// Copyright 2019 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 loader import ( "bytes" "cmd/internal/goobj" "cmd/internal/objabi" "cmd/internal/sys" "cmd/link/internal/sym" "fmt" "testing" ) // dummyAddSym adds the named symbol to the loader as if it had been // read from a Go object file. Note that it allocates a global // index without creating an associated object reader, so one can't // do anything interesting with this symbol (such as look at its // data or relocations). func addDummyObjSym(t *testing.T, ldr *Loader, or *oReader, name string) Sym { idx := uint32(len(ldr.objSyms)) st := loadState{l: ldr} return st.addSym(name, 0, or, idx, nonPkgDef, &goobj.Sym{}) } func mkLoader() *Loader { edummy := func(str string, off int) {} er := ErrorReporter{} ldr := NewLoader(0, edummy, &er) er.ldr = ldr return ldr } func TestAddMaterializedSymbol(t *testing.T) { ldr := mkLoader() dummyOreader := oReader{version: -1, syms: make([]Sym, 100)} or := &dummyOreader // Create some syms from a dummy object file symbol to get things going. ts1 := addDummyObjSym(t, ldr, or, "type.uint8") ts2 := addDummyObjSym(t, ldr, or, "mumble") ts3 := addDummyObjSym(t, ldr, or, "type.string") // Create some external symbols. es1 := ldr.LookupOrCreateSym("extnew1", 0) if es1 == 0 { t.Fatalf("LookupOrCreateSym failed for extnew1") } es1x := ldr.LookupOrCreateSym("extnew1", 0) if es1x != es1 { t.Fatalf("LookupOrCreateSym lookup: expected %d got %d for second lookup", es1, es1x) } es2 := ldr.LookupOrCreateSym("go.info.type.uint8", 0) if es2 == 0 { t.Fatalf("LookupOrCreateSym failed for go.info.type.uint8") } // Create a nameless symbol es3 := ldr.CreateStaticSym("") if es3 == 0 { t.Fatalf("CreateStaticSym failed for nameless sym") } // Grab symbol builder pointers sb1 := ldr.MakeSymbolUpdater(es1) sb2 := ldr.MakeSymbolUpdater(es2) sb3 := ldr.MakeSymbolUpdater(es3) // Suppose we create some more symbols, which triggers a grow. // Make sure the symbol builder's payload pointer is valid, // even across a grow. for i := 0; i < 9999; i++ { ldr.CreateStaticSym("dummy") } // Check get/set symbol type es3typ := sb3.Type() if es3typ != sym.Sxxx { t.Errorf("SymType(es3): expected %v, got %v", sym.Sxxx, es3typ) } sb3.SetType(sym.SRODATA) es3typ = sb3.Type() if es3typ != sym.SRODATA { t.Errorf("SymType(es3): expected %v, got %v", sym.SRODATA, es3typ) } es3typ = ldr.SymType(es3) if es3typ != sym.SRODATA { t.Errorf("SymType(es3): expected %v, got %v", sym.SRODATA, es3typ) } // New symbols should not initially be reachable. if ldr.AttrReachable(es1) || ldr.AttrReachable(es2) || ldr.AttrReachable(es3) { t.Errorf("newly materialized symbols should not be reachable") } // ... however it should be possible to set/unset their reachability. ldr.SetAttrReachable(es3, true) if !ldr.AttrReachable(es3) { t.Errorf("expected reachable symbol after update") } ldr.SetAttrReachable(es3, false) if ldr.AttrReachable(es3) { t.Errorf("expected unreachable symbol after update") } // Test expansion of attr bitmaps for idx := 0; idx < 36; idx++ { es := ldr.LookupOrCreateSym(fmt.Sprintf("zext%d", idx), 0) if ldr.AttrOnList(es) { t.Errorf("expected OnList after creation") } ldr.SetAttrOnList(es, true) if !ldr.AttrOnList(es) { t.Errorf("expected !OnList after update") } if ldr.AttrDuplicateOK(es) { t.Errorf("expected DupOK after creation") } ldr.SetAttrDuplicateOK(es, true) if !ldr.AttrDuplicateOK(es) { t.Errorf("expected !DupOK after update") } } sb1 = ldr.MakeSymbolUpdater(es1) sb2 = ldr.MakeSymbolUpdater(es2) // Get/set a few other attributes if ldr.AttrVisibilityHidden(es3) { t.Errorf("expected initially not hidden") } ldr.SetAttrVisibilityHidden(es3, true) if !ldr.AttrVisibilityHidden(es3) { t.Errorf("expected hidden after update") } // Test get/set symbol value. toTest := []Sym{ts2, es3} for i, s := range toTest { if v := ldr.SymValue(s); v != 0 { t.Errorf("ldr.Value(%d): expected 0 got %d\n", s, v) } nv := int64(i + 101) ldr.SetSymValue(s, nv) if v := ldr.SymValue(s); v != nv { t.Errorf("ldr.SetValue(%d,%d): expected %d got %d\n", s, nv, nv, v) } } // Check/set alignment es3al := ldr.SymAlign(es3) if es3al != 0 { t.Errorf("SymAlign(es3): expected 0, got %d", es3al) } ldr.SetSymAlign(es3, 128) es3al = ldr.SymAlign(es3) if es3al != 128 { t.Errorf("SymAlign(es3): expected 128, got %d", es3al) } // Add some relocations to the new symbols. r1, _ := sb1.AddRel(objabi.R_ADDR) r1.SetOff(0) r1.SetSiz(1) r1.SetSym(ts1) r2, _ := sb1.AddRel(objabi.R_CALL) r2.SetOff(3) r2.SetSiz(8) r2.SetSym(ts2) r3, _ := sb2.AddRel(objabi.R_USETYPE) r3.SetOff(7) r3.SetSiz(1) r3.SetSym(ts3) // Add some data to the symbols. d1 := []byte{1, 2, 3} d2 := []byte{4, 5, 6, 7} sb1.AddBytes(d1) sb2.AddBytes(d2) // Now invoke the usual loader interfaces to make sure // we're getting the right things back for these symbols. // First relocations... expRel := [][]Reloc{{r1, r2}, {r3}} for k, sb := range []*SymbolBuilder{sb1, sb2} { rsl := sb.Relocs() exp := expRel[k] if !sameRelocSlice(&rsl, exp) { t.Errorf("expected relocs %v, got %v", exp, rsl) } } // ... then data. dat := sb2.Data() if bytes.Compare(dat, d2) != 0 { t.Errorf("expected es2 data %v, got %v", d2, dat) } // Nameless symbol should still be nameless. es3name := ldr.RawSymName(es3) if "" != es3name { t.Errorf("expected es3 name of '', got '%s'", es3name) } // Read value of materialized symbol. es1val := sb1.Value() if 0 != es1val { t.Errorf("expected es1 value of 0, got %v", es1val) } // Test other misc methods irm := ldr.IsReflectMethod(es1) if 0 != es1val { t.Errorf("expected IsReflectMethod(es1) value of 0, got %v", irm) } } func sameRelocSlice(s1 *Relocs, s2 []Reloc) bool { if s1.Count() != len(s2) { return false } for i := 0; i < s1.Count(); i++ { r1 := s1.At(i) r2 := &s2[i] if r1.Sym() != r2.Sym() || r1.Type() != r2.Type() || r1.Off() != r2.Off() || r1.Add() != r2.Add() || r1.Siz() != r2.Siz() { return false } } return true } type addFunc func(l *Loader, s Sym, s2 Sym) Sym func mkReloc(l *Loader, typ objabi.RelocType, off int32, siz uint8, add int64, sym Sym) Reloc { r := Reloc{&goobj.Reloc{}, l.extReader, l} r.SetType(typ) r.SetOff(off) r.SetSiz(siz) r.SetAdd(add) r.SetSym(sym) return r } func TestAddDataMethods(t *testing.T) { ldr := mkLoader() dummyOreader := oReader{version: -1, syms: make([]Sym, 100)} or := &dummyOreader // Populate loader with some symbols. addDummyObjSym(t, ldr, or, "type.uint8") ldr.LookupOrCreateSym("hello", 0) arch := sys.ArchAMD64 var testpoints = []struct { which string addDataFunc addFunc expData []byte expKind sym.SymKind expRel []Reloc }{ { which: "AddUint8", addDataFunc: func(l *Loader, s Sym, _ Sym) Sym { sb := l.MakeSymbolUpdater(s) sb.AddUint8('a') return s }, expData: []byte{'a'}, expKind: sym.SDATA, }, { which: "AddUintXX", addDataFunc: func(l *Loader, s Sym, _ Sym) Sym { sb := l.MakeSymbolUpdater(s) sb.AddUintXX(arch, 25185, 2) return s }, expData: []byte{'a', 'b'}, expKind: sym.SDATA, }, { which: "SetUint8", addDataFunc: func(l *Loader, s Sym, _ Sym) Sym { sb := l.MakeSymbolUpdater(s) sb.AddUint8('a') sb.AddUint8('b') sb.SetUint8(arch, 1, 'c') return s }, expData: []byte{'a', 'c'}, expKind: sym.SDATA, }, { which: "AddString", addDataFunc: func(l *Loader, s Sym, _ Sym) Sym { sb := l.MakeSymbolUpdater(s) sb.Addstring("hello") return s }, expData: []byte{'h', 'e', 'l', 'l', 'o', 0}, expKind: sym.SNOPTRDATA, }, { which: "AddAddrPlus", addDataFunc: func(l *Loader, s Sym, s2 Sym) Sym { sb := l.MakeSymbolUpdater(s) sb.AddAddrPlus(arch, s2, 3) return s }, expData: []byte{0, 0, 0, 0, 0, 0, 0, 0}, expKind: sym.SDATA, expRel: []Reloc{mkReloc(ldr, objabi.R_ADDR, 0, 8, 3, 6)}, }, { which: "AddAddrPlus4", addDataFunc: func(l *Loader, s Sym, s2 Sym) Sym { sb := l.MakeSymbolUpdater(s) sb.AddAddrPlus4(arch, s2, 3) return s }, expData: []byte{0, 0, 0, 0}, expKind: sym.SDATA, expRel: []Reloc{mkReloc(ldr, objabi.R_ADDR, 0, 4, 3, 7)}, }, { which: "AddCURelativeAddrPlus", addDataFunc: func(l *Loader, s Sym, s2 Sym) Sym { sb := l.MakeSymbolUpdater(s) sb.AddCURelativeAddrPlus(arch, s2, 7) return s }, expData: []byte{0, 0, 0, 0, 0, 0, 0, 0}, expKind: sym.SDATA, expRel: []Reloc{mkReloc(ldr, objabi.R_ADDRCUOFF, 0, 8, 7, 8)}, }, } var pmi Sym for k, tp := range testpoints { name := fmt.Sprintf("new%d", k+1) mi := ldr.LookupOrCreateSym(name, 0) if mi == 0 { t.Fatalf("LookupOrCreateSym failed for '" + name + "'") } mi = tp.addDataFunc(ldr, mi, pmi) if ldr.SymType(mi) != tp.expKind { t.Errorf("testing Loader.%s: expected kind %s got %s", tp.which, tp.expKind, ldr.SymType(mi)) } if bytes.Compare(ldr.Data(mi), tp.expData) != 0 { t.Errorf("testing Loader.%s: expected data %v got %v", tp.which, tp.expData, ldr.Data(mi)) } relocs := ldr.Relocs(mi) if !sameRelocSlice(&relocs, tp.expRel) { t.Fatalf("testing Loader.%s: got relocslice %+v wanted %+v", tp.which, relocs, tp.expRel) } pmi = mi } } func TestOuterSub(t *testing.T) { ldr := mkLoader() dummyOreader := oReader{version: -1, syms: make([]Sym, 100)} or := &dummyOreader // Populate loader with some symbols. addDummyObjSym(t, ldr, or, "type.uint8") es1 := ldr.LookupOrCreateSym("outer", 0) ldr.MakeSymbolUpdater(es1).SetSize(101) es2 := ldr.LookupOrCreateSym("sub1", 0) es3 := ldr.LookupOrCreateSym("sub2", 0) es4 := ldr.LookupOrCreateSym("sub3", 0) es5 := ldr.LookupOrCreateSym("sub4", 0) es6 := ldr.LookupOrCreateSym("sub5", 0) // Should not have an outer sym initially if ldr.OuterSym(es1) != 0 { t.Errorf("es1 outer sym set ") } if ldr.SubSym(es2) != 0 { t.Errorf("es2 outer sym set ") } // Establish first outer/sub relationship ldr.AddInteriorSym(es1, es2) if ldr.OuterSym(es1) != 0 { t.Errorf("ldr.OuterSym(es1) got %d wanted %d", ldr.OuterSym(es1), 0) } if ldr.OuterSym(es2) != es1 { t.Errorf("ldr.OuterSym(es2) got %d wanted %d", ldr.OuterSym(es2), es1) } if ldr.SubSym(es1) != es2 { t.Errorf("ldr.SubSym(es1) got %d wanted %d", ldr.SubSym(es1), es2) } if ldr.SubSym(es2) != 0 { t.Errorf("ldr.SubSym(es2) got %d wanted %d", ldr.SubSym(es2), 0) } // Establish second outer/sub relationship ldr.AddInteriorSym(es1, es3) if ldr.OuterSym(es1) != 0 { t.Errorf("ldr.OuterSym(es1) got %d wanted %d", ldr.OuterSym(es1), 0) } if ldr.OuterSym(es2) != es1 { t.Errorf("ldr.OuterSym(es2) got %d wanted %d", ldr.OuterSym(es2), es1) } if ldr.OuterSym(es3) != es1 { t.Errorf("ldr.OuterSym(es3) got %d wanted %d", ldr.OuterSym(es3), es1) } if ldr.SubSym(es1) != es3 { t.Errorf("ldr.SubSym(es1) got %d wanted %d", ldr.SubSym(es1), es3) } if ldr.SubSym(es3) != es2 { t.Errorf("ldr.SubSym(es3) got %d wanted %d", ldr.SubSym(es3), es2) } // Some more ldr.AddInteriorSym(es1, es4) ldr.AddInteriorSym(es1, es5) ldr.AddInteriorSym(es1, es6) // Set values. ldr.SetSymValue(es2, 7) ldr.SetSymValue(es3, 1) ldr.SetSymValue(es4, 13) ldr.SetSymValue(es5, 101) ldr.SetSymValue(es6, 3) // Sort news := ldr.SortSub(es1) if news != es3 { t.Errorf("ldr.SortSub leader got %d wanted %d", news, es3) } pv := int64(-1) count := 0 for ss := ldr.SubSym(es1); ss != 0; ss = ldr.SubSym(ss) { v := ldr.SymValue(ss) if v <= pv { t.Errorf("ldr.SortSub sortfail at %d: val %d >= prev val %d", ss, v, pv) } pv = v count++ } if count != 5 { t.Errorf("expected %d in sub list got %d", 5, count) } }