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- #
- #
- # The Nim Compiler
- # (c) Copyright 2017 Andreas Rumpf
- #
- # See the file "copying.txt", included in this
- # distribution, for details about the copyright.
- #
- ## Data flow analysis for Nim.
- ## We transform the AST into a linear list of instructions first to
- ## make this easier to handle: There are only 2 different branching
- ## instructions: 'goto X' is an unconditional goto, 'fork X'
- ## is a conditional goto (either the next instruction or 'X' can be
- ## taken). Exhaustive case statements are translated
- ## so that the last branch is transformed into an 'else' branch.
- ## ``return`` and ``break`` are all covered by 'goto'.
- ##
- ## Control flow through exception handling:
- ## Contrary to popular belief, exception handling doesn't cause
- ## many problems for this DFA representation, ``raise`` is a statement
- ## that ``goes to`` the outer ``finally`` or ``except`` if there is one,
- ## otherwise it is the same as ``return``. Every call is treated as
- ## a call that can potentially ``raise``. However, without a surrounding
- ## ``try`` we don't emit these ``fork ReturnLabel`` instructions in order
- ## to speed up the dataflow analysis passes.
- ##
- ## The data structures and algorithms used here are inspired by
- ## "A Graph–Free Approach to Data–Flow Analysis" by Markus Mohnen.
- ## https://link.springer.com/content/pdf/10.1007/3-540-45937-5_6.pdf
- import ast, types, intsets, lineinfos, renderer, asciitables
- from patterns import sameTrees
- type
- InstrKind* = enum
- goto, fork, def, use
- Instr* = object
- n*: PNode # contains the def/use location.
- case kind*: InstrKind
- of goto, fork: dest*: int
- else: discard
- ControlFlowGraph* = seq[Instr]
- TPosition = distinct int
- TBlock = object
- case isTryBlock: bool
- of false:
- label: PSym
- breakFixups: seq[(TPosition, seq[PNode])] #Contains the gotos for the breaks along with their pending finales
- of true:
- finale: PNode
- raiseFixups: seq[TPosition] #Contains the gotos for the raises
- Con = object
- code: ControlFlowGraph
- inTryStmt: int
- blocks: seq[TBlock]
- owner: PSym
- proc codeListing(c: ControlFlowGraph, start = 0; last = -1): string =
- # for debugging purposes
- # first iteration: compute all necessary labels:
- var jumpTargets = initIntSet()
- let last = if last < 0: c.len-1 else: min(last, c.len-1)
- for i in start..last:
- if c[i].kind in {goto, fork}:
- jumpTargets.incl(i+c[i].dest)
- var i = start
- while i <= last:
- if i in jumpTargets: result.add("L" & $i & ":\n")
- result.add "\t"
- result.add ($i & " " & $c[i].kind)
- result.add "\t"
- case c[i].kind
- of def, use:
- result.add renderTree(c[i].n)
- of goto, fork:
- result.add "L"
- result.addInt c[i].dest+i
- result.add("\t#")
- result.add($c[i].n.info.line)
- result.add("\n")
- inc i
- if i in jumpTargets: result.add("L" & $i & ": End\n")
- proc echoCfg*(c: ControlFlowGraph; start = 0; last = -1) {.deprecated.} =
- ## echos the ControlFlowGraph for debugging purposes.
- echo codeListing(c, start, last).alignTable
- proc forkI(c: var Con; n: PNode): TPosition =
- result = TPosition(c.code.len)
- c.code.add Instr(n: n, kind: fork, dest: 0)
- proc gotoI(c: var Con; n: PNode): TPosition =
- result = TPosition(c.code.len)
- c.code.add Instr(n: n, kind: goto, dest: 0)
- #[
- Join is no more
- ===============
- Instead of generating join instructions we adapt our traversal of the CFG.
- When encountering a fork we split into two paths, we follow the path
- starting at "pc + 1" until it encounters the joinpoint: "pc + forkInstr.dest".
- If we encounter gotos that would jump further than the current joinpoint,
- as can happen with gotos generated by unstructured controlflow such as break, raise or return,
- we simply suspend following the current path, and follow the other path until the new joinpoint
- which is simply the instruction pointer returned to us by the now suspended path.
- If the path we are following now, also encounters a goto that exceeds the joinpoint
- we repeat the process; suspending the current path and evaluating the other one with a new joinpoint.
- If we eventually reach a common joinpoint we join the two paths.
- This new "ping-pong" approach has the obvious advantage of not requiring join instructions, as such
- cutting down on the CFG size but is also mandatory for correctly handling complicated cases
- of unstructured controlflow.
- Design of join
- ==============
- block:
- if cond: break
- def(x)
- use(x)
- Generates:
- L0: fork lab1
- join L0 # patched.
- goto Louter
- lab1:
- def x
- join L0
- Louter:
- use x
- block outer:
- while a:
- while b:
- if foo:
- if bar:
- break outer # --> we need to 'join' every pushed 'fork' here
- This works and then our abstract interpretation needs to deal with 'fork'
- differently. It really causes a split in execution. Two threads are
- "spawned" and both need to reach the 'join L' instruction. Afterwards
- the abstract interpretations are joined and execution resumes single
- threaded.
- Abstract Interpretation
- -----------------------
- proc interpret(pc, state, comesFrom): state =
- result = state
- # we need an explicit 'create' instruction (an explicit heap), in order
- # to deal with 'var x = create(); var y = x; var z = y; destroy(z)'
- while true:
- case pc
- of fork:
- let a = interpret(pc+1, result, pc)
- let b = interpret(forkTarget, result, pc)
- result = a ++ b # ++ is a union operation
- inc pc
- of join:
- if joinTarget == comesFrom: return result
- else: inc pc
- of use X:
- if not result.contains(x):
- error "variable not initialized " & x
- inc pc
- of def X:
- if not result.contains(x):
- result.incl X
- else:
- error "overwrite of variable causes memory leak " & x
- inc pc
- of destroy X:
- result.excl X
- This is correct but still can lead to false positives:
- proc p(cond: bool) =
- if cond:
- new(x)
- otherThings()
- if cond:
- destroy x
- Is not a leak. We should find a way to model *data* flow, not just
- control flow. One solution is to rewrite the 'if' without a fork
- instruction. The unstructured aspect can now be easily dealt with
- the 'goto' and 'join' instructions.
- proc p(cond: bool) =
- L0: fork Lend
- new(x)
- # do not 'join' here!
- Lend:
- otherThings()
- join L0 # SKIP THIS FOR new(x) SOMEHOW
- destroy x
- join L0 # but here.
- But if we follow 'goto Louter' we will never come to the join point.
- We restore the bindings after popping pc from the stack then there
- "no" problem?!
- while cond:
- prelude()
- if not condB: break
- postlude()
- --->
- var setFlag = true
- while cond and not setFlag:
- prelude()
- if not condB:
- setFlag = true # BUT: Dependency
- if not setFlag: # HERE
- postlude()
- --->
- var setFlag = true
- while cond and not setFlag:
- prelude()
- if not condB:
- postlude()
- setFlag = true
- -------------------------------------------------
- while cond:
- prelude()
- if more:
- if not condB: break
- stuffHere()
- postlude()
- -->
- var setFlag = true
- while cond and not setFlag:
- prelude()
- if more:
- if not condB:
- setFlag = false
- else:
- stuffHere()
- postlude()
- else:
- postlude()
- This is getting complicated. Instead we keep the whole 'join' idea but
- duplicate the 'join' instructions on breaks and return exits!
- ]#
- proc genLabel(c: Con): TPosition = TPosition(c.code.len)
- template checkedDistance(dist): int =
- doAssert low(int) div 2 + 1 < dist and dist < high(int) div 2
- dist
- proc jmpBack(c: var Con, n: PNode, p = TPosition(0)) =
- c.code.add Instr(n: n, kind: goto, dest: checkedDistance(p.int - c.code.len))
- proc patch(c: var Con, p: TPosition) =
- # patch with current index
- c.code[p.int].dest = checkedDistance(c.code.len - p.int)
- proc gen(c: var Con; n: PNode)
- proc popBlock(c: var Con; oldLen: int) =
- var exits: seq[TPosition]
- exits.add c.gotoI(newNode(nkEmpty))
- for f in c.blocks[oldLen].breakFixups:
- c.patch(f[0])
- for finale in f[1]:
- c.gen(finale)
- exits.add c.gotoI(newNode(nkEmpty))
- for e in exits:
- c.patch e
- c.blocks.setLen(oldLen)
- template withBlock(labl: PSym; body: untyped) =
- let oldLen = c.blocks.len
- c.blocks.add TBlock(isTryBlock: false, label: labl)
- body
- popBlock(c, oldLen)
- proc isTrue(n: PNode): bool =
- n.kind == nkSym and n.sym.kind == skEnumField and n.sym.position != 0 or
- n.kind == nkIntLit and n.intVal != 0
- when true:
- proc genWhile(c: var Con; n: PNode) =
- # We unroll every loop 3 times. We emulate 0, 1, 2 iterations
- # through the loop. We need to prove this is correct for our
- # purposes. But Herb Sutter claims it is. (Proof by authority.)
- #[
- while cond:
- body
- Becomes:
- block:
- if cond:
- body
- if cond:
- body
- if cond:
- body
- We still need to ensure 'break' resolves properly, so an AST to AST
- translation is impossible.
- So the code to generate is:
- cond
- fork L4 # F1
- body
- cond
- fork L5 # F2
- body
- cond
- fork L6 # F3
- body
- L6:
- join F3
- L5:
- join F2
- L4:
- join F1
- ]#
- if isTrue(n[0]):
- # 'while true' is an idiom in Nim and so we produce
- # better code for it:
- withBlock(nil):
- for i in 0..2:
- c.gen(n[1])
- else:
- withBlock(nil):
- var endings: array[3, TPosition]
- for i in 0..2:
- c.gen(n[0])
- endings[i] = c.forkI(n)
- c.gen(n[1])
- for i in countdown(endings.high, 0):
- c.patch(endings[i])
- else:
- proc genWhile(c: var Con; n: PNode) =
- # lab1:
- # cond, tmp
- # fork tmp, lab2
- # body
- # jmp lab1
- # lab2:
- let lab1 = c.genLabel
- withBlock(nil):
- if isTrue(n[0]):
- c.gen(n[1])
- c.jmpBack(n, lab1)
- else:
- c.gen(n[0])
- forkT(n):
- c.gen(n[1])
- c.jmpBack(n, lab1)
- template forkT(n, body) =
- let lab1 = c.forkI(n)
- body
- c.patch(lab1)
- proc genIf(c: var Con, n: PNode) =
- #[
- if cond:
- A
- elif condB:
- B
- elif condC:
- C
- else:
- D
- cond
- fork lab1
- A
- goto Lend
- lab1:
- condB
- fork lab2
- B
- goto Lend2
- lab2:
- condC
- fork L3
- C
- goto Lend3
- L3:
- D
- goto Lend3 # not eliminated to simplify the join generation
- Lend3:
- join F3
- Lend2:
- join F2
- Lend:
- join F1
- ]#
- var endings: seq[TPosition] = @[]
- for i in 0..<n.len:
- let it = n[i]
- c.gen(it[0])
- if it.len == 2:
- forkT(it[1]):
- c.gen(it[1])
- endings.add c.gotoI(it[1])
- for i in countdown(endings.high, 0):
- c.patch(endings[i])
- proc genAndOr(c: var Con; n: PNode) =
- # asgn dest, a
- # fork lab1
- # asgn dest, b
- # lab1:
- # join F1
- c.gen(n[1])
- forkT(n):
- c.gen(n[2])
- proc genCase(c: var Con; n: PNode) =
- # if (!expr1) goto lab1;
- # thenPart
- # goto LEnd
- # lab1:
- # if (!expr2) goto lab2;
- # thenPart2
- # goto LEnd
- # lab2:
- # elsePart
- # Lend:
- let isExhaustive = skipTypes(n[0].typ,
- abstractVarRange-{tyTypeDesc}).kind notin {tyFloat..tyFloat128, tyString}
- var endings: seq[TPosition] = @[]
- c.gen(n[0])
- for i in 1..<n.len:
- let it = n[i]
- if it.len == 1 or (i == n.len-1 and isExhaustive):
- # treat the last branch as 'else' if this is an exhaustive case statement.
- c.gen(it.lastSon)
- else:
- forkT(it.lastSon):
- c.gen(it.lastSon)
- endings.add c.gotoI(it.lastSon)
- for i in countdown(endings.high, 0):
- let endPos = endings[i]
- c.patch(endPos)
- proc genBlock(c: var Con; n: PNode) =
- withBlock(n[0].sym):
- c.gen(n[1])
- proc genBreakOrRaiseAux(c: var Con, i: int, n: PNode) =
- let lab1 = c.gotoI(n)
- if c.blocks[i].isTryBlock:
- c.blocks[i].raiseFixups.add lab1
- else:
- var trailingFinales: seq[PNode]
- if c.inTryStmt > 0: #Ok, we are in a try, lets see which (if any) try's we break out from:
- for b in countdown(c.blocks.high, i):
- if c.blocks[b].isTryBlock:
- trailingFinales.add c.blocks[b].finale
- c.blocks[i].breakFixups.add (lab1, trailingFinales)
- proc genBreak(c: var Con; n: PNode) =
- if n[0].kind == nkSym:
- for i in countdown(c.blocks.high, 0):
- if not c.blocks[i].isTryBlock and c.blocks[i].label == n[0].sym:
- genBreakOrRaiseAux(c, i, n)
- return
- #globalError(n.info, "VM problem: cannot find 'break' target")
- else:
- for i in countdown(c.blocks.high, 0):
- if not c.blocks[i].isTryBlock:
- genBreakOrRaiseAux(c, i, n)
- return
- proc genTry(c: var Con; n: PNode) =
- var endings: seq[TPosition] = @[]
- let oldLen = c.blocks.len
- c.blocks.add TBlock(isTryBlock: true, finale: if n[^1].kind == nkFinally: n[^1] else: newNode(nkEmpty))
- inc c.inTryStmt
- c.gen(n[0])
- dec c.inTryStmt
- for f in c.blocks[oldLen].raiseFixups:
- c.patch(f)
- c.blocks.setLen oldLen
- for i in 1..<n.len:
- let it = n[i]
- if it.kind != nkFinally:
- forkT(it):
- c.gen(it.lastSon)
- endings.add c.gotoI(it)
- for i in countdown(endings.high, 0):
- c.patch(endings[i])
- let fin = lastSon(n)
- if fin.kind == nkFinally:
- c.gen(fin[0])
- template genNoReturn(c: var Con; n: PNode) =
- # leave the graph
- c.code.add Instr(n: n, kind: goto, dest: high(int) - c.code.len)
- proc genRaise(c: var Con; n: PNode) =
- gen(c, n[0])
- if c.inTryStmt > 0:
- for i in countdown(c.blocks.high, 0):
- if c.blocks[i].isTryBlock:
- genBreakOrRaiseAux(c, i, n)
- return
- assert false #Unreachable
- else:
- genNoReturn(c, n)
- proc genImplicitReturn(c: var Con) =
- if c.owner.kind in {skProc, skFunc, skMethod, skIterator, skConverter} and resultPos < c.owner.ast.len:
- gen(c, c.owner.ast[resultPos])
- proc genReturn(c: var Con; n: PNode) =
- if n[0].kind != nkEmpty:
- gen(c, n[0])
- else:
- genImplicitReturn(c)
- genBreakOrRaiseAux(c, 0, n)
- const
- InterestingSyms = {skVar, skResult, skLet, skParam, skForVar, skTemp}
- PathKinds0 = {nkDotExpr, nkCheckedFieldExpr,
- nkBracketExpr, nkDerefExpr, nkHiddenDeref,
- nkAddr, nkHiddenAddr,
- nkObjDownConv, nkObjUpConv}
- PathKinds1 = {nkHiddenStdConv, nkHiddenSubConv}
- proc skipConvDfa*(n: PNode): PNode =
- result = n
- while true:
- case result.kind
- of nkObjDownConv, nkObjUpConv:
- result = result[0]
- of PathKinds1:
- result = result[1]
- else: break
- proc aliases*(obj, field: PNode): bool =
- var n = field
- var obj = obj
- while true:
- case obj.kind
- of {nkObjDownConv, nkObjUpConv, nkAddr, nkHiddenAddr, nkDerefExpr, nkHiddenDeref}:
- obj = obj[0]
- of PathKinds1:
- obj = obj[1]
- else: break
- while true:
- if sameTrees(obj, n): return true
- case n.kind
- of PathKinds0:
- n = n[0]
- of PathKinds1:
- n = n[1]
- else: break
- type InstrTargetKind* = enum
- None, Full, Partial
- proc instrTargets*(insloc, loc: PNode): InstrTargetKind =
- if sameTrees(insloc, loc) or insloc.aliases(loc):
- Full # x -> x; x -> x.f
- elif loc.aliases(insloc):
- Partial # x.f -> x
- else: None
- proc isAnalysableFieldAccess*(orig: PNode; owner: PSym): bool =
- var n = orig
- while true:
- case n.kind
- of PathKinds0 - {nkBracketExpr, nkHiddenDeref, nkDerefExpr}:
- n = n[0]
- of PathKinds1:
- n = n[1]
- of nkBracketExpr:
- # in a[i] the 'i' must be known
- if n.len > 1 and n[1].kind in {nkCharLit..nkUInt64Lit}:
- n = n[0]
- else:
- return false
- of nkHiddenDeref, nkDerefExpr:
- # We "own" sinkparam[].loc but not ourVar[].location as it is a nasty
- # pointer indirection.
- # bug #14159, we cannot reason about sinkParam[].location as it can
- # still be shared for tyRef.
- n = n[0]
- return n.kind == nkSym and n.sym.owner == owner and
- (n.sym.typ.skipTypes(abstractInst-{tyOwned}).kind in {tyOwned})
- else: break
- # XXX Allow closure deref operations here if we know
- # the owner controlled the closure allocation?
- result = n.kind == nkSym and n.sym.owner == owner and
- {sfGlobal, sfThread, sfCursor} * n.sym.flags == {} and
- (n.sym.kind != skParam or isSinkParam(n.sym)) # or n.sym.typ.kind == tyVar)
- # Note: There is a different move analyzer possible that checks for
- # consume(param.key); param.key = newValue for all paths. Then code like
- #
- # let splited = split(move self.root, x)
- # self.root = merge(splited.lower, splited.greater)
- #
- # could be written without the ``move self.root``. However, this would be
- # wrong! Then the write barrier for the ``self.root`` assignment would
- # free the old data and all is lost! Lesson: Don't be too smart, trust the
- # lower level C++ optimizer to specialize this code.
- proc skipTrivials(c: var Con, n: PNode): PNode =
- result = n
- while true:
- case result.kind
- of PathKinds0 - {nkBracketExpr}:
- result = result[0]
- of nkBracketExpr:
- gen(c, result[1])
- result = result[0]
- of PathKinds1:
- result = result[1]
- else: break
- proc genUse(c: var Con; orig: PNode) =
- let n = c.skipTrivials(orig)
- if n.kind == nkSym and n.sym.kind in InterestingSyms:
- c.code.add Instr(n: orig, kind: use)
- elif n.kind in nkCallKinds:
- gen(c, n)
- proc genDef(c: var Con; orig: PNode) =
- let n = c.skipTrivials(orig)
- if n.kind == nkSym and n.sym.kind in InterestingSyms:
- c.code.add Instr(n: orig, kind: def)
- proc genCall(c: var Con; n: PNode) =
- gen(c, n[0])
- var t = n[0].typ
- if t != nil: t = t.skipTypes(abstractInst)
- for i in 1..<n.len:
- gen(c, n[i])
- when false:
- if t != nil and i < t.len and t[i].kind == tyOut:
- # Pass by 'out' is a 'must def'. Good enough for a move optimizer.
- genDef(c, n[i])
- # every call can potentially raise:
- if c.inTryStmt > 0 and canRaiseConservative(n[0]):
- # we generate the instruction sequence:
- # fork lab1
- # goto exceptionHandler (except or finally)
- # lab1:
- # join F1
- forkT(n):
- for i in countdown(c.blocks.high, 0):
- if c.blocks[i].isTryBlock:
- genBreakOrRaiseAux(c, i, n)
- break
- proc genMagic(c: var Con; n: PNode; m: TMagic) =
- case m
- of mAnd, mOr: c.genAndOr(n)
- of mNew, mNewFinalize:
- genDef(c, n[1])
- for i in 2..<n.len: gen(c, n[i])
- else:
- genCall(c, n)
- proc genVarSection(c: var Con; n: PNode) =
- for a in n:
- if a.kind == nkCommentStmt:
- discard
- elif a.kind == nkVarTuple:
- gen(c, a.lastSon)
- for i in 0..<a.len-2: genDef(c, a[i])
- else:
- gen(c, a.lastSon)
- if a.lastSon.kind != nkEmpty:
- genDef(c, a[0])
- proc gen(c: var Con; n: PNode) =
- case n.kind
- of nkSym: genUse(c, n)
- of nkCallKinds:
- if n[0].kind == nkSym:
- let s = n[0].sym
- if s.magic != mNone:
- genMagic(c, n, s.magic)
- else:
- genCall(c, n)
- if sfNoReturn in n[0].sym.flags:
- genNoReturn(c, n)
- else:
- genCall(c, n)
- of nkCharLit..nkNilLit: discard
- of nkAsgn, nkFastAsgn:
- gen(c, n[1])
- # watch out: 'obj[i].f2 = value' sets 'f2' but
- # "uses" 'i'. But we are only talking about builtin array indexing so
- # it doesn't matter and 'x = 34' is NOT a usage of 'x'.
- genDef(c, n[0])
- of PathKinds0 - {nkObjDownConv, nkObjUpConv}:
- genUse(c, n)
- of nkIfStmt, nkIfExpr: genIf(c, n)
- of nkWhenStmt:
- # This is "when nimvm" node. Chose the first branch.
- gen(c, n[0][1])
- of nkCaseStmt: genCase(c, n)
- of nkWhileStmt: genWhile(c, n)
- of nkBlockExpr, nkBlockStmt: genBlock(c, n)
- of nkReturnStmt: genReturn(c, n)
- of nkRaiseStmt: genRaise(c, n)
- of nkBreakStmt: genBreak(c, n)
- of nkTryStmt, nkHiddenTryStmt: genTry(c, n)
- of nkStmtList, nkStmtListExpr, nkChckRangeF, nkChckRange64, nkChckRange,
- nkBracket, nkCurly, nkPar, nkTupleConstr, nkClosure, nkObjConstr, nkYieldStmt:
- for x in n: gen(c, x)
- of nkPragmaBlock: gen(c, n.lastSon)
- of nkDiscardStmt, nkObjDownConv, nkObjUpConv, nkStringToCString, nkCStringToString:
- gen(c, n[0])
- of nkConv, nkExprColonExpr, nkExprEqExpr, nkCast, PathKinds1:
- gen(c, n[1])
- of nkVarSection, nkLetSection: genVarSection(c, n)
- of nkDefer: doAssert false, "dfa construction pass requires the elimination of 'defer'"
- else: discard
- proc constructCfg*(s: PSym; body: PNode): ControlFlowGraph =
- ## constructs a control flow graph for ``body``.
- var c = Con(code: @[], blocks: @[], owner: s)
- withBlock(s):
- gen(c, body)
- genImplicitReturn(c)
- when defined(gcArc) or defined(gcOrc):
- result = c.code # will move
- else:
- shallowCopy(result, c.code)
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