#
#
# 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 semantic checking for pragmas
import
os, condsyms, ast, astalgo, idents, semdata, msgs, renderer,
wordrecg, ropes, options, strutils, extccomp, math, magicsys, trees,
types, lookups, lineinfos, pathutils, linter
when defined(nimPreviewSlimSystem):
import std/assertions
from ic / ic import addCompilerProc
const
FirstCallConv* = wNimcall
LastCallConv* = wNoconv
const
declPragmas = {wImportc, wImportObjC, wImportCpp, wImportJs, wExportc, wExportCpp,
wExportNims, wExtern, wDeprecated, wNodecl, wError, wUsed}
## common pragmas for declarations, to a good approximation
procPragmas* = declPragmas + {FirstCallConv..LastCallConv,
wMagic, wNoSideEffect, wSideEffect, wNoreturn, wNosinks, wDynlib, wHeader,
wCompilerProc, wNonReloadable, wCore, wProcVar, wVarargs, wCompileTime, wMerge,
wBorrow, wImportCompilerProc, wThread,
wAsmNoStackFrame, wDiscardable, wNoInit, wCodegenDecl,
wGensym, wInject, wRaises, wEffectsOf, wTags, wLocks, wDelegator, wGcSafe,
wConstructor, wLiftLocals, wStackTrace, wLineTrace, wNoDestroy,
wRequires, wEnsures, wEnforceNoRaises}
converterPragmas* = procPragmas
methodPragmas* = procPragmas+{wBase}-{wImportCpp}
templatePragmas* = {wDeprecated, wError, wGensym, wInject, wDirty,
wDelegator, wExportNims, wUsed, wPragma}
macroPragmas* = declPragmas + {FirstCallConv..LastCallConv,
wMagic, wNoSideEffect, wCompilerProc, wNonReloadable, wCore,
wDiscardable, wGensym, wInject, wDelegator}
iteratorPragmas* = declPragmas + {FirstCallConv..LastCallConv, wNoSideEffect, wSideEffect,
wMagic, wBorrow,
wDiscardable, wGensym, wInject, wRaises, wEffectsOf,
wTags, wLocks, wGcSafe, wRequires, wEnsures}
exprPragmas* = {wLine, wLocks, wNoRewrite, wGcSafe, wNoSideEffect}
stmtPragmas* = {
wHint, wWarning, wError,
wFatal, wDefine, wUndef, wCompile, wLink, wLinksys, wPure, wPush, wPop,
wPassl, wPassc, wLocalPassc,
wDeadCodeElimUnused, # deprecated, always on
wDeprecated,
wPragma, wEmit, wUnroll,
wLinearScanEnd, wPatterns, wTrMacros, wEffects, wNoForward, wReorder, wComputedGoto,
wExperimental, wThis, wUsed, wInvariant, wAssume, wAssert}
stmtPragmasTopLevel* = {wChecks, wObjChecks, wFieldChecks, wRangeChecks,
wBoundChecks, wOverflowChecks, wNilChecks, wStaticBoundchecks,
wStyleChecks, wAssertions,
wWarnings, wHints,
wLineDir, wStackTrace, wLineTrace, wOptimization,
wFloatChecks, wInfChecks, wNanChecks}
lambdaPragmas* = {FirstCallConv..LastCallConv,
wNoSideEffect, wSideEffect, wNoreturn, wNosinks, wDynlib, wHeader,
wThread, wAsmNoStackFrame,
wRaises, wLocks, wTags, wRequires, wEnsures, wEffectsOf,
wGcSafe, wCodegenDecl, wNoInit, wCompileTime}
typePragmas* = declPragmas + {wMagic, wAcyclic,
wPure, wHeader, wCompilerProc, wCore, wFinal, wSize, wShallow,
wIncompleteStruct, wCompleteStruct, wByCopy, wByRef,
wInheritable, wGensym, wInject, wRequiresInit, wUnchecked, wUnion, wPacked,
wCppNonPod, wBorrow, wGcSafe, wPartial, wExplain, wPackage}
fieldPragmas* = declPragmas + {wGuard, wBitsize, wCursor,
wRequiresInit, wNoalias, wAlign} - {wExportNims, wNodecl} # why exclude these?
varPragmas* = declPragmas + {wVolatile, wRegister, wThreadVar,
wMagic, wHeader, wCompilerProc, wCore, wDynlib,
wNoInit, wCompileTime, wGlobal,
wGensym, wInject, wCodegenDecl,
wGuard, wGoto, wCursor, wNoalias, wAlign}
constPragmas* = declPragmas + {wHeader, wMagic,
wGensym, wInject,
wIntDefine, wStrDefine, wBoolDefine, wCompilerProc, wCore}
paramPragmas* = {wNoalias, wInject, wGensym}
letPragmas* = varPragmas
procTypePragmas* = {FirstCallConv..LastCallConv, wVarargs, wNoSideEffect,
wThread, wRaises, wEffectsOf, wLocks, wTags, wGcSafe,
wRequires, wEnsures}
forVarPragmas* = {wInject, wGensym}
allRoutinePragmas* = methodPragmas + iteratorPragmas + lambdaPragmas
enumFieldPragmas* = {wDeprecated}
proc getPragmaVal*(procAst: PNode; name: TSpecialWord): PNode =
let p = procAst[pragmasPos]
if p.kind == nkEmpty: return nil
for it in p:
if it.kind in nkPragmaCallKinds and it.len == 2 and it[0].kind == nkIdent and
it[0].ident.id == ord(name):
return it[1]
proc pragma*(c: PContext, sym: PSym, n: PNode, validPragmas: TSpecialWords;
isStatement: bool = false)
proc recordPragma(c: PContext; n: PNode; args: varargs[string]) =
var recorded = newNodeI(nkReplayAction, n.info)
for i in 0..args.high:
recorded.add newStrNode(args[i], n.info)
addPragmaComputation(c, recorded)
const
errStringLiteralExpected = "string literal expected"
errIntLiteralExpected = "integer literal expected"
proc invalidPragma*(c: PContext; n: PNode) =
localError(c.config, n.info, "invalid pragma: " & renderTree(n, {renderNoComments}))
proc illegalCustomPragma*(c: PContext, n: PNode, s: PSym) =
localError(c.config, n.info, "cannot attach a custom pragma to '" & s.name.s & "'")
proc pragmaProposition(c: PContext, n: PNode) =
if n.kind notin nkPragmaCallKinds or n.len != 2:
localError(c.config, n.info, "proposition expected")
else:
n[1] = c.semExpr(c, n[1])
proc pragmaEnsures(c: PContext, n: PNode) =
if n.kind notin nkPragmaCallKinds or n.len != 2:
localError(c.config, n.info, "proposition expected")
else:
openScope(c)
let o = getCurrOwner(c)
if o.kind in routineKinds and o.typ != nil and o.typ.sons[0] != nil:
var s = newSym(skResult, getIdent(c.cache, "result"), nextSymId(c.idgen), o, n.info)
s.typ = o.typ.sons[0]
incl(s.flags, sfUsed)
addDecl(c, s)
n[1] = c.semExpr(c, n[1])
closeScope(c)
proc pragmaAsm*(c: PContext, n: PNode): char =
result = '\0'
if n != nil:
for i in 0..<n.len:
let it = n[i]
if it.kind in nkPragmaCallKinds and it.len == 2 and it[0].kind == nkIdent:
case whichKeyword(it[0].ident)
of wSubsChar:
if it[1].kind == nkCharLit: result = chr(int(it[1].intVal))
else: invalidPragma(c, it)
else: invalidPragma(c, it)
else:
invalidPragma(c, it)
proc setExternName(c: PContext; s: PSym, extname: string, info: TLineInfo) =
# special cases to improve performance:
if extname == "$1":
s.loc.r = rope(s.name.s)
elif '$' notin extname:
s.loc.r = rope(extname)
else:
try:
s.loc.r = rope(extname % s.name.s)
except ValueError:
localError(c.config, info, "invalid extern name: '" & extname & "'. (Forgot to escape '$'?)")
when hasFFI:
s.cname = $s.loc.r
if c.config.cmd == cmdNimfix and '$' notin extname:
# note that '{.importc.}' is transformed into '{.importc: "$1".}'
s.loc.flags.incl(lfFullExternalName)
proc makeExternImport(c: PContext; s: PSym, extname: string, info: TLineInfo) =
setExternName(c, s, extname, info)
incl(s.flags, sfImportc)
excl(s.flags, sfForward)
proc makeExternExport(c: PContext; s: PSym, extname: string, info: TLineInfo) =
setExternName(c, s, extname, info)
incl(s.flags, sfExportc)
proc processImportCompilerProc(c: PContext; s: PSym, extname: string, info: TLineInfo) =
setExternName(c, s, extname, info)
incl(s.flags, sfImportc)
excl(s.flags, sfForward)
incl(s.loc.flags, lfImportCompilerProc)
proc processImportCpp(c: PContext; s: PSym, extname: string, info: TLineInfo) =
setExternName(c, s, extname, info)
incl(s.flags, sfImportc)
incl(s.flags, sfInfixCall)
excl(s.flags, sfForward)
if c.config.backend == backendC:
let m = s.getModule()
incl(m.flags, sfCompileToCpp)
incl c.config.globalOptions, optMixedMode
proc processImportObjC(c: PContext; s: PSym, extname: string, info: TLineInfo) =
setExternName(c, s, extname, info)
incl(s.flags, sfImportc)
incl(s.flags, sfNamedParamCall)
excl(s.flags, sfForward)
let m = s.getModule()
incl(m.flags, sfCompileToObjc)
proc newEmptyStrNode(c: PContext; n: PNode): PNode {.noinline.} =
result = newNodeIT(nkStrLit, n.info, getSysType(c.graph, n.info, tyString))
result.strVal = ""
proc getStrLitNode(c: PContext, n: PNode): PNode =
if n.kind notin nkPragmaCallKinds or n.len != 2:
localError(c.config, n.info, errStringLiteralExpected)
# error correction:
result = newEmptyStrNode(c, n)
else:
n[1] = c.semConstExpr(c, n[1])
case n[1].kind
of nkStrLit, nkRStrLit, nkTripleStrLit: result = n[1]
else:
localError(c.config, n.info, errStringLiteralExpected)
# error correction:
result = newEmptyStrNode(c, n)
proc expectStrLit(c: PContext, n: PNode): string =
result = getStrLitNode(c, n).strVal
proc expectIntLit(c: PContext, n: PNode): int =
if n.kind notin nkPragmaCallKinds or n.len != 2:
localError(c.config, n.info, errIntLiteralExpected)
else:
n[1] = c.semConstExpr(c, n[1])
case n[1].kind
of nkIntLit..nkInt64Lit: result = int(n[1].intVal)
else: localError(c.config, n.info, errIntLiteralExpected)
proc getOptionalStr(c: PContext, n: PNode, defaultStr: string): string =
if n.kind in nkPragmaCallKinds: result = expectStrLit(c, n)
else: result = defaultStr
proc processCodegenDecl(c: PContext, n: PNode, sym: PSym) =
sym.constraint = getStrLitNode(c, n)
proc processMagic(c: PContext, n: PNode, s: PSym) =
#if sfSystemModule notin c.module.flags:
# liMessage(n.info, errMagicOnlyInSystem)
if n.kind notin nkPragmaCallKinds or n.len != 2:
localError(c.config, n.info, errStringLiteralExpected)
return
var v: string
if n[1].kind == nkIdent: v = n[1].ident.s
else: v = expectStrLit(c, n)
for m in TMagic:
if substr($m, 1) == v:
s.magic = m
break
if s.magic == mNone: message(c.config, n.info, warnUnknownMagic, v)
proc wordToCallConv(sw: TSpecialWord): TCallingConvention =
# this assumes that the order of special words and calling conventions is
# the same
TCallingConvention(ord(ccNimCall) + ord(sw) - ord(wNimcall))
proc isTurnedOn(c: PContext, n: PNode): bool =
if n.kind in nkPragmaCallKinds and n.len == 2:
let x = c.semConstBoolExpr(c, n[1])
n[1] = x
if x.kind == nkIntLit: return x.intVal != 0
localError(c.config, n.info, "'on' or 'off' expected")
proc onOff(c: PContext, n: PNode, op: TOptions, resOptions: var TOptions) =
if isTurnedOn(c, n): resOptions.incl op
else: resOptions.excl op
proc pragmaNoForward(c: PContext, n: PNode; flag=sfNoForward) =
if isTurnedOn(c, n):
incl(c.module.flags, flag)
c.features.incl codeReordering
else:
excl(c.module.flags, flag)
# c.features.excl codeReordering
# deprecated as of 0.18.1
message(c.config, n.info, warnDeprecated,
"use {.experimental: \"codeReordering\".} instead; " &
(if flag == sfNoForward: "{.noForward.}" else: "{.reorder.}") & " is deprecated")
proc processCallConv(c: PContext, n: PNode) =
if n.kind in nkPragmaCallKinds and n.len == 2 and n[1].kind == nkIdent:
let sw = whichKeyword(n[1].ident)
case sw
of FirstCallConv..LastCallConv:
c.optionStack[^1].defaultCC = wordToCallConv(sw)
else: localError(c.config, n.info, "calling convention expected")
else:
localError(c.config, n.info, "calling convention expected")
proc getLib(c: PContext, kind: TLibKind, path: PNode): PLib =
for it in c.libs:
if it.kind == kind and trees.exprStructuralEquivalent(it.path, path):
return it
result = newLib(kind)
result.path = path
c.libs.add result
if path.kind in {nkStrLit..nkTripleStrLit}:
result.isOverriden = options.isDynlibOverride(c.config, path.strVal)
proc expectDynlibNode(c: PContext, n: PNode): PNode =
if n.kind notin nkPragmaCallKinds or n.len != 2:
localError(c.config, n.info, errStringLiteralExpected)
# error correction:
result = newEmptyStrNode(c, n)
else:
# For the OpenGL wrapper we support:
# {.dynlib: myGetProcAddr(...).}
result = c.semExpr(c, n[1])
if result.kind == nkSym and result.sym.kind == skConst:
result = result.sym.ast # look it up
if result.typ == nil or result.typ.kind notin {tyPointer, tyString, tyProc}:
localError(c.config, n.info, errStringLiteralExpected)
result = newEmptyStrNode(c, n)
proc processDynLib(c: PContext, n: PNode, sym: PSym) =
if (sym == nil) or (sym.kind == skModule):
let lib = getLib(c, libDynamic, expectDynlibNode(c, n))
if not lib.isOverriden:
c.optionStack[^1].dynlib = lib
else:
if n.kind in nkPragmaCallKinds:
var lib = getLib(c, libDynamic, expectDynlibNode(c, n))
if not lib.isOverriden:
addToLib(lib, sym)
incl(sym.loc.flags, lfDynamicLib)
else:
incl(sym.loc.flags, lfExportLib)
# since we'll be loading the dynlib symbols dynamically, we must use
# a calling convention that doesn't introduce custom name mangling
# cdecl is the default - the user can override this explicitly
if sym.kind in routineKinds and sym.typ != nil and
tfExplicitCallConv notin sym.typ.flags:
sym.typ.callConv = ccCDecl
proc processNote(c: PContext, n: PNode) =
template handleNote(enumVals, notes) =
let x = findStr(enumVals.a, enumVals.b, n[0][1].ident.s, errUnknown)
if x != errUnknown:
nk = TNoteKind(x)
let x = c.semConstBoolExpr(c, n[1])
n[1] = x
if x.kind == nkIntLit and x.intVal != 0: incl(notes, nk)
else: excl(notes, nk)
else:
invalidPragma(c, n)
if n.kind in nkPragmaCallKinds and n.len == 2 and
n[0].kind == nkBracketExpr and
n[0].len == 2 and
n[0][1].kind == nkIdent and n[0][0].kind == nkIdent:
var nk: TNoteKind
case whichKeyword(n[0][0].ident)
of wHint: handleNote(hintMin .. hintMax, c.config.notes)
of wWarning: handleNote(warnMin .. warnMax, c.config.notes)
of wWarningAsError: handleNote(warnMin .. warnMax, c.config.warningAsErrors)
of wHintAsError: handleNote(hintMin .. hintMax, c.config.warningAsErrors)
else: invalidPragma(c, n)
else: invalidPragma(c, n)
proc pragmaToOptions(w: TSpecialWord): TOptions {.inline.} =
case w
of wChecks: ChecksOptions
of wObjChecks: {optObjCheck}
of wFieldChecks: {optFieldCheck}
of wRangeChecks: {optRangeCheck}
of wBoundChecks: {optBoundsCheck}
of wOverflowChecks: {optOverflowCheck}
of wFloatChecks: {optNaNCheck, optInfCheck}
of wNanChecks: {optNaNCheck}
of wInfChecks: {optInfCheck}
of wStaticBoundchecks: {optStaticBoundsCheck}
of wStyleChecks: {optStyleCheck}
of wAssertions: {optAssert}
of wWarnings: {optWarns}
of wHints: {optHints}
of wLineDir: {optLineDir}
of wStackTrace: {optStackTrace}
of wLineTrace: {optLineTrace}
of wDebugger: {optNone}
of wProfiler: {optProfiler, optMemTracker}
of wMemTracker: {optMemTracker}
of wByRef: {optByRef}
of wImplicitStatic: {optImplicitStatic}
of wPatterns, wTrMacros: {optTrMacros}
of wSinkInference: {optSinkInference}
else: {}
proc processExperimental(c: PContext; n: PNode) =
if n.kind notin nkPragmaCallKinds or n.len != 2:
c.features.incl oldExperimentalFeatures
else:
n[1] = c.semConstExpr(c, n[1])
case n[1].kind
of nkStrLit, nkRStrLit, nkTripleStrLit:
try:
let feature = parseEnum[Feature](n[1].strVal)
c.features.incl feature
if feature == codeReordering:
if not isTopLevel(c):
localError(c.config, n.info,
"Code reordering experimental pragma only valid at toplevel")
c.module.flags.incl sfReorder
except ValueError:
localError(c.config, n[1].info, "unknown experimental feature")
else:
localError(c.config, n.info, errStringLiteralExpected)
proc tryProcessOption(c: PContext, n: PNode, resOptions: var TOptions): bool =
result = true
if n.kind notin nkPragmaCallKinds or n.len != 2: result = false
elif n[0].kind == nkBracketExpr: processNote(c, n)
elif n[0].kind != nkIdent: result = false
else:
let sw = whichKeyword(n[0].ident)
if sw == wExperimental:
processExperimental(c, n)
return true
let opts = pragmaToOptions(sw)
if opts != {}:
onOff(c, n, opts, resOptions)
else:
case sw
of wCallconv: processCallConv(c, n)
of wDynlib: processDynLib(c, n, nil)
of wOptimization:
if n[1].kind != nkIdent:
invalidPragma(c, n)
else:
case n[1].ident.s.normalize
of "speed":
incl(resOptions, optOptimizeSpeed)
excl(resOptions, optOptimizeSize)
of "size":
excl(resOptions, optOptimizeSpeed)
incl(resOptions, optOptimizeSize)
of "none":
excl(resOptions, optOptimizeSpeed)
excl(resOptions, optOptimizeSize)
else: localError(c.config, n.info, "'none', 'speed' or 'size' expected")
else: result = false
proc processOption(c: PContext, n: PNode, resOptions: var TOptions) =
if not tryProcessOption(c, n, resOptions):
# calling conventions (boring...):
localError(c.config, n.info, "option expected")
proc processPush(c: PContext, n: PNode, start: int) =
if n[start-1].kind in nkPragmaCallKinds:
localError(c.config, n.info, "'push' cannot have arguments")
var x = pushOptionEntry(c)
for i in start..<n.len:
if not tryProcessOption(c, n[i], c.config.options):
# simply store it somewhere:
if x.otherPragmas.isNil:
x.otherPragmas = newNodeI(nkPragma, n.info)
x.otherPragmas.add n[i]
#localError(c.config, n.info, errOptionExpected)
# If stacktrace is disabled globally we should not enable it
if optStackTrace notin c.optionStack[0].options:
c.config.options.excl(optStackTrace)
when defined(debugOptions):
echo c.config $ n.info, " PUSH config is now ", c.config.options
proc processPop(c: PContext, n: PNode) =
if c.optionStack.len <= 1:
localError(c.config, n.info, "{.pop.} without a corresponding {.push.}")
else:
popOptionEntry(c)
when defined(debugOptions):
echo c.config $ n.info, " POP config is now ", c.config.options
proc processDefine(c: PContext, n: PNode) =
if (n.kind in nkPragmaCallKinds and n.len == 2) and (n[1].kind == nkIdent):
defineSymbol(c.config.symbols, n[1].ident.s)
else:
invalidPragma(c, n)
proc processUndef(c: PContext, n: PNode) =
if (n.kind in nkPragmaCallKinds and n.len == 2) and (n[1].kind == nkIdent):
undefSymbol(c.config.symbols, n[1].ident.s)
else:
invalidPragma(c, n)
proc relativeFile(c: PContext; n: PNode; ext=""): AbsoluteFile =
var s = expectStrLit(c, n)
if ext.len > 0 and splitFile(s).ext == "":
s = addFileExt(s, ext)
result = AbsoluteFile parentDir(toFullPath(c.config, n.info)) / s
if not fileExists(result):
if isAbsolute(s): result = AbsoluteFile s
else:
result = findFile(c.config, s)
if result.isEmpty: result = AbsoluteFile s
proc processCompile(c: PContext, n: PNode) =
proc docompile(c: PContext; it: PNode; src, dest: AbsoluteFile; customArgs: string) =
var cf = Cfile(nimname: splitFile(src).name,
cname: src, obj: dest, flags: {CfileFlag.External},
customArgs: customArgs)
extccomp.addExternalFileToCompile(c.config, cf)
recordPragma(c, it, "compile", src.string, dest.string, customArgs)
proc getStrLit(c: PContext, n: PNode; i: int): string =
n[i] = c.semConstExpr(c, n[i])
case n[i].kind
of nkStrLit, nkRStrLit, nkTripleStrLit:
shallowCopy(result, n[i].strVal)
else:
localError(c.config, n.info, errStringLiteralExpected)
result = ""
let it = if n.kind in nkPragmaCallKinds and n.len == 2: n[1] else: n
if it.kind in {nkPar, nkTupleConstr} and it.len == 2:
let s = getStrLit(c, it, 0)
let dest = getStrLit(c, it, 1)
var found = parentDir(toFullPath(c.config, n.info)) / s
for f in os.walkFiles(found):
let obj = completeCfilePath(c.config, AbsoluteFile(dest % extractFilename(f)))
docompile(c, it, AbsoluteFile f, obj, "")
else:
var s = ""
var customArgs = ""
if n.kind in nkCallKinds:
s = getStrLit(c, n, 1)
if n.len <= 3:
customArgs = getStrLit(c, n, 2)
else:
localError(c.config, n.info, "'.compile' pragma takes up 2 arguments")
else:
s = expectStrLit(c, n)
var found = AbsoluteFile(parentDir(toFullPath(c.config, n.info)) / s)
if not fileExists(found):
if isAbsolute(s): found = AbsoluteFile s
else:
found = findFile(c.config, s)
if found.isEmpty: found = AbsoluteFile s
let obj = toObjFile(c.config, completeCfilePath(c.config, found, false))
docompile(c, it, found, obj, customArgs)
proc processLink(c: PContext, n: PNode) =
let found = relativeFile(c, n, CC[c.config.cCompiler].objExt)
extccomp.addExternalFileToLink(c.config, found)
recordPragma(c, n, "link", found.string)
proc semAsmOrEmit*(con: PContext, n: PNode, marker: char): PNode =
case n[1].kind
of nkStrLit, nkRStrLit, nkTripleStrLit:
result = newNodeI(if n.kind == nkAsmStmt: nkAsmStmt else: nkArgList, n.info)
var str = n[1].strVal
if str == "":
localError(con.config, n.info, "empty 'asm' statement")
return
# now parse the string literal and substitute symbols:
var a = 0
while true:
var b = strutils.find(str, marker, a)
var sub = if b < 0: substr(str, a) else: substr(str, a, b - 1)
if sub != "": result.add newStrNode(nkStrLit, sub)
if b < 0: break
var c = strutils.find(str, marker, b + 1)
if c < 0: sub = substr(str, b + 1)
else: sub = substr(str, b + 1, c - 1)
if sub != "":
var amb = false
var e = searchInScopes(con, getIdent(con.cache, sub), amb)
# XXX what to do here if 'amb' is true?
if e != nil:
incl(e.flags, sfUsed)
result.add newSymNode(e)
else:
result.add newStrNode(nkStrLit, sub)
else:
# an empty '``' produces a single '`'
result.add newStrNode(nkStrLit, $marker)
if c < 0: break
a = c + 1
else:
illFormedAstLocal(n, con.config)
result = newNodeI(nkAsmStmt, n.info)
proc pragmaEmit(c: PContext, n: PNode) =
if n.kind notin nkPragmaCallKinds or n.len != 2:
localError(c.config, n.info, errStringLiteralExpected)
else:
let n1 = n[1]
if n1.kind == nkBracket:
var b = newNodeI(nkBracket, n1.info, n1.len)
for i in 0..<n1.len:
b[i] = c.semExpr(c, n1[i])
n[1] = b
else:
n[1] = c.semConstExpr(c, n1)
case n[1].kind
of nkStrLit, nkRStrLit, nkTripleStrLit:
n[1] = semAsmOrEmit(c, n, '`')
else:
localError(c.config, n.info, errStringLiteralExpected)
proc noVal(c: PContext; n: PNode) =
if n.kind in nkPragmaCallKinds and n.len > 1: invalidPragma(c, n)
proc pragmaUnroll(c: PContext, n: PNode) =
if c.p.nestedLoopCounter <= 0:
invalidPragma(c, n)
elif n.kind in nkPragmaCallKinds and n.len == 2:
var unrollFactor = expectIntLit(c, n)
if unrollFactor <% 32:
n[1] = newIntNode(nkIntLit, unrollFactor)
else:
invalidPragma(c, n)
proc pragmaLine(c: PContext, n: PNode) =
if n.kind in nkPragmaCallKinds and n.len == 2:
n[1] = c.semConstExpr(c, n[1])
let a = n[1]
if a.kind in {nkPar, nkTupleConstr}:
# unpack the tuple
var x = a[0]
var y = a[1]
if x.kind == nkExprColonExpr: x = x[1]
if y.kind == nkExprColonExpr: y = y[1]
if x.kind != nkStrLit:
localError(c.config, n.info, errStringLiteralExpected)
elif y.kind != nkIntLit:
localError(c.config, n.info, errIntLiteralExpected)
else:
n.info.fileIndex = fileInfoIdx(c.config, AbsoluteFile(x.strVal))
n.info.line = uint16(y.intVal)
else:
localError(c.config, n.info, "tuple expected")
else:
# sensible default:
n.info = getInfoContext(c.config, -1)
proc processPragma(c: PContext, n: PNode, i: int) =
let it = n[i]
if it.kind notin nkPragmaCallKinds and it.safeLen == 2: invalidPragma(c, n)
elif it.safeLen != 2 or it[0].kind != nkIdent or it[1].kind != nkIdent:
invalidPragma(c, n)
var userPragma = newSym(skTemplate, it[1].ident, nextSymId(c.idgen), nil, it.info, c.config.options)
userPragma.ast = newTreeI(nkPragma, n.info, n.sons[i+1..^1])
strTableAdd(c.userPragmas, userPragma)
proc pragmaRaisesOrTags(c: PContext, n: PNode) =
proc processExc(c: PContext, x: PNode) =
if c.hasUnresolvedArgs(c, x):
x.typ = makeTypeFromExpr(c, x)
else:
var t = skipTypes(c.semTypeNode(c, x, nil), skipPtrs)
if t.kind notin {tyObject, tyOr}:
localError(c.config, x.info, errGenerated, "invalid type for raises/tags list")
x.typ = t
if n.kind in nkPragmaCallKinds and n.len == 2:
let it = n[1]
if it.kind notin {nkCurly, nkBracket}:
processExc(c, it)
else:
for e in items(it): processExc(c, e)
else:
invalidPragma(c, n)
proc pragmaLockStmt(c: PContext; it: PNode) =
if it.kind notin nkPragmaCallKinds or it.len != 2:
invalidPragma(c, it)
else:
let n = it[1]
if n.kind != nkBracket:
localError(c.config, n.info, errGenerated, "locks pragma takes a list of expressions")
else:
for i in 0..<n.len:
n[i] = c.semExpr(c, n[i])
proc pragmaLocks(c: PContext, it: PNode): TLockLevel =
if it.kind notin nkPragmaCallKinds or it.len != 2:
invalidPragma(c, it)
else:
case it[1].kind
of nkStrLit, nkRStrLit, nkTripleStrLit:
if it[1].strVal == "unknown":
result = UnknownLockLevel
else:
localError(c.config, it[1].info, "invalid string literal for locks pragma (only allowed string is \"unknown\")")
else:
let x = expectIntLit(c, it)
if x < 0 or x > MaxLockLevel:
localError(c.config, it[1].info, "integer must be within 0.." & $MaxLockLevel)
else:
result = TLockLevel(x)
proc typeBorrow(c: PContext; sym: PSym, n: PNode) =
if n.kind in nkPragmaCallKinds and n.len == 2:
let it = n[1]
if it.kind != nkAccQuoted:
localError(c.config, n.info, "a type can only borrow `.` for now")
incl(sym.typ.flags, tfBorrowDot)
proc markCompilerProc(c: PContext; s: PSym) =
# minor hack ahead: FlowVar is the only generic .compilerproc type which
# should not have an external name set:
if s.kind != skType or s.name.s != "FlowVar":
makeExternExport(c, s, "$1", s.info)
incl(s.flags, sfCompilerProc)
incl(s.flags, sfUsed)
registerCompilerProc(c.graph, s)
if c.config.symbolFiles != disabledSf:
addCompilerProc(c.encoder, c.packedRepr, s)
proc deprecatedStmt(c: PContext; outerPragma: PNode) =
let pragma = outerPragma[1]
if pragma.kind in {nkStrLit..nkTripleStrLit}:
incl(c.module.flags, sfDeprecated)
c.module.constraint = getStrLitNode(c, outerPragma)
return
if pragma.kind != nkBracket:
localError(c.config, pragma.info, "list of key:value pairs expected"); return
for n in pragma:
if n.kind in nkPragmaCallKinds and n.len == 2:
let dest = qualifiedLookUp(c, n[1], {checkUndeclared})
if dest == nil or dest.kind in routineKinds:
localError(c.config, n.info, warnUser, "the .deprecated pragma is unreliable for routines")
let src = considerQuotedIdent(c, n[0])
let alias = newSym(skAlias, src, nextSymId(c.idgen), dest, n[0].info, c.config.options)
incl(alias.flags, sfExported)
if sfCompilerProc in dest.flags: markCompilerProc(c, alias)
addInterfaceDecl(c, alias)
n[1] = newSymNode(dest)
else:
localError(c.config, n.info, "key:value pair expected")
proc pragmaGuard(c: PContext; it: PNode; kind: TSymKind): PSym =
if it.kind notin nkPragmaCallKinds or it.len != 2:
invalidPragma(c, it); return
let n = it[1]
if n.kind == nkSym:
result = n.sym
elif kind == skField:
# First check if the guard is a global variable:
result = qualifiedLookUp(c, n, {})
if result.isNil or result.kind notin {skLet, skVar} or
sfGlobal notin result.flags:
# We return a dummy symbol; later passes over the type will repair it.
# Generic instantiation needs to know about this too. But we're lazy
# and perform the lookup on demand instead.
result = newSym(skUnknown, considerQuotedIdent(c, n), nextSymId(c.idgen), nil, n.info,
c.config.options)
else:
result = qualifiedLookUp(c, n, {checkUndeclared})
proc semCustomPragma(c: PContext, n: PNode): PNode =
var callNode: PNode
if n.kind in {nkIdent, nkSym}:
# pragma -> pragma()
callNode = newTree(nkCall, n)
elif n.kind == nkExprColonExpr:
# pragma: arg -> pragma(arg)
callNode = newTree(nkCall, n[0], n[1])
elif n.kind in nkPragmaCallKinds:
callNode = n
else:
invalidPragma(c, n)
return n
let r = c.semOverloadedCall(c, callNode, n, {skTemplate}, {efNoUndeclared})
if r.isNil or sfCustomPragma notin r[0].sym.flags:
invalidPragma(c, n)
return n
result = r
# Transform the nkCall node back to its original form if possible
if n.kind == nkIdent and r.len == 1:
# pragma() -> pragma
result = result[0]
elif n.kind == nkExprColonExpr and r.len == 2:
# pragma(arg) -> pragma: arg
result.transitionSonsKind(n.kind)
proc processEffectsOf(c: PContext, n: PNode; owner: PSym) =
proc processParam(c: PContext; n: PNode) =
let r = c.semExpr(c, n)
if r.kind == nkSym and r.sym.kind == skParam:
if r.sym.owner == owner:
incl r.sym.flags, sfEffectsDelayed
else:
localError(c.config, n.info, errGenerated, "parameter cannot be declared as .effectsOf")
else:
localError(c.config, n.info, errGenerated, "parameter name expected")
if n.kind notin nkPragmaCallKinds or n.len != 2:
localError(c.config, n.info, errGenerated, "parameter name expected")
else:
let it = n[1]
if it.kind in {nkCurly, nkBracket}:
for x in items(it): processParam(c, x)
else:
processParam(c, it)
proc singlePragma(c: PContext, sym: PSym, n: PNode, i: var int,
validPragmas: TSpecialWords,
comesFromPush, isStatement: bool): bool =
var it = n[i]
var key = if it.kind in nkPragmaCallKinds and it.len > 1: it[0] else: it
if key.kind == nkBracketExpr:
processNote(c, it)
return
elif key.kind == nkCast:
if comesFromPush:
localError(c.config, n.info, "a 'cast' pragma cannot be pushed")
elif not isStatement:
localError(c.config, n.info, "'cast' pragma only allowed in a statement context")
case whichPragma(key[1])
of wRaises, wTags: pragmaRaisesOrTags(c, key[1])
else: discard
return
elif key.kind notin nkIdentKinds:
n[i] = semCustomPragma(c, it)
return
let ident = considerQuotedIdent(c, key)
var userPragma = strTableGet(c.userPragmas, ident)
if userPragma != nil:
if {optStyleHint, optStyleError} * c.config.globalOptions != {}:
styleCheckUse(c.config, key.info, userPragma)
# number of pragmas increase/decrease with user pragma expansion
inc c.instCounter
if c.instCounter > 100:
globalError(c.config, it.info, "recursive dependency: " & userPragma.name.s)
pragma(c, sym, userPragma.ast, validPragmas, isStatement)
n.sons[i..i] = userPragma.ast.sons # expand user pragma with its content
i.inc(userPragma.ast.len - 1) # inc by -1 is ok, user pragmas was empty
dec c.instCounter
else:
let k = whichKeyword(ident)
if k in validPragmas:
if {optStyleHint, optStyleError} * c.config.globalOptions != {}:
checkPragmaUse(c.config, key.info, k, ident.s)
case k
of wExportc, wExportCpp:
makeExternExport(c, sym, getOptionalStr(c, it, "$1"), it.info)
if k == wExportCpp:
if c.config.backend != backendCpp:
localError(c.config, it.info, "exportcpp requires `cpp` backend, got: " & $c.config.backend)
else:
incl(sym.flags, sfMangleCpp)
incl(sym.flags, sfUsed) # avoid wrong hints
of wImportc:
let name = getOptionalStr(c, it, "$1")
cppDefine(c.config, name)
recordPragma(c, it, "cppdefine", name)
makeExternImport(c, sym, name, it.info)
of wImportCompilerProc:
let name = getOptionalStr(c, it, "$1")
cppDefine(c.config, name)
recordPragma(c, it, "cppdefine", name)
processImportCompilerProc(c, sym, name, it.info)
of wExtern: setExternName(c, sym, expectStrLit(c, it), it.info)
of wDirty:
if sym.kind == skTemplate: incl(sym.flags, sfDirty)
else: invalidPragma(c, it)
of wImportCpp:
processImportCpp(c, sym, getOptionalStr(c, it, "$1"), it.info)
of wCppNonPod:
incl(sym.flags, sfCppNonPod)
of wImportJs:
if c.config.backend != backendJs:
localError(c.config, it.info, "`importjs` pragma requires the JavaScript target")
let name = getOptionalStr(c, it, "$1")
incl(sym.flags, sfImportc)
incl(sym.flags, sfInfixCall)
if sym.kind in skProcKinds and {'(', '#', '@'} notin name:
localError(c.config, n.info, "`importjs` for routines requires a pattern")
setExternName(c, sym, name, it.info)
of wImportObjC:
processImportObjC(c, sym, getOptionalStr(c, it, "$1"), it.info)
of wSize:
if sym.typ == nil: invalidPragma(c, it)
var size = expectIntLit(c, it)
case size
of 1, 2, 4:
sym.typ.size = size
sym.typ.align = int16 size
of 8:
sym.typ.size = 8
sym.typ.align = floatInt64Align(c.config)
else:
localError(c.config, it.info, "size may only be 1, 2, 4 or 8")
of wAlign:
let alignment = expectIntLit(c, it)
if isPowerOfTwo(alignment) and alignment > 0:
sym.alignment = max(sym.alignment, alignment)
else:
localError(c.config, it.info, "power of two expected")
of wNodecl:
noVal(c, it)
incl(sym.loc.flags, lfNoDecl)
of wPure, wAsmNoStackFrame:
noVal(c, it)
if sym != nil:
if k == wPure and sym.kind in routineKinds: invalidPragma(c, it)
else: incl(sym.flags, sfPure)
of wVolatile:
noVal(c, it)
incl(sym.flags, sfVolatile)
of wCursor:
noVal(c, it)
incl(sym.flags, sfCursor)
of wRegister:
noVal(c, it)
incl(sym.flags, sfRegister)
of wNoalias:
noVal(c, it)
incl(sym.flags, sfNoalias)
of wEffectsOf:
processEffectsOf(c, it, sym)
of wThreadVar:
noVal(c, it)
incl(sym.flags, {sfThread, sfGlobal})
of wDeadCodeElimUnused: discard # deprecated, dead code elim always on
of wNoForward: pragmaNoForward(c, it)
of wReorder: pragmaNoForward(c, it, flag = sfReorder)
of wMagic: processMagic(c, it, sym)
of wCompileTime:
noVal(c, it)
if comesFromPush:
if sym.kind in {skProc, skFunc}:
incl(sym.flags, sfCompileTime)
else:
incl(sym.flags, sfCompileTime)
#incl(sym.loc.flags, lfNoDecl)
of wGlobal:
noVal(c, it)
incl(sym.flags, sfGlobal)
incl(sym.flags, sfPure)
of wMerge:
# only supported for backwards compat, doesn't do anything anymore
noVal(c, it)
of wConstructor:
noVal(c, it)
incl(sym.flags, sfConstructor)
of wHeader:
var lib = getLib(c, libHeader, getStrLitNode(c, it))
addToLib(lib, sym)
incl(sym.flags, sfImportc)
incl(sym.loc.flags, lfHeader)
incl(sym.loc.flags, lfNoDecl)
# implies nodecl, because otherwise header would not make sense
if sym.loc.r == nil: sym.loc.r = rope(sym.name.s)
of wNoSideEffect:
noVal(c, it)
if sym != nil:
incl(sym.flags, sfNoSideEffect)
if sym.typ != nil: incl(sym.typ.flags, tfNoSideEffect)
of wSideEffect:
noVal(c, it)
incl(sym.flags, sfSideEffect)
of wNoreturn:
noVal(c, it)
# Disable the 'noreturn' annotation when in the "Quirky Exceptions" mode!
if c.config.exc != excQuirky:
incl(sym.flags, sfNoReturn)
if sym.typ[0] != nil:
localError(c.config, sym.ast[paramsPos][0].info,
".noreturn with return type not allowed")
of wNoDestroy:
noVal(c, it)
incl(sym.flags, sfGeneratedOp)
of wNosinks:
noVal(c, it)
incl(sym.flags, sfWasForwarded)
of wDynlib:
processDynLib(c, it, sym)
of wCompilerProc, wCore:
noVal(c, it) # compilerproc may not get a string!
cppDefine(c.graph.config, sym.name.s)
recordPragma(c, it, "cppdefine", sym.name.s)
if sfFromGeneric notin sym.flags: markCompilerProc(c, sym)
of wNonReloadable:
sym.flags.incl sfNonReloadable
of wProcVar:
noVal(c, it)
incl(sym.flags, sfProcvar)
of wExplain:
sym.flags.incl sfExplain
of wDeprecated:
if sym != nil and sym.kind in routineKinds + {skType, skVar, skLet}:
if it.kind in nkPragmaCallKinds: discard getStrLitNode(c, it)
incl(sym.flags, sfDeprecated)
elif sym != nil and sym.kind != skModule:
# We don't support the extra annotation field
if it.kind in nkPragmaCallKinds:
localError(c.config, it.info, "annotation to deprecated not supported here")
incl(sym.flags, sfDeprecated)
# At this point we're quite sure this is a statement and applies to the
# whole module
elif it.kind in nkPragmaCallKinds: deprecatedStmt(c, it)
else: incl(c.module.flags, sfDeprecated)
of wVarargs:
noVal(c, it)
if sym.typ == nil: invalidPragma(c, it)
else: incl(sym.typ.flags, tfVarargs)
of wBorrow:
if sym.kind == skType:
typeBorrow(c, sym, it)
else:
noVal(c, it)
incl(sym.flags, sfBorrow)
of wFinal:
noVal(c, it)
if sym.typ == nil: invalidPragma(c, it)
else: incl(sym.typ.flags, tfFinal)
of wInheritable:
noVal(c, it)
if sym.typ == nil or tfFinal in sym.typ.flags: invalidPragma(c, it)
else: incl(sym.typ.flags, tfInheritable)
of wPackage:
noVal(c, it)
if sym.typ == nil: invalidPragma(c, it)
else: incl(sym.flags, sfForward)
of wAcyclic:
noVal(c, it)
if sym.typ == nil: invalidPragma(c, it)
else: incl(sym.typ.flags, tfAcyclic)
of wShallow:
noVal(c, it)
if sym.typ == nil: invalidPragma(c, it)
else: incl(sym.typ.flags, tfShallow)
of wThread:
noVal(c, it)
incl(sym.flags, sfThread)
incl(sym.flags, sfProcvar)
if sym.typ != nil:
incl(sym.typ.flags, tfThread)
if sym.typ.callConv == ccClosure: sym.typ.callConv = ccNimCall
of wGcSafe:
noVal(c, it)
if sym != nil:
if sym.kind != skType: incl(sym.flags, sfThread)
if sym.typ != nil: incl(sym.typ.flags, tfGcSafe)
else: invalidPragma(c, it)
else:
discard "no checking if used as a code block"
of wPacked:
noVal(c, it)
if sym.typ == nil: invalidPragma(c, it)
else: incl(sym.typ.flags, tfPacked)
of wHint:
let s = expectStrLit(c, it)
recordPragma(c, it, "hint", s)
message(c.config, it.info, hintUser, s)
of wWarning:
let s = expectStrLit(c, it)
recordPragma(c, it, "warning", s)
message(c.config, it.info, warnUser, s)
of wError:
if sym != nil and (sym.isRoutine or sym.kind == skType) and not isStatement:
# This is subtle but correct: the error *statement* is only
# allowed when 'wUsed' is not in validPragmas. Here this is the easiest way to
# distinguish properly between
# ``proc p() {.error}`` and ``proc p() = {.error: "msg".}``
if it.kind in nkPragmaCallKinds: discard getStrLitNode(c, it)
incl(sym.flags, sfError)
excl(sym.flags, sfForward)
else:
let s = expectStrLit(c, it)
recordPragma(c, it, "error", s)
localError(c.config, it.info, errUser, s)
of wFatal: fatal(c.config, it.info, expectStrLit(c, it))
of wDefine: processDefine(c, it)
of wUndef: processUndef(c, it)
of wCompile: processCompile(c, it)
of wLink: processLink(c, it)
of wPassl:
let s = expectStrLit(c, it)
extccomp.addLinkOption(c.config, s)
recordPragma(c, it, "passl", s)
of wPassc:
let s = expectStrLit(c, it)
extccomp.addCompileOption(c.config, s)
recordPragma(c, it, "passc", s)
of wLocalPassc:
assert sym != nil and sym.kind == skModule
let s = expectStrLit(c, it)
extccomp.addLocalCompileOption(c.config, s, toFullPathConsiderDirty(c.config, sym.info.fileIndex))
recordPragma(c, it, "localpassl", s)
of wPush:
processPush(c, n, i + 1)
result = true
of wPop:
processPop(c, it)
result = true
of wPragma:
if not sym.isNil and sym.kind == skTemplate:
sym.flags.incl sfCustomPragma
else:
processPragma(c, n, i)
result = true
of wDiscardable:
noVal(c, it)
if sym != nil: incl(sym.flags, sfDiscardable)
of wNoInit:
noVal(c, it)
if sym != nil: incl(sym.flags, sfNoInit)
of wCodegenDecl: processCodegenDecl(c, it, sym)
of wChecks, wObjChecks, wFieldChecks, wRangeChecks, wBoundChecks,
wOverflowChecks, wNilChecks, wAssertions, wWarnings, wHints,
wLineDir, wOptimization, wStaticBoundchecks, wStyleChecks,
wCallconv, wDebugger, wProfiler,
wFloatChecks, wNanChecks, wInfChecks, wPatterns, wTrMacros:
processOption(c, it, c.config.options)
of wStackTrace, wLineTrace:
if sym.kind in {skProc, skMethod, skConverter}:
processOption(c, it, sym.options)
else:
processOption(c, it, c.config.options)
of FirstCallConv..LastCallConv:
assert(sym != nil)
if sym.typ == nil: invalidPragma(c, it)
else:
sym.typ.callConv = wordToCallConv(k)
sym.typ.flags.incl tfExplicitCallConv
of wEmit: pragmaEmit(c, it)
of wUnroll: pragmaUnroll(c, it)
of wLinearScanEnd, wComputedGoto: noVal(c, it)
of wEffects:
# is later processed in effect analysis:
noVal(c, it)
of wIncompleteStruct:
noVal(c, it)
if sym.typ == nil: invalidPragma(c, it)
else: incl(sym.typ.flags, tfIncompleteStruct)
of wCompleteStruct:
noVal(c, it)
if sym.typ == nil: invalidPragma(c, it)
else: incl(sym.typ.flags, tfCompleteStruct)
of wUnchecked:
noVal(c, it)
if sym.typ == nil or sym.typ.kind notin {tyArray, tyUncheckedArray}:
invalidPragma(c, it)
else:
sym.typ.kind = tyUncheckedArray
of wUnion:
if c.config.backend == backendJs:
localError(c.config, it.info, "`{.union.}` is not implemented for js backend.")
else:
noVal(c, it)
if sym.typ == nil: invalidPragma(c, it)
else: incl(sym.typ.flags, tfUnion)
of wRequiresInit:
noVal(c, it)
if sym.kind == skField:
sym.flags.incl sfRequiresInit
elif sym.typ != nil:
incl(sym.typ.flags, tfNeedsFullInit)
else:
invalidPragma(c, it)
of wByRef:
noVal(c, it)
if sym == nil or sym.typ == nil:
processOption(c, it, c.config.options)
else:
incl(sym.typ.flags, tfByRef)
of wByCopy:
noVal(c, it)
if sym.kind != skType or sym.typ == nil: invalidPragma(c, it)
else: incl(sym.typ.flags, tfByCopy)
of wPartial:
noVal(c, it)
if sym.kind != skType or sym.typ == nil: invalidPragma(c, it)
else:
incl(sym.typ.flags, tfPartial)
of wInject, wGensym:
# We check for errors, but do nothing with these pragmas otherwise
# as they are handled directly in 'evalTemplate'.
noVal(c, it)
if sym == nil: invalidPragma(c, it)
of wLine: pragmaLine(c, it)
of wRaises, wTags: pragmaRaisesOrTags(c, it)
of wLocks:
if sym == nil: pragmaLockStmt(c, it)
elif sym.typ == nil: invalidPragma(c, it)
else: sym.typ.lockLevel = pragmaLocks(c, it)
of wBitsize:
if sym == nil or sym.kind != skField:
invalidPragma(c, it)
else:
sym.bitsize = expectIntLit(c, it)
if sym.bitsize <= 0:
localError(c.config, it.info, "bitsize needs to be positive")
of wGuard:
if sym == nil or sym.kind notin {skVar, skLet, skField}:
invalidPragma(c, it)
else:
sym.guard = pragmaGuard(c, it, sym.kind)
of wGoto:
if sym == nil or sym.kind notin {skVar, skLet}:
invalidPragma(c, it)
else:
sym.flags.incl sfGoto
of wExportNims:
if sym == nil: invalidPragma(c, it)
else: magicsys.registerNimScriptSymbol(c.graph, sym)
of wExperimental:
if not isTopLevel(c):
localError(c.config, n.info, "'experimental' pragma only valid as toplevel statement or in a 'push' environment")
processExperimental(c, it)
of wThis:
if it.kind in nkPragmaCallKinds and it.len == 2:
c.selfName = considerQuotedIdent(c, it[1])
message(c.config, n.info, warnDeprecated, "'.this' pragma is deprecated")
elif it.kind == nkIdent or it.len == 1:
c.selfName = getIdent(c.cache, "self")
message(c.config, n.info, warnDeprecated, "'.this' pragma is deprecated")
else:
localError(c.config, it.info, "'this' pragma is allowed to have zero or one arguments")
of wNoRewrite:
noVal(c, it)
of wBase:
noVal(c, it)
sym.flags.incl sfBase
of wIntDefine:
sym.magic = mIntDefine
of wStrDefine:
sym.magic = mStrDefine
of wBoolDefine:
sym.magic = mBoolDefine
of wUsed:
noVal(c, it)
if sym == nil: invalidPragma(c, it)
else: sym.flags.incl sfUsed
of wLiftLocals: discard
of wRequires, wInvariant, wAssume, wAssert:
pragmaProposition(c, it)
of wEnsures:
pragmaEnsures(c, it)
of wEnforceNoRaises:
sym.flags.incl sfNeverRaises
else: invalidPragma(c, it)
elif comesFromPush and whichKeyword(ident) != wInvalid:
discard "ignore the .push pragma; it doesn't apply"
else:
if sym == nil or (sym.kind in {skVar, skLet, skParam,
skField, skProc, skFunc, skConverter, skMethod, skType}):
n[i] = semCustomPragma(c, it)
elif sym != nil:
illegalCustomPragma(c, it, sym)
else:
invalidPragma(c, it)
proc overwriteLineInfo(n: PNode; info: TLineInfo) =
n.info = info
for i in 0..<n.safeLen:
overwriteLineInfo(n[i], info)
proc mergePragmas(n, pragmas: PNode) =
var pragmas = copyTree(pragmas)
overwriteLineInfo pragmas, n.info
if n[pragmasPos].kind == nkEmpty:
n[pragmasPos] = pragmas
else:
for p in pragmas: n[pragmasPos].add p
proc implicitPragmas*(c: PContext, sym: PSym, info: TLineInfo,
validPragmas: TSpecialWords) =
if sym != nil and sym.kind != skModule:
for it in c.optionStack:
let o = it.otherPragmas
if not o.isNil and sfFromGeneric notin sym.flags: # see issue #12985
pushInfoContext(c.config, info)
var i = 0
while i < o.len:
if singlePragma(c, sym, o, i, validPragmas, true, false):
internalError(c.config, info, "implicitPragmas")
inc i
popInfoContext(c.config)
if sym.kind in routineKinds and sym.ast != nil: mergePragmas(sym.ast, o)
if lfExportLib in sym.loc.flags and sfExportc notin sym.flags:
localError(c.config, info, ".dynlib requires .exportc")
var lib = c.optionStack[^1].dynlib
if {lfDynamicLib, lfHeader} * sym.loc.flags == {} and
sfImportc in sym.flags and lib != nil:
incl(sym.loc.flags, lfDynamicLib)
addToLib(lib, sym)
if sym.loc.r == nil: sym.loc.r = rope(sym.name.s)
proc hasPragma*(n: PNode, pragma: TSpecialWord): bool =
if n == nil: return false
for p in n:
var key = if p.kind in nkPragmaCallKinds and p.len > 1: p[0] else: p
if key.kind == nkIdent and whichKeyword(key.ident) == pragma:
return true
return false
proc pragmaRec(c: PContext, sym: PSym, n: PNode, validPragmas: TSpecialWords;
isStatement: bool) =
if n == nil: return
var i = 0
while i < n.len:
if singlePragma(c, sym, n, i, validPragmas, false, isStatement): break
inc i
proc pragma(c: PContext, sym: PSym, n: PNode, validPragmas: TSpecialWords;
isStatement: bool) =
if n == nil: return
pragmaRec(c, sym, n, validPragmas, isStatement)
# XXX: in the case of a callable def, this should use its info
implicitPragmas(c, sym, n.info, validPragmas)
proc pragmaCallable*(c: PContext, sym: PSym, n: PNode, validPragmas: TSpecialWords,
isStatement: bool = false) =
if n == nil: return
if n[pragmasPos].kind != nkEmpty:
pragmaRec(c, sym, n[pragmasPos], validPragmas, isStatement)