src/cmd/compile/internal/gc/scope.go - go - Git at Google

 // Copyright 2017 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 gc

 import (
 	"cmd/internal/dwarf"
 	"cmd/internal/obj"
 	"cmd/internal/src"
 	"sort"
 )

 // See golang.org/issue/20390.
 func xposBefore(p, q src.XPos) bool {
 	return Ctxt.PosTable.Pos(p).Before(Ctxt.PosTable.Pos(q))
 }

 func findScope(marks []Mark, pos src.XPos) ScopeID {
 	i := sort.Search(len(marks), func(i int) bool {
 		return xposBefore(pos, marks[i].Pos)
 	})
 	if i == 0 {
 		return 0
 	}
 	return marks[i-1].Scope
 }

 func assembleScopes(fnsym *obj.LSym, fn *Node, dwarfVars []*dwarf.Var, varScopes []ScopeID) []dwarf.Scope {
 	// Initialize the DWARF scope tree based on lexical scopes.
 	dwarfScopes := make([]dwarf.Scope, 1+len(fn.Func.Parents))
 	for i, parent := range fn.Func.Parents {
 		dwarfScopes[i+1].Parent = int32(parent)
 	}

 	scopeVariables(dwarfVars, varScopes, dwarfScopes)
 	scopePCs(fnsym, fn.Func.Marks, dwarfScopes)
 	return compactScopes(dwarfScopes)
 }

 // scopeVariables assigns DWARF variable records to their scopes.
 func scopeVariables(dwarfVars []*dwarf.Var, varScopes []ScopeID, dwarfScopes []dwarf.Scope) {
 	sort.Stable(varsByScopeAndOffset{dwarfVars, varScopes})

 	i0 := 0
 	for i := range dwarfVars {
 		if varScopes[i] == varScopes[i0] {
 			continue
 		}
 		dwarfScopes[varScopes[i0]].Vars = dwarfVars[i0:i]
 		i0 = i
 	}
 	if i0 < len(dwarfVars) {
 		dwarfScopes[varScopes[i0]].Vars = dwarfVars[i0:]
 	}
 }

 // A scopedPCs represents a non-empty half-open interval of PCs that
 // share a common source position.
 type scopedPCs struct {
 	start, end int64
 	pos        src.XPos
 	scope      ScopeID
 }

 // scopePCs assigns PC ranges to their scopes.
 func scopePCs(fnsym *obj.LSym, marks []Mark, dwarfScopes []dwarf.Scope) {
 	// If there aren't any child scopes (in particular, when scope
 	// tracking is disabled), we can skip a whole lot of work.
 	if len(marks) == 0 {
 		return
 	}

 	// Break function text into scopedPCs.
 	var pcs []scopedPCs
 	p0 := fnsym.Func.Text
 	for p := fnsym.Func.Text; p != nil; p = p.Link {
 		if p.Pos == p0.Pos {
 			continue
 		}
 		if p0.Pc < p.Pc {
 			pcs = append(pcs, scopedPCs{start: p0.Pc, end: p.Pc, pos: p0.Pos})
 		}
 		p0 = p
 	}
 	if p0.Pc < fnsym.Size {
 		pcs = append(pcs, scopedPCs{start: p0.Pc, end: fnsym.Size, pos: p0.Pos})
 	}

 	// Sort PCs by source position, and walk in parallel with
 	// scope marks to assign a lexical scope to each PC interval.
 	sort.Sort(pcsByPos(pcs))
 	var marki int
 	var scope ScopeID
 	for i := range pcs {
 		for marki < len(marks) && !xposBefore(pcs[i].pos, marks[marki].Pos) {
 			scope = marks[marki].Scope
 			marki++
 		}
 		pcs[i].scope = scope
 	}

 	// Re-sort to create sorted PC ranges for each DWARF scope.
 	sort.Sort(pcsByPC(pcs))
 	for _, pc := range pcs {
 		r := &dwarfScopes[pc.scope].Ranges
 		if i := len(*r); i > 0 && (*r)[i-1].End == pc.start {
 			(*r)[i-1].End = pc.end
 		} else {
 			*r = append(*r, dwarf.Range{Start: pc.start, End: pc.end})
 		}
 	}
 }

 func compactScopes(dwarfScopes []dwarf.Scope) []dwarf.Scope {
 	// Forward pass to collapse empty scopes into parents.
 	remap := make([]int32, len(dwarfScopes))
 	j := int32(1)
 	for i := 1; i < len(dwarfScopes); i++ {
 		s := &dwarfScopes[i]
 		s.Parent = remap[s.Parent]
 		if len(s.Vars) == 0 {
 			dwarfScopes[s.Parent].UnifyRanges(s)
 			remap[i] = s.Parent
 			continue
 		}
 		remap[i] = j
 		dwarfScopes[j] = *s
 		j++
 	}
 	dwarfScopes = dwarfScopes[:j]

 	// Reverse pass to propagate PC ranges to parent scopes.
 	for i := len(dwarfScopes) - 1; i > 0; i-- {
 		s := &dwarfScopes[i]
 		dwarfScopes[s.Parent].UnifyRanges(s)
 	}

 	return dwarfScopes
 }

 type pcsByPC []scopedPCs

 func (s pcsByPC) Len() int      { return len(s) }
 func (s pcsByPC) Swap(i, j int) { s[i], s[j] = s[j], s[i] }
 func (s pcsByPC) Less(i, j int) bool {
 	return s[i].start < s[j].start
 }

 type pcsByPos []scopedPCs

 func (s pcsByPos) Len() int      { return len(s) }
 func (s pcsByPos) Swap(i, j int) { s[i], s[j] = s[j], s[i] }
 func (s pcsByPos) Less(i, j int) bool {
 	return xposBefore(s[i].pos, s[j].pos)
 }

 type varsByScopeAndOffset struct {
 	vars   []*dwarf.Var
 	scopes []ScopeID
 }

 func (v varsByScopeAndOffset) Len() int {
 	return len(v.vars)
 }

 func (v varsByScopeAndOffset) Less(i, j int) bool {
 	if v.scopes[i] != v.scopes[j] {
 		return v.scopes[i] < v.scopes[j]
 	}
 	return v.vars[i].StackOffset < v.vars[j].StackOffset
 }

 func (v varsByScopeAndOffset) Swap(i, j int) {
 	v.vars[i], v.vars[j] = v.vars[j], v.vars[i]
 	v.scopes[i], v.scopes[j] = v.scopes[j], v.scopes[i]
 }
	// Copyright 2017 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 gc

	import (
	"cmd/internal/dwarf"
	"cmd/internal/obj"
	"cmd/internal/src"
	"sort"
	)

	// See golang.org/issue/20390.
	func xposBefore(p, q src.XPos) bool {
	return Ctxt.PosTable.Pos(p).Before(Ctxt.PosTable.Pos(q))
	}

	func findScope(marks []Mark, pos src.XPos) ScopeID {
	i := sort.Search(len(marks), func(i int) bool {
	return xposBefore(pos, marks[i].Pos)
	})
	if i == 0 {
	return 0
	}
	return marks[i-1].Scope
	}

	func assembleScopes(fnsym obj.LSym, fn Node, dwarfVars []*dwarf.Var, varScopes []ScopeID) []dwarf.Scope {
	// Initialize the DWARF scope tree based on lexical scopes.
	dwarfScopes := make([]dwarf.Scope, 1+len(fn.Func.Parents))
	for i, parent := range fn.Func.Parents {
	dwarfScopes[i+1].Parent = int32(parent)
	}

	scopeVariables(dwarfVars, varScopes, dwarfScopes)
	scopePCs(fnsym, fn.Func.Marks, dwarfScopes)
	return compactScopes(dwarfScopes)
	}

	// scopeVariables assigns DWARF variable records to their scopes.
	func scopeVariables(dwarfVars []*dwarf.Var, varScopes []ScopeID, dwarfScopes []dwarf.Scope) {
	sort.Stable(varsByScopeAndOffset{dwarfVars, varScopes})

	i0 := 0
	for i := range dwarfVars {
	if varScopes[i] == varScopes[i0] {
	continue
	}
	dwarfScopes[varScopes[i0]].Vars = dwarfVars[i0:i]
	i0 = i
	}
	if i0 < len(dwarfVars) {
	dwarfScopes[varScopes[i0]].Vars = dwarfVars[i0:]
	}
	}

	// A scopedPCs represents a non-empty half-open interval of PCs that
	// share a common source position.
	type scopedPCs struct {
	start, end int64
	pos src.XPos
	scope ScopeID
	}

	// scopePCs assigns PC ranges to their scopes.
	func scopePCs(fnsym *obj.LSym, marks []Mark, dwarfScopes []dwarf.Scope) {
	// If there aren't any child scopes (in particular, when scope
	// tracking is disabled), we can skip a whole lot of work.
	if len(marks) == 0 {
	return
	}

	// Break function text into scopedPCs.
	var pcs []scopedPCs
	p0 := fnsym.Func.Text
	for p := fnsym.Func.Text; p != nil; p = p.Link {
	if p.Pos == p0.Pos {
	continue
	}
	if p0.Pc < p.Pc {
	pcs = append(pcs, scopedPCs{start: p0.Pc, end: p.Pc, pos: p0.Pos})
	}
	p0 = p
	}
	if p0.Pc < fnsym.Size {
	pcs = append(pcs, scopedPCs{start: p0.Pc, end: fnsym.Size, pos: p0.Pos})
	}

	// Sort PCs by source position, and walk in parallel with
	// scope marks to assign a lexical scope to each PC interval.
	sort.Sort(pcsByPos(pcs))
	var marki int
	var scope ScopeID
	for i := range pcs {
	for marki < len(marks) && !xposBefore(pcs[i].pos, marks[marki].Pos) {
	scope = marks[marki].Scope
	marki++
	}
	pcs[i].scope = scope
	}

	// Re-sort to create sorted PC ranges for each DWARF scope.
	sort.Sort(pcsByPC(pcs))
	for _, pc := range pcs {
	r := &dwarfScopes[pc.scope].Ranges
	if i := len(r); i > 0 && (r)[i-1].End == pc.start {
	(*r)[i-1].End = pc.end
	} else {
	r = append(r, dwarf.Range{Start: pc.start, End: pc.end})
	}
	}
	}

	func compactScopes(dwarfScopes []dwarf.Scope) []dwarf.Scope {
	// Forward pass to collapse empty scopes into parents.
	remap := make([]int32, len(dwarfScopes))
	j := int32(1)
	for i := 1; i < len(dwarfScopes); i++ {
	s := &dwarfScopes[i]
	s.Parent = remap[s.Parent]
	if len(s.Vars) == 0 {
	dwarfScopes[s.Parent].UnifyRanges(s)
	remap[i] = s.Parent
	continue
	}
	remap[i] = j
	dwarfScopes[j] = *s
	j++
	}
	dwarfScopes = dwarfScopes[:j]

	// Reverse pass to propagate PC ranges to parent scopes.
	for i := len(dwarfScopes) - 1; i > 0; i-- {
	s := &dwarfScopes[i]
	dwarfScopes[s.Parent].UnifyRanges(s)
	}

	return dwarfScopes
	}

	type pcsByPC []scopedPCs

	func (s pcsByPC) Len() int { return len(s) }
	func (s pcsByPC) Swap(i, j int) { s[i], s[j] = s[j], s[i] }
	func (s pcsByPC) Less(i, j int) bool {
	return s[i].start < s[j].start
	}

	type pcsByPos []scopedPCs

	func (s pcsByPos) Len() int { return len(s) }
	func (s pcsByPos) Swap(i, j int) { s[i], s[j] = s[j], s[i] }
	func (s pcsByPos) Less(i, j int) bool {
	return xposBefore(s[i].pos, s[j].pos)
	}

	type varsByScopeAndOffset struct {
	vars []*dwarf.Var
	scopes []ScopeID
	}

	func (v varsByScopeAndOffset) Len() int {
	return len(v.vars)
	}

	func (v varsByScopeAndOffset) Less(i, j int) bool {
	if v.scopes[i] != v.scopes[j] {
	return v.scopes[i] < v.scopes[j]
	}
	return v.vars[i].StackOffset < v.vars[j].StackOffset
	}

	func (v varsByScopeAndOffset) Swap(i, j int) {
	v.vars[i], v.vars[j] = v.vars[j], v.vars[i]
	v.scopes[i], v.scopes[j] = v.scopes[j], v.scopes[i]
	}