#
#
# The Nim Compiler
# (c) Copyright 2012 Andreas Rumpf
#
# See the file "copying.txt", included in this
# distribution, for details about the copyright.
#
# Algorithms for the abstract syntax tree: hash tables, lists
# and sets of nodes are supported. Efficiency is important as
# the data structures here are used in various places of the compiler.
import
ast, hashes, intsets, strutils, options, lineinfos, ropes, idents, rodutils,
msgs
proc hashNode*(p: RootRef): Hash
proc treeToYaml*(conf: ConfigRef; n: PNode, indent: int = 0, maxRecDepth: int = - 1): Rope
# Convert a tree into its YAML representation; this is used by the
# YAML code generator and it is invaluable for debugging purposes.
# If maxRecDepht <> -1 then it won't print the whole graph.
proc typeToYaml*(conf: ConfigRef; n: PType, indent: int = 0, maxRecDepth: int = - 1): Rope
proc symToYaml*(conf: ConfigRef; n: PSym, indent: int = 0, maxRecDepth: int = - 1): Rope
proc lineInfoToStr*(conf: ConfigRef; info: TLineInfo): Rope
when declared(echo):
# these are for debugging only: They are not really deprecated, but I want
# the warning so that release versions do not contain debugging statements:
proc debug*(n: PSym; conf: ConfigRef = nil) {.exportc: "debugSym", deprecated.}
proc debug*(n: PType; conf: ConfigRef = nil) {.exportc: "debugType", deprecated.}
proc debug*(n: PNode; conf: ConfigRef = nil) {.exportc: "debugNode", deprecated.}
template debug*(x: PSym|PType|PNode) {.deprecated.} =
when compiles(c.config):
debug(c.config, x)
elif compiles(c.graph.config):
debug(c.graph.config, x)
else:
error()
template debug*(x: auto) {.deprecated.} =
echo x
template mdbg*: bool {.deprecated.} =
when compiles(c.graph):
c.module.fileIdx == c.graph.config.projectMainIdx
elif compiles(c.module):
c.module.fileIdx == c.config.projectMainIdx
elif compiles(c.c.module):
c.c.module.fileIdx == c.c.config.projectMainIdx
elif compiles(m.c.module):
m.c.module.fileIdx == m.c.config.projectMainIdx
elif compiles(cl.c.module):
cl.c.module.fileIdx == cl.c.config.projectMainIdx
elif compiles(p):
when compiles(p.lex):
p.lex.fileIdx == p.lex.config.projectMainIdx
else:
p.module.module.fileIdx == p.config.projectMainIdx
elif compiles(m.module.fileIdx):
m.module.fileIdx == m.config.projectMainIdx
elif compiles(L.fileIdx):
L.fileIdx == L.config.projectMainIdx
else:
error()
# --------------------------- ident tables ----------------------------------
proc idTableGet*(t: TIdTable, key: PIdObj): RootRef
proc idTableGet*(t: TIdTable, key: int): RootRef
proc idTablePut*(t: var TIdTable, key: PIdObj, val: RootRef)
proc idTableHasObjectAsKey*(t: TIdTable, key: PIdObj): bool
# checks if `t` contains the `key` (compared by the pointer value, not only
# `key`'s id)
proc idNodeTableGet*(t: TIdNodeTable, key: PIdObj): PNode
proc idNodeTablePut*(t: var TIdNodeTable, key: PIdObj, val: PNode)
# ---------------------------------------------------------------------------
proc getSymFromList*(list: PNode, ident: PIdent, start: int = 0): PSym
proc lookupInRecord*(n: PNode, field: PIdent): PSym
proc mustRehash*(length, counter: int): bool
proc nextTry*(h, maxHash: Hash): Hash {.inline.}
# ------------- table[int, int] ---------------------------------------------
const
InvalidKey* = low(int)
type
TIIPair*{.final.} = object
key*, val*: int
TIIPairSeq* = seq[TIIPair]
TIITable*{.final.} = object # table[int, int]
counter*: int
data*: TIIPairSeq
proc initIiTable*(x: var TIITable)
proc iiTableGet*(t: TIITable, key: int): int
proc iiTablePut*(t: var TIITable, key, val: int)
# implementation
proc skipConvAndClosure*(n: PNode): PNode =
result = n
while true:
case result.kind
of nkObjUpConv, nkObjDownConv, nkChckRange, nkChckRangeF, nkChckRange64,
nkClosure:
result = result.sons[0]
of nkHiddenStdConv, nkHiddenSubConv, nkConv:
result = result.sons[1]
else: break
proc sameValue*(a, b: PNode): bool =
result = false
case a.kind
of nkCharLit..nkUInt64Lit:
if b.kind in {nkCharLit..nkUInt64Lit}: result = a.intVal == b.intVal
of nkFloatLit..nkFloat64Lit:
if b.kind in {nkFloatLit..nkFloat64Lit}: result = a.floatVal == b.floatVal
of nkStrLit..nkTripleStrLit:
if b.kind in {nkStrLit..nkTripleStrLit}: result = a.strVal == b.strVal
else:
# don't raise an internal error for 'nim check':
#InternalError(a.info, "SameValue")
discard
proc leValue*(a, b: PNode): bool =
# a <= b?
result = false
case a.kind
of nkCharLit..nkUInt32Lit:
if b.kind in {nkCharLit..nkUInt32Lit}: result = a.intVal <= b.intVal
of nkFloatLit..nkFloat64Lit:
if b.kind in {nkFloatLit..nkFloat64Lit}: result = a.floatVal <= b.floatVal
of nkStrLit..nkTripleStrLit:
if b.kind in {nkStrLit..nkTripleStrLit}: result = a.strVal <= b.strVal
else:
# don't raise an internal error for 'nim check':
#InternalError(a.info, "leValue")
discard
proc weakLeValue*(a, b: PNode): TImplication =
if a.kind notin nkLiterals or b.kind notin nkLiterals:
result = impUnknown
else:
result = if leValue(a, b): impYes else: impNo
proc lookupInRecord(n: PNode, field: PIdent): PSym =
result = nil
case n.kind
of nkRecList:
for i in 0 ..< sonsLen(n):
result = lookupInRecord(n.sons[i], field)
if result != nil: return
of nkRecCase:
if (n.sons[0].kind != nkSym): return nil
result = lookupInRecord(n.sons[0], field)
if result != nil: return
for i in 1 ..< sonsLen(n):
case n.sons[i].kind
of nkOfBranch, nkElse:
result = lookupInRecord(lastSon(n.sons[i]), field)
if result != nil: return
else: return nil
of nkSym:
if n.sym.name.id == field.id: result = n.sym
else: return nil
proc getModule*(s: PSym): PSym =
result = s
assert((result.kind == skModule) or (result.owner != result))
while result != nil and result.kind != skModule: result = result.owner
proc getSymFromList(list: PNode, ident: PIdent, start: int = 0): PSym =
for i in start ..< sonsLen(list):
if list.sons[i].kind == nkSym:
result = list.sons[i].sym
if result.name.id == ident.id: return
else: return nil
result = nil
proc hashNode(p: RootRef): Hash =
result = hash(cast[pointer](p))
proc mustRehash(length, counter: int): bool =
assert(length > counter)
result = (length * 2 < counter * 3) or (length - counter < 4)
proc rspaces(x: int): Rope =
# returns x spaces
result = rope(spaces(x))
proc toYamlChar(c: char): string =
case c
of '\0'..'\x1F', '\x7F'..'\xFF': result = "\\u" & strutils.toHex(ord(c), 4)
of '\'', '\"', '\\': result = '\\' & c
else: result = $c
proc makeYamlString*(s: string): Rope =
# We have to split long strings into many ropes. Otherwise
# this could trigger InternalError(111). See the ropes module for
# further information.
const MaxLineLength = 64
result = nil
var res = "\""
for i in 0 ..< s.len:
if (i + 1) mod MaxLineLength == 0:
add(res, '\"')
add(res, "\n")
add(result, rope(res))
res = "\"" # reset
add(res, toYamlChar(s[i]))
add(res, '\"')
add(result, rope(res))
proc flagsToStr[T](flags: set[T]): Rope =
if flags == {}:
result = rope("[]")
else:
result = nil
for x in items(flags):
if result != nil: add(result, ", ")
add(result, makeYamlString($x))
result = "[" & result & "]"
proc lineInfoToStr(conf: ConfigRef; info: TLineInfo): Rope =
result = "[$1, $2, $3]" % [makeYamlString(toFilename(conf, info)),
rope(toLinenumber(info)),
rope(toColumn(info))]
proc treeToYamlAux(conf: ConfigRef; n: PNode, marker: var IntSet,
indent, maxRecDepth: int): Rope
proc symToYamlAux(conf: ConfigRef; n: PSym, marker: var IntSet,
indent, maxRecDepth: int): Rope
proc typeToYamlAux(conf: ConfigRef; n: PType, marker: var IntSet,
indent, maxRecDepth: int): Rope
proc symToYamlAux(conf: ConfigRef; n: PSym, marker: var IntSet, indent: int,
maxRecDepth: int): Rope =
if n == nil:
result = rope("null")
elif containsOrIncl(marker, n.id):
result = "\"$1\"" % [rope(n.name.s)]
else:
var ast = treeToYamlAux(conf, n.ast, marker, indent + 2, maxRecDepth - 1)
#rope("typ"), typeToYamlAux(conf, n.typ, marker,
# indent + 2, maxRecDepth - 1),
let istr = rspaces(indent + 2)
result = rope("{")
addf(result, "$N$1\"kind\": $2", [istr, makeYamlString($n.kind)])
addf(result, "$N$1\"name\": $2", [istr, makeYamlString(n.name.s)])
addf(result, "$N$1\"typ\": $2", [istr, typeToYamlAux(conf, n.typ, marker, indent + 2, maxRecDepth - 1)])
if conf != nil:
# if we don't pass the config, we probably don't care about the line info
addf(result, "$N$1\"info\": $2", [istr, lineInfoToStr(conf, n.info)])
if card(n.flags) > 0:
addf(result, "$N$1\"flags\": $2", [istr, flagsToStr(n.flags)])
addf(result, "$N$1\"magic\": $2", [istr, makeYamlString($n.magic)])
addf(result, "$N$1\"ast\": $2", [istr, ast])
addf(result, "$N$1\"options\": $2", [istr, flagsToStr(n.options)])
addf(result, "$N$1\"position\": $2", [istr, rope(n.position)])
addf(result, "$N$1\"k\": $2", [istr, makeYamlString($n.loc.k)])
addf(result, "$N$1\"storage\": $2", [istr, makeYamlString($n.loc.storage)])
if card(n.loc.flags) > 0:
addf(result, "$N$1\"flags\": $2", [istr, makeYamlString($n.loc.flags)])
addf(result, "$N$1\"r\": $2", [istr, n.loc.r])
addf(result, "$N$1\"lode\": $2", [istr, treeToYamlAux(conf, n.loc.lode, marker, indent + 2, maxRecDepth - 1)])
addf(result, "$N$1}", [rspaces(indent)])
proc typeToYamlAux(conf: ConfigRef; n: PType, marker: var IntSet, indent: int,
maxRecDepth: int): Rope =
var sonsRope: Rope
if n == nil:
sonsRope = rope("null")
elif containsOrIncl(marker, n.id):
sonsRope = "\"$1 @$2\"" % [rope($n.kind), rope(
strutils.toHex(cast[ByteAddress](n), sizeof(n) * 2))]
else:
if sonsLen(n) > 0:
sonsRope = rope("[")
for i in 0 ..< sonsLen(n):
if i > 0: add(sonsRope, ",")
addf(sonsRope, "$N$1$2", [rspaces(indent + 4), typeToYamlAux(conf, n.sons[i],
marker, indent + 4, maxRecDepth - 1)])
addf(sonsRope, "$N$1]", [rspaces(indent + 2)])
else:
sonsRope = rope("null")
let istr = rspaces(indent + 2)
result = rope("{")
addf(result, "$N$1\"kind\": $2", [istr, makeYamlString($n.kind)])
addf(result, "$N$1\"sym\": $2", [istr, symToYamlAux(conf, n.sym, marker, indent + 2, maxRecDepth - 1)])
addf(result, "$N$1\"n\": $2", [istr, treeToYamlAux(conf, n.n, marker, indent + 2, maxRecDepth - 1)])
if card(n.flags) > 0:
addf(result, "$N$1\"flags\": $2", [istr, flagsToStr(n.flags)])
addf(result, "$N$1\"callconv\": $2", [istr, makeYamlString(CallingConvToStr[n.callConv])])
addf(result, "$N$1\"size\": $2", [istr, rope(n.size)])
addf(result, "$N$1\"align\": $2", [istr, rope(n.align)])
addf(result, "$N$1\"sons\": $2", [istr, sonsRope])
proc treeToYamlAux(conf: ConfigRef; n: PNode, marker: var IntSet, indent: int,
maxRecDepth: int): Rope =
if n == nil:
result = rope("null")
else:
var istr = rspaces(indent + 2)
result = "{$N$1\"kind\": $2" % [istr, makeYamlString($n.kind)]
if maxRecDepth != 0:
if conf != nil:
addf(result, ",$N$1\"info\": $2", [istr, lineInfoToStr(conf, n.info)])
case n.kind
of nkCharLit..nkInt64Lit:
addf(result, ",$N$1\"intVal\": $2", [istr, rope(n.intVal)])
of nkFloatLit, nkFloat32Lit, nkFloat64Lit:
addf(result, ",$N$1\"floatVal\": $2",
[istr, rope(n.floatVal.toStrMaxPrecision)])
of nkStrLit..nkTripleStrLit:
addf(result, ",$N$1\"strVal\": $2", [istr, makeYamlString(n.strVal)])
of nkSym:
addf(result, ",$N$1\"sym\": $2",
[istr, symToYamlAux(conf, n.sym, marker, indent + 2, maxRecDepth)])
of nkIdent:
if n.ident != nil:
addf(result, ",$N$1\"ident\": $2", [istr, makeYamlString(n.ident.s)])
else:
addf(result, ",$N$1\"ident\": null", [istr])
else:
if sonsLen(n) > 0:
addf(result, ",$N$1\"sons\": [", [istr])
for i in 0 ..< sonsLen(n):
if i > 0: add(result, ",")
addf(result, "$N$1$2", [rspaces(indent + 4), treeToYamlAux(conf, n.sons[i],
marker, indent + 4, maxRecDepth - 1)])
addf(result, "$N$1]", [istr])
addf(result, ",$N$1\"typ\": $2",
[istr, typeToYamlAux(conf, n.typ, marker, indent + 2, maxRecDepth)])
addf(result, "$N$1}", [rspaces(indent)])
proc treeToYaml(conf: ConfigRef; n: PNode, indent: int = 0, maxRecDepth: int = - 1): Rope =
var marker = initIntSet()
result = treeToYamlAux(conf, n, marker, indent, maxRecDepth)
proc typeToYaml(conf: ConfigRef; n: PType, indent: int = 0, maxRecDepth: int = - 1): Rope =
var marker = initIntSet()
result = typeToYamlAux(conf, n, marker, indent, maxRecDepth)
proc symToYaml(conf: ConfigRef; n: PSym, indent: int = 0, maxRecDepth: int = - 1): Rope =
var marker = initIntSet()
result = symToYamlAux(conf, n, marker, indent, maxRecDepth)
import tables
const backrefStyle = "\e[90m"
const enumStyle = "\e[34m"
const numberStyle = "\e[33m"
const stringStyle = "\e[32m"
const resetStyle = "\e[0m"
type
DebugPrinter = object
conf: ConfigRef
visited: Table[pointer, int]
renderSymType: bool
indent: int
currentLine: int
firstItem: bool
useColor: bool
res: string
proc indentMore(this: var DebugPrinter) =
this.indent += 2
proc indentLess(this: var DebugPrinter) =
this.indent -= 2
proc newlineAndIndent(this: var DebugPrinter) =
this.res.add "\n"
this.currentLine += 1
for i in 0 ..< this.indent:
this.res.add ' '
proc openCurly(this: var DebugPrinter) =
this.res.add "{"
this.indentMore
this.firstItem = true
proc closeCurly(this: var DebugPrinter) =
this.indentLess
this.newlineAndIndent
this.res.add "}"
proc comma(this: var DebugPrinter) =
this.res.add ", "
proc openBracket(this: var DebugPrinter) =
this.res.add "["
#this.indentMore
proc closeBracket(this: var DebugPrinter) =
#this.indentLess
this.res.add "]"
proc key(this: var DebugPrinter; key: string) =
if not this.firstItem:
this.res.add ","
this.firstItem = false
this.newlineAndIndent
this.res.add "\""
this.res.add key
this.res.add "\": "
proc value(this: var DebugPrinter; value: string) =
if this.useColor:
this.res.add stringStyle
this.res.add "\""
this.res.add value
this.res.add "\""
if this.useColor:
this.res.add resetStyle
proc value(this: var DebugPrinter; value: BiggestInt) =
if this.useColor:
this.res.add numberStyle
this.res.addInt value
if this.useColor:
this.res.add resetStyle
proc value[T: enum](this: var DebugPrinter; value: T) =
if this.useColor:
this.res.add enumStyle
this.res.add "\""
this.res.add $value
this.res.add "\""
if this.useColor:
this.res.add resetStyle
proc value[T: enum](this: var DebugPrinter; value: set[T]) =
this.openBracket
let high = card(value)-1
var i = 0
for v in value:
this.value v
if i != high:
this.comma
inc i
this.closeBracket
template earlyExit(this: var DebugPrinter; n: PType | PNode | PSym) =
if n == nil:
this.res.add "null"
return
let index = this.visited.getOrDefault(cast[pointer](n), -1)
if index < 0:
this.visited[cast[pointer](n)] = this.currentLine
else:
if this.useColor:
this.res.add backrefStyle
this.res.add "<defined "
this.res.addInt(this.currentLine - index)
this.res.add " lines upwards>"
if this.useColor:
this.res.add resetStyle
return
proc value(this: var DebugPrinter; value: PType)
proc value(this: var DebugPrinter; value: PNode)
proc value(this: var DebugPrinter; value: PSym) =
earlyExit(this, value)
this.openCurly
this.key("kind")
this.value(value.kind)
this.key("name")
this.value(value.name.s)
this.key("id")
this.value(value.id)
if value.kind in {skField, skEnumField, skParam}:
this.key("position")
this.value(value.position)
if card(value.flags) > 0:
this.key("flags")
this.value(value.flags)
if this.renderSymType and value.typ != nil:
this.key "typ"
this.value(value.typ)
this.closeCurly
proc value(this: var DebugPrinter; value: PType) =
earlyExit(this, value)
this.openCurly
this.key "kind"
this.value value.kind
this.key "id"
this.value value.id
if value.sym != nil:
this.key "sym"
this.value value.sym
#this.value value.sym.name.s
if card(value.flags) > 0:
this.key "flags"
this.value value.flags
if value.kind in IntegralTypes and value.n != nil:
this.key "n"
this.value value.n
if sonsLen(value) > 0:
this.key "sons"
this.openBracket
for i in 0 ..< sonsLen(value):
this.value value.sons[i]
if i != sonsLen(value) - 1:
this.comma
this.closeBracket
if value.n != nil:
this.key "n"
this.value value.n
this.closeCurly
proc value(this: var DebugPrinter; value: PNode) =
earlyExit(this, value)
this.openCurly
this.key "kind"
this.value value.kind
when defined(useNodeIds):
this.key "id"
this.value value.id
if this.conf != nil:
this.key "info"
this.value $lineInfoToStr(this.conf, value.info)
if card(value.flags) > 0:
this.key "flags"
this.value value.flags
case value.kind
of nkCharLit..nkUInt64Lit:
this.key "intVal"
this.value value.intVal
of nkFloatLit, nkFloat32Lit, nkFloat64Lit:
this.key "floatVal"
this.value value.floatVal.toStrMaxPrecision
of nkStrLit..nkTripleStrLit:
this.key "strVal"
this.value value.strVal
of nkSym:
this.key "sym"
this.value value.sym
#this.value value.sym.name.s
of nkIdent:
if value.ident != nil:
this.key "ident"
this.value value.ident.s
else:
if this.renderSymType and value.typ != nil:
this.key "typ"
this.value value.typ
if sonsLen(value) > 0:
this.key "sons"
this.openBracket
for i in 0 ..< sonsLen(value):
this.value value.sons[i]
if i != sonsLen(value) - 1:
this.comma
this.closeBracket
this.closeCurly
when declared(echo):
proc debug(n: PSym; conf: ConfigRef) =
var this: DebugPrinter
this.visited = initTable[pointer, int]()
this.renderSymType = true
this.useColor = not defined(windows)
this.value(n)
echo($this.res)
proc debug(n: PType; conf: ConfigRef) =
var this: DebugPrinter
this.visited = initTable[pointer, int]()
this.renderSymType = true
this.useColor = not defined(windows)
this.value(n)
echo($this.res)
proc debug(n: PNode; conf: ConfigRef) =
var this: DebugPrinter
this.visited = initTable[pointer, int]()
#this.renderSymType = true
this.useColor = not defined(windows)
this.value(n)
echo($this.res)
proc nextTry(h, maxHash: Hash): Hash =
result = ((5 * h) + 1) and maxHash
# For any initial h in range(maxHash), repeating that maxHash times
# generates each int in range(maxHash) exactly once (see any text on
# random-number generation for proof).
proc objectSetContains*(t: TObjectSet, obj: RootRef): bool =
# returns true whether n is in t
var h: Hash = hashNode(obj) and high(t.data) # start with real hash value
while t.data[h] != nil:
if t.data[h] == obj:
return true
h = nextTry(h, high(t.data))
result = false
proc objectSetRawInsert(data: var TObjectSeq, obj: RootRef) =
var h: Hash = hashNode(obj) and high(data)
while data[h] != nil:
assert(data[h] != obj)
h = nextTry(h, high(data))
assert(data[h] == nil)
data[h] = obj
proc objectSetEnlarge(t: var TObjectSet) =
var n: TObjectSeq
newSeq(n, len(t.data) * GrowthFactor)
for i in 0 .. high(t.data):
if t.data[i] != nil: objectSetRawInsert(n, t.data[i])
swap(t.data, n)
proc objectSetIncl*(t: var TObjectSet, obj: RootRef) =
if mustRehash(len(t.data), t.counter): objectSetEnlarge(t)
objectSetRawInsert(t.data, obj)
inc(t.counter)
proc objectSetContainsOrIncl*(t: var TObjectSet, obj: RootRef): bool =
# returns true if obj is already in the string table:
var h: Hash = hashNode(obj) and high(t.data)
while true:
var it = t.data[h]
if it == nil: break
if it == obj:
return true # found it
h = nextTry(h, high(t.data))
if mustRehash(len(t.data), t.counter):
objectSetEnlarge(t)
objectSetRawInsert(t.data, obj)
else:
assert(t.data[h] == nil)
t.data[h] = obj
inc(t.counter)
result = false
proc strTableContains*(t: TStrTable, n: PSym): bool =
var h: Hash = n.name.h and high(t.data) # start with real hash value
while t.data[h] != nil:
if (t.data[h] == n):
return true
h = nextTry(h, high(t.data))
result = false
proc strTableRawInsert(data: var seq[PSym], n: PSym) =
var h: Hash = n.name.h and high(data)
while data[h] != nil:
if data[h] == n:
# allowed for 'export' feature:
#InternalError(n.info, "StrTableRawInsert: " & n.name.s)
return
h = nextTry(h, high(data))
assert(data[h] == nil)
data[h] = n
proc symTabReplaceRaw(data: var seq[PSym], prevSym: PSym, newSym: PSym) =
assert prevSym.name.h == newSym.name.h
var h: Hash = prevSym.name.h and high(data)
while data[h] != nil:
if data[h] == prevSym:
data[h] = newSym
return
h = nextTry(h, high(data))
assert false
proc symTabReplace*(t: var TStrTable, prevSym: PSym, newSym: PSym) =
symTabReplaceRaw(t.data, prevSym, newSym)
proc strTableEnlarge(t: var TStrTable) =
var n: seq[PSym]
newSeq(n, len(t.data) * GrowthFactor)
for i in 0 .. high(t.data):
if t.data[i] != nil: strTableRawInsert(n, t.data[i])
swap(t.data, n)
proc strTableAdd*(t: var TStrTable, n: PSym) =
if mustRehash(len(t.data), t.counter): strTableEnlarge(t)
strTableRawInsert(t.data, n)
inc(t.counter)
proc strTableInclReportConflict*(t: var TStrTable, n: PSym;
onConflictKeepOld = false): PSym =
# returns true if n is already in the string table:
# It is essential that `n` is written nevertheless!
# This way the newest redefinition is picked by the semantic analyses!
assert n.name != nil
var h: Hash = n.name.h and high(t.data)
var replaceSlot = -1
while true:
var it = t.data[h]
if it == nil: break
# Semantic checking can happen multiple times thanks to templates
# and overloading: (var x=@[]; x).mapIt(it).
# So it is possible the very same sym is added multiple
# times to the symbol table which we allow here with the 'it == n' check.
if it.name.id == n.name.id:
if it == n: return nil
replaceSlot = h
h = nextTry(h, high(t.data))
if replaceSlot >= 0:
if not onConflictKeepOld:
t.data[replaceSlot] = n # overwrite it with newer definition!
return t.data[replaceSlot] # found it
elif mustRehash(len(t.data), t.counter):
strTableEnlarge(t)
strTableRawInsert(t.data, n)
else:
assert(t.data[h] == nil)
t.data[h] = n
inc(t.counter)
result = nil
proc strTableIncl*(t: var TStrTable, n: PSym;
onConflictKeepOld = false): bool {.discardable.} =
result = strTableInclReportConflict(t, n, onConflictKeepOld) != nil
proc strTableGet*(t: TStrTable, name: PIdent): PSym =
var h: Hash = name.h and high(t.data)
while true:
result = t.data[h]
if result == nil: break
if result.name.id == name.id: break
h = nextTry(h, high(t.data))
type
TIdentIter* = object # iterator over all syms with same identifier
h*: Hash # current hash
name*: PIdent
proc nextIdentIter*(ti: var TIdentIter, tab: TStrTable): PSym =
var h = ti.h and high(tab.data)
var start = h
result = tab.data[h]
while result != nil:
if result.name.id == ti.name.id: break
h = nextTry(h, high(tab.data))
if h == start:
result = nil
break
result = tab.data[h]
ti.h = nextTry(h, high(tab.data))
proc initIdentIter*(ti: var TIdentIter, tab: TStrTable, s: PIdent): PSym =
ti.h = s.h
ti.name = s
if tab.counter == 0: result = nil
else: result = nextIdentIter(ti, tab)
proc nextIdentExcluding*(ti: var TIdentIter, tab: TStrTable,
excluding: IntSet): PSym =
var h: Hash = ti.h and high(tab.data)
var start = h
result = tab.data[h]
while result != nil:
if result.name.id == ti.name.id and not contains(excluding, result.id):
break
h = nextTry(h, high(tab.data))
if h == start:
result = nil
break
result = tab.data[h]
ti.h = nextTry(h, high(tab.data))
if result != nil and contains(excluding, result.id): result = nil
proc firstIdentExcluding*(ti: var TIdentIter, tab: TStrTable, s: PIdent,
excluding: IntSet): PSym =
ti.h = s.h
ti.name = s
if tab.counter == 0: result = nil
else: result = nextIdentExcluding(ti, tab, excluding)
type
TTabIter* = object
h: Hash
proc nextIter*(ti: var TTabIter, tab: TStrTable): PSym =
# usage:
# var
# i: TTabIter
# s: PSym
# s = InitTabIter(i, table)
# while s != nil:
# ...
# s = NextIter(i, table)
#
result = nil
while (ti.h <= high(tab.data)):
result = tab.data[ti.h]
inc(ti.h) # ... and increment by one always
if result != nil: break
proc initTabIter*(ti: var TTabIter, tab: TStrTable): PSym =
ti.h = 0
if tab.counter == 0:
result = nil
else:
result = nextIter(ti, tab)
iterator items*(tab: TStrTable): PSym =
var it: TTabIter
var s = initTabIter(it, tab)
while s != nil:
yield s
s = nextIter(it, tab)
proc hasEmptySlot(data: TIdPairSeq): bool =
for h in 0 .. high(data):
if data[h].key == nil:
return true
result = false
proc idTableRawGet(t: TIdTable, key: int): int =
var h: Hash
h = key and high(t.data) # start with real hash value
while t.data[h].key != nil:
if t.data[h].key.id == key:
return h
h = nextTry(h, high(t.data))
result = - 1
proc idTableHasObjectAsKey(t: TIdTable, key: PIdObj): bool =
var index = idTableRawGet(t, key.id)
if index >= 0: result = t.data[index].key == key
else: result = false
proc idTableGet(t: TIdTable, key: PIdObj): RootRef =
var index = idTableRawGet(t, key.id)
if index >= 0: result = t.data[index].val
else: result = nil
proc idTableGet(t: TIdTable, key: int): RootRef =
var index = idTableRawGet(t, key)
if index >= 0: result = t.data[index].val
else: result = nil
iterator pairs*(t: TIdTable): tuple[key: int, value: RootRef] =
for i in 0..high(t.data):
if t.data[i].key != nil:
yield (t.data[i].key.id, t.data[i].val)
proc idTableRawInsert(data: var TIdPairSeq, key: PIdObj, val: RootRef) =
var h: Hash
h = key.id and high(data)
while data[h].key != nil:
assert(data[h].key.id != key.id)
h = nextTry(h, high(data))
assert(data[h].key == nil)
data[h].key = key
data[h].val = val
proc idTablePut(t: var TIdTable, key: PIdObj, val: RootRef) =
var
index: int
n: TIdPairSeq
index = idTableRawGet(t, key.id)
if index >= 0:
assert(t.data[index].key != nil)
t.data[index].val = val
else:
if mustRehash(len(t.data), t.counter):
newSeq(n, len(t.data) * GrowthFactor)
for i in 0 .. high(t.data):
if t.data[i].key != nil:
idTableRawInsert(n, t.data[i].key, t.data[i].val)
assert(hasEmptySlot(n))
swap(t.data, n)
idTableRawInsert(t.data, key, val)
inc(t.counter)
iterator idTablePairs*(t: TIdTable): tuple[key: PIdObj, val: RootRef] =
for i in 0 .. high(t.data):
if not isNil(t.data[i].key): yield (t.data[i].key, t.data[i].val)
proc idNodeTableRawGet(t: TIdNodeTable, key: PIdObj): int =
var h: Hash
h = key.id and high(t.data) # start with real hash value
while t.data[h].key != nil:
if t.data[h].key.id == key.id:
return h
h = nextTry(h, high(t.data))
result = - 1
proc idNodeTableGet(t: TIdNodeTable, key: PIdObj): PNode =
var index: int
index = idNodeTableRawGet(t, key)
if index >= 0: result = t.data[index].val
else: result = nil
proc idNodeTableRawInsert(data: var TIdNodePairSeq, key: PIdObj, val: PNode) =
var h: Hash
h = key.id and high(data)
while data[h].key != nil:
assert(data[h].key.id != key.id)
h = nextTry(h, high(data))
assert(data[h].key == nil)
data[h].key = key
data[h].val = val
proc idNodeTablePut(t: var TIdNodeTable, key: PIdObj, val: PNode) =
var index = idNodeTableRawGet(t, key)
if index >= 0:
assert(t.data[index].key != nil)
t.data[index].val = val
else:
if mustRehash(len(t.data), t.counter):
var n: TIdNodePairSeq
newSeq(n, len(t.data) * GrowthFactor)
for i in 0 .. high(t.data):
if t.data[i].key != nil:
idNodeTableRawInsert(n, t.data[i].key, t.data[i].val)
swap(t.data, n)
idNodeTableRawInsert(t.data, key, val)
inc(t.counter)
iterator pairs*(t: TIdNodeTable): tuple[key: PIdObj, val: PNode] =
for i in 0 .. high(t.data):
if not isNil(t.data[i].key): yield (t.data[i].key, t.data[i].val)
proc initIITable(x: var TIITable) =
x.counter = 0
newSeq(x.data, StartSize)
for i in 0 ..< StartSize: x.data[i].key = InvalidKey
proc iiTableRawGet(t: TIITable, key: int): int =
var h: Hash
h = key and high(t.data) # start with real hash value
while t.data[h].key != InvalidKey:
if t.data[h].key == key: return h
h = nextTry(h, high(t.data))
result = -1
proc iiTableGet(t: TIITable, key: int): int =
var index = iiTableRawGet(t, key)
if index >= 0: result = t.data[index].val
else: result = InvalidKey
proc iiTableRawInsert(data: var TIIPairSeq, key, val: int) =
var h: Hash
h = key and high(data)
while data[h].key != InvalidKey:
assert(data[h].key != key)
h = nextTry(h, high(data))
assert(data[h].key == InvalidKey)
data[h].key = key
data[h].val = val
proc iiTablePut(t: var TIITable, key, val: int) =
var index = iiTableRawGet(t, key)
if index >= 0:
assert(t.data[index].key != InvalidKey)
t.data[index].val = val
else:
if mustRehash(len(t.data), t.counter):
var n: TIIPairSeq
newSeq(n, len(t.data) * GrowthFactor)
for i in 0 .. high(n): n[i].key = InvalidKey
for i in 0 .. high(t.data):
if t.data[i].key != InvalidKey:
iiTableRawInsert(n, t.data[i].key, t.data[i].val)
swap(t.data, n)
iiTableRawInsert(t.data, key, val)
inc(t.counter)
proc isAddrNode*(n: PNode): bool =
case n.kind
of nkAddr, nkHiddenAddr: true
of nkCallKinds:
if n[0].kind == nkSym and n[0].sym.magic == mAddr: true
else: false
else: false