#
#
# The Nimrod Compiler
# (c) Copyright 2009 Andreas Rumpf
#
# See the file "copying.txt", included in this
# distribution, for details about the copyright.
#
## LLVM code generator.
import
ast, astalgo, strutils, nhashes, trees, platform, magicsys, extccomp, options,
nversion, nimsets, msgs, crc, bitsets, idents, lists, types, ccgutils, os,
times, ropes, math, passes, rodread, wordrecg, rnimsyn, treetab, cgmeth,
llvm
proc llvmGenPass*(): TPass
type
TLabel = PRope # for the C generator a label is just a rope
TCFileSection = enum # the sections a generated C file consists of
cfsHeaders, # section for C include file headers
cfsForwardTypes, # section for C forward typedefs
cfsTypes, # section for C typedefs
cfsSeqTypes, # section for sequence types only
# this is needed for strange type generation
# reasons
cfsFieldInfo, # section for field information
cfsTypeInfo, # section for type information
cfsProcHeaders, # section for C procs prototypes
cfsData, # section for C constant data
cfsVars, # section for C variable declarations
cfsProcs, # section for C procs that are not inline
cfsTypeInit1, # section 1 for declarations of type information
cfsTypeInit2, # section 2 for init of type information
cfsTypeInit3, # section 3 for init of type information
cfsDebugInit, # section for init of debug information
cfsDynLibInit, # section for init of dynamic library binding
cfsDynLibDeinit # section for deinitialization of dynamic libraries
TCTypeKind = enum # describes the type kind of a C type
ctVoid, ctChar, ctBool, ctUInt, ctUInt8, ctUInt16, ctUInt32, ctUInt64,
ctInt, ctInt8, ctInt16, ctInt32, ctInt64, ctFloat, ctFloat32, ctFloat64,
ctFloat128, ctArray, ctStruct, ctPtr, ctNimStr, ctNimSeq, ctProc, ctCString
TCFileSections = array[TCFileSection, PRope] # represents a generated C file
TCProcSection = enum # the sections a generated C proc consists of
cpsLocals, # section of local variables for C proc
cpsInit, # section for init of variables for C proc
cpsStmts # section of local statements for C proc
TCProcSections = array[TCProcSection, PRope] # represents a generated C proc
BModule = ref TCGen
BProc = ref TCProc
TBlock{.final.} = object
id*: int # the ID of the label; positive means that it
# has been used (i.e. the label should be emitted)
nestedTryStmts*: int # how many try statements is it nested into
TCProc{.final.} = object # represents C proc that is currently generated
s*: TCProcSections # the procs sections; short name for readability
prc*: PSym # the Nimrod proc that this C proc belongs to
BeforeRetNeeded*: bool # true iff 'BeforeRet' label for proc is needed
nestedTryStmts*: Natural # in how many nested try statements we are
# (the vars must be volatile then)
labels*: Natural # for generating unique labels in the C proc
blocks*: seq[TBlock] # nested blocks
options*: TOptions # options that should be used for code
# generation; this is the same as prc.options
# unless prc == nil
frameLen*: int # current length of frame descriptor
sendClosure*: PType # closure record type that we pass
receiveClosure*: PType # closure record type that we get
module*: BModule # used to prevent excessive parameter passing
TTypeSeq = seq[PType]
TCGen = object of TPassContext # represents a C source file
module*: PSym
filename*: string
s*: TCFileSections # sections of the C file
cfilename*: string # filename of the module (including path,
# without extension)
typeCache*: TIdTable # cache the generated types
forwTypeCache*: TIdTable # cache for forward declarations of types
declaredThings*: TIntSet # things we have declared in this .c file
declaredProtos*: TIntSet # prototypes we have declared in this .c file
headerFiles*: TLinkedList # needed headers to include
typeInfoMarker*: TIntSet # needed for generating type information
initProc*: BProc # code for init procedure
typeStack*: TTypeSeq # used for type generation
dataCache*: TNodeTable
forwardedProcs*: TSymSeq # keep forwarded procs here
typeNodes*, nimTypes*: int # used for type info generation
typeNodesName*, nimTypesName*: PRope # used for type info generation
labels*: natural # for generating unique module-scope names
var
mainModProcs, mainModInit: PRope # parts of the main module
gMapping: PRope # the generated mapping file (if requested)
gProcProfile: Natural # proc profile counter
gGeneratedSyms: TIntSet # set of ID's of generated symbols
gPendingModules: seq[BModule] = @[] # list of modules that are not
# finished with code generation
gForwardedProcsCounter: int = 0
gNimDat: BModule # generated global data
proc ropeff(cformat, llvmformat: string, args: openarray[PRope]): PRope =
if gCmd == cmdCompileToLLVM: result = ropef(llvmformat, args)
else: result = ropef(cformat, args)
proc appff(dest: var PRope, cformat, llvmformat: string,
args: openarray[PRope]) =
if gCmd == cmdCompileToLLVM: appf(dest, llvmformat, args)
else: appf(dest, cformat, args)
proc addForwardedProc(m: BModule, prc: PSym) =
m.forwardedProcs.add(prc)
inc(gForwardedProcsCounter)
proc addPendingModule(m: BModule) =
for i in countup(0, high(gPendingModules)):
if gPendingModules[i] == m:
InternalError("module already pending: " & m.module.name.s)
gPendingModules.add(m)
proc findPendingModule(m: BModule, s: PSym): BModule =
var ms = getModule(s)
if ms.id == m.module.id:
return m
for i in countup(0, high(gPendingModules)):
result = gPendingModules[i]
if result.module.id == ms.id: return
InternalError(s.info, "no pending module found for: " & s.name.s)
proc initLoc(result: var TLoc, k: TLocKind, typ: PType, s: TStorageLoc) =
result.k = k
result.s = s
result.t = GetUniqueType(typ)
result.r = nil
result.a = - 1
result.flags = {}
proc fillLoc(a: var TLoc, k: TLocKind, typ: PType, r: PRope, s: TStorageLoc) =
# fills the loc if it is not already initialized
if a.k == locNone:
a.k = k
a.t = getUniqueType(typ)
a.a = - 1
a.s = s
if a.r == nil: a.r = r
proc newProc(prc: PSym, module: BModule): BProc =
new(result)
result.prc = prc
result.module = module
if prc != nil: result.options = prc.options
else: result.options = gOptions
result.blocks = @[]
proc isSimpleConst(typ: PType): bool =
result = not (skipTypes(typ, abstractVar).kind in
{tyTuple, tyObject, tyArray, tyArrayConstr, tySet, tySequence})
proc useHeader(m: BModule, sym: PSym) =
if lfHeader in sym.loc.Flags:
assert(sym.annex != nil)
discard lists.IncludeStr(m.headerFiles, getStr(sym.annex.path))
proc UseMagic(m: BModule, name: string)
include "ccgtypes.nim"
# ------------------------------ Manager of temporaries ------------------
proc getTemp(p: BProc, t: PType, result: var TLoc) =
inc(p.labels)
if gCmd == cmdCompileToLLVM:
result.r = con("%LOC", toRope(p.labels))
else:
result.r = con("LOC", toRope(p.labels))
appf(p.s[cpsLocals], "$1 $2;$n", [getTypeDesc(p.module, t), result.r])
result.k = locTemp
result.a = - 1
result.t = getUniqueType(t)
result.s = OnStack
result.flags = {}
proc cstringLit(p: BProc, r: var PRope, s: string): PRope =
if gCmd == cmdCompileToLLVM:
inc(p.module.labels)
inc(p.labels)
result = ropef("%LOC$1", [toRope(p.labels)])
appf(p.module.s[cfsData], "@C$1 = private constant [$2 x i8] $3$n",
[toRope(p.module.labels), toRope(len(s)), makeLLVMString(s)])
appf(r, "$1 = getelementptr [$2 x i8]* @C$3, %NI 0, %NI 0$n",
[result, toRope(len(s)), toRope(p.module.labels)])
else:
result = makeCString(s)
proc cstringLit(m: BModule, r: var PRope, s: string): PRope =
if gCmd == cmdCompileToLLVM:
inc(m.labels, 2)
result = ropef("%MOC$1", [toRope(m.labels - 1)])
appf(m.s[cfsData], "@MOC$1 = private constant [$2 x i8] $3$n",
[toRope(m.labels), toRope(len(s)), makeLLVMString(s)])
appf(r, "$1 = getelementptr [$2 x i8]* @MOC$3, %NI 0, %NI 0$n",
[result, toRope(len(s)), toRope(m.labels)])
else:
result = makeCString(s)
proc allocParam(p: BProc, s: PSym) =
assert(s.kind == skParam)
if not (lfParamCopy in s.loc.flags):
inc(p.labels)
var tmp = con("%LOC", toRope(p.labels))
incl(s.loc.flags, lfParamCopy)
incl(s.loc.flags, lfIndirect)
appf(p.s[cpsInit], "$1 = alloca $3$n" & "store $3 $2, $3* $1$n",
[tmp, s.loc.r, getTypeDesc(p.module, s.loc.t)])
s.loc.r = tmp
proc localDebugInfo(p: BProc, s: PSym) =
var name, a: PRope
if {optStackTrace, optEndb} * p.options != {optStackTrace, optEndb}: return
if gCmd == cmdCompileToLLVM:
# "address" is the 0th field
# "typ" is the 1rst field
# "name" is the 2nd field
name = cstringLit(p, p.s[cpsInit], normalize(s.name.s))
if (s.kind == skParam) and not ccgIntroducedPtr(s): allocParam(p, s)
inc(p.labels, 3)
appf(p.s[cpsInit], "%LOC$6 = getelementptr %TF* %F, %NI 0, $1, %NI 0$n" &
"%LOC$7 = getelementptr %TF* %F, %NI 0, $1, %NI 1$n" &
"%LOC$8 = getelementptr %TF* %F, %NI 0, $1, %NI 2$n" &
"store i8* $2, i8** %LOC$6$n" & "store $3* $4, $3** %LOC$7$n" &
"store i8* $5, i8** %LOC$8$n", [toRope(p.frameLen), s.loc.r,
getTypeDesc(p.module, "TNimType"),
genTypeInfo(p.module, s.loc.t), name,
toRope(p.labels), toRope(p.labels - 1),
toRope(p.labels - 2)])
else:
a = con("&", s.loc.r)
if (s.kind == skParam) and ccgIntroducedPtr(s): a = s.loc.r
appf(p.s[cpsInit],
"F.s[$1].address = (void*)$3; F.s[$1].typ = $4; F.s[$1].name = $2;$n", [
toRope(p.frameLen), makeCString(normalize(s.name.s)), a,
genTypeInfo(p.module, s.loc.t)])
inc(p.frameLen)
proc assignLocalVar(p: BProc, s: PSym) =
#assert(s.loc.k == locNone) // not yet assigned
# this need not be fullfilled for inline procs; they are regenerated
# for each module that uses them!
if s.loc.k == locNone:
fillLoc(s.loc, locLocalVar, s.typ, mangleName(s), OnStack)
if gCmd == cmdCompileToLLVM:
appf(p.s[cpsLocals], "$1 = alloca $2$n",
[s.loc.r, getTypeDesc(p.module, s.loc.t)])
incl(s.loc.flags, lfIndirect)
else:
app(p.s[cpsLocals], getTypeDesc(p.module, s.loc.t))
if sfRegister in s.flags: app(p.s[cpsLocals], " register")
if (sfVolatile in s.flags) or (p.nestedTryStmts > 0):
app(p.s[cpsLocals], " volatile")
appf(p.s[cpsLocals], " $1;$n", [s.loc.r])
localDebugInfo(p, s)
proc assignGlobalVar(p: BProc, s: PSym) =
if s.loc.k == locNone:
fillLoc(s.loc, locGlobalVar, s.typ, mangleName(s), OnHeap)
if gCmd == cmdCompileToLLVM:
appf(p.module.s[cfsVars], "$1 = linkonce global $2 zeroinitializer$n",
[s.loc.r, getTypeDesc(p.module, s.loc.t)])
incl(s.loc.flags, lfIndirect)
else:
useHeader(p.module, s)
if lfNoDecl in s.loc.flags: return
if sfImportc in s.flags: app(p.module.s[cfsVars], "extern ")
app(p.module.s[cfsVars], getTypeDesc(p.module, s.loc.t))
if sfRegister in s.flags: app(p.module.s[cfsVars], " register")
if sfVolatile in s.flags: app(p.module.s[cfsVars], " volatile")
if sfThreadVar in s.flags: app(p.module.s[cfsVars], " NIM_THREADVAR")
appf(p.module.s[cfsVars], " $1;$n", [s.loc.r])
if {optStackTrace, optEndb} * p.module.module.options ==
{optStackTrace, optEndb}:
useMagic(p.module, "dbgRegisterGlobal")
appff(p.module.s[cfsDebugInit], "dbgRegisterGlobal($1, &$2, $3);$n",
"call void @dbgRegisterGlobal(i8* $1, i8* $2, $4* $3)$n", [cstringLit(
p, p.module.s[cfsDebugInit], normalize(s.owner.name.s & '.' & s.name.s)),
s.loc.r, genTypeInfo(p.module, s.typ), getTypeDesc(p.module, "TNimType")])
proc iff(cond: bool, the, els: PRope): PRope =
if cond: result = the
else: result = els
proc assignParam(p: BProc, s: PSym) =
assert(s.loc.r != nil)
if (sfAddrTaken in s.flags) and (gCmd == cmdCompileToLLVM): allocParam(p, s)
localDebugInfo(p, s)
proc fillProcLoc(sym: PSym) =
if sym.loc.k == locNone:
fillLoc(sym.loc, locProc, sym.typ, mangleName(sym), OnStack)
proc getLabel(p: BProc): TLabel =
inc(p.labels)
result = con("LA", toRope(p.labels))
proc fixLabel(p: BProc, labl: TLabel) =
appf(p.s[cpsStmts], "$1: ;$n", [labl])
proc genVarPrototype(m: BModule, sym: PSym)
proc genConstPrototype(m: BModule, sym: PSym)
proc genProc(m: BModule, prc: PSym)
proc genStmts(p: BProc, t: PNode)
proc genProcPrototype(m: BModule, sym: PSym)
include "ccgexprs.nim", "ccgstmts.nim"
# ----------------------------- dynamic library handling -----------------
# We don't finalize dynamic libs as this does the OS for us.
proc libCandidates(s: string, dest: var TStringSeq) =
var le = strutils.find(s, '(')
var ri = strutils.find(s, ')', le+1)
if le >= 0 and ri > le:
var prefix = copy(s, 0, le - 1)
var suffix = copy(s, ri + 1)
for middle in split(copy(s, le + 1, ri - 1), '|'):
libCandidates(prefix & middle & suffix, dest)
else:
add(dest, s)
proc loadDynamicLib(m: BModule, lib: PLib) =
assert(lib != nil)
if not lib.generated:
lib.generated = true
var tmp = getGlobalTempName()
assert(lib.name == nil)
lib.name = tmp # BUGFIX: useMagic has awful side-effects
appf(m.s[cfsVars], "static void* $1;$n", [tmp])
if lib.path.kind in {nkStrLit..nkTripleStrLit}:
var s: TStringSeq = @[]
libCandidates(lib.path.strVal, s)
var loadlib: PRope = nil
for i in countup(0, high(s)):
inc(m.labels)
if i > 0: app(loadlib, "||")
appf(loadlib, "($1 = nimLoadLibrary((NimStringDesc*) &$2))$n",
[tmp, getStrLit(m, s[i])])
appf(m.s[cfsDynLibInit],
"if (!($1)) nimLoadLibraryError((NimStringDesc*) &$2);$n",
[loadlib, getStrLit(m, lib.path.strVal)])
else:
var p = newProc(nil, m)
var dest: TLoc
initLocExpr(p, lib.path, dest)
app(m.s[cfsVars], p.s[cpsLocals])
app(m.s[cfsDynLibInit], p.s[cpsInit])
app(m.s[cfsDynLibInit], p.s[cpsStmts])
appf(m.s[cfsDynLibInit],
"if (!($1 = nimLoadLibrary($2))) nimLoadLibraryError($2);$n",
[tmp, rdLoc(dest)])
useMagic(m, "nimLoadLibrary")
useMagic(m, "nimUnloadLibrary")
useMagic(m, "NimStringDesc")
useMagic(m, "nimLoadLibraryError")
if lib.name == nil: InternalError("loadDynamicLib")
proc SymInDynamicLib(m: BModule, sym: PSym) =
var lib = sym.annex
var extname = sym.loc.r
loadDynamicLib(m, lib)
useMagic(m, "nimGetProcAddr")
if gCmd == cmdCompileToLLVM: incl(sym.loc.flags, lfIndirect)
var tmp = ropeff("Dl_$1", "@Dl_$1", [toRope(sym.id)])
sym.loc.r = tmp # from now on we only need the internal name
sym.typ.sym = nil # generate a new name
inc(m.labels, 2)
appff(m.s[cfsDynLibInit],
"$1 = ($2) nimGetProcAddr($3, $4);$n", "%MOC$5 = load i8* $3$n" &
"%MOC$6 = call $2 @nimGetProcAddr(i8* %MOC$5, i8* $4)$n" &
"store $2 %MOC$6, $2* $1$n", [tmp, getTypeDesc(m, sym.typ),
lib.name, cstringLit(m, m.s[cfsDynLibInit], ropeToStr(extname)),
toRope(m.labels), toRope(m.labels - 1)])
appff(m.s[cfsVars], "$2 $1;$n",
"$1 = linkonce global $2 zeroinitializer$n",
[sym.loc.r, getTypeDesc(m, sym.loc.t)])
proc UseMagic(m: BModule, name: string) =
var sym = magicsys.getCompilerProc(name)
if sym != nil:
case sym.kind
of skProc, skMethod, skConverter: genProc(m, sym)
of skVar, skResult: genVarPrototype(m, sym)
of skType: discard getTypeDesc(m, sym.typ)
else: InternalError("useMagic: " & name)
elif not (sfSystemModule in m.module.flags):
rawMessage(errSystemNeeds, name) # don't be too picky here
proc generateHeaders(m: BModule) =
app(m.s[cfsHeaders], "#include \"nimbase.h\"" & tnl & tnl)
var it = PStrEntry(m.headerFiles.head)
while it != nil:
if not (it.data[0] in {'\"', '<'}):
appf(m.s[cfsHeaders], "#include \"$1\"$n", [toRope(it.data)])
else:
appf(m.s[cfsHeaders], "#include $1$n", [toRope(it.data)])
it = PStrEntry(it.Next)
proc getFrameDecl(p: BProc) =
var slots: PRope
if p.frameLen > 0:
useMagic(p.module, "TVarSlot")
slots = ropeff(" TVarSlot s[$1];$n", ", [$1 x %TVarSlot]",
[toRope(p.frameLen)])
else:
slots = nil
appff(p.s[cpsLocals], "volatile struct {TFrame* prev;" &
"NCSTRING procname;NI line;NCSTRING filename;" &
"NI len;$n$1} F;$n",
"%TF = type {%TFrame*, i8*, %NI, %NI$1}$n" &
"%F = alloca %TF$n", [slots])
inc(p.labels)
prepend(p.s[cpsInit], ropeff("F.len = $1;$n",
"%LOC$2 = getelementptr %TF %F, %NI 4$n" &
"store %NI $1, %NI* %LOC$2$n", [toRope(p.frameLen), toRope(p.labels)]))
proc retIsNotVoid(s: PSym): bool =
result = (s.typ.sons[0] != nil) and not isInvalidReturnType(s.typ.sons[0])
proc initFrame(p: BProc, procname, filename: PRope): PRope =
inc(p.labels, 5)
result = ropeff("F.procname = $1;$n" & "F.prev = framePtr;$n" &
"F.filename = $2;$n" & "F.line = 0;$n" & "framePtr = (TFrame*)&F;$n",
"%LOC$3 = getelementptr %TF %F, %NI 1$n" &
"%LOC$4 = getelementptr %TF %F, %NI 0$n" &
"%LOC$5 = getelementptr %TF %F, %NI 3$n" &
"%LOC$6 = getelementptr %TF %F, %NI 2$n" & "store i8* $1, i8** %LOC$3$n" &
"store %TFrame* @framePtr, %TFrame** %LOC$4$n" &
"store i8* $2, i8** %LOC$5$n" & "store %NI 0, %NI* %LOC$6$n" &
"%LOC$7 = bitcast %TF* %F to %TFrame*$n" &
"store %TFrame* %LOC$7, %TFrame** @framePtr$n", [procname, filename,
toRope(p.labels), toRope(p.labels - 1), toRope(p.labels - 2),
toRope(p.labels - 3), toRope(p.labels - 4)])
proc deinitFrame(p: BProc): PRope =
inc(p.labels, 3)
result = ropeff("framePtr = framePtr->prev;$n",
"%LOC$1 = load %TFrame* @framePtr$n" &
"%LOC$2 = getelementptr %TFrame* %LOC$1, %NI 0$n" &
"%LOC$3 = load %TFrame** %LOC$2$n" &
"store %TFrame* $LOC$3, %TFrame** @framePtr", [toRope(p.labels),
toRope(p.labels - 1), toRope(p.labels - 2)])
proc genProcAux(m: BModule, prc: PSym) =
var
p: BProc
generatedProc, header, returnStmt, procname, filename: PRope
res, param: PSym
p = newProc(prc, m)
header = genProcHeader(m, prc)
if (gCmd != cmdCompileToLLVM) and (lfExportLib in prc.loc.flags):
header = con("N_LIB_EXPORT ", header)
returnStmt = nil
assert(prc.ast != nil)
if not (sfPure in prc.flags) and (prc.typ.sons[0] != nil):
res = prc.ast.sons[resultPos].sym # get result symbol
if not isInvalidReturnType(prc.typ.sons[0]):
# declare the result symbol:
assignLocalVar(p, res)
assert(res.loc.r != nil)
returnStmt = ropeff("return $1;$n", "ret $1$n", [rdLoc(res.loc)])
else:
fillResult(res)
assignParam(p, res)
if skipTypes(res.typ, abstractInst).kind == tyArray:
incl(res.loc.flags, lfIndirect)
res.loc.s = OnUnknown
initVariable(p, res)
genObjectInit(p, res.typ, res.loc, true)
for i in countup(1, sonsLen(prc.typ.n) - 1):
param = prc.typ.n.sons[i].sym
assignParam(p, param)
genStmts(p, prc.ast.sons[codePos]) # modifies p.locals, p.init, etc.
if sfPure in prc.flags:
generatedProc = ropeff("$1 {$n$2$3$4}$n", "define $1 {$n$2$3$4}$n", [header,
p.s[cpsLocals], p.s[cpsInit], p.s[cpsStmts]])
else:
generatedProc = ropeff("$1 {$n", "define $1 {$n", [header])
if optStackTrace in prc.options:
getFrameDecl(p)
app(generatedProc, p.s[cpsLocals])
procname = CStringLit(p, generatedProc,
prc.owner.name.s & '.' & prc.name.s)
filename = CStringLit(p, generatedProc, toFilename(prc.info))
app(generatedProc, initFrame(p, procname, filename))
else:
app(generatedProc, p.s[cpsLocals])
if (optProfiler in prc.options) and (gCmd != cmdCompileToLLVM):
if gProcProfile >= 64 * 1024:
InternalError(prc.info, "too many procedures for profiling")
useMagic(m, "profileData")
app(p.s[cpsLocals], "ticks NIM_profilingStart;" & tnl)
if prc.loc.a < 0:
appf(m.s[cfsDebugInit], "profileData[$1].procname = $2;$n", [
toRope(gProcProfile),
makeCString(prc.owner.name.s & '.' & prc.name.s)])
prc.loc.a = gProcProfile
inc(gProcProfile)
prepend(p.s[cpsInit], toRope("NIM_profilingStart = getticks();" & tnl))
app(generatedProc, p.s[cpsInit])
app(generatedProc, p.s[cpsStmts])
if p.beforeRetNeeded: app(generatedProc, "BeforeRet: ;" & tnl)
if optStackTrace in prc.options: app(generatedProc, deinitFrame(p))
if (optProfiler in prc.options) and (gCmd != cmdCompileToLLVM):
appf(generatedProc, "profileData[$1].total += elapsed(getticks(), NIM_profilingStart);$n",
[toRope(prc.loc.a)])
app(generatedProc, returnStmt)
app(generatedProc, '}' & tnl)
app(m.s[cfsProcs], generatedProc) #if prc.kind = skMethod then addMethodToCompile(gNimDat, prc);
proc genProcPrototype(m: BModule, sym: PSym) =
useHeader(m, sym)
if (lfNoDecl in sym.loc.Flags): return
if lfDynamicLib in sym.loc.Flags:
if (sym.owner.id != m.module.id) and
not intSetContainsOrIncl(m.declaredThings, sym.id):
appff(m.s[cfsVars], "extern $1 Dl_$2;$n",
"@Dl_$2 = linkonce global $1 zeroinitializer$n",
[getTypeDesc(m, sym.loc.t), toRope(sym.id)])
if gCmd == cmdCompileToLLVM: incl(sym.loc.flags, lfIndirect)
else:
if not IntSetContainsOrIncl(m.declaredProtos, sym.id):
appf(m.s[cfsProcHeaders], "$1;$n", [genProcHeader(m, sym)])
proc genProcNoForward(m: BModule, prc: PSym) =
fillProcLoc(prc)
useHeader(m, prc)
genProcPrototype(m, prc)
if (lfNoDecl in prc.loc.Flags): return
if prc.typ.callConv == ccInline:
# We add inline procs to the calling module to enable C based inlining.
# This also means that a check with ``gGeneratedSyms`` is wrong, we need
# a check for ``m.declaredThings``.
if not intSetContainsOrIncl(m.declaredThings, prc.id): genProcAux(m, prc)
elif lfDynamicLib in prc.loc.flags:
if not IntSetContainsOrIncl(gGeneratedSyms, prc.id):
SymInDynamicLib(findPendingModule(m, prc), prc)
elif not (sfImportc in prc.flags):
if not IntSetContainsOrIncl(gGeneratedSyms, prc.id):
genProcAux(findPendingModule(m, prc), prc)
proc genProc(m: BModule, prc: PSym) =
if sfBorrow in prc.flags: return
fillProcLoc(prc)
if {sfForward, sfFromGeneric} * prc.flags != {}: addForwardedProc(m, prc)
else: genProcNoForward(m, prc)
proc genVarPrototype(m: BModule, sym: PSym) =
assert(sfGlobal in sym.flags)
useHeader(m, sym)
fillLoc(sym.loc, locGlobalVar, sym.typ, mangleName(sym), OnHeap)
if (lfNoDecl in sym.loc.Flags) or
intSetContainsOrIncl(m.declaredThings, sym.id):
return
if sym.owner.id != m.module.id:
# else we already have the symbol generated!
assert(sym.loc.r != nil)
if gCmd == cmdCompileToLLVM:
incl(sym.loc.flags, lfIndirect)
appf(m.s[cfsVars], "$1 = linkonce global $2 zeroinitializer$n",
[sym.loc.r, getTypeDesc(m, sym.loc.t)])
else:
app(m.s[cfsVars], "extern ")
app(m.s[cfsVars], getTypeDesc(m, sym.loc.t))
if sfRegister in sym.flags: app(m.s[cfsVars], " register")
if sfVolatile in sym.flags: app(m.s[cfsVars], " volatile")
if sfThreadVar in sym.flags: app(m.s[cfsVars], " NIM_THREADVAR")
appf(m.s[cfsVars], " $1;$n", [sym.loc.r])
proc genConstPrototype(m: BModule, sym: PSym) =
useHeader(m, sym)
if sym.loc.k == locNone:
fillLoc(sym.loc, locData, sym.typ, mangleName(sym), OnUnknown)
if (lfNoDecl in sym.loc.Flags) or
intSetContainsOrIncl(m.declaredThings, sym.id):
return
if sym.owner.id != m.module.id:
# else we already have the symbol generated!
assert(sym.loc.r != nil)
appff(m.s[cfsData], "extern NIM_CONST $1 $2;$n",
"$1 = linkonce constant $2 zeroinitializer",
[getTypeDesc(m, sym.loc.t), sym.loc.r])
proc getFileHeader(cfilenoext: string): PRope =
if optCompileOnly in gGlobalOptions:
result = ropeff("/* Generated by Nimrod Compiler v$1 */$n" &
"/* (c) 2009 Andreas Rumpf */$n", "; Generated by Nimrod Compiler v$1$n" &
"; (c) 2009 Andreas Rumpf$n", [toRope(versionAsString)])
else:
result = ropeff("/* Generated by Nimrod Compiler v$1 */$n" &
"/* (c) 2009 Andreas Rumpf */$n" & "/* Compiled for: $2, $3, $4 */$n" &
"/* Command for C compiler:$n $5 */$n", "; Generated by Nimrod Compiler v$1$n" &
"; (c) 2009 Andreas Rumpf$n" & "; Compiled for: $2, $3, $4$n" &
"; Command for LLVM compiler:$n $5$n", [toRope(versionAsString),
toRope(platform.OS[targetOS].name),
toRope(platform.CPU[targetCPU].name),
toRope(extccomp.CC[extccomp.ccompiler].name),
toRope(getCompileCFileCmd(cfilenoext))])
case platform.CPU[targetCPU].intSize
of 16:
appff(result,
"$ntypedef short int NI;$n" & "typedef unsigned short int NU;$n",
"$n%NI = type i16$n", [])
of 32:
appff(result,
"$ntypedef long int NI;$n" & "typedef unsigned long int NU;$n",
"$n%NI = type i32$n", [])
of 64:
appff(result, "$ntypedef long long int NI;$n" &
"typedef unsigned long long int NU;$n", "$n%NI = type i64$n", [])
else:
nil
proc genMainProc(m: BModule) =
const
CommonMainBody = " setStackBottom(dummy);$n" & " nim__datInit();$n" &
" systemInit();$n" & "$1" & "$2"
CommonMainBodyLLVM = " %MOC$3 = bitcast [8 x %NI]* %dummy to i8*$n" &
" call void @setStackBottom(i8* %MOC$3)$n" &
" call void @nim__datInit()$n" & " call void systemInit()$n" & "$1" &
"$2"
PosixNimMain = "int cmdCount;$n" & "char** cmdLine;$n" & "char** gEnv;$n" &
"N_CDECL(void, NimMain)(void) {$n" & " int dummy[8];$n" &
CommonMainBody & "}$n"
PosixCMain = "int main(int argc, char** args, char** env) {$n" &
" cmdLine = args;$n" & " cmdCount = argc;$n" & " gEnv = env;$n" &
" NimMain();$n" & " return 0;$n" & "}$n"
PosixNimMainLLVM = "@cmdCount = linkonce i32$n" &
"@cmdLine = linkonce i8**$n" & "@gEnv = linkonce i8**$n" &
"define void @NimMain(void) {$n" & " %dummy = alloca [8 x %NI]$n" &
CommonMainBodyLLVM & "}$n"
PosixCMainLLVM = "define i32 @main(i32 %argc, i8** %args, i8** %env) {$n" &
" store i8** %args, i8*** @cmdLine$n" &
" store i32 %argc, i32* @cmdCount$n" &
" store i8** %env, i8*** @gEnv$n" & " call void @NimMain()$n" &
" ret i32 0$n" & "}$n"
WinNimMain = "N_CDECL(void, NimMain)(void) {$n" & " int dummy[8];$n" &
CommonMainBody & "}$n"
WinCMain = "N_STDCALL(int, WinMain)(HINSTANCE hCurInstance, $n" &
" HINSTANCE hPrevInstance, $n" &
" LPSTR lpCmdLine, int nCmdShow) {$n" &
" NimMain();$n" & " return 0;$n" & "}$n"
WinNimMainLLVM = "define void @NimMain(void) {$n" &
" %dummy = alloca [8 x %NI]$n" & CommonMainBodyLLVM & "}$n"
WinCMainLLVM = "define stdcall i32 @WinMain(i32 %hCurInstance, $n" &
" i32 %hPrevInstance, $n" &
" i8* %lpCmdLine, i32 %nCmdShow) {$n" &
" call void @NimMain()$n" & " ret i32 0$n" & "}$n"
WinNimDllMain = "N_LIB_EXPORT N_CDECL(void, NimMain)(void) {$n" &
" int dummy[8];$n" & CommonMainBody & "}$n"
WinCDllMain = "BOOL WINAPI DllMain(HINSTANCE hinstDLL, DWORD fwdreason, $n" &
" LPVOID lpvReserved) {$n" & " NimMain();$n" &
" return 1;$n" & "}$n"
WinNimDllMainLLVM = WinNimMainLLVM
WinCDllMainLLVM = "define stdcall i32 @DllMain(i32 %hinstDLL, i32 %fwdreason, $n" &
" i8* %lpvReserved) {$n" &
" call void @NimMain()$n" & " ret i32 1$n" & "}$n"
var nimMain, otherMain: TFormatStr
useMagic(m, "setStackBottom")
if (platform.targetOS == osWindows) and
(gGlobalOptions * {optGenGuiApp, optGenDynLib} != {}):
if optGenGuiApp in gGlobalOptions:
if gCmd == cmdCompileToLLVM:
nimMain = WinNimMainLLVM
otherMain = WinCMainLLVM
else:
nimMain = WinNimMain
otherMain = WinCMain
else:
if gCmd == cmdCompileToLLVM:
nimMain = WinNimDllMainLLVM
otherMain = WinCDllMainLLVM
else:
nimMain = WinNimDllMain
otherMain = WinCDllMain
discard lists.IncludeStr(m.headerFiles, "<windows.h>")
else:
if gCmd == cmdCompileToLLVM:
nimMain = PosixNimMainLLVM
otherMain = PosixCMainLLVM
else:
nimMain = PosixNimMain
otherMain = PosixCMain
if gBreakpoints != nil: useMagic(m, "dbgRegisterBreakpoint")
inc(m.labels)
appf(m.s[cfsProcs], nimMain, [gBreakpoints, mainModInit, toRope(m.labels)])
if not (optNoMain in gGlobalOptions): appf(m.s[cfsProcs], otherMain, [])
proc getInitName(m: PSym): PRope =
result = ropeff("$1Init", "@$1Init", [toRope(m.name.s)])
proc registerModuleToMain(m: PSym) =
var initname = getInitName(m)
appff(mainModProcs, "N_NOINLINE(void, $1)(void);$n",
"declare void $1() noinline$n", [initname])
if not (sfSystemModule in m.flags):
appff(mainModInit, "$1();$n", "call void ()* $1$n", [initname])
proc genInitCode(m: BModule) =
var initname, prc, procname, filename: PRope
if optProfiler in m.initProc.options:
# This does not really belong here, but there is no good place for this
# code. I don't want to put this to the proc generation as the
# ``IncludeStr`` call is quite slow.
discard lists.IncludeStr(m.headerFiles, "<cycle.h>")
initname = getInitName(m.module)
prc = ropeff("N_NOINLINE(void, $1)(void) {$n",
"define void $1() noinline {$n", [initname])
if m.typeNodes > 0:
useMagic(m, "TNimNode")
appff(m.s[cfsTypeInit1], "static TNimNode $1[$2];$n",
"$1 = private alloca [$2 x @TNimNode]$n",
[m.typeNodesName, toRope(m.typeNodes)])
if m.nimTypes > 0:
useMagic(m, "TNimType")
appff(m.s[cfsTypeInit1], "static TNimType $1[$2];$n",
"$1 = private alloca [$2 x @TNimType]$n",
[m.nimTypesName, toRope(m.nimTypes)])
if optStackTrace in m.initProc.options:
getFrameDecl(m.initProc)
app(prc, m.initProc.s[cpsLocals])
app(prc, m.s[cfsTypeInit1])
procname = CStringLit(m.initProc, prc, "module " & m.module.name.s)
filename = CStringLit(m.initProc, prc, toFilename(m.module.info))
app(prc, initFrame(m.initProc, procname, filename))
else:
app(prc, m.initProc.s[cpsLocals])
app(prc, m.s[cfsTypeInit1])
app(prc, m.s[cfsTypeInit2])
app(prc, m.s[cfsTypeInit3])
app(prc, m.s[cfsDebugInit])
app(prc, m.s[cfsDynLibInit])
app(prc, m.initProc.s[cpsInit])
app(prc, m.initProc.s[cpsStmts])
if optStackTrace in m.initProc.options: app(prc, deinitFrame(m.initProc))
app(prc, '}' & tnl & tnl)
app(m.s[cfsProcs], prc)
proc genModule(m: BModule, cfilenoext: string): PRope =
result = getFileHeader(cfilenoext)
generateHeaders(m)
for i in countup(low(TCFileSection), cfsProcs): app(result, m.s[i])
proc rawNewModule(module: PSym, filename: string): BModule =
new(result)
InitLinkedList(result.headerFiles)
intSetInit(result.declaredThings)
intSetInit(result.declaredProtos)
result.cfilename = filename
result.filename = filename
initIdTable(result.typeCache)
initIdTable(result.forwTypeCache)
result.module = module
intSetInit(result.typeInfoMarker)
result.initProc = newProc(nil, result)
result.initProc.options = gOptions
initNodeTable(result.dataCache)
result.typeStack = @[]
result.forwardedProcs = @[]
result.typeNodesName = getTempName()
result.nimTypesName = getTempName()
proc newModule(module: PSym, filename: string): BModule =
result = rawNewModule(module, filename)
if (optDeadCodeElim in gGlobalOptions):
if (sfDeadCodeElim in module.flags):
InternalError("added pending module twice: " & filename)
addPendingModule(result)
proc registerTypeInfoModule() =
const moduleName = "nim__dat"
var s = NewSym(skModule, getIdent(moduleName), nil)
gNimDat = rawNewModule(s, joinPath(options.projectPath, moduleName) & ".nim")
addPendingModule(gNimDat)
appff(mainModProcs, "N_NOINLINE(void, $1)(void);$n",
"declare void $1() noinline$n", [getInitName(s)])
proc myOpen(module: PSym, filename: string): PPassContext =
if gNimDat == nil: registerTypeInfoModule()
result = newModule(module, filename)
proc myOpenCached(module: PSym, filename: string, rd: PRodReader): PPassContext =
var cfile, cfilenoext, objFile: string
if gNimDat == nil:
registerTypeInfoModule()
#MessageOut('cgen.myOpenCached has been called ' + filename);
cfile = changeFileExt(completeCFilePath(filename), cExt)
cfilenoext = changeFileExt(cfile, "")
addFileToLink(cfilenoext)
registerModuleToMain(module)
# XXX: this cannot be right here, initalization has to be appended during
# the ``myClose`` call
result = nil
proc shouldRecompile(code: PRope, cfile, cfilenoext: string): bool =
result = true
if not (optForceFullMake in gGlobalOptions):
var objFile = toObjFile(cfilenoext)
if writeRopeIfNotEqual(code, cfile): return
if ExistsFile(objFile) and os.FileNewer(objFile, cfile): result = false
else:
writeRope(code, cfile)
proc myProcess(b: PPassContext, n: PNode): PNode =
result = n
if b == nil: return
var m = BModule(b)
m.initProc.options = gOptions
genStmts(m.initProc, n)
proc finishModule(m: BModule) =
var i = 0
while i <= high(m.forwardedProcs):
# Note: ``genProc`` may add to ``m.forwardedProcs``, so we cannot use
# a ``for`` loop here
var prc = m.forwardedProcs[i]
if sfForward in prc.flags: InternalError(prc.info, "still forwarded")
genProcNoForward(m, prc)
inc(i)
assert(gForwardedProcsCounter >= i)
dec(gForwardedProcsCounter, i)
setlen(m.forwardedProcs, 0)
proc writeModule(m: BModule) =
var
cfile, cfilenoext: string
code: PRope
# generate code for the init statements of the module:
genInitCode(m)
finishTypeDescriptions(m)
cfile = completeCFilePath(m.cfilename)
cfilenoext = changeFileExt(cfile, "")
if sfMainModule in m.module.flags:
# generate main file:
app(m.s[cfsProcHeaders], mainModProcs)
code = genModule(m, cfilenoext)
if shouldRecompile(code, changeFileExt(cfile, cExt), cfilenoext):
addFileToCompile(cfilenoext)
addFileToLink(cfilenoext)
proc myClose(b: PPassContext, n: PNode): PNode =
result = n
if b == nil: return
var m = BModule(b)
if n != nil:
m.initProc.options = gOptions
genStmts(m.initProc, n)
registerModuleToMain(m.module)
if not (optDeadCodeElim in gGlobalOptions) and
not (sfDeadCodeElim in m.module.flags):
finishModule(m)
if sfMainModule in m.module.flags:
var disp = generateMethodDispatchers()
for i in countup(0, sonsLen(disp) - 1): genProcAux(gNimDat, disp.sons[i].sym)
genMainProc(m)
# we need to process the transitive closure because recursive module
# deps are allowed (and the system module is processed in the wrong
# order anyway)
while gForwardedProcsCounter > 0:
for i in countup(0, high(gPendingModules)):
finishModule(gPendingModules[i])
for i in countup(0, high(gPendingModules)): writeModule(gPendingModules[i])
setlen(gPendingModules, 0)
if not (optDeadCodeElim in gGlobalOptions) and
not (sfDeadCodeElim in m.module.flags):
writeModule(m)
if sfMainModule in m.module.flags: writeMapping(gMapping)
proc llvmgenPass(): TPass =
initPass(result)
result.open = myOpen
result.openCached = myOpenCached
result.process = myProcess
result.close = myClose
InitIiTable(gToTypeInfoId)
IntSetInit(gGeneratedSyms)