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#
#
# The Nim Compiler
# (c) Copyright 2015 Andreas Rumpf
#
# See the file "copying.txt", included in this
# distribution, for details about the copyright.
#
## This module implements the C code generator.
import
ast, astalgo, trees, platform, magicsys, extccomp, options,
nversion, nimsets, msgs, bitsets, idents, types,
ccgutils, ropes, wordrecg, treetab, cgmeth,
rodutils, renderer, cgendata, aliases,
lowerings, ndi, lineinfos, pathutils, transf,
injectdestructors, astmsgs, modulepaths, backendpragmas,
mangleutils
from expanddefaults import caseObjDefaultBranch
import pipelineutils
when defined(nimPreviewSlimSystem):
import std/assertions
when not defined(leanCompiler):
import spawn, semparallel
import std/strutils except `%`, addf # collides with ropes.`%`
from ic / ic import ModuleBackendFlag
import std/[dynlib, math, tables, sets, os, intsets, hashes]
const
# we use some ASCII control characters to insert directives that will be converted to real code in a postprocessing pass
postprocessDirStart = '\1'
postprocessDirSep = '\31'
postprocessDirEnd = '\23'
when not declared(dynlib.libCandidates):
proc libCandidates(s: string, dest: var seq[string]) =
## given a library name pattern `s` write possible library names to `dest`.
var le = strutils.find(s, '(')
var ri = strutils.find(s, ')', le+1)
if le >= 0 and ri > le:
var prefix = substr(s, 0, le - 1)
var suffix = substr(s, ri + 1)
for middle in split(substr(s, le + 1, ri - 1), '|'):
libCandidates(prefix & middle & suffix, dest)
else:
dest.add(s)
when options.hasTinyCBackend:
import tccgen
proc hcrOn(m: BModule): bool = m.config.hcrOn
proc hcrOn(p: BProc): bool = p.module.config.hcrOn
proc addForwardedProc(m: BModule, prc: PSym) =
m.g.forwardedProcs.add(prc)
proc findPendingModule(m: BModule, s: PSym): BModule =
# TODO fixme
if m.config.symbolFiles == v2Sf:
let ms = s.itemId.module #getModule(s)
result = m.g.modules[ms]
else:
var ms = getModule(s)
result = m.g.modules[ms.position]
proc initLoc(k: TLocKind, lode: PNode, s: TStorageLoc, flags: TLocFlags = {}): TLoc =
result = TLoc(k: k, storage: s, lode: lode,
r: "", flags: flags
)
proc fillLoc(a: var TLoc, k: TLocKind, lode: PNode, r: Rope, s: TStorageLoc) {.inline.} =
# fills the loc if it is not already initialized
if a.k == locNone:
a.k = k
a.lode = lode
a.storage = s
if a.r == "": a.r = r
proc fillLoc(a: var TLoc, k: TLocKind, lode: PNode, s: TStorageLoc) {.inline.} =
# fills the loc if it is not already initialized
if a.k == locNone:
a.k = k
a.lode = lode
a.storage = s
proc t(a: TLoc): PType {.inline.} =
if a.lode.kind == nkSym:
result = a.lode.sym.typ
else:
result = a.lode.typ
proc lodeTyp(t: PType): PNode =
result = newNode(nkEmpty)
result.typ = t
proc isSimpleConst(typ: PType): bool =
let t = skipTypes(typ, abstractVar)
result = t.kind notin
{tyTuple, tyObject, tyArray, tySet, tySequence} and not
(t.kind == tyProc and t.callConv == ccClosure)
proc useHeader(m: BModule, sym: PSym) =
if lfHeader in sym.loc.flags:
assert(sym.annex != nil)
let str = getStr(sym.annex.path)
m.includeHeader(str)
proc cgsym(m: BModule, name: string)
proc cgsymValue(m: BModule, name: string): Rope
proc getCFile(m: BModule): AbsoluteFile
proc getModuleDllPath(m: BModule): Rope =
let (dir, name, ext) = splitFile(getCFile(m))
let filename = strutils.`%`(platform.OS[m.g.config.target.targetOS].dllFrmt, [name & ext])
result = makeCString(dir.string & "/" & filename)
proc getModuleDllPath(m: BModule, module: int): Rope =
result = getModuleDllPath(m.g.modules[module])
proc getModuleDllPath(m: BModule, s: PSym): Rope =
result = getModuleDllPath(m.g.modules[s.itemId.module])
import std/macros
proc cgFormatValue(result: var string; value: string) =
result.add value
proc cgFormatValue(result: var string; value: BiggestInt) =
result.addInt value
proc cgFormatValue(result: var string; value: Int128) =
result.addInt128 value
# TODO: please document
macro ropecg(m: BModule, frmt: static[FormatStr], args: untyped): Rope =
args.expectKind nnkBracket
# echo "ropecg ", newLit(frmt).repr, ", ", args.repr
var i = 0
result = nnkStmtListExpr.newTree()
result.add quote do:
assert `m` != nil
let resVar = genSym(nskVar, "res")
# during `koch boot` the median of all generates strings from this
# macro is around 40 bytes in length.
result.add newVarStmt(resVar, newCall(bindSym"newStringOfCap", newLit(80)))
let formatValue = bindSym"cgFormatValue"
var num = 0
var strLit = ""
template flushStrLit() =
if strLit != "":
result.add newCall(ident "add", resVar, newLit(strLit))
strLit.setLen 0
while i < frmt.len:
if frmt[i] == '$':
inc(i) # skip '$'
case frmt[i]
of '$':
strLit.add '$'
inc(i)
of '#':
flushStrLit()
inc(i)
result.add newCall(formatValue, resVar, args[num])
inc(num)
of '^':
flushStrLit()
inc(i)
result.add newCall(formatValue, resVar, args[^1])
inc(num)
of '0'..'9':
var j = 0
while true:
j = (j * 10) + ord(frmt[i]) - ord('0')
inc(i)
if i >= frmt.len or not (frmt[i] in {'0'..'9'}): break
num = j
if j > args.len:
error("ropes: invalid format string " & newLit(frmt).repr & " args.len: " & $args.len)
flushStrLit()
result.add newCall(formatValue, resVar, args[j-1])
of 'n':
flushStrLit()
result.add quote do:
if optLineDir notin `m`.config.options:
`resVar`.add("\L")
inc(i)
of 'N':
strLit.add "\L"
inc(i)
else:
error("ropes: invalid format string $" & frmt[i])
elif frmt[i] == '#' and frmt[i+1] in IdentStartChars:
inc(i)
var j = i
while frmt[j] in IdentChars: inc(j)
var ident = newLit(substr(frmt, i, j-1))
i = j
flushStrLit()
result.add newCall(formatValue, resVar, newCall(ident"cgsymValue", m, ident))
elif frmt[i] == '#' and frmt[i+1] == '$':
inc(i, 2)
var j = 0
while frmt[i] in Digits:
j = (j * 10) + ord(frmt[i]) - ord('0')
inc(i)
let ident = args[j-1]
flushStrLit()
result.add newCall(formatValue, resVar, newCall(ident"cgsymValue", m, ident))
elif frmt[i] == '#' and frmt[i+1] == '#':
inc(i, 2)
strLit.add("#")
else:
strLit.add(frmt[i])
inc(i)
flushStrLit()
result.add newCall(ident"rope", resVar)
proc addIndent(p: BProc; result: var Rope) =
var i = result.len
let newLen = i + p.blocks.len
result.setLen newLen
while i < newLen:
result[i] = '\t'
inc i
template appcg(m: BModule, c: var Rope, frmt: FormatStr,
args: untyped) =
c.add(ropecg(m, frmt, args))
template appcg(m: BModule, sec: TCFileSection, frmt: FormatStr,
args: untyped) =
m.s[sec].add(ropecg(m, frmt, args))
template appcg(p: BProc, sec: TCProcSection, frmt: FormatStr,
args: untyped) =
p.s(sec).add(ropecg(p.module, frmt, args))
template line(p: BProc, sec: TCProcSection, r: string) =
addIndent p, p.s(sec)
p.s(sec).add(r)
template lineF(p: BProc, sec: TCProcSection, frmt: FormatStr,
args: untyped) =
addIndent p, p.s(sec)
p.s(sec).add(frmt % args)
template lineCg(p: BProc, sec: TCProcSection, frmt: FormatStr,
args: untyped) =
addIndent p, p.s(sec)
p.s(sec).add(ropecg(p.module, frmt, args))
template linefmt(p: BProc, sec: TCProcSection, frmt: FormatStr,
args: untyped) =
addIndent p, p.s(sec)
p.s(sec).add(ropecg(p.module, frmt, args))
proc safeLineNm(info: TLineInfo): int =
result = toLinenumber(info)
if result < 0: result = 0 # negative numbers are not allowed in #line
proc genPostprocessDir(field1, field2, field3: string): string =
result = postprocessDirStart & field1 & postprocessDirSep & field2 & postprocessDirSep & field3 & postprocessDirEnd
proc genCLineDir(r: var Rope, fileIdx: FileIndex, line: int; conf: ConfigRef) =
assert line >= 0
if optLineDir in conf.options and line > 0:
if fileIdx == InvalidFileIdx:
r.add(rope("\n#line " & $line & " \"generated_not_to_break_here\"\n"))
else:
r.add(rope("\n#line " & $line & " FX_" & $fileIdx.int32 & "\n"))
proc genCLineDir(r: var Rope, fileIdx: FileIndex, line: int; p: BProc; info: TLineInfo; lastFileIndex: FileIndex) =
assert line >= 0
if optLineDir in p.config.options and line > 0:
if fileIdx == InvalidFileIdx:
r.add(rope("\n#line " & $line & " \"generated_not_to_break_here\"\n"))
else:
r.add(rope("\n#line " & $line & " FX_" & $fileIdx.int32 & "\n"))
proc genCLineDir(r: var Rope, info: TLineInfo; conf: ConfigRef) =
if optLineDir in conf.options:
genCLineDir(r, info.fileIndex, info.safeLineNm, conf)
proc freshLineInfo(p: BProc; info: TLineInfo): bool =
if p.lastLineInfo.line != info.line or
p.lastLineInfo.fileIndex != info.fileIndex:
p.lastLineInfo.line = info.line
p.lastLineInfo.fileIndex = info.fileIndex
result = true
else:
result = false
proc genCLineDir(r: var Rope, p: BProc, info: TLineInfo; conf: ConfigRef) =
if optLineDir in conf.options:
let lastFileIndex = p.lastLineInfo.fileIndex
if freshLineInfo(p, info):
genCLineDir(r, info.fileIndex, info.safeLineNm, p, info, lastFileIndex)
proc genLineDir(p: BProc, t: PNode) =
if p == p.module.preInitProc: return
let line = t.info.safeLineNm
if optEmbedOrigSrc in p.config.globalOptions:
p.s(cpsStmts).add("//" & sourceLine(p.config, t.info) & "\L")
let lastFileIndex = p.lastLineInfo.fileIndex
let freshLine = freshLineInfo(p, t.info)
if freshLine:
genCLineDir(p.s(cpsStmts), t.info.fileIndex, line, p, t.info, lastFileIndex)
if ({optLineTrace, optStackTrace} * p.options == {optLineTrace, optStackTrace}) and
(p.prc == nil or sfPure notin p.prc.flags) and t.info.fileIndex != InvalidFileIdx:
if freshLine:
line(p, cpsStmts, genPostprocessDir("nimln", $line, $t.info.fileIndex.int32))
proc accessThreadLocalVar(p: BProc, s: PSym)
proc emulatedThreadVars(conf: ConfigRef): bool {.inline.}
proc genProc(m: BModule, prc: PSym)
proc raiseInstr(p: BProc; result: var Rope)
template compileToCpp(m: BModule): untyped =
m.config.backend == backendCpp or sfCompileToCpp in m.module.flags
proc getTempName(m: BModule): Rope =
result = m.tmpBase & rope(m.labels)
inc m.labels
proc rdLoc(a: TLoc): Rope =
# 'read' location (deref if indirect)
if lfIndirect in a.flags:
result = "(*" & a.r & ")"
else:
result = a.r
proc addRdLoc(a: TLoc; result: var Rope) =
if lfIndirect in a.flags:
result.add "(*" & a.r & ")"
else:
result.add a.r
proc lenField(p: BProc): Rope {.inline.} =
result = rope(if p.module.compileToCpp: "len" else: "Sup.len")
proc lenExpr(p: BProc; a: TLoc): Rope =
if optSeqDestructors in p.config.globalOptions:
result = rdLoc(a) & ".len"
else:
result = "($1 ? $1->$2 : 0)" % [rdLoc(a), lenField(p)]
proc dataFieldAccessor(p: BProc, sym: Rope): Rope =
if optSeqDestructors in p.config.globalOptions:
result = "(" & sym & ").p"
else:
result = sym
proc dataField(p: BProc): Rope =
if optSeqDestructors in p.config.globalOptions:
result = rope".p->data"
else:
result = rope"->data"
proc genProcPrototype(m: BModule, sym: PSym)
include ccgliterals
include ccgtypes
# ------------------------------ Manager of temporaries ------------------
template mapTypeChooser(n: PNode): TSymKind =
(if n.kind == nkSym: n.sym.kind else: skVar)
template mapTypeChooser(a: TLoc): TSymKind = mapTypeChooser(a.lode)
proc addAddrLoc(conf: ConfigRef; a: TLoc; result: var Rope) =
if lfIndirect notin a.flags and mapType(conf, a.t, mapTypeChooser(a) == skParam) != ctArray:
result.add "(&" & a.r & ")"
else:
result.add a.r
proc addrLoc(conf: ConfigRef; a: TLoc): Rope =
if lfIndirect notin a.flags and mapType(conf, a.t, mapTypeChooser(a) == skParam) != ctArray:
result = "(&" & a.r & ")"
else:
result = a.r
proc byRefLoc(p: BProc; a: TLoc): Rope =
if lfIndirect notin a.flags and mapType(p.config, a.t, mapTypeChooser(a) == skParam) != ctArray and not
p.module.compileToCpp:
result = "(&" & a.r & ")"
else:
result = a.r
proc rdCharLoc(a: TLoc): Rope =
# read a location that may need a char-cast:
result = rdLoc(a)
if skipTypes(a.t, abstractRange).kind == tyChar:
result = "((NU8)($1))" % [result]
type
TAssignmentFlag = enum
needToCopy
needTempForOpenArray
TAssignmentFlags = set[TAssignmentFlag]
proc genObjConstr(p: BProc, e: PNode, d: var TLoc)
proc rawConstExpr(p: BProc, n: PNode; d: var TLoc)
proc genAssignment(p: BProc, dest, src: TLoc, flags: TAssignmentFlags)
type
ObjConstrMode = enum
constructObj,
constructRefObj
proc genObjectInit(p: BProc, section: TCProcSection, t: PType, a: var TLoc,
mode: ObjConstrMode) =
#if optNimV2 in p.config.globalOptions: return
case analyseObjectWithTypeField(t)
of frNone:
discard
of frHeader:
var r = rdLoc(a)
if mode == constructRefObj: r = "(*$1)" % [r]
var s = skipTypes(t, abstractInst)
if not p.module.compileToCpp:
while s.kind == tyObject and s[0] != nil:
r.add(".Sup")
s = skipTypes(s[0], skipPtrs)
if optTinyRtti in p.config.globalOptions:
linefmt(p, section, "$1.m_type = $2;$n", [r, genTypeInfoV2(p.module, t, a.lode.info)])
else:
linefmt(p, section, "$1.m_type = $2;$n", [r, genTypeInfoV1(p.module, t, a.lode.info)])
of frEmbedded:
if optTinyRtti in p.config.globalOptions:
var tmp: TLoc = default(TLoc)
if mode == constructRefObj:
let objType = t.skipTypes(abstractInst+{tyRef})
rawConstExpr(p, newNodeIT(nkType, a.lode.info, objType), tmp)
linefmt(p, cpsStmts,
"#nimCopyMem((void*)$1, (NIM_CONST void*)&$2, sizeof($3));$n",
[rdLoc(a), rdLoc(tmp), getTypeDesc(p.module, objType, descKindFromSymKind mapTypeChooser(a))])
else:
rawConstExpr(p, newNodeIT(nkType, a.lode.info, t), tmp)
genAssignment(p, a, tmp, {})
else:
# worst case for performance:
var r = if mode == constructObj: addrLoc(p.config, a) else: rdLoc(a)
linefmt(p, section, "#objectInit($1, $2);$n", [r, genTypeInfoV1(p.module, t, a.lode.info)])
if isException(t):
var r = rdLoc(a)
if mode == constructRefObj: r = "(*$1)" % [r]
var s = skipTypes(t, abstractInst)
if not p.module.compileToCpp:
while s.kind == tyObject and s[0] != nil and s.sym.magic != mException:
r.add(".Sup")
s = skipTypes(s[0], skipPtrs)
linefmt(p, section, "$1.name = $2;$n", [r, makeCString(t.skipTypes(abstractInst).sym.name.s)])
proc genRefAssign(p: BProc, dest, src: TLoc)
proc isComplexValueType(t: PType): bool {.inline.} =
let t = t.skipTypes(abstractInst + tyUserTypeClasses)
result = t.kind in {tyArray, tySet, tyTuple, tyObject, tyOpenArray} or
(t.kind == tyProc and t.callConv == ccClosure)
include ccgreset
proc resetLoc(p: BProc, loc: var TLoc) =
let containsGcRef = optSeqDestructors notin p.config.globalOptions and containsGarbageCollectedRef(loc.t)
let typ = skipTypes(loc.t, abstractVarRange)
if isImportedCppType(typ): return
if optSeqDestructors in p.config.globalOptions and typ.kind in {tyString, tySequence}:
assert loc.r != ""
let atyp = skipTypes(loc.t, abstractInst)
if atyp.kind in {tyVar, tyLent}:
linefmt(p, cpsStmts, "$1->len = 0; $1->p = NIM_NIL;$n", [rdLoc(loc)])
else:
linefmt(p, cpsStmts, "$1.len = 0; $1.p = NIM_NIL;$n", [rdLoc(loc)])
elif not isComplexValueType(typ):
if containsGcRef:
var nilLoc: TLoc = initLoc(locTemp, loc.lode, OnStack)
nilLoc.r = rope("NIM_NIL")
genRefAssign(p, loc, nilLoc)
else:
linefmt(p, cpsStmts, "$1 = 0;$n", [rdLoc(loc)])
else:
if loc.storage != OnStack and containsGcRef:
specializeReset(p, loc)
when false:
linefmt(p, cpsStmts, "#genericReset((void*)$1, $2);$n",
[addrLoc(p.config, loc), genTypeInfoV1(p.module, loc.t, loc.lode.info)])
# XXX: generated reset procs should not touch the m_type
# field, so disabling this should be safe:
genObjectInit(p, cpsStmts, loc.t, loc, constructObj)
else:
# array passed as argument decayed into pointer, bug #7332
# so we use getTypeDesc here rather than rdLoc(loc)
let tyDesc = getTypeDesc(p.module, loc.t, descKindFromSymKind mapTypeChooser(loc))
if p.module.compileToCpp and isOrHasImportedCppType(typ):
if lfIndirect in loc.flags:
#C++ cant be just zeroed. We need to call the ctors
var tmp = getTemp(p, loc.t)
linefmt(p, cpsStmts,"#nimCopyMem((void*)$1, (NIM_CONST void*)$2, sizeof($3));$n",
[addrLoc(p.config, loc), addrLoc(p.config, tmp), tyDesc])
else:
linefmt(p, cpsStmts, "#nimZeroMem((void*)$1, sizeof($2));$n",
[addrLoc(p.config, loc), tyDesc])
# XXX: We can be extra clever here and call memset only
# on the bytes following the m_type field?
genObjectInit(p, cpsStmts, loc.t, loc, constructObj)
proc constructLoc(p: BProc, loc: var TLoc, isTemp = false) =
let typ = loc.t
if optSeqDestructors in p.config.globalOptions and skipTypes(typ, abstractInst + {tyStatic}).kind in {tyString, tySequence}:
linefmt(p, cpsStmts, "$1.len = 0; $1.p = NIM_NIL;$n", [rdLoc(loc)])
elif not isComplexValueType(typ):
if containsGarbageCollectedRef(loc.t):
var nilLoc: TLoc = initLoc(locTemp, loc.lode, OnStack)
nilLoc.r = rope("NIM_NIL")
genRefAssign(p, loc, nilLoc)
else:
linefmt(p, cpsStmts, "$1 = ($2)0;$n", [rdLoc(loc),
getTypeDesc(p.module, typ, descKindFromSymKind mapTypeChooser(loc))])
else:
if (not isTemp or containsGarbageCollectedRef(loc.t)) and not hasNoInit(loc.t):
# don't use nimZeroMem for temporary values for performance if we can
# avoid it:
if not isOrHasImportedCppType(typ):
linefmt(p, cpsStmts, "#nimZeroMem((void*)$1, sizeof($2));$n",
[addrLoc(p.config, loc), getTypeDesc(p.module, typ, descKindFromSymKind mapTypeChooser(loc))])
genObjectInit(p, cpsStmts, loc.t, loc, constructObj)
proc initLocalVar(p: BProc, v: PSym, immediateAsgn: bool) =
if sfNoInit notin v.flags:
# we know it is a local variable and thus on the stack!
# If ``not immediateAsgn`` it is not initialized in a binding like
# ``var v = X`` and thus we need to init it.
# If ``v`` contains a GC-ref we may pass it to ``unsureAsgnRef`` somehow
# which requires initialization. However this can really only happen if
# ``var v = X()`` gets transformed into ``X(&v)``.
# Nowadays the logic in ccgcalls deals with this case however.
if not immediateAsgn:
constructLoc(p, v.loc)
proc getTemp(p: BProc, t: PType, needsInit=false): TLoc =
inc(p.labels)
result = TLoc(r: "T" & rope(p.labels) & "_", k: locTemp, lode: lodeTyp t,
storage: OnStack, flags: {})
if p.module.compileToCpp and isOrHasImportedCppType(t):
var didGenTemp = false
linefmt(p, cpsLocals, "$1 $2$3;$n", [getTypeDesc(p.module, t, dkVar), result.r,
genCppInitializer(p.module, p, t, didGenTemp)])
else:
linefmt(p, cpsLocals, "$1 $2;$n", [getTypeDesc(p.module, t, dkVar), result.r])
constructLoc(p, result, not needsInit)
when false:
# XXX Introduce a compiler switch in order to detect these easily.
if getSize(p.config, t) > 1024 * 1024:
if p.prc != nil:
echo "ENORMOUS TEMPORARY! ", p.config $ p.prc.info
else:
echo "ENORMOUS TEMPORARY! ", p.config $ p.lastLineInfo
writeStackTrace()
proc getTempCpp(p: BProc, t: PType, value: Rope): TLoc =
inc(p.labels)
result = TLoc(r: "T" & rope(p.labels) & "_", k: locTemp, lode: lodeTyp t,
storage: OnStack, flags: {})
linefmt(p, cpsStmts, "auto $1 = $2;$n", [result.r, value])
proc getIntTemp(p: BProc): TLoc =
inc(p.labels)
result = TLoc(r: "T" & rope(p.labels) & "_", k: locTemp,
storage: OnStack, lode: lodeTyp getSysType(p.module.g.graph, unknownLineInfo, tyInt),
flags: {})
linefmt(p, cpsLocals, "NI $1;$n", [result.r])
proc localVarDecl(p: BProc; n: PNode): Rope =
result = ""
let s = n.sym
if s.loc.k == locNone:
fillLocalName(p, s)
fillLoc(s.loc, locLocalVar, n, OnStack)
if s.kind == skLet: incl(s.loc.flags, lfNoDeepCopy)
if s.kind in {skLet, skVar, skField, skForVar} and s.alignment > 0:
result.addf("NIM_ALIGN($1) ", [rope(s.alignment)])
genCLineDir(result, p, n.info, p.config)
result.add getTypeDesc(p.module, s.typ, dkVar)
if sfCodegenDecl notin s.flags:
if sfRegister in s.flags: result.add(" register")
#elif skipTypes(s.typ, abstractInst).kind in GcTypeKinds:
# decl.add(" GC_GUARD")
if sfVolatile in s.flags: result.add(" volatile")
if sfNoalias in s.flags: result.add(" NIM_NOALIAS")
result.add(" ")
result.add(s.loc.r)
else:
result = runtimeFormat(s.cgDeclFrmt, [result, s.loc.r])
proc assignLocalVar(p: BProc, n: PNode) =
#assert(s.loc.k == locNone) # not yet assigned
# this need not be fulfilled for inline procs; they are regenerated
# for each module that uses them!
let nl = if optLineDir in p.config.options: "" else: "\n"
var decl = localVarDecl(p, n)
if p.module.compileToCpp and isOrHasImportedCppType(n.typ):
var didGenTemp = false
decl.add genCppInitializer(p.module, p, n.typ, didGenTemp)
decl.add ";" & nl
line(p, cpsLocals, decl)
include ccgthreadvars
proc varInDynamicLib(m: BModule, sym: PSym)
proc treatGlobalDifferentlyForHCR(m: BModule, s: PSym): bool =
return m.hcrOn and {sfThread, sfGlobal} * s.flags == {sfGlobal} and
({lfNoDecl, lfHeader} * s.loc.flags == {})
# and s.owner.kind == skModule # owner isn't always a module (global pragma on local var)
# and s.loc.k == locGlobalVar # loc isn't always initialized when this proc is used
proc genGlobalVarDecl(p: BProc, n: PNode; td, value: Rope; decl: var Rope) =
let s = n.sym
if sfCodegenDecl notin s.flags:
if s.kind in {skLet, skVar, skField, skForVar} and s.alignment > 0:
decl.addf "NIM_ALIGN($1) ", [rope(s.alignment)]
if p.hcrOn: decl.add("static ")
elif sfImportc in s.flags: decl.add("extern ")
elif lfExportLib in s.loc.flags: decl.add("N_LIB_EXPORT_VAR ")
else: decl.add("N_LIB_PRIVATE ")
if s.kind == skLet and value != "": decl.add("NIM_CONST ")
decl.add(td)
if p.hcrOn: decl.add("*")
if sfRegister in s.flags: decl.add(" register")
if sfVolatile in s.flags: decl.add(" volatile")
if sfNoalias in s.flags: decl.add(" NIM_NOALIAS")
else:
if value != "":
decl = runtimeFormat(s.cgDeclFrmt & " = $#;$n", [td, s.loc.r, value])
else:
decl = runtimeFormat(s.cgDeclFrmt & ";$n", [td, s.loc.r])
proc genCppVarForCtor(p: BProc; call: PNode; decl: var Rope; didGenTemp: var bool)
proc assignGlobalVar(p: BProc, n: PNode; value: Rope) =
let s = n.sym
if s.loc.k == locNone:
fillBackendName(p.module, s)
fillLoc(s.loc, locGlobalVar, n, OnHeap)
if treatGlobalDifferentlyForHCR(p.module, s): incl(s.loc.flags, lfIndirect)
if lfDynamicLib in s.loc.flags:
var q = findPendingModule(p.module, s)
if q != nil and not containsOrIncl(q.declaredThings, s.id):
varInDynamicLib(q, s)
else:
s.loc.r = mangleDynLibProc(s)
if value != "":
internalError(p.config, n.info, ".dynlib variables cannot have a value")
return
useHeader(p.module, s)
if lfNoDecl in s.loc.flags: return
if not containsOrIncl(p.module.declaredThings, s.id):
if sfThread in s.flags:
declareThreadVar(p.module, s, sfImportc in s.flags)
if value != "":
internalError(p.config, n.info, ".threadvar variables cannot have a value")
else:
var decl: Rope = ""
let td = getTypeDesc(p.module, s.loc.t, dkVar)
genGlobalVarDecl(p, n, td, value, decl)
if s.constraint.isNil:
if value != "":
if p.module.compileToCpp and value.startsWith "{{}":
# TODO: taking this branch, re"\{\{\}(,\s\{\})*\}" might be emitted, resulting in
# either warnings (GCC 12.2+) or errors (Clang 15, MSVC 19.3+) of C++11+ compilers **when
# explicit constructors are around** due to overload resolution rules in place [^0][^1][^2]
# *Workaround* here: have C++'s static initialization mechanism do the default init work,
# for us lacking a deeper knowledge of an imported object's constructors' ex-/implicitness
# (so far) *and yet* trying to achieve default initialization.
# Still, generating {}s in genConstObjConstr() just to omit them here is faaaar from ideal;
# need to figure out a better way, possibly by keeping around more data about the
# imported objects' contructors?
#
# [^0]: https://en.cppreference.com/w/cpp/language/aggregate_initialization
# [^1]: https://cplusplus.github.io/CWG/issues/1518.html
# [^2]: https://eel.is/c++draft/over.match.ctor
decl.addf(" $1;$n", [s.loc.r])
else:
decl.addf(" $1 = $2;$n", [s.loc.r, value])
else:
decl.addf(" $1;$n", [s.loc.r])
p.module.s[cfsVars].add(decl)
if p.withinLoop > 0 and value == "":
# fixes tests/run/tzeroarray:
resetLoc(p, s.loc)
proc callGlobalVarCppCtor(p: BProc; v: PSym; vn, value: PNode; didGenTemp: var bool) =
let s = vn.sym
fillBackendName(p.module, s)
fillLoc(s.loc, locGlobalVar, vn, OnHeap)
var decl: Rope = ""
let td = getTypeDesc(p.module, vn.sym.typ, dkVar)
genGlobalVarDecl(p, vn, td, "", decl)
decl.add " " & $s.loc.r
genCppVarForCtor(p, value, decl, didGenTemp)
if didGenTemp: return # generated in the caller
p.module.s[cfsVars].add decl
proc assignParam(p: BProc, s: PSym, retType: PType) =
assert(s.loc.r != "")
scopeMangledParam(p, s)
proc fillProcLoc(m: BModule; n: PNode) =
let sym = n.sym
if sym.loc.k == locNone:
fillBackendName(m, sym)
fillLoc(sym.loc, locProc, n, OnStack)
proc getLabel(p: BProc): TLabel =
inc(p.labels)
result = "LA" & rope(p.labels) & "_"
proc fixLabel(p: BProc, labl: TLabel) =
p.s(cpsStmts).add("$1: ;$n" % [labl])
proc genVarPrototype(m: BModule, n: PNode)
proc requestConstImpl(p: BProc, sym: PSym)
proc genStmts(p: BProc, t: PNode)
proc expr(p: BProc, n: PNode, d: var TLoc)
proc putLocIntoDest(p: BProc, d: var TLoc, s: TLoc)
proc intLiteral(i: BiggestInt; result: var Rope)
proc genLiteral(p: BProc, n: PNode; result: var Rope)
proc genOtherArg(p: BProc; ri: PNode; i: int; typ: PType; result: var Rope; argsCounter: var int)
proc raiseExit(p: BProc)
proc raiseExitCleanup(p: BProc, destroy: string)
proc initLocExpr(p: BProc, e: PNode, flags: TLocFlags = {}): TLoc =
result = initLoc(locNone, e, OnUnknown, flags)
expr(p, e, result)
proc initLocExprSingleUse(p: BProc, e: PNode): TLoc =
result = initLoc(locNone, e, OnUnknown)
if e.kind in nkCallKinds and (e[0].kind != nkSym or e[0].sym.magic == mNone):
# We cannot check for tfNoSideEffect here because of mutable parameters.
discard "bug #8202; enforce evaluation order for nested calls for C++ too"
# We may need to consider that 'f(g())' cannot be rewritten to 'tmp = g(); f(tmp)'
# if 'tmp' lacks a move/assignment operator.
if e[0].kind == nkSym and sfCompileToCpp in e[0].sym.flags:
result.flags.incl lfSingleUse
else:
result.flags.incl lfSingleUse
expr(p, e, result)
include ccgcalls, "ccgstmts.nim"
proc initFrame(p: BProc, procname, filename: Rope): Rope =
const frameDefines = """
$1define nimfr_(proc, file) \
TFrame FR_; \
FR_.procname = proc; FR_.filename = file; FR_.line = 0; FR_.len = 0; #nimFrame(&FR_);
$1define nimfrs_(proc, file, slots, length) \
struct {TFrame* prev;NCSTRING procname;NI line;NCSTRING filename;NI len;VarSlot s[slots];} FR_; \
FR_.procname = proc; FR_.filename = file; FR_.line = 0; FR_.len = length; #nimFrame((TFrame*)&FR_);
$1define nimln_(n) \
FR_.line = n;
$1define nimlf_(n, file) \
FR_.line = n; FR_.filename = file;
"""
if p.module.s[cfsFrameDefines].len == 0:
appcg(p.module, p.module.s[cfsFrameDefines], frameDefines, ["#"])
cgsym(p.module, "nimFrame")
result = ropecg(p.module, "\tnimfr_($1, $2);$n", [procname, filename])
proc initFrameNoDebug(p: BProc; frame, procname, filename: Rope; line: int): Rope =
cgsym(p.module, "nimFrame")
p.blocks[0].sections[cpsLocals].addf("TFrame $1;$n", [frame])
result = ropecg(p.module, "\t$1.procname = $2; $1.filename = $3; " &
" $1.line = $4; $1.len = -1; nimFrame(&$1);$n",
[frame, procname, filename, line])
proc deinitFrameNoDebug(p: BProc; frame: Rope): Rope =
result = ropecg(p.module, "\t#popFrameOfAddr(&$1);$n", [frame])
proc deinitFrame(p: BProc): Rope =
result = ropecg(p.module, "\t#popFrame();$n", [])
include ccgexprs
# ----------------------------- dynamic library handling -----------------
# We don't finalize dynamic libs as the OS does this for us.
proc isGetProcAddr(lib: PLib): bool =
let n = lib.path
result = n.kind in nkCallKinds and n.typ != nil and
n.typ.kind in {tyPointer, tyProc}
proc loadDynamicLib(m: BModule, lib: PLib) =
assert(lib != nil)
if not lib.generated:
lib.generated = true
var tmp = getTempName(m)
assert(lib.name == "")
lib.name = tmp # BUGFIX: cgsym has awful side-effects
m.s[cfsVars].addf("static void* $1;$n", [tmp])
if lib.path.kind in {nkStrLit..nkTripleStrLit}:
var s: TStringSeq = @[]
libCandidates(lib.path.strVal, s)
rawMessage(m.config, hintDependency, lib.path.strVal)
var loadlib: Rope = ""
for i in 0..high(s):
inc(m.labels)
if i > 0: loadlib.add("||")
let n = newStrNode(nkStrLit, s[i])
n.info = lib.path.info
appcg(m, loadlib, "($1 = #nimLoadLibrary(", [tmp])
genStringLiteral(m, n, loadlib)
loadlib.addf "))$n", []
appcg(m, m.s[cfsDynLibInit],
"if (!($1)) #nimLoadLibraryError(",
[loadlib])
genStringLiteral(m, lib.path, m.s[cfsDynLibInit])
m.s[cfsDynLibInit].addf ");$n", []
else:
var p = newProc(nil, m)
p.options.excl optStackTrace
p.flags.incl nimErrorFlagDisabled
var dest: TLoc = initLoc(locTemp, lib.path, OnStack)
dest.r = getTempName(m)
appcg(m, m.s[cfsDynLibInit],"$1 $2;$n",
[getTypeDesc(m, lib.path.typ, dkVar), rdLoc(dest)])
expr(p, lib.path, dest)
m.s[cfsVars].add(p.s(cpsLocals))
m.s[cfsDynLibInit].add(p.s(cpsInit))
m.s[cfsDynLibInit].add(p.s(cpsStmts))
appcg(m, m.s[cfsDynLibInit],
"if (!($1 = #nimLoadLibrary($2))) #nimLoadLibraryError($2);$n",
[tmp, rdLoc(dest)])
if lib.name == "": internalError(m.config, "loadDynamicLib")
proc mangleDynLibProc(sym: PSym): Rope =
# we have to build this as a single rope in order not to trip the
# optimization in genInfixCall, see test tests/cpp/t8241.nim
if sfCompilerProc in sym.flags:
# NOTE: sym.loc.r is the external name!
result = rope(sym.name.s)
else:
result = rope(strutils.`%`("Dl_$1_", $sym.id))
proc symInDynamicLib(m: BModule, sym: PSym) =
var lib = sym.annex
let isCall = isGetProcAddr(lib)
var extname = sym.loc.r
if not isCall: loadDynamicLib(m, lib)
var tmp = mangleDynLibProc(sym)
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)
if isCall:
let n = lib.path
var a: TLoc = initLocExpr(m.initProc, n[0])
var params = rdLoc(a) & "("
for i in 1..<n.len-1:
a = initLocExpr(m.initProc, n[i])
params.add(rdLoc(a))
params.add(", ")
let load = "\t$1 = ($2) ($3$4));$n" %
[tmp, getTypeDesc(m, sym.typ, dkVar), params, makeCString($extname)]
var last = lastSon(n)
if last.kind == nkHiddenStdConv: last = last[1]
internalAssert(m.config, last.kind == nkStrLit)
let idx = last.strVal
if idx.len == 0:
m.initProc.s(cpsStmts).add(load)
elif idx.len == 1 and idx[0] in {'0'..'9'}:
m.extensionLoaders[idx[0]].add(load)
else:
internalError(m.config, sym.info, "wrong index: " & idx)
else:
appcg(m, m.s[cfsDynLibInit],
"\t$1 = ($2) #nimGetProcAddr($3, $4);$n",
[tmp, getTypeDesc(m, sym.typ, dkVar), lib.name, makeCString($extname)])
m.s[cfsVars].addf("$2 $1;$n", [sym.loc.r, getTypeDesc(m, sym.loc.t, dkVar)])
proc varInDynamicLib(m: BModule, sym: PSym) =
var lib = sym.annex
var extname = sym.loc.r
loadDynamicLib(m, lib)
incl(sym.loc.flags, lfIndirect)
var tmp = mangleDynLibProc(sym)
sym.loc.r = tmp # from now on we only need the internal name
inc(m.labels, 2)
appcg(m, m.s[cfsDynLibInit],
"$1 = ($2*) #nimGetProcAddr($3, $4);$n",
[tmp, getTypeDesc(m, sym.typ, dkVar), lib.name, makeCString($extname)])
m.s[cfsVars].addf("$2* $1;$n",
[sym.loc.r, getTypeDesc(m, sym.loc.t, dkVar)])
proc symInDynamicLibPartial(m: BModule, sym: PSym) =
sym.loc.r = mangleDynLibProc(sym)
sym.typ.sym = nil # generate a new name
proc cgsymImpl(m: BModule; sym: PSym) {.inline.} =
case sym.kind
of skProc, skFunc, skMethod, skConverter, skIterator: genProc(m, sym)
of skVar, skResult, skLet: genVarPrototype(m, newSymNode sym)
of skType: discard getTypeDesc(m, sym.typ)
else: internalError(m.config, "cgsym: " & $sym.kind)
proc cgsym(m: BModule, name: string) =
let sym = magicsys.getCompilerProc(m.g.graph, name)
if sym != nil:
cgsymImpl m, sym
else:
rawMessage(m.config, errGenerated, "system module needs: " & name)
proc cgsymValue(m: BModule, name: string): Rope =
let sym = magicsys.getCompilerProc(m.g.graph, name)
if sym != nil:
cgsymImpl m, sym
else:
rawMessage(m.config, errGenerated, "system module needs: " & name)
result = sym.loc.r
if m.hcrOn and sym != nil and sym.kind in {skProc..skIterator}:
result.addActualSuffixForHCR(m.module, sym)
proc generateHeaders(m: BModule) =
var nimbase = m.config.nimbasePattern
if nimbase == "": nimbase = "nimbase.h"
m.s[cfsHeaders].addf("\L#include \"$1\"\L", [nimbase])
for it in m.headerFiles:
if it[0] == '#':
m.s[cfsHeaders].add(rope(it.replace('`', '"') & "\L"))
elif it[0] notin {'"', '<'}:
m.s[cfsHeaders].addf("#include \"$1\"$N", [rope(it)])
else:
m.s[cfsHeaders].addf("#include $1$N", [rope(it)])
m.s[cfsHeaders].add("""#undef LANGUAGE_C
#undef MIPSEB
#undef MIPSEL
#undef PPC
#undef R3000
#undef R4000
#undef i386
#undef linux
#undef mips
#undef near
#undef far
#undef powerpc
#undef unix
""")
proc openNamespaceNim(namespace: string; result: var Rope) =
result.add("namespace ")
result.add(namespace)
result.add(" {\L")
proc closeNamespaceNim(result: var Rope) =
result.add("}\L")
proc closureSetup(p: BProc, prc: PSym) =
if tfCapturesEnv notin prc.typ.flags: return
# prc.ast[paramsPos].last contains the type we're after:
var ls = lastSon(prc.ast[paramsPos])
if ls.kind != nkSym:
internalError(p.config, prc.info, "closure generation failed")
var env = ls.sym
#echo "created environment: ", env.id, " for ", prc.name.s
assignLocalVar(p, ls)
# generate cast assignment:
if p.config.selectedGC == gcGo:
linefmt(p, cpsStmts, "#unsureAsgnRef((void**) $1, ($2) ClE_0);$n",
[addrLoc(p.config, env.loc), getTypeDesc(p.module, env.typ)])
else:
linefmt(p, cpsStmts, "$1 = ($2) ClE_0;$n",
[rdLoc(env.loc), getTypeDesc(p.module, env.typ)])
const harmless = {nkConstSection, nkTypeSection, nkEmpty, nkCommentStmt, nkTemplateDef,
nkMacroDef, nkMixinStmt, nkBindStmt, nkFormalParams} +
declarativeDefs
proc containsResult(n: PNode): bool =
result = false
case n.kind
of succ(nkEmpty)..pred(nkSym), succ(nkSym)..nkNilLit, harmless:
discard
of nkReturnStmt:
for i in 0..<n.len:
if containsResult(n[i]): return true
result = n.len > 0 and n[0].kind == nkEmpty
of nkSym:
if n.sym.kind == skResult:
result = true
else:
for i in 0..<n.len:
if containsResult(n[i]): return true
proc easyResultAsgn(n: PNode): PNode =
result = nil
case n.kind
of nkStmtList, nkStmtListExpr:
var i = 0
while i < n.len and n[i].kind in harmless: inc i
if i < n.len: result = easyResultAsgn(n[i])
of nkAsgn, nkFastAsgn, nkSinkAsgn:
if n[0].kind == nkSym and n[0].sym.kind == skResult and not containsResult(n[1]):
incl n.flags, nfPreventCg
return n[1]
of nkReturnStmt:
if n.len > 0:
result = easyResultAsgn(n[0])
if result != nil: incl n.flags, nfPreventCg
else: discard
type
InitResultEnum = enum Unknown, InitSkippable, InitRequired
proc allPathsAsgnResult(p: BProc; n: PNode): InitResultEnum =
# Exceptions coming from calls don't have not be considered here:
#
# proc bar(): string = raise newException(...)
#
# proc foo(): string =
# # optimized out: 'reset(result)'
# result = bar()
#
# try:
# a = foo()
# except:
# echo "a was not written to"
#
template allPathsInBranch(it) =
let a = allPathsAsgnResult(p, it)
case a
of InitRequired: return InitRequired
of InitSkippable: discard
of Unknown:
# sticky, but can be overwritten by InitRequired:
result = Unknown
result = Unknown
case n.kind
of nkStmtList, nkStmtListExpr:
for it in n:
result = allPathsAsgnResult(p, it)
if result != Unknown: return result
of nkAsgn, nkFastAsgn, nkSinkAsgn:
if n[0].kind == nkSym and n[0].sym.kind == skResult:
if not containsResult(n[1]):
if allPathsAsgnResult(p, n[1]) == InitRequired:
result = InitRequired
else:
result = InitSkippable
else: result = InitRequired
elif containsResult(n):
result = InitRequired
else:
result = allPathsAsgnResult(p, n[1])
of nkReturnStmt:
if n.len > 0:
if n[0].kind == nkEmpty and result != InitSkippable:
# This is a bare `return` statement, if `result` was not initialized
# anywhere else (or if we're not sure about this) let's require it to be
# initialized. This avoids cases like #9286 where this heuristic lead to
# wrong code being generated.
result = InitRequired
else: result = allPathsAsgnResult(p, n[0])
of nkIfStmt, nkIfExpr:
var exhaustive = false
result = InitSkippable
for it in n:
# Every condition must not use 'result':
if it.len == 2 and containsResult(it[0]):
return InitRequired
if it.len == 1: exhaustive = true
allPathsInBranch(it.lastSon)
# if the 'if' statement is not exhaustive and yet it touched 'result'
# in some way, say Unknown.
if not exhaustive: result = Unknown
of nkCaseStmt:
if containsResult(n[0]): return InitRequired
result = InitSkippable
var exhaustive = skipTypes(n[0].typ,
abstractVarRange-{tyTypeDesc}).kind notin {tyFloat..tyFloat128, tyString, tyCstring}
for i in 1..<n.len:
let it = n[i]
allPathsInBranch(it.lastSon)
if it.kind == nkElse: exhaustive = true
if not exhaustive: result = Unknown
of nkWhileStmt:
# some dubious code can assign the result in the 'while'
# condition and that would be fine. Everything else isn't:
result = allPathsAsgnResult(p, n[0])
if result == Unknown:
result = allPathsAsgnResult(p, n[1])
# we cannot assume that the 'while' loop is really executed at least once:
if result == InitSkippable: result = Unknown
of harmless:
result = Unknown
of nkGotoState, nkBreakState:
# give up for now.
result = InitRequired
of nkSym:
# some path reads from 'result' before it was written to!
if n.sym.kind == skResult: result = InitRequired
of nkTryStmt, nkHiddenTryStmt:
# We need to watch out for the following problem:
# try:
# result = stuffThatRaises()
# except:
# discard "result was not set"
#
# So ... even if the assignment to 'result' is the very first
# assignment this is not good enough! The only pattern we allow for
# is 'finally: result = x'
result = InitSkippable
allPathsInBranch(n[0])
for i in 1..<n.len:
if n[i].kind == nkFinally:
result = allPathsAsgnResult(p, n[i].lastSon)
else:
allPathsInBranch(n[i].lastSon)
of nkCallKinds:
if canRaiseDisp(p, n[0]):
result = InitRequired
else:
for i in 0..<n.safeLen:
allPathsInBranch(n[i])
of nkRaiseStmt:
result = InitRequired
of nkChckRangeF, nkChckRange64, nkChckRange:
# TODO: more checks might need to be covered like overflow, indexDefect etc.
# bug #22852
result = InitRequired
else:
for i in 0..<n.safeLen:
allPathsInBranch(n[i])
proc getProcTypeCast(m: BModule, prc: PSym): Rope =
result = getTypeDesc(m, prc.loc.t)
if prc.typ.callConv == ccClosure:
var rettype, params: Rope = ""
var check = initIntSet()
genProcParams(m, prc.typ, rettype, params, check)
result = "$1(*)$2" % [rettype, params]
proc genProcBody(p: BProc; procBody: PNode) =
genStmts(p, procBody) # modifies p.locals, p.init, etc.
if {nimErrorFlagAccessed, nimErrorFlagDeclared, nimErrorFlagDisabled} * p.flags == {nimErrorFlagAccessed}:
p.flags.incl nimErrorFlagDeclared
p.blocks[0].sections[cpsLocals].add(ropecg(p.module, "NIM_BOOL* nimErr_;$n", []))
p.blocks[0].sections[cpsInit].add(ropecg(p.module, "nimErr_ = #nimErrorFlag();$n", []))
proc isNoReturn(m: BModule; s: PSym): bool {.inline.} =
sfNoReturn in s.flags and m.config.exc != excGoto
proc genProcAux*(m: BModule, prc: PSym) =
var p = newProc(prc, m)
var header = newRopeAppender()
let isCppMember = m.config.backend == backendCpp and sfCppMember * prc.flags != {}
if isCppMember:
genMemberProcHeader(m, prc, header)
else:
genProcHeader(m, prc, header)
var returnStmt: Rope = ""
assert(prc.ast != nil)
var procBody = transformBody(m.g.graph, m.idgen, prc, {})
if sfInjectDestructors in prc.flags:
procBody = injectDestructorCalls(m.g.graph, m.idgen, prc, procBody)
let tmpInfo = prc.info
discard freshLineInfo(p, prc.info)
if sfPure notin prc.flags and prc.typ.returnType != nil:
if resultPos >= prc.ast.len:
internalError(m.config, prc.info, "proc has no result symbol")
let resNode = prc.ast[resultPos]
let res = resNode.sym # get result symbol
if not isInvalidReturnType(m.config, prc.typ) and sfConstructor notin prc.flags:
if sfNoInit in prc.flags: incl(res.flags, sfNoInit)
if sfNoInit in prc.flags and p.module.compileToCpp and (let val = easyResultAsgn(procBody); val != nil):
var decl = localVarDecl(p, resNode)
var a: TLoc = initLocExprSingleUse(p, val)
linefmt(p, cpsStmts, "$1 = $2;$n", [decl, rdLoc(a)])
else:
# declare the result symbol:
assignLocalVar(p, resNode)
assert(res.loc.r != "")
if p.config.selectedGC in {gcArc, gcAtomicArc, gcOrc} and
allPathsAsgnResult(p, procBody) == InitSkippable:
# In an ideal world the codegen could rely on injectdestructors doing its job properly
# and then the analysis step would not be required.
discard "result init optimized out"
else:
initLocalVar(p, res, immediateAsgn=false)
returnStmt = ropecg(p.module, "\treturn $1;$n", [rdLoc(res.loc)])
elif sfConstructor in prc.flags:
resNode.sym.loc.flags.incl lfIndirect
fillLoc(resNode.sym.loc, locParam, resNode, "this", OnHeap)
prc.loc.r = getTypeDesc(m, resNode.sym.loc.t, dkVar)
else:
fillResult(p.config, resNode, prc.typ)
assignParam(p, res, prc.typ.returnType)
# We simplify 'unsureAsgn(result, nil); unsureAsgn(result, x)'
# to 'unsureAsgn(result, x)'
# Sketch why this is correct: If 'result' points to a stack location
# the 'unsureAsgn' is a nop. If it points to a global variable the
# global is either 'nil' or points to valid memory and so the RC operation
# succeeds without touching not-initialized memory.
if sfNoInit in prc.flags: discard
elif allPathsAsgnResult(p, procBody) == InitSkippable: discard
else:
resetLoc(p, res.loc)
if skipTypes(res.typ, abstractInst).kind == tyArray:
#incl(res.loc.flags, lfIndirect)
res.loc.storage = OnUnknown
for i in 1..<prc.typ.n.len:
let param = prc.typ.n[i].sym
if param.typ.isCompileTimeOnly: continue
assignParam(p, param, prc.typ.returnType)
closureSetup(p, prc)
genProcBody(p, procBody)
prc.info = tmpInfo
var generatedProc: Rope = ""
generatedProc.genCLineDir prc.info, m.config
if isNoReturn(p.module, prc):
if hasDeclspec in extccomp.CC[p.config.cCompiler].props and not isCppMember:
header = "__declspec(noreturn) " & header
if sfPure in prc.flags:
if hasDeclspec in extccomp.CC[p.config.cCompiler].props and not isCppMember:
header = "__declspec(naked) " & header
generatedProc.add ropecg(p.module, "$1 {$n$2$3$4}$N$N",
[header, p.s(cpsLocals), p.s(cpsInit), p.s(cpsStmts)])
else:
if m.hcrOn and isReloadable(m, prc):
# Add forward declaration for "_actual"-suffixed functions defined in the same module (or inline).
# This fixes the use of methods and also the case when 2 functions within the same module
# call each other using directly the "_actual" versions (an optimization) - see issue #11608
m.s[cfsProcHeaders].addf("$1;\n", [header])
generatedProc.add ropecg(p.module, "$1 {$n", [header])
if optStackTrace in prc.options:
generatedProc.add(p.s(cpsLocals))
var procname = makeCString(prc.name.s)
generatedProc.add(initFrame(p, procname, quotedFilename(p.config, prc.info)))
else:
generatedProc.add(p.s(cpsLocals))
if optProfiler in prc.options:
# invoke at proc entry for recursion:
appcg(p, cpsInit, "\t#nimProfile();$n", [])
# this pair of {} is required for C++ (C++ is weird with its
# control flow integrity checks):
if beforeRetNeeded in p.flags: generatedProc.add("{")
generatedProc.add(p.s(cpsInit))
generatedProc.add(p.s(cpsStmts))
if beforeRetNeeded in p.flags: generatedProc.add("\t}BeforeRet_: ;\n")
if optStackTrace in prc.options: generatedProc.add(deinitFrame(p))
generatedProc.add(returnStmt)
generatedProc.add("}\n")
m.s[cfsProcs].add(generatedProc)
if isReloadable(m, prc):
m.s[cfsDynLibInit].addf("\t$1 = ($3) hcrRegisterProc($4, \"$1\", (void*)$2);$n",
[prc.loc.r, prc.loc.r & "_actual", getProcTypeCast(m, prc), getModuleDllPath(m, prc)])
proc requiresExternC(m: BModule; sym: PSym): bool {.inline.} =
result = (sfCompileToCpp in m.module.flags and
sfCompileToCpp notin sym.getModule().flags and
m.config.backend != backendCpp) or (
sym.flags * {sfInfixCall, sfCompilerProc, sfMangleCpp} == {} and
sym.flags * {sfImportc, sfExportc} != {} and
sym.magic == mNone and
m.config.backend == backendCpp)
proc genProcPrototype(m: BModule, sym: PSym) =
useHeader(m, sym)
if lfNoDecl in sym.loc.flags or sfCppMember * sym.flags != {}: return
if lfDynamicLib in sym.loc.flags:
if sym.itemId.module != m.module.position and
not containsOrIncl(m.declaredThings, sym.id):
m.s[cfsVars].add(ropecg(m, "$1 $2 $3;$n",
[(if isReloadable(m, sym): "static" else: "extern"),
getTypeDesc(m, sym.loc.t), mangleDynLibProc(sym)]))
if isReloadable(m, sym):
m.s[cfsDynLibInit].addf("\t$1 = ($2) hcrGetProc($3, \"$1\");$n",
[mangleDynLibProc(sym), getTypeDesc(m, sym.loc.t), getModuleDllPath(m, sym)])
elif not containsOrIncl(m.declaredProtos, sym.id):
let asPtr = isReloadable(m, sym)
var header = newRopeAppender()
genProcHeader(m, sym, header, asPtr)
if not asPtr:
if isNoReturn(m, sym) and hasDeclspec in extccomp.CC[m.config.cCompiler].props:
header = "__declspec(noreturn) " & header
if sym.typ.callConv != ccInline and requiresExternC(m, sym):
header = "extern \"C\" " & header
if sfPure in sym.flags and hasAttribute in CC[m.config.cCompiler].props:
header.add(" __attribute__((naked))")
if isNoReturn(m, sym) and hasAttribute in CC[m.config.cCompiler].props:
header.add(" __attribute__((noreturn))")
m.s[cfsProcHeaders].add(ropecg(m, "$1;$N", [header]))
# TODO: figure out how to rename this - it DOES generate a forward declaration
proc genProcNoForward(m: BModule, prc: PSym) =
if lfImportCompilerProc in prc.loc.flags:
fillProcLoc(m, prc.ast[namePos])
useHeader(m, prc)
# dependency to a compilerproc:
cgsym(m, prc.name.s)
return
if lfNoDecl in prc.loc.flags:
fillProcLoc(m, prc.ast[namePos])
genProcPrototype(m, prc)
elif lfDynamicLib in prc.loc.flags:
var q = findPendingModule(m, prc)
fillProcLoc(q, prc.ast[namePos])
genProcPrototype(m, prc)
if q != nil and not containsOrIncl(q.declaredThings, prc.id):
symInDynamicLib(q, prc)
# register the procedure even though it is in a different dynamic library and will not be
# reloadable (and has no _actual suffix) - other modules will need to be able to get it through
# the hcr dynlib (also put it in the DynLibInit section - right after it gets loaded)
if isReloadable(q, prc):
q.s[cfsDynLibInit].addf("\t$1 = ($2) hcrRegisterProc($3, \"$1\", (void*)$1);$n",
[prc.loc.r, getTypeDesc(q, prc.loc.t), getModuleDllPath(m, q.module)])
else:
symInDynamicLibPartial(m, prc)
elif prc.typ.callConv == ccInline:
# We add inline procs to the calling module to enable C based inlining.
# This also means that a check with ``q.declaredThings`` is wrong, we need
# a check for ``m.declaredThings``.
if not containsOrIncl(m.declaredThings, prc.id):
#if prc.loc.k == locNone:
# mangle the inline proc based on the module where it is defined -
# not on the first module that uses it
let m2 = if m.config.symbolFiles != disabledSf: m
else: findPendingModule(m, prc)
fillProcLoc(m2, prc.ast[namePos])
#elif {sfExportc, sfImportc} * prc.flags == {}:
# # reset name to restore consistency in case of hashing collisions:
# echo "resetting ", prc.id, " by ", m.module.name.s
# prc.loc.r = nil
# prc.loc.r = mangleName(m, prc)
genProcPrototype(m, prc)
genProcAux(m, prc)
elif sfImportc notin prc.flags:
var q = findPendingModule(m, prc)
fillProcLoc(q, prc.ast[namePos])
# generate a getProc call to initialize the pointer for this
# externally-to-the-current-module defined proc, also important
# to do the declaredProtos check before the call to genProcPrototype
if isReloadable(m, prc) and prc.id notin m.declaredProtos and
q != nil and q.module.id != m.module.id:
m.s[cfsDynLibInit].addf("\t$1 = ($2) hcrGetProc($3, \"$1\");$n",
[prc.loc.r, getProcTypeCast(m, prc), getModuleDllPath(m, prc)])
genProcPrototype(m, prc)
if q != nil and not containsOrIncl(q.declaredThings, prc.id):
# make sure there is a "prototype" in the external module
# which will actually become a function pointer
if isReloadable(m, prc):
genProcPrototype(q, prc)
genProcAux(q, prc)
else:
fillProcLoc(m, prc.ast[namePos])
useHeader(m, prc)
if sfInfixCall notin prc.flags: genProcPrototype(m, prc)
proc requestConstImpl(p: BProc, sym: PSym) =
if genConstSetup(p, sym):
let m = p.module
# declare implementation:
var q = findPendingModule(m, sym)
if q != nil and not containsOrIncl(q.declaredThings, sym.id):
assert q.initProc.module == q
genConstDefinition(q, p, sym)
# declare header:
if q != m and not containsOrIncl(m.declaredThings, sym.id):
genConstHeader(m, q, p, sym)
proc isActivated(prc: PSym): bool = prc.typ != nil
proc genProc(m: BModule, prc: PSym) =
if sfBorrow in prc.flags or not isActivated(prc): return
if sfForward in prc.flags:
addForwardedProc(m, prc)
fillProcLoc(m, prc.ast[namePos])
else:
genProcNoForward(m, prc)
if {sfExportc, sfCompilerProc} * prc.flags == {sfExportc} and
m.g.generatedHeader != nil and lfNoDecl notin prc.loc.flags:
genProcPrototype(m.g.generatedHeader, prc)
if prc.typ.callConv == ccInline:
if not containsOrIncl(m.g.generatedHeader.declaredThings, prc.id):
genProcAux(m.g.generatedHeader, prc)
proc genVarPrototype(m: BModule, n: PNode) =
#assert(sfGlobal in sym.flags)
let sym = n.sym
useHeader(m, sym)
fillBackendName(m, sym)
fillLoc(sym.loc, locGlobalVar, n, OnHeap)
if treatGlobalDifferentlyForHCR(m, sym): incl(sym.loc.flags, lfIndirect)
if (lfNoDecl in sym.loc.flags) or contains(m.declaredThings, sym.id):
return
if sym.owner.id != m.module.id:
# else we already have the symbol generated!
assert(sym.loc.r != "")
incl(m.declaredThings, sym.id)
if sfThread in sym.flags:
declareThreadVar(m, sym, true)
else:
if sym.kind in {skLet, skVar, skField, skForVar} and sym.alignment > 0:
m.s[cfsVars].addf "NIM_ALIGN($1) ", [rope(sym.alignment)]
m.s[cfsVars].add(if m.hcrOn: "static " else: "extern ")
m.s[cfsVars].add(getTypeDesc(m, sym.loc.t, dkVar))
if m.hcrOn: m.s[cfsVars].add("*")
if lfDynamicLib in sym.loc.flags: m.s[cfsVars].add("*")
if sfRegister in sym.flags: m.s[cfsVars].add(" register")
if sfVolatile in sym.flags: m.s[cfsVars].add(" volatile")
if sfNoalias in sym.flags: m.s[cfsVars].add(" NIM_NOALIAS")
m.s[cfsVars].addf(" $1;$n", [sym.loc.r])
if m.hcrOn: m.initProc.procSec(cpsLocals).addf(
"\t$1 = ($2*)hcrGetGlobal($3, \"$1\");$n", [sym.loc.r,
getTypeDesc(m, sym.loc.t, dkVar), getModuleDllPath(m, sym)])
proc addNimDefines(result: var Rope; conf: ConfigRef) {.inline.} =
result.addf("#define NIM_INTBITS $1\L", [
platform.CPU[conf.target.targetCPU].intSize.rope])
if conf.cppCustomNamespace.len > 0:
result.add("#define USE_NIM_NAMESPACE ")
result.add(conf.cppCustomNamespace)
result.add("\L")
if conf.isDefined("nimEmulateOverflowChecks"):
result.add("#define NIM_EmulateOverflowChecks\L")
proc headerTop(): Rope =
result = "/* Generated by Nim Compiler v$1 */$N" % [rope(VersionAsString)]
proc getCopyright(conf: ConfigRef; cfile: Cfile): Rope =
result = headerTop()
if optCompileOnly notin conf.globalOptions:
result.add ("/* Compiled for: $1, $2, $3 */$N" &
"/* Command for C compiler:$n $4 */$N") %
[rope(platform.OS[conf.target.targetOS].name),
rope(platform.CPU[conf.target.targetCPU].name),
rope(extccomp.CC[conf.cCompiler].name),
rope(getCompileCFileCmd(conf, cfile))]
proc getFileHeader(conf: ConfigRef; cfile: Cfile): Rope =
result = getCopyright(conf, cfile)
if conf.hcrOn: result.add("#define NIM_HOT_CODE_RELOADING\L")
addNimDefines(result, conf)
proc getSomeNameForModule(conf: ConfigRef, filename: AbsoluteFile): Rope =
## Returns a mangled module name.
result = ""
result.add mangleModuleName(conf, filename).mangle
proc getSomeNameForModule(m: BModule): Rope =
## Returns a mangled module name.
assert m.module.kind == skModule
assert m.module.owner.kind == skPackage
result = ""
result.add mangleModuleName(m.g.config, m.filename).mangle
proc getSomeInitName(m: BModule, suffix: string): Rope =
if not m.hcrOn:
result = getSomeNameForModule(m)
else:
result = ""
result.add suffix
proc getInitName(m: BModule): Rope =
if sfMainModule in m.module.flags:
# generate constant name for main module, for "easy" debugging.
result = rope(m.config.nimMainPrefix) & rope"NimMainModule"
else:
result = getSomeInitName(m, "Init000")
proc getDatInitName(m: BModule): Rope = getSomeInitName(m, "DatInit000")
proc getHcrInitName(m: BModule): Rope = getSomeInitName(m, "HcrInit000")
proc hcrGetProcLoadCode(m: BModule, sym, prefix, handle, getProcFunc: string): Rope
proc genMainProc(m: BModule) =
## this function is called in cgenWriteModules after all modules are closed,
## it means raising dependency on the symbols is too late as it will not propagate
## into other modules, only simple rope manipulations are allowed
var preMainCode: Rope = ""
if m.hcrOn:
proc loadLib(handle: string, name: string): Rope =
result = ""
let prc = magicsys.getCompilerProc(m.g.graph, name)
assert prc != nil
let n = newStrNode(nkStrLit, prc.annex.path.strVal)
n.info = prc.annex.path.info
var strLit = newRopeAppender()
genStringLiteral(m, n, strLit)
appcg(m, result, "\tif (!($1 = #nimLoadLibrary($2)))$N" &
"\t\t#nimLoadLibraryError($2);$N",
[handle, strLit])
preMainCode.add(loadLib("hcr_handle", "hcrGetProc"))
if m.config.selectedGC in {gcArc, gcAtomicArc, gcOrc}:
preMainCode.add("\t$1PreMain();\L" % [rope m.config.nimMainPrefix])
else:
preMainCode.add("\tvoid* rtl_handle;\L")
preMainCode.add(loadLib("rtl_handle", "nimGC_setStackBottom"))
preMainCode.add(hcrGetProcLoadCode(m, "nimGC_setStackBottom", "nimrtl_", "rtl_handle", "nimGetProcAddr"))
preMainCode.add("\tinner = $1PreMain;\L" % [rope m.config.nimMainPrefix])
preMainCode.add("\tinitStackBottomWith_actual((void *)&inner);\L")
preMainCode.add("\t(*inner)();\L")
else:
preMainCode.add("\t$1PreMain();\L" % [rope m.config.nimMainPrefix])
var posixCmdLine: Rope = ""
if optNoMain notin m.config.globalOptions:
posixCmdLine.add "N_LIB_PRIVATE int cmdCount;\L"
posixCmdLine.add "N_LIB_PRIVATE char** cmdLine;\L"
posixCmdLine.add "N_LIB_PRIVATE char** gEnv;\L"
const
# The use of a volatile function pointer to call Pre/NimMainInner
# prevents inlining of the NimMainInner function and dependent
# functions, which might otherwise merge their stack frames.
PreMainBody = "$N" &
"N_LIB_PRIVATE void $3PreMainInner(void) {$N" &
"$2" &
"}$N$N" &
"$4" &
"N_LIB_PRIVATE void $3PreMain(void) {$N" &
"##if $5$N" & # 1 for volatile call, 0 for non-volatile
"\tvoid (*volatile inner)(void);$N" &
"\tinner = $3PreMainInner;$N" &
"$1" &
"\t(*inner)();$N" &
"##else$N" &
"$1" &
"\t$3PreMainInner();$N" &
"##endif$N" &
"}$N$N"
MainProcs =
"\t$^NimMain();$N"
MainProcsWithResult =
MainProcs & ("\treturn $1nim_program_result;$N")
NimMainInner = "N_LIB_PRIVATE N_CDECL(void, $5NimMainInner)(void) {$N" &
"$1" &
"}$N$N"
NimMainProc =
"N_CDECL(void, $5NimMain)(void) {$N" &
"##if $6$N" & # 1 for volatile call, 0 for non-volatile
"\tvoid (*volatile inner)(void);$N" &
"$4" &
"\tinner = $5NimMainInner;$N" &
"$2" &
"\t(*inner)();$N" &
"##else$N" &
"$4" &
"$2" &
"\t$5NimMainInner();$N" &
"##endif$N" &
"}$N$N"
NimMainBody = NimMainInner & NimMainProc
PosixCMain =
"int main(int argc, char** args, char** env) {$N" &
"\tcmdLine = args;$N" &
"\tcmdCount = argc;$N" &
"\tgEnv = env;$N" &
MainProcsWithResult &
"}$N$N"
StandaloneCMain =
"int main(void) {$N" &
MainProcs &
"\treturn 0;$N" &
"}$N$N"
WinNimMain = NimMainBody
WinCMain = "N_STDCALL(int, WinMain)(HINSTANCE hCurInstance, $N" &
" HINSTANCE hPrevInstance, $N" &
" LPSTR lpCmdLine, int nCmdShow) {$N" &
MainProcsWithResult & "}$N$N"
WinNimDllMain = NimMainInner & "N_LIB_EXPORT " & NimMainProc
WinCDllMain =
"BOOL WINAPI DllMain(HINSTANCE hinstDLL, DWORD fwdreason, $N" &
" LPVOID lpvReserved) {$N" &
"\tif (fwdreason == DLL_PROCESS_ATTACH) {$N" & MainProcs & "\t}$N" &
"\treturn 1;$N}$N$N"
PosixNimDllMain = WinNimDllMain
PosixCDllMain =
"N_LIB_PRIVATE void NIM_POSIX_INIT NimMainInit(void) {$N" &
MainProcs &
"}$N$N"
GenodeNimMain =
"extern Genode::Env *nim_runtime_env;$N" &
"extern \"C\" void nim_component_construct(Genode::Env*);$N$N" &
NimMainBody
ComponentConstruct =
"void Libc::Component::construct(Libc::Env &env) {$N" &
"\t// Set Env used during runtime initialization$N" &
"\tnim_runtime_env = &env;$N" &
"\tLibc::with_libc([&] () {$N\t" &
"\t// Initialize runtime and globals$N" &
MainProcs &
"\t// Call application construct$N" &
"\t\tnim_component_construct(&env);$N" &
"\t});$N" &
"}$N$N"
if m.config.target.targetOS == osWindows and
m.config.globalOptions * {optGenGuiApp, optGenDynLib} != {}:
m.includeHeader("<windows.h>")
elif m.config.target.targetOS == osGenode:
m.includeHeader("<libc/component.h>")
let initStackBottomCall =
if m.config.target.targetOS == osStandalone or m.config.selectedGC in {gcNone, gcArc, gcAtomicArc, gcOrc}: "".rope
else: ropecg(m, "\t#initStackBottomWith((void *)&inner);$N", [])
inc(m.labels)
let isVolatile = if m.config.selectedGC notin {gcNone, gcArc, gcAtomicArc, gcOrc}: "1" else: "0"
appcg(m, m.s[cfsProcs], PreMainBody, [m.g.mainDatInit, m.g.otherModsInit, m.config.nimMainPrefix, posixCmdLine, isVolatile])
if m.config.target.targetOS == osWindows and
m.config.globalOptions * {optGenGuiApp, optGenDynLib} != {}:
if optGenGuiApp in m.config.globalOptions:
const nimMain = WinNimMain
appcg(m, m.s[cfsProcs], nimMain,
[m.g.mainModInit, initStackBottomCall, m.labels, preMainCode, m.config.nimMainPrefix, isVolatile])
else:
const nimMain = WinNimDllMain
appcg(m, m.s[cfsProcs], nimMain,
[m.g.mainModInit, initStackBottomCall, m.labels, preMainCode, m.config.nimMainPrefix, isVolatile])
elif m.config.target.targetOS == osGenode:
const nimMain = GenodeNimMain
appcg(m, m.s[cfsProcs], nimMain,
[m.g.mainModInit, initStackBottomCall, m.labels, preMainCode, m.config.nimMainPrefix, isVolatile])
elif optGenDynLib in m.config.globalOptions:
const nimMain = PosixNimDllMain
appcg(m, m.s[cfsProcs], nimMain,
[m.g.mainModInit, initStackBottomCall, m.labels, preMainCode, m.config.nimMainPrefix, isVolatile])
else:
const nimMain = NimMainBody
appcg(m, m.s[cfsProcs], nimMain,
[m.g.mainModInit, initStackBottomCall, m.labels, preMainCode, m.config.nimMainPrefix, isVolatile])
if optNoMain notin m.config.globalOptions:
if m.config.cppCustomNamespace.len > 0:
closeNamespaceNim(m.s[cfsProcs])
m.s[cfsProcs].add "using namespace " & m.config.cppCustomNamespace & ";\L"
if m.config.target.targetOS == osWindows and
m.config.globalOptions * {optGenGuiApp, optGenDynLib} != {}:
if optGenGuiApp in m.config.globalOptions:
const otherMain = WinCMain
appcg(m, m.s[cfsProcs], otherMain, [if m.hcrOn: "*" else: "", m.config.nimMainPrefix])
else:
const otherMain = WinCDllMain
appcg(m, m.s[cfsProcs], otherMain, [m.config.nimMainPrefix])
elif m.config.target.targetOS == osGenode:
const otherMain = ComponentConstruct
appcg(m, m.s[cfsProcs], otherMain, [m.config.nimMainPrefix])
elif optGenDynLib in m.config.globalOptions:
const otherMain = PosixCDllMain
appcg(m, m.s[cfsProcs], otherMain, [m.config.nimMainPrefix])
elif m.config.target.targetOS == osStandalone:
const otherMain = StandaloneCMain
appcg(m, m.s[cfsProcs], otherMain, [m.config.nimMainPrefix])
else:
const otherMain = PosixCMain
appcg(m, m.s[cfsProcs], otherMain, [if m.hcrOn: "*" else: "", m.config.nimMainPrefix])
if m.config.cppCustomNamespace.len > 0:
openNamespaceNim(m.config.cppCustomNamespace, m.s[cfsProcs])
proc registerInitProcs*(g: BModuleList; m: PSym; flags: set[ModuleBackendFlag]) =
## Called from the IC backend.
if HasDatInitProc in flags:
let datInit = getSomeNameForModule(g.config, g.config.toFullPath(m.info.fileIndex).AbsoluteFile) & "DatInit000"
g.mainModProcs.addf("N_LIB_PRIVATE N_NIMCALL(void, $1)(void);$N", [datInit])
g.mainDatInit.addf("\t$1();$N", [datInit])
if HasModuleInitProc in flags:
let init = getSomeNameForModule(g.config, g.config.toFullPath(m.info.fileIndex).AbsoluteFile) & "Init000"
g.mainModProcs.addf("N_LIB_PRIVATE N_NIMCALL(void, $1)(void);$N", [init])
let initCall = "\t$1();$N" % [init]
if sfMainModule in m.flags:
g.mainModInit.add(initCall)
elif sfSystemModule in m.flags:
g.mainDatInit.add(initCall) # systemInit must called right after systemDatInit if any
else:
g.otherModsInit.add(initCall)
proc whichInitProcs*(m: BModule): set[ModuleBackendFlag] =
# called from IC.
result = {}
if m.hcrOn or m.preInitProc.s(cpsInit).len > 0 or m.preInitProc.s(cpsStmts).len > 0:
result.incl HasModuleInitProc
for i in cfsTypeInit1..cfsDynLibInit:
if m.s[i].len != 0:
result.incl HasDatInitProc
break
proc registerModuleToMain(g: BModuleList; m: BModule) =
let
init = m.getInitName
datInit = m.getDatInitName
if m.hcrOn:
var hcrModuleMeta = "$nN_LIB_PRIVATE const char* hcr_module_list[] = {$n" % []
let systemModulePath = getModuleDllPath(m, g.modules[g.graph.config.m.systemFileIdx.int].module)
let mainModulePath = getModuleDllPath(m, m.module)
if sfMainModule in m.module.flags:
hcrModuleMeta.addf("\t$1,$n", [systemModulePath])
g.graph.importDeps.withValue(FileIndex(m.module.position), deps):
for curr in deps[]:
hcrModuleMeta.addf("\t$1,$n", [getModuleDllPath(m, g.modules[curr.int].module)])
hcrModuleMeta.addf("\t\"\"};$n", [])
hcrModuleMeta.addf("$nN_LIB_EXPORT N_NIMCALL(void**, HcrGetImportedModules)() { return (void**)hcr_module_list; }$n", [])
hcrModuleMeta.addf("$nN_LIB_EXPORT N_NIMCALL(char*, HcrGetSigHash)() { return \"$1\"; }$n$n",
[($sigHash(m.module, m.config)).rope])
if sfMainModule in m.module.flags:
g.mainModProcs.add(hcrModuleMeta)
g.mainModProcs.addf("static void* hcr_handle;$N", [])
g.mainModProcs.addf("N_LIB_EXPORT N_NIMCALL(void, $1)(void);$N", [init])
g.mainModProcs.addf("N_LIB_EXPORT N_NIMCALL(void, $1)(void);$N", [datInit])
g.mainModProcs.addf("N_LIB_EXPORT N_NIMCALL(void, $1)(void*, N_NIMCALL_PTR(void*, getProcAddr)(void*, char*));$N", [m.getHcrInitName])
g.mainModProcs.addf("N_LIB_EXPORT N_NIMCALL(void, HcrCreateTypeInfos)(void);$N", [])
g.mainModInit.addf("\t$1();$N", [init])
g.otherModsInit.addf("\thcrInit((void**)hcr_module_list, $1, $2, $3, hcr_handle, nimGetProcAddr);$n",
[mainModulePath, systemModulePath, datInit])
g.mainDatInit.addf("\t$1(hcr_handle, nimGetProcAddr);$N", [m.getHcrInitName])
g.mainDatInit.addf("\thcrAddModule($1);\n", [mainModulePath])
g.mainDatInit.addf("\tHcrCreateTypeInfos();$N", [])
# nasty nasty hack to get the command line functionality working with HCR
# register the 2 variables on behalf of the os module which might not even
# be loaded (in which case it will get collected but that is not a problem)
# EDIT: indeed, this hack, in combination with another un-necessary one
# (`makeCString` was doing line wrap of string litterals) was root cause for
# bug #16265.
let osModulePath = ($systemModulePath).replace("stdlib_system", "stdlib_os").rope
g.mainDatInit.addf("\thcrAddModule($1);\n", [osModulePath])
g.mainDatInit.add("\tint* cmd_count;\n")
g.mainDatInit.add("\tchar*** cmd_line;\n")
g.mainDatInit.addf("\thcrRegisterGlobal($1, \"cmdCount\", sizeof(cmd_count), NULL, (void**)&cmd_count);$N", [osModulePath])
g.mainDatInit.addf("\thcrRegisterGlobal($1, \"cmdLine\", sizeof(cmd_line), NULL, (void**)&cmd_line);$N", [osModulePath])
g.mainDatInit.add("\t*cmd_count = cmdCount;\n")
g.mainDatInit.add("\t*cmd_line = cmdLine;\n")
else:
m.s[cfsInitProc].add(hcrModuleMeta)
return
if m.s[cfsDatInitProc].len > 0:
g.mainModProcs.addf("N_LIB_PRIVATE N_NIMCALL(void, $1)(void);$N", [datInit])
g.mainDatInit.addf("\t$1();$N", [datInit])
# Initialization of TLS and GC should be done in between
# systemDatInit and systemInit calls if any
if sfSystemModule in m.module.flags:
if emulatedThreadVars(m.config) and m.config.target.targetOS != osStandalone:
g.mainDatInit.add(ropecg(m, "\t#initThreadVarsEmulation();$N", []))
if m.config.target.targetOS != osStandalone and m.config.selectedGC notin {gcNone, gcArc, gcAtomicArc, gcOrc}:
g.mainDatInit.add(ropecg(m, "\t#initStackBottomWith((void *)&inner);$N", []))
if m.s[cfsInitProc].len > 0:
g.mainModProcs.addf("N_LIB_PRIVATE N_NIMCALL(void, $1)(void);$N", [init])
let initCall = "\t$1();$N" % [init]
if sfMainModule in m.module.flags:
g.mainModInit.add(initCall)
elif sfSystemModule in m.module.flags:
g.mainDatInit.add(initCall) # systemInit must called right after systemDatInit if any
else:
g.otherModsInit.add(initCall)
proc genDatInitCode(m: BModule) =
## this function is called in cgenWriteModules after all modules are closed,
## it means raising dependency on the symbols is too late as it will not propagate
## into other modules, only simple rope manipulations are allowed
var moduleDatInitRequired = m.hcrOn
var prc = "$1 N_NIMCALL(void, $2)(void) {$N" %
[rope(if m.hcrOn: "N_LIB_EXPORT" else: "N_LIB_PRIVATE"), getDatInitName(m)]
# we don't want to break into such init code - could happen if a line
# directive from a function written by the user spills after itself
genCLineDir(prc, InvalidFileIdx, 999999, m.config)
for i in cfsTypeInit1..cfsDynLibInit:
if m.s[i].len != 0:
moduleDatInitRequired = true
prc.add(m.s[i])
prc.addf("}$N$N", [])
if moduleDatInitRequired:
m.s[cfsDatInitProc].add(prc)
#rememberFlag(m.g.graph, m.module, HasDatInitProc)
# Very similar to the contents of symInDynamicLib - basically only the
# things needed for the hot code reloading runtime procs to be loaded
proc hcrGetProcLoadCode(m: BModule, sym, prefix, handle, getProcFunc: string): Rope =
let prc = magicsys.getCompilerProc(m.g.graph, sym)
assert prc != nil
fillProcLoc(m, prc.ast[namePos])
var extname = prefix & sym
var tmp = mangleDynLibProc(prc)
prc.loc.r = tmp
prc.typ.sym = nil
if not containsOrIncl(m.declaredThings, prc.id):
m.s[cfsVars].addf("static $2 $1;$n", [prc.loc.r, getTypeDesc(m, prc.loc.t, dkVar)])
result = "\t$1 = ($2) $3($4, $5);$n" %
[tmp, getTypeDesc(m, prc.typ, dkVar), getProcFunc.rope, handle.rope, makeCString(prefix & sym)]
proc genInitCode(m: BModule) =
## this function is called in cgenWriteModules after all modules are closed,
## it means raising dependency on the symbols is too late as it will not propagate
## into other modules, only simple rope manipulations are allowed
var moduleInitRequired = m.hcrOn
let initname = getInitName(m)
var prc = "$1 N_NIMCALL(void, $2)(void) {$N" %
[rope(if m.hcrOn: "N_LIB_EXPORT" else: "N_LIB_PRIVATE"), initname]
# we don't want to break into such init code - could happen if a line
# directive from a function written by the user spills after itself
genCLineDir(prc, InvalidFileIdx, 999999, m.config)
if m.typeNodes > 0:
if m.hcrOn:
appcg(m, m.s[cfsTypeInit1], "\t#TNimNode* $1;$N", [m.typeNodesName])
appcg(m, m.s[cfsTypeInit1], "\thcrRegisterGlobal($3, \"$1_$2\", sizeof(TNimNode) * $2, NULL, (void**)&$1);$N",
[m.typeNodesName, m.typeNodes, getModuleDllPath(m, m.module)])
else:
appcg(m, m.s[cfsTypeInit1], "static #TNimNode $1[$2];$n",
[m.typeNodesName, m.typeNodes])
if m.nimTypes > 0:
appcg(m, m.s[cfsTypeInit1], "static #TNimType $1[$2];$n",
[m.nimTypesName, m.nimTypes])
if m.hcrOn:
prc.addf("\tint* nim_hcr_dummy_ = 0;$n" &
"\tNIM_BOOL nim_hcr_do_init_ = " &
"hcrRegisterGlobal($1, \"module_initialized_\", 1, NULL, (void**)&nim_hcr_dummy_);$n",
[getModuleDllPath(m, m.module)])
template writeSection(thing: untyped, section: TCProcSection, addHcrGuards = false) =
if m.thing.s(section).len > 0:
moduleInitRequired = true
if addHcrGuards: prc.add("\tif (nim_hcr_do_init_) {\n\n")
prc.add(m.thing.s(section))
if addHcrGuards: prc.add("\n\t} // nim_hcr_do_init_\n")
if m.preInitProc.s(cpsInit).len > 0 or m.preInitProc.s(cpsStmts).len > 0:
# Give this small function its own scope
prc.addf("{$N", [])
# Keep a bogus frame in case the code needs one
prc.add("\tTFrame FR_; FR_.len = 0;\n")
writeSection(preInitProc, cpsLocals)
writeSection(preInitProc, cpsInit, m.hcrOn)
writeSection(preInitProc, cpsStmts)
prc.addf("}/* preInitProc end */$N", [])
when false:
m.initProc.blocks[0].sections[cpsLocals].add m.preInitProc.s(cpsLocals)
m.initProc.blocks[0].sections[cpsInit].prepend m.preInitProc.s(cpsInit)
m.initProc.blocks[0].sections[cpsStmts].prepend m.preInitProc.s(cpsStmts)
# add new scope for following code, because old vcc compiler need variable
# be defined at the top of the block
prc.addf("{$N", [])
writeSection(initProc, cpsLocals)
if m.initProc.s(cpsInit).len > 0 or m.initProc.s(cpsStmts).len > 0:
moduleInitRequired = true
if optStackTrace in m.initProc.options and frameDeclared notin m.flags:
# BUT: the generated init code might depend on a current frame, so
# declare it nevertheless:
incl m.flags, frameDeclared
if preventStackTrace notin m.flags:
var procname = makeCString(m.module.name.s)
prc.add(initFrame(m.initProc, procname, quotedFilename(m.config, m.module.info)))
else:
prc.add("\tTFrame FR_; FR_.len = 0;\n")
writeSection(initProc, cpsInit, m.hcrOn)
writeSection(initProc, cpsStmts)
if beforeRetNeeded in m.initProc.flags:
prc.add("\tBeforeRet_: ;\n")
if m.config.exc == excGoto:
if getCompilerProc(m.g.graph, "nimTestErrorFlag") != nil:
m.appcg(prc, "\t#nimTestErrorFlag();$n", [])
if optStackTrace in m.initProc.options and preventStackTrace notin m.flags:
prc.add(deinitFrame(m.initProc))
elif m.config.exc == excGoto:
if getCompilerProc(m.g.graph, "nimTestErrorFlag") != nil:
m.appcg(prc, "\t#nimTestErrorFlag();$n", [])
prc.addf("}$N", [])
prc.addf("}$N$N", [])
# we cannot simply add the init proc to ``m.s[cfsProcs]`` anymore because
# that would lead to a *nesting* of merge sections which the merger does
# not support. So we add it to another special section: ``cfsInitProc``
if m.hcrOn:
var procsToLoad = @["hcrRegisterProc", "hcrGetProc", "hcrRegisterGlobal", "hcrGetGlobal"]
m.s[cfsInitProc].addf("N_LIB_EXPORT N_NIMCALL(void, $1)(void* handle, N_NIMCALL_PTR(void*, getProcAddr)(void*, char*)) {$N", [getHcrInitName(m)])
if sfMainModule in m.module.flags:
# additional procs to load
procsToLoad.add("hcrInit")
procsToLoad.add("hcrAddModule")
# load procs
for curr in procsToLoad:
m.s[cfsInitProc].add(hcrGetProcLoadCode(m, curr, "", "handle", "getProcAddr"))
m.s[cfsInitProc].addf("}$N$N", [])
for i, el in pairs(m.extensionLoaders):
if el != "":
let ex = "NIM_EXTERNC N_NIMCALL(void, nimLoadProcs$1)(void) {$2}$N$N" %
[(i.ord - '0'.ord).rope, el]
moduleInitRequired = true
prc.add(ex)
if moduleInitRequired or sfMainModule in m.module.flags:
m.s[cfsInitProc].add(prc)
#rememberFlag(m.g.graph, m.module, HasModuleInitProc)
genDatInitCode(m)
if m.hcrOn:
m.s[cfsInitProc].addf("N_LIB_EXPORT N_NIMCALL(void, HcrCreateTypeInfos)(void) {$N", [])
m.s[cfsInitProc].add(m.hcrCreateTypeInfosProc)
m.s[cfsInitProc].addf("}$N$N", [])
registerModuleToMain(m.g, m)
proc postprocessCode(conf: ConfigRef, r: var Rope) =
# find the first directive
var f = r.find(postprocessDirStart)
if f == -1:
return
var
nimlnDirLastF = ""
var res: Rope = r.substr(0, f - 1)
while f != -1:
var
e = r.find(postprocessDirEnd, f + 1)
dir = r.substr(f + 1, e - 1).split(postprocessDirSep)
case dir[0]
of "nimln":
if dir[2] == nimlnDirLastF:
res.add("nimln_(" & dir[1] & ");")
else:
res.add("nimlf_(" & dir[1] & ", " & quotedFilename(conf, dir[2].parseInt.FileIndex) & ");")
nimlnDirLastF = dir[2]
else:
raiseAssert "unexpected postprocess directive"
# find the next directive
f = r.find(postprocessDirStart, e + 1)
# copy the code until the next directive
if f != -1:
res.add(r.substr(e + 1, f - 1))
else:
res.add(r.substr(e + 1))
r = res
proc genModule(m: BModule, cfile: Cfile): Rope =
var moduleIsEmpty = true
result = getFileHeader(m.config, cfile)
generateThreadLocalStorage(m)
generateHeaders(m)
result.add(m.s[cfsHeaders])
if m.config.cppCustomNamespace.len > 0:
openNamespaceNim(m.config.cppCustomNamespace, result)
if m.s[cfsFrameDefines].len > 0:
result.add(m.s[cfsFrameDefines])
for i in cfsForwardTypes..cfsProcs:
if m.s[i].len > 0:
moduleIsEmpty = false
result.add(m.s[i])
if m.s[cfsInitProc].len > 0:
moduleIsEmpty = false
result.add(m.s[cfsInitProc])
if m.s[cfsDatInitProc].len > 0 or m.hcrOn:
moduleIsEmpty = false
result.add(m.s[cfsDatInitProc])
if m.config.cppCustomNamespace.len > 0:
closeNamespaceNim(result)
if optLineDir in m.config.options:
var srcFileDefs = ""
for fi in 0..m.config.m.fileInfos.high:
srcFileDefs.add("#define FX_" & $fi & " " & makeSingleLineCString(toFullPath(m.config, fi.FileIndex)) & "\n")
result = srcFileDefs & result
if moduleIsEmpty:
result = ""
postprocessCode(m.config, result)
proc initProcOptions(m: BModule): TOptions =
let opts = m.config.options
if sfSystemModule in m.module.flags: opts-{optStackTrace} else: opts
proc rawNewModule(g: BModuleList; module: PSym, filename: AbsoluteFile): BModule =
new(result)
result.g = g
result.tmpBase = rope("TM" & $hashOwner(module) & "_")
result.headerFiles = @[]
result.declaredThings = initIntSet()
result.declaredProtos = initIntSet()
result.cfilename = filename
result.filename = filename
result.typeCache = initTable[SigHash, Rope]()
result.forwTypeCache = initTable[SigHash, Rope]()
result.module = module
result.typeInfoMarker = initTable[SigHash, Rope]()
result.sigConflicts = initCountTable[SigHash]()
result.initProc = newProc(nil, result)
for i in low(result.s)..high(result.s): result.s[i] = newRopeAppender()
result.initProc.options = initProcOptions(result)
result.preInitProc = newProc(nil, result)
result.preInitProc.flags.incl nimErrorFlagDisabled
result.preInitProc.labels = 100_000 # little hack so that unique temporaries are generated
result.dataCache = initNodeTable()
result.typeStack = @[]
result.typeNodesName = getTempName(result)
result.nimTypesName = getTempName(result)
# no line tracing for the init sections of the system module so that we
# don't generate a TFrame which can confuse the stack bottom initialization:
if sfSystemModule in module.flags:
incl result.flags, preventStackTrace
excl(result.preInitProc.options, optStackTrace)
let ndiName = if optCDebug in g.config.globalOptions: changeFileExt(completeCfilePath(g.config, filename), "ndi")
else: AbsoluteFile""
open(result.ndi, ndiName, g.config)
proc rawNewModule(g: BModuleList; module: PSym; conf: ConfigRef): BModule =
result = rawNewModule(g, module, AbsoluteFile toFullPath(conf, module.position.FileIndex))
proc newModule*(g: BModuleList; module: PSym; conf: ConfigRef): BModule =
# we should create only one cgen module for each module sym
result = rawNewModule(g, module, conf)
if module.position >= g.modules.len:
setLen(g.modules, module.position + 1)
#growCache g.modules, module.position
g.modules[module.position] = result
template injectG() {.dirty.} =
if graph.backend == nil:
graph.backend = newModuleList(graph)
let g = BModuleList(graph.backend)
proc setupCgen*(graph: ModuleGraph; module: PSym; idgen: IdGenerator): PPassContext =
injectG()
result = newModule(g, module, graph.config)
result.idgen = idgen
if optGenIndex in graph.config.globalOptions and g.generatedHeader == nil:
let f = if graph.config.headerFile.len > 0: AbsoluteFile graph.config.headerFile
else: graph.config.projectFull
g.generatedHeader = rawNewModule(g, module,
changeFileExt(completeCfilePath(graph.config, f), hExt))
incl g.generatedHeader.flags, isHeaderFile
proc writeHeader(m: BModule) =
var result = headerTop()
var guard = "__$1__" % [m.filename.splitFile.name.rope]
result.addf("#ifndef $1$n#define $1$n", [guard])
addNimDefines(result, m.config)
generateHeaders(m)
generateThreadLocalStorage(m)
for i in cfsHeaders..cfsProcs:
result.add(m.s[i])
if m.config.cppCustomNamespace.len > 0 and i == cfsHeaders:
openNamespaceNim(m.config.cppCustomNamespace, result)
result.add(m.s[cfsInitProc])
if optGenDynLib in m.config.globalOptions:
result.add("N_LIB_IMPORT ")
result.addf("N_CDECL(void, $1NimMain)(void);$n", [rope m.config.nimMainPrefix])
if m.config.cppCustomNamespace.len > 0: closeNamespaceNim(result)
result.addf("#endif /* $1 */$n", [guard])
if not writeRope(result, m.filename):
rawMessage(m.config, errCannotOpenFile, m.filename.string)
proc getCFile(m: BModule): AbsoluteFile =
let ext =
if m.compileToCpp: ".nim.cpp"
elif m.config.backend == backendObjc or sfCompileToObjc in m.module.flags: ".nim.m"
else: ".nim.c"
result = changeFileExt(completeCfilePath(m.config, mangleModuleName(m.config, m.cfilename).AbsoluteFile), ext)
when false:
proc myOpenCached(graph: ModuleGraph; module: PSym, rd: PRodReader): PPassContext =
injectG()
var m = newModule(g, module, graph.config)
readMergeInfo(getCFile(m), m)
result = m
proc addHcrInitGuards(p: BProc, n: PNode, inInitGuard: var bool) =
if n.kind == nkStmtList:
for child in n:
addHcrInitGuards(p, child, inInitGuard)
else:
let stmtShouldExecute = n.kind in {nkVarSection, nkLetSection} or
nfExecuteOnReload in n.flags
if inInitGuard:
if stmtShouldExecute:
endBlock(p)
inInitGuard = false
else:
if not stmtShouldExecute:
line(p, cpsStmts, "if (nim_hcr_do_init_)\n")
startBlock(p)
inInitGuard = true
genStmts(p, n)
proc genTopLevelStmt*(m: BModule; n: PNode) =
## Also called from `ic/cbackend.nim`.
if pipelineutils.skipCodegen(m.config, n): return
m.initProc.options = initProcOptions(m)
#softRnl = if optLineDir in m.config.options: noRnl else: rnl
# XXX replicate this logic!
var transformedN = transformStmt(m.g.graph, m.idgen, m.module, n)
if sfInjectDestructors in m.module.flags:
transformedN = injectDestructorCalls(m.g.graph, m.idgen, m.module, transformedN)
if m.hcrOn:
addHcrInitGuards(m.initProc, transformedN, m.inHcrInitGuard)
else:
genProcBody(m.initProc, transformedN)
proc shouldRecompile(m: BModule; code: Rope, cfile: Cfile): bool =
if optForceFullMake notin m.config.globalOptions:
if not moduleHasChanged(m.g.graph, m.module):
result = false
elif not equalsFile(code, cfile.cname):
when false:
#m.config.symbolFiles == readOnlySf: #isDefined(m.config, "nimdiff"):
if fileExists(cfile.cname):
copyFile(cfile.cname.string, cfile.cname.string & ".backup")
echo "diff ", cfile.cname.string, ".backup ", cfile.cname.string
else:
echo "new file ", cfile.cname.string
if not writeRope(code, cfile.cname):
rawMessage(m.config, errCannotOpenFile, cfile.cname.string)
result = true
elif fileExists(cfile.obj) and os.fileNewer(cfile.obj.string, cfile.cname.string):
result = false
else:
result = true
else:
if not writeRope(code, cfile.cname):
rawMessage(m.config, errCannotOpenFile, cfile.cname.string)
result = true
# We need 2 different logics here: pending modules (including
# 'nim__dat') may require file merging for the combination of dead code
# elimination and incremental compilation! Non pending modules need no
# such logic and in fact the logic hurts for the main module at least;
# it would generate multiple 'main' procs, for instance.
proc writeModule(m: BModule, pending: bool) =
template onExit() = close(m.ndi, m.config)
let cfile = getCFile(m)
if moduleHasChanged(m.g.graph, m.module):
genInitCode(m)
finishTypeDescriptions(m)
if sfMainModule in m.module.flags:
# generate main file:
genMainProc(m)
m.s[cfsProcHeaders].add(m.g.mainModProcs)
generateThreadVarsSize(m)
var cf = Cfile(nimname: m.module.name.s, cname: cfile,
obj: completeCfilePath(m.config, toObjFile(m.config, cfile)), flags: {})
var code = genModule(m, cf)
if code != "" or m.config.symbolFiles != disabledSf:
when hasTinyCBackend:
if m.config.cmd == cmdTcc:
tccgen.compileCCode($code, m.config)
onExit()
return
if not shouldRecompile(m, code, cf): cf.flags = {CfileFlag.Cached}
addFileToCompile(m.config, cf)
onExit()
proc updateCachedModule(m: BModule) =
let cfile = getCFile(m)
var cf = Cfile(nimname: m.module.name.s, cname: cfile,
obj: completeCfilePath(m.config, toObjFile(m.config, cfile)), flags: {})
if sfMainModule notin m.module.flags:
genMainProc(m)
cf.flags = {CfileFlag.Cached}
addFileToCompile(m.config, cf)
proc generateLibraryDestroyGlobals(graph: ModuleGraph; m: BModule; body: PNode; isDynlib: bool): PSym =
let procname = getIdent(graph.cache, "NimDestroyGlobals")
result = newSym(skProc, procname, m.idgen, m.module.owner, m.module.info)
result.typ = newProcType(m.module.info, m.idgen, m.module.owner)
result.typ.callConv = ccCDecl
incl result.flags, sfExportc
result.loc.r = "NimDestroyGlobals"
if isDynlib:
incl(result.loc.flags, lfExportLib)
let theProc = newNodeI(nkProcDef, m.module.info, bodyPos+1)
for i in 0..<theProc.len: theProc[i] = newNodeI(nkEmpty, m.module.info)
theProc[namePos] = newSymNode(result)
theProc[bodyPos] = body
result.ast = theProc
proc finalCodegenActions*(graph: ModuleGraph; m: BModule; n: PNode) =
## Also called from IC.
if sfMainModule in m.module.flags:
# phase ordering problem here: We need to announce this
# dependency to 'nimTestErrorFlag' before system.c has been written to disk.
if m.config.exc == excGoto and getCompilerProc(graph, "nimTestErrorFlag") != nil:
cgsym(m, "nimTestErrorFlag")
if {optGenStaticLib, optGenDynLib, optNoMain} * m.config.globalOptions == {}:
for i in countdown(high(graph.globalDestructors), 0):
n.add graph.globalDestructors[i]
else:
var body = newNodeI(nkStmtList, m.module.info)
for i in countdown(high(graph.globalDestructors), 0):
body.add graph.globalDestructors[i]
body.flags.incl nfTransf # should not be further transformed
let dtor = generateLibraryDestroyGlobals(graph, m, body, optGenDynLib in m.config.globalOptions)
genProcAux(m, dtor)
if pipelineutils.skipCodegen(m.config, n): return
if moduleHasChanged(graph, m.module):
# if the module is cached, we don't regenerate the main proc
# nor the dispatchers? But if the dispatchers changed?
# XXX emit the dispatchers into its own .c file?
if n != nil:
m.initProc.options = initProcOptions(m)
genProcBody(m.initProc, n)
if m.hcrOn:
# make sure this is pulled in (meaning hcrGetGlobal() is called for it during init)
let sym = magicsys.getCompilerProc(m.g.graph, "programResult")
# ignore when not available, could be a module imported early in `system`
if sym != nil:
cgsymImpl m, sym
if m.inHcrInitGuard:
endBlock(m.initProc)
if sfMainModule in m.module.flags:
if m.hcrOn:
# pull ("define" since they are inline when HCR is on) these functions in the main file
# so it can load the HCR runtime and later pass the library handle to the HCR runtime which
# will in turn pass it to the other modules it initializes so they can initialize the
# register/get procs so they don't have to have the definitions of these functions as well
cgsym(m, "nimLoadLibrary")
cgsym(m, "nimLoadLibraryError")
cgsym(m, "nimGetProcAddr")
cgsym(m, "procAddrError")
cgsym(m, "rawWrite")
# raise dependencies on behalf of genMainProc
if m.config.target.targetOS != osStandalone and m.config.selectedGC notin {gcNone, gcArc, gcAtomicArc, gcOrc}:
cgsym(m, "initStackBottomWith")
if emulatedThreadVars(m.config) and m.config.target.targetOS != osStandalone:
cgsym(m, "initThreadVarsEmulation")
if m.g.forwardedProcs.len == 0:
incl m.flags, objHasKidsValid
if optMultiMethods in m.g.config.globalOptions or
m.g.config.selectedGC notin {gcArc, gcOrc, gcAtomicArc} or
vtables notin m.g.config.features:
generateIfMethodDispatchers(graph, m.idgen)
let mm = m
m.g.modulesClosed.add mm
proc genForwardedProcs(g: BModuleList) =
# Forward declared proc:s lack bodies when first encountered, so they're given
# a second pass here
# Note: ``genProcNoForward`` may add to ``forwardedProcs``
while g.forwardedProcs.len > 0:
let
prc = g.forwardedProcs.pop()
m = g.modules[prc.itemId.module]
if sfForward in prc.flags:
internalError(m.config, prc.info, "still forwarded: " & prc.name.s)
genProcNoForward(m, prc)
proc cgenWriteModules*(backend: RootRef, config: ConfigRef) =
let g = BModuleList(backend)
g.config = config
# we need to process the transitive closure because recursive module
# deps are allowed (and the system module is processed in the wrong
# order anyway)
genForwardedProcs(g)
for m in cgenModules(g):
m.writeModule(pending=true)
writeMapping(config, g.mapping)
if g.generatedHeader != nil: writeHeader(g.generatedHeader)
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