGen) randInt(bits uint64) uint64 {
v := r.rand64()
switch {
case r.nOutOf(100, 182):
v %= 10
case bits >= 8 && r.nOutOf(50, 82):
v = specialInts[r.Intn(specialIntIndex[bits/8])]
case r.nOutOf(10, 32):
v %= 256
case r.nOutOf(10, 22):
v %= 4 << 10
case r.nOutOf(10, 12):
v %= 64 << 10
default:
v %= 1 << 31
}
switch {
case r.nOutOf(100, 107):
case r.nOutOf(5, 7):
v = uint64(-int64(v))
default:
v <<= uint(r.Intn(int(bits)))
}
return truncateToBitSize(v, bits)
}
func truncateToBitSize(v, bitSize uint64) uint64 {
if bitSize == 0 || bitSize > 64 {
panic(fmt.Sprintf("invalid bitSize value: %d", bitSize))
}
return v & uint64(1<<bitSize-1)
}
func (r *randGen) randRangeInt(begin, end, bitSize uint64) uint64 {
if r.oneOf(100) {
return r.randInt(bitSize)
}
return begin + (r.Uint64() % (end - begin + 1))
}
// biasedRand returns a random int in range [0..n),
// probability of n-1 is k times higher than probability of 0.
func (r *randGen) biasedRand(n, k int) int {
nf, kf := float64(n), float64(k)
rf := nf * (kf/2 + 1) * r.Float64()
bf := (-1 + math.Sqrt(1+2*kf*rf/nf)) * nf / kf
return int(bf)
}
func (r *randGen) randArrayLen() uint64 {
const maxLen = 10
// biasedRand produces: 10, 9, ..., 1, 0,
// we want: 1, 2, ..., 9, 10, 0
return uint64(maxLen-r.biasedRand(maxLen+1, 10)+1) % (maxLen + 1)
}
func (r *randGen) randBufLen() (n uint64) {
switch {
case r.nOutOf(50, 56):
n = r.rand(256)
case r.nOutOf(5, 6):
n = 4 << 10
}
return
}
func (r *randGen) randPageCount() (n uint64) {
switch {
case r.nOutOf(100, 106):
n = r.rand(4) + 1
case r.nOutOf(5, 6):
n = r.rand(20) + 1
default:
n = (r.rand(3) + 1) * 512
}
return
}
// Change a flag value or generate a new one.
func (r *randGen) flags(vv []uint64, bitmask bool, oldVal uint64) (v uint64) {
v = oldVal
if r.oneOf(5) {
// Ignore the old value sometimes.
v = 0
}
switch {
case (bitmask && r.nOutOf(7, 10)) || (!bitmask && r.nOutOf(1, 5)):
// Try flipping randomly chosen flags.
// Prioritized when bitmask == true.
for stop := false; !stop; stop = r.oneOf(3) {
flag := vv[r.rand(len(vv))]
if r.oneOf(5) {
// Try choosing adjacent bit values in case we forgot
// to add all relevant flags to the descriptions.
if r.bin() {
flag >>= 1
} else {
flag <<= 1
}
}
v ^= flag
}
case (bitmask && r.nOutOf(2, 3)) || (!bitmask && r.nOutOf(7, 8)):
// Chose a random flag.
// Prioritized when bitmask == false.
v = vv[r.rand(len(vv))]
case r.bin():
v = 0
default:
v = r.rand64()
}
return
}
func (r *randGen) filename(s *state, typ *BufferType) string {
fn := r.filenameImpl(s)
if len(fn) != 0 && fn[len(fn)-1] == 0 {
panic(fmt.Sprintf("zero-terminated filename: %q", fn))
}
if escapingFilename(fn) {
panic(fmt.Sprintf("sandbox escaping file name %q, s.files are %v", fn, s.files))
}
if !typ.Varlen() {
size := typ.Size()
if uint64(len(fn)) < size {
fn += string(make([]byte, size-uint64(len(fn))))
}
fn = fn[:size]
} else if !typ.NoZ {
fn += "\x00"
}
return fn
}
func escapingFilename(file string) bool {
file = filepath.Clean(file)
return len(file) >= 1 && file[0] == '/' ||
len(file) >= 2 && file[0] == '.' && file[1] == '.'
}
var specialFiles = []string{"", "."}
func (r *randGen) filenameImpl(s *state) string {
if r.oneOf(100) {
return specialFiles[r.Intn(len(specialFiles))]
}
if len(s.files) == 0 || r.oneOf(10) {
// Generate a new name.
dir := "."
if r.oneOf(2) && len(s.files) != 0 {
dir = r.randFromMap(s.files)
if len(dir) > 0 && dir[len(dir)-1] == 0 {
dir = dir[:len(dir)-1]
}
if r.oneOf(10) && filepath.Clean(dir)[0] != '.' {
dir += "/.."
}
}
for i := 0; ; i++ {
f := fmt.Sprintf("%v/file%v", dir, i)
if !s.files[f] {
return f
}
}
}
return r.randFromMap(s.files)
}
func (r *randGen) randFromMap(m map[string]bool) string {
files := make([]string, 0, len(m))
for f := range m {
files = append(files, f)
}
sort.Strings(files)
return files[r.Intn(len(files))]
}
func (r *randGen) randString(s *state, t *BufferType) []byte {
if len(t.Values) != 0 {
return []byte(t.Values[r.Intn(len(t.Values))])
}
if len(s.strings) != 0 && r.bin() {
// Return an existing string.
// TODO(dvyukov): make s.strings indexed by string SubKind.
return []byte(r.randFromMap(s.strings))
}
punct := []byte{'!', '@', '#', '$', '%', '^', '&', '*', '(', ')', '-', '+', '\\',
'/', ':', '.', ',', '-', '\'', '[', ']', '{', '}'}
buf := new(bytes.Buffer)
for r.nOutOf(3, 4) {
switch {
case r.nOutOf(10, 21):
dict := r.target.StringDictionary
if len(dict) != 0 {
buf.WriteString(dict[r.Intn(len(dict))])
}
case r.nOutOf(10, 11):
buf.Write([]byte{punct[r.Intn(len(punct))]})
default:
buf.Write([]byte{byte(r.Intn(256))})
}
}
if r.oneOf(100) == t.NoZ {
buf.Write([]byte{0})
}
return buf.Bytes()
}
func (r *randGen) allocAddr(s *state, typ Type, size uint64, data Arg) *PointerArg {
return MakePointerArg(typ, s.ma.alloc(r, size), data)
}
func (r *randGen) allocVMA(s *state, typ Type, numPages uint64) *PointerArg {
page := s.va.alloc(r, numPages)
return MakeVmaPointerArg(typ, page*r.target.PageSize, numPages*r.target.PageSize)
}
func (r *randGen) createResource(s *state, res *ResourceType) (arg Arg, calls []*Call) {
if r.inCreateResource {
special := res.SpecialValues()
return MakeResultArg(res, nil, special[r.Intn(len(special))]), nil
}
r.inCreateResource = true
defer func() { r.inCreateResource = false }()
kind := res.Desc.Name
// We may have no resources, but still be in createResource due to ANYRES.
if len(r.target.resourceMap) != 0 && r.oneOf(1000) {
// Spoof resource subkind.
var all []string
for kind1 := range r.target.resourceMap {
if r.target.isCompatibleResource(res.Desc.Kind[0], kind1) {
all = append(all, kind1)
}
}
if len(all) == 0 {
panic(fmt.Sprintf("got no spoof resources for %v in %v/%v",
kind, r.target.OS, r.target.Arch))
}
sort.Strings(all)
kind = all[r.Intn(len(all))]
}
// Find calls that produce the necessary resources.
metas0 := r.target.resourceCtors[kind]
// TODO: reduce priority of less specialized ctors.
var metas []*Syscall
for _, meta := range metas0 {
if s.ct == nil || s.ct.run[meta.ID] == nil {
continue
}
metas = append(metas, meta)
}
if len(metas) == 0 {
return res.DefaultArg(), nil
}
// Now we have a set of candidate calls that can create the necessary resource.
for i := 0; i < 1e3; i++ {
// Generate one of them.
meta := metas[r.Intn(len(metas))]
calls := r.generateParticularCall(s, meta)
s1 := newState(r.target, s.ct, nil)
s1.analyze(calls[len(calls)-1])
// Now see if we have what we want.
var allres []*ResultArg
for kind1, res1 := range s1.resources {
if r.target.isCompatibleResource(kind, kind1) {
allres = append(allres, res1...)
}
}
if len(allres) != 0 {
// Bingo!
arg := MakeResultArg(res, allres[r.Intn(len(allres))], 0)
return arg, calls
}
// Discard unsuccessful calls.
// Note: s.ma/va have already noted allocations of the new objects
// in discarded syscalls, ideally we should recreate state
// by analyzing the program again.
for _, c := range calls {
ForeachArg(c, func(arg Arg, _ *ArgCtx) {
if a, ok := arg.(*ResultArg); ok && a.Res != nil {
delete(a.Res.uses, a)
}
})
}
}
// Generally we can loop several times, e.g. when we choose a call that returns
// the resource in an array, but then generateArg generated that array of zero length.
// But we must succeed eventually.
var ctors []string
for _, meta := range metas {
ctors = append(ctors, meta.Name)
}
panic(fmt.Sprintf("failed to create a resource %v with %v",
res.Desc.Kind[0], strings.Join(ctors, ", ")))
}
func (r *randGen) generateText(kind TextKind) []byte {
switch kind {
case TextTarget:
if r.target.Arch == "amd64" || r.target.Arch == "386" {
cfg := createTargetIfuzzConfig(r.target)
return ifuzz.Generate(cfg, r.Rand)
}
fallthrough
case TextArm64:
// Just a stub, need something better.
text := make([]byte, 50)
for i := range text {
text[i] = byte(r.Intn(256))
}
return text
default:
cfg := createIfuzzConfig(kind)
return ifuzz.Generate(cfg, r.Rand)
}
}
func (r *randGen) mutateText(kind TextKind, text []byte) []byte {
switch kind {
case TextTarget:
if r.target.Arch == "amd64" || r.target.Arch == "386" {
cfg := createTargetIfuzzConfig(r.target)
return ifuzz.Mutate(cfg, r.Rand, text)
}
fallthrough
case TextArm64:
return mutateData(r, text, 40, 60)
default:
cfg := createIfuzzConfig(kind)
return ifuzz.Mutate(cfg, r.Rand, text)
}
}
func createTargetIfuzzConfig(target *Target) *ifuzz.Config {
cfg := &ifuzz.Config{
Len: 10,
Priv: false,
Exec: true,
MemRegions: []ifuzz.MemRegion{
{Start: target.DataOffset, Size: target.NumPages * target.PageSize},
},
}
for _, p := range target.SpecialPointers {
cfg.MemRegions = append(cfg.MemRegions, ifuzz.MemRegion{
Start: p & ^target.PageSize, Size: p & ^target.PageSize + target.PageSize,
})
}
switch target.Arch {
case "amd64":
cfg.Mode = ifuzz.ModeLong64
case "386":
cfg.Mode = ifuzz.ModeProt32
default:
panic("unknown text kind")
}
return cfg
}
func createIfuzzConfig(kind TextKind) *ifuzz.Config {
cfg := &ifuzz.Config{
Len: 10,
Priv: true,
Exec: true,
MemRegions: []ifuzz.MemRegion{
{Start: 0 << 12, Size: 1 << 12},
{Start: 1 << 12, Size: 1 << 12},
{Start: 2 << 12, Size: 1 << 12},
{Start: 3 << 12, Size: 1 << 12},
{Start: 4 << 12, Size: 1 << 12},
{Start: 5 << 12, Size: 1 << 12},
{Start: 6 << 12, Size: 1 << 12},
{Start: 7 << 12, Size: 1 << 12},
{Start: 8 << 12, Size: 1 << 12},
{Start: 9 << 12, Size: 1 << 12},
{Start: 0xfec00000, Size: 0x100}, // ioapic
},
}
switch kind {
case TextX86Real:
cfg.Mode = ifuzz.ModeReal16
case TextX86bit16:
cfg.Mode = ifuzz.ModeProt16
case TextX86bit32:
cfg.Mode = ifuzz.ModeProt32
case TextX86bit64:
cfg.Mode = ifuzz.ModeLong64
default:
panic("unknown text kind")
}
return cfg
}
// nOutOf returns true n out of outOf times.
func (r *randGen) nOutOf(n, outOf int) bool {
if n <= 0 || n >= outOf {
panic("bad probability")
}
v := r.Intn(outOf)
return v < n
}
func (r *randGen) generateCall(s *state, p *Prog, insertionPoint int) []*Call {
idx := 0
if s.ct == nil {
idx = r.Intn(len(r.target.Syscalls))
} else if insertionPoint <= 0 {
idx = s.ct.enabledCalls[r.Intn(len(s.ct.enabledCalls))].ID
} else {
call := -1
if len(p.Calls) != 0 {
// Choosing the base call is based on the insertion point of the new calls sequence.
call = p.Calls[r.Intn(insertionPoint)].Meta.ID
}
idx = s.ct.Choose(r.Rand, call)
}
meta := r.target.Syscalls[idx]
return r.generateParticularCall(s, meta)
}
func (r *randGen) generateParticularCall(s *state, meta *Syscall) (calls []*Call) {
c := &Call{
Meta: meta,
Ret: MakeReturnArg(meta.Ret),
}
c.Args, calls = r.generateArgs(s, meta.Args)
r.target.assignSizesCall(c)
calls = append(calls, c)
for _, c1 := range calls {
r.target.SanitizeCall(c1)
}
return calls
}
// GenerateAllSyzProg generates a program that contains all pseudo syz_ calls for testing.
func (target *Target) GenerateAllSyzProg(rs rand.Source) *Prog {
p := &Prog{
Target: target,
}
r := newRand(target, rs)
s := newState(target, nil, nil)
handled := make(map[string]bool)
for _, meta := range target.Syscalls {
if !strings.HasPrefix(meta.CallName, "syz_") || handled[meta.CallName] {
continue
}
handled[meta.CallName] = true
calls := r.generateParticularCall(s, meta)
for _, c := range calls {
s.analyze(c)
p.Calls = append(p.Calls, c)
}
}
if err := p.validate(); err != nil {
panic(err)
}
return p
}
// GenerateSimpleProg generates the simplest non-empty program for testing
// (e.g. containing a single mmap).
func (target *Target) GenerateSimpleProg() *Prog {
return &Prog{
Target: target,
Calls: []*Call{target.MakeMmap(0, target.PageSize)},
}
}
func (target *Target) GenerateUberMmapProg() *Prog {
return &Prog{
Target: target,
Calls: []*Call{target.MakeMmap(0, target.NumPages*target.PageSize)},
}
}
func (r *randGen) generateArgs(s *state, types []Type) ([]Arg, []*Call) {
var calls []*Call
args := make([]Arg, len(types))
// Generate all args. Size args have the default value 0 for now.
for i, typ := range types {
arg, calls1 := r.generateArg(s, typ)
if arg == nil {
panic(fmt.Sprintf("generated arg is nil for type '%v', types: %+v", typ.Name(), types))
}
args[i] = arg
calls = append(calls, calls1...)
}
return args, calls
}
func (r *randGen) generateArg(s *state, typ Type) (arg Arg, calls []*Call) {
return r.generateArgImpl(s, typ, false)
}
func (r *randGen) generateArgImpl(s *state, typ Type, ignoreSpecial bool) (arg Arg, calls []*Call) {
if typ.Dir() == DirOut {
// No need to generate something interesting for output scalar arguments.
// But we still need to generate the argument itself so that it can be referenced
// in subsequent calls. For the same reason we do generate pointer/array/struct
// output arguments (their elements can be referenced in subsequent calls).
switch typ.(type) {
case *IntType, *FlagsType, *ConstType, *ProcType,
*VmaType, *ResourceType:
return typ.DefaultArg(), nil
}
}
if typ.Optional() && r.oneOf(5) {
if res, ok := typ.(*ResourceType); ok {
v := res.Desc.Values[r.Intn(len(res.Desc.Values))]
return MakeResultArg(typ, nil, v), nil
}
return typ.DefaultArg(), nil
}
// Allow infinite recursion for optional pointers.
if pt, ok := typ.(*PtrType); ok && typ.Optional() {
switch pt.Type.(type) {
case *StructType, *ArrayType, *UnionType:
name := pt.Type.Name()
r.recDepth[name]++
defer func() {
r.recDepth[name]--
if r.recDepth[name] == 0 {
delete(r.recDepth, name)
}
}()
if r.recDepth[name] >= 3 {
return MakeSpecialPointerArg(typ, 0), nil
}
}
}
if !ignoreSpecial && typ.Dir() != DirOut {
switch typ.(type) {
case *StructType, *UnionType:
if gen := r.target.SpecialTypes[typ.Name()]; gen != nil {
return gen(&Gen{r, s}, typ, nil)
}
}
}
return typ.generate(r, s)
}
func (a *ResourceType) generate(r *randGen, s *state) (arg Arg, calls []*Call) {
switch {
case r.nOutOf(2, 5):
var res *ResultArg
res, calls = resourceCentric(a, s, r)
if res == nil {
return r.createResource(s, a)
}
arg = MakeResultArg(a, res, 0)
case r.nOutOf(1, 2):
// Get an existing resource.
alltypes := make([][]*ResultArg, 0, len(s.resources))
for _, res1 := range s.resources {
alltypes = append(alltypes, res1)
}
sort.Slice(alltypes, func(i, j int) bool {
return alltypes[i][0].Type().Name() < alltypes[j][0].Type().Name()
})
var allres []*ResultArg
for _, res1 := range alltypes {
name1 := res1[0].Type().Name()
if r.target.isCompatibleResource(a.Desc.Name, name1) ||
r.oneOf(20) && r.target.isCompatibleResource(a.Desc.Kind[0], name1) {
allres = append(allres, res1...)
}
}
if len(allres) != 0 {
arg = MakeResultArg(a, allres[r.Intn(len(allres))], 0)
} else {
arg, calls = r.createResource(s, a)
}
case r.nOutOf(2, 3):
// Create a new resource.
arg, calls = r.createResource(s, a)
default:
special := a.SpecialValues()
arg = MakeResultArg(a, nil, special[r.Intn(len(special))])
}
return arg, calls
}
func (a *BufferType) generate(r *randGen, s *state) (arg Arg, calls []*Call) {
switch a.Kind {
case BufferBlobRand, BufferBlobRange:
sz := r.randBufLen()
if a.Kind == BufferBlobRange {
sz = r.randRange(a.RangeBegin, a.RangeEnd)
}
if a.Dir() == DirOut {
return MakeOutDataArg(a, sz), nil
}
data := make([]byte, sz)
for i := range data {
data[i] = byte(r.Intn(256))
}
return MakeDataArg(a, data), nil
case BufferString:
data := r.randString(s, a)
if a.Dir() == DirOut {
return MakeOutDataArg(a, uint64(len(data))), nil
}
return MakeDataArg(a, data), nil
case BufferFilename:
if a.Dir() == DirOut {
var sz uint64
switch {
case !a.Varlen():
sz = a.Size()
case r.nOutOf(1, 3):
sz = r.rand(100)
case r.nOutOf(1, 2):
sz = 108 // UNIX_PATH_MAX
default:
sz = 4096 // PATH_MAX
}
return MakeOutDataArg(a, sz), nil
}
return MakeDataArg(a, []byte(r.filename(s, a))), nil
case BufferText:
if a.Dir() == DirOut {
return MakeOutDataArg(a, uint64(r.Intn(100))), nil
}
return MakeDataArg(a, r.generateText(a.Text)), nil
default:
panic("unknown buffer kind")
}
}
func (a *VmaType) generate(r *randGen, s *state) (arg Arg, calls []*Call) {
npages := r.randPageCount()
if a.RangeBegin != 0 || a.RangeEnd != 0 {
npages = a.RangeBegin + uint64(r.Intn(int(a.RangeEnd-a.RangeBegin+1)))
}
return r.allocVMA(s, a, npages), nil
}
func (a *FlagsType) generate(r *randGen, s *state) (arg Arg, calls []*Call) {
return MakeConstArg(a, r.flags(a.Vals, a.BitMask, 0)), nil
}
func (a *ConstType) generate(r *randGen, s *state) (arg Arg, calls []*Call) {
return MakeConstArg(a, a.Val), nil
}
func (a *IntType) generate(r *randGen, s *state) (arg Arg, calls []*Call) {
bits := a.TypeBitSize()
v := r.randInt(bits)
switch a.Kind {
case IntFileoff:
switch {
case r.nOutOf(90, 101):
v = 0
case r.nOutOf(10, 11):
v = r.rand(100)
default:
v = r.randInt(bits)
}
case IntRange:
v = r.randRangeInt(a.RangeBegin, a.RangeEnd, bits)
}
return MakeConstArg(a, v), nil
}
func (a *ProcType) generate(r *randGen, s *state) (arg Arg, calls []*Call) {
return MakeConstArg(a, r.rand(int(a.ValuesPerProc))), nil
}
func (a *ArrayType) generate(r *randGen, s *state) (arg Arg, calls []*Call) {
var count uint64
switch a.Kind {
case ArrayRandLen:
count = r.randArrayLen()
case ArrayRangeLen:
count = r.randRange(a.RangeBegin, a.RangeEnd)
}
var inner []Arg
for i := uint64(0); i < count; i++ {
arg1, calls1 := r.generateArg(s, a.Type)
inner = append(inner, arg1)
calls = append(calls, calls1...)
}
return MakeGroupArg(a, inner), calls
}
func (a *StructType) generate(r *randGen, s *state) (arg Arg, calls []*Call) {
args, calls := r.generateArgs(s, a.Fields)
group := MakeGroupArg(a, args)
return group, calls
}
func (a *UnionType) generate(r *randGen, s *state) (arg Arg, calls []*Call) {
optType := a.Fields[r.Intn(len(a.Fields))]
opt, calls := r.generateArg(s, optType)
return MakeUnionArg(a, opt), calls
}
func (a *PtrType) generate(r *randGen, s *state) (arg Arg, calls []*Call) {
if r.oneOf(1000) {
index := r.rand(len(r.target.SpecialPointers))
return MakeSpecialPointerArg(a, index), nil
}
inner, calls := r.generateArg(s, a.Type)
arg = r.allocAddr(s, a, inner.Size(), inner)
return arg, calls
}
func (a *LenType) generate(r *randGen, s *state) (arg Arg, calls []*Call) {
// Updated later in assignSizesCall.
return MakeConstArg(a, 0), nil
}
func (a *CsumType) generate(r *randGen, s *state) (arg Arg, calls []*Call) {
// Filled at runtime by executor.
return MakeConstArg(a, 0), nil
}
// Finds a compatible resource with the type `t` and the calls that initialize that resource.
func resourceCentric(t *ResourceType, s *state, r *randGen) (resource *ResultArg, calls []*Call) {
var p *Prog
for idx := range r.Perm(len(s.corpus)) {
p = s.corpus[idx].Clone()
resources := getCompatibleResources(p, t.TypeName, r)
if len(resources) > 0 {
resource = resources[r.Intn(len(resources))]
break
}
}
// No compatible resource was found.
if resource == nil {
return nil, nil
}
// Set that stores the resources that appear in the same calls with the selected resource.
relatedRes := map[*ResultArg]bool{resource: true}
// Remove unrelated calls from the program.
for idx := len(p.Calls) - 1; idx >= 0; idx-- {
includeCall := false
var newResources []*ResultArg
ForeachArg(p.Calls[idx], func(arg Arg, _ *ArgCtx) {
if a, ok := arg.(*ResultArg); ok {
if a.Res != nil && !relatedRes[a.Res] {
newResources = append(newResources, a.Res)
}
if relatedRes[a] || relatedRes[a.Res] {
includeCall = true
}
}
})
if !includeCall {
p.removeCall(idx)
} else {
for _, res := range newResources {
relatedRes[res] = true
}
}
}
// Selects a biased random length of the returned calls (more calls could offer more
// interesting programs). The values returned (n = len(calls): n, n-1, ..., 2.
biasedLen := 2 + r.biasedRand(len(calls)-1, 10)
// Removes the references that are not used anymore.
for i := biasedLen; i < len(calls); i++ {
p.removeCall(i)
}
return resource, p.Calls
}
func getCompatibleResources(p *Prog, resourceType string, r *randGen) (resources []*ResultArg) {
for _, c := range p.Calls {
ForeachArg(c, func(arg Arg, _ *ArgCtx) {
// Collect only initialized resources (the ones that are already used in other calls).
a, ok := arg.(*ResultArg)
if !ok || len(a.uses) == 0 || a.typ.Dir() != DirOut {
return
}
if !r.target.isCompatibleResource(resourceType, a.typ.Name()) {
return
}
resources = append(resources, a)
})
}
return resources
}