Retro68/gcc/libphobos/libdruntime/core/demangle.d
Wolfgang Thaller 6fbf4226da gcc-9.1
2019-06-20 20:10:10 +02:00

2631 lines
75 KiB
D

/**
* The demangle module converts mangled D symbols to a representation similar
* to what would have existed in code.
*
* Copyright: Copyright Sean Kelly 2010 - 2014.
* License: Distributed under the
* $(LINK2 http://www.boost.org/LICENSE_1_0.txt, Boost Software License 1.0).
* (See accompanying file LICENSE)
* Authors: Sean Kelly
* Source: $(DRUNTIMESRC core/_demangle.d)
*/
module core.demangle;
version (OSX)
version = Darwin;
else version (iOS)
version = Darwin;
else version (TVOS)
version = Darwin;
else version (WatchOS)
version = Darwin;
debug(trace) import core.stdc.stdio : printf;
debug(info) import core.stdc.stdio : printf;
private struct NoHooks
{
// supported hooks
// static bool parseLName(ref Demangle);
// static char[] parseType(ref Demangle, char[])
}
private struct Demangle(Hooks = NoHooks)
{
// NOTE: This implementation currently only works with mangled function
// names as they exist in an object file. Type names mangled via
// the .mangleof property are effectively incomplete as far as the
// ABI is concerned and so are not considered to be mangled symbol
// names.
// NOTE: This implementation builds the demangled buffer in place by
// writing data as it is decoded and then rearranging it later as
// needed. In practice this results in very little data movement,
// and the performance cost is more than offset by the gain from
// not allocating dynamic memory to assemble the name piecemeal.
//
// If the destination buffer is too small, parsing will restart
// with a larger buffer. Since this generally means only one
// allocation during the course of a parsing run, this is still
// faster than assembling the result piecemeal.
pure @safe:
enum AddType { no, yes }
this( const(char)[] buf_, char[] dst_ = null )
{
this( buf_, AddType.yes, dst_ );
}
this( const(char)[] buf_, AddType addType_, char[] dst_ = null )
{
buf = buf_;
addType = addType_;
dst = dst_;
}
enum size_t minBufSize = 4000;
const(char)[] buf = null;
char[] dst = null;
size_t pos = 0;
size_t len = 0;
size_t brp = 0; // current back reference pos
AddType addType = AddType.yes;
bool mute = false;
Hooks hooks;
static class ParseException : Exception
{
@safe pure nothrow this( string msg )
{
super( msg );
}
}
static class OverflowException : Exception
{
@safe pure nothrow this( string msg )
{
super( msg );
}
}
static void error( string msg = "Invalid symbol" ) @trusted /* exception only used in module */
{
pragma(inline, false); // tame dmd inliner
//throw new ParseException( msg );
debug(info) printf( "error: %.*s\n", cast(int) msg.length, msg.ptr );
throw __ctfe ? new ParseException(msg)
: cast(ParseException) cast(void*) typeid(ParseException).initializer;
}
static void overflow( string msg = "Buffer overflow" ) @trusted /* exception only used in module */
{
pragma(inline, false); // tame dmd inliner
//throw new OverflowException( msg );
debug(info) printf( "overflow: %.*s\n", cast(int) msg.length, msg.ptr );
throw cast(OverflowException) cast(void*) typeid(OverflowException).initializer;
}
//////////////////////////////////////////////////////////////////////////
// Type Testing and Conversion
//////////////////////////////////////////////////////////////////////////
static bool isAlpha( char val )
{
return ('a' <= val && 'z' >= val) ||
('A' <= val && 'Z' >= val) ||
(0x80 & val); // treat all unicode as alphabetic
}
static bool isDigit( char val )
{
return '0' <= val && '9' >= val;
}
static bool isHexDigit( char val )
{
return ('0' <= val && '9' >= val) ||
('a' <= val && 'f' >= val) ||
('A' <= val && 'F' >= val);
}
static ubyte ascii2hex( char val )
{
if (val >= 'a' && val <= 'f')
return cast(ubyte)(val - 'a' + 10);
if (val >= 'A' && val <= 'F')
return cast(ubyte)(val - 'A' + 10);
if (val >= '0' && val <= '9')
return cast(ubyte)(val - '0');
error();
return 0;
}
//////////////////////////////////////////////////////////////////////////
// Data Output
//////////////////////////////////////////////////////////////////////////
static bool contains( const(char)[] a, const(char)[] b ) @trusted
{
if (a.length && b.length)
{
auto bend = b.ptr + b.length;
auto aend = a.ptr + a.length;
return a.ptr <= b.ptr && bend <= aend;
}
return false;
}
// move val to the end of the dst buffer
char[] shift( const(char)[] val )
{
pragma(inline, false); // tame dmd inliner
if ( val.length && !mute )
{
assert( contains( dst[0 .. len], val ) );
debug(info) printf( "shifting (%.*s)\n", cast(int) val.length, val.ptr );
if (len + val.length > dst.length)
overflow();
size_t v = &val[0] - &dst[0];
dst[len .. len + val.length] = val[];
for (size_t p = v; p < len; p++)
dst[p] = dst[p + val.length];
return dst[len - val.length .. len];
}
return null;
}
// remove val from dst buffer
void remove( const(char)[] val )
{
pragma(inline, false); // tame dmd inliner
if ( val.length )
{
assert( contains( dst[0 .. len], val ) );
debug(info) printf( "removing (%.*s)\n", cast(int) val.length, val.ptr );
size_t v = &val[0] - &dst[0];
for (size_t p = v; p < len; p++)
dst[p] = dst[p + val.length];
len -= val.length;
}
}
char[] append( const(char)[] val )
{
pragma(inline, false); // tame dmd inliner
if ( val.length && !mute )
{
if ( !dst.length )
dst.length = minBufSize;
assert( !contains( dst[0 .. len], val ) );
debug(info) printf( "appending (%.*s)\n", cast(int) val.length, val.ptr );
if ( &dst[len] == &val[0] &&
dst.length - len >= val.length )
{
// data is already in place
auto t = dst[len .. len + val.length];
len += val.length;
return t;
}
if ( dst.length - len >= val.length )
{
dst[len .. len + val.length] = val[];
auto t = dst[len .. len + val.length];
len += val.length;
return t;
}
overflow();
}
return null;
}
void putComma(size_t n)
{
pragma(inline, false);
if (n)
put(", ");
}
char[] put(char c)
{
char[1] val = c;
return put(val[]);
}
char[] put( const(char)[] val )
{
pragma(inline, false); // tame dmd inliner
if ( val.length )
{
if ( !contains( dst[0 .. len], val ) )
return append( val );
return shift( val );
}
return null;
}
void putAsHex( size_t val, int width = 0 )
{
import core.internal.string;
UnsignedStringBuf buf;
auto s = unsignedToTempString(val, buf, 16);
int slen = cast(int)s.length;
if (slen < width)
{
foreach (i; slen .. width)
put('0');
}
put(s);
}
void pad( const(char)[] val )
{
if ( val.length )
{
append( " " );
put( val );
}
}
void silent( lazy void dg )
{
debug(trace) printf( "silent+\n" );
debug(trace) scope(success) printf( "silent-\n" );
auto n = len; dg(); len = n;
}
//////////////////////////////////////////////////////////////////////////
// Parsing Utility
//////////////////////////////////////////////////////////////////////////
@property bool empty()
{
return pos >= buf.length;
}
@property char front()
{
if ( pos < buf.length )
return buf[pos];
return char.init;
}
char peek( size_t n )
{
if ( pos + n < buf.length )
return buf[pos + n];
return char.init;
}
void test( char val )
{
if ( val != front )
error();
}
void popFront()
{
if ( pos++ >= buf.length )
error();
}
void match( char val )
{
test( val );
popFront();
}
void match( const(char)[] val )
{
foreach (char e; val )
{
test( e );
popFront();
}
}
void eat( char val )
{
if ( val == front )
popFront();
}
bool isSymbolNameFront()
{
char val = front;
if ( isDigit( val ) || val == '_' )
return true;
if ( val != 'Q' )
return false;
// check the back reference encoding after 'Q'
val = peekBackref();
return isDigit( val ); // identifier ref
}
// return the first character at the back reference
char peekBackref()
{
assert( front == 'Q' );
auto n = decodeBackref!1();
if (!n || n > pos)
error("invalid back reference");
return buf[pos - n];
}
size_t decodeBackref(size_t peekAt = 0)()
{
enum base = 26;
size_t n = 0;
for (size_t p; ; p++)
{
char t;
static if (peekAt > 0)
{
t = peek(peekAt + p);
}
else
{
t = front;
popFront();
}
if (t < 'A' || t > 'Z')
{
if (t < 'a' || t > 'z')
error("invalid back reference");
n = base * n + t - 'a';
return n;
}
n = base * n + t - 'A';
}
}
//////////////////////////////////////////////////////////////////////////
// Parsing Implementation
//////////////////////////////////////////////////////////////////////////
/*
Number:
Digit
Digit Number
*/
const(char)[] sliceNumber()
{
debug(trace) printf( "sliceNumber+\n" );
debug(trace) scope(success) printf( "sliceNumber-\n" );
auto beg = pos;
while ( true )
{
auto t = front;
if (t >= '0' && t <= '9')
popFront();
else
return buf[beg .. pos];
}
}
size_t decodeNumber()
{
debug(trace) printf( "decodeNumber+\n" );
debug(trace) scope(success) printf( "decodeNumber-\n" );
return decodeNumber( sliceNumber() );
}
size_t decodeNumber( const(char)[] num )
{
debug(trace) printf( "decodeNumber+\n" );
debug(trace) scope(success) printf( "decodeNumber-\n" );
size_t val = 0;
foreach ( c; num )
{
import core.checkedint : mulu, addu;
bool overflow = false;
val = mulu(val, 10, overflow);
val = addu(val, c - '0', overflow);
if (overflow)
error();
}
return val;
}
void parseReal()
{
debug(trace) printf( "parseReal+\n" );
debug(trace) scope(success) printf( "parseReal-\n" );
char[64] tbuf = void;
size_t tlen = 0;
real val = void;
if ( 'I' == front )
{
match( "INF" );
put( "real.infinity" );
return;
}
if ( 'N' == front )
{
popFront();
if ( 'I' == front )
{
match( "INF" );
put( "-real.infinity" );
return;
}
if ( 'A' == front )
{
match( "AN" );
put( "real.nan" );
return;
}
tbuf[tlen++] = '-';
}
tbuf[tlen++] = '0';
tbuf[tlen++] = 'X';
if ( !isHexDigit( front ) )
error( "Expected hex digit" );
tbuf[tlen++] = front;
tbuf[tlen++] = '.';
popFront();
while ( isHexDigit( front ) )
{
tbuf[tlen++] = front;
popFront();
}
match( 'P' );
tbuf[tlen++] = 'p';
if ( 'N' == front )
{
tbuf[tlen++] = '-';
popFront();
}
else
{
tbuf[tlen++] = '+';
}
while ( isDigit( front ) )
{
tbuf[tlen++] = front;
popFront();
}
tbuf[tlen] = 0;
debug(info) printf( "got (%s)\n", tbuf.ptr );
pureReprintReal( tbuf[] );
debug(info) printf( "converted (%.*s)\n", cast(int) tlen, tbuf.ptr );
put( tbuf[0 .. tlen] );
}
/*
LName:
Number Name
Name:
Namestart
Namestart Namechars
Namestart:
_
Alpha
Namechar:
Namestart
Digit
Namechars:
Namechar
Namechar Namechars
*/
void parseLName()
{
debug(trace) printf( "parseLName+\n" );
debug(trace) scope(success) printf( "parseLName-\n" );
static if (__traits(hasMember, Hooks, "parseLName"))
if (hooks.parseLName(this))
return;
if ( front == 'Q' )
{
// back reference to LName
auto refPos = pos;
popFront();
size_t n = decodeBackref();
if ( !n || n > refPos )
error( "Invalid LName back reference" );
if ( !mute )
{
auto savePos = pos;
scope(exit) pos = savePos;
pos = refPos - n;
parseLName();
}
return;
}
auto n = decodeNumber();
if ( n == 0 )
{
put( "__anonymous" );
return;
}
if ( n > buf.length || n > buf.length - pos )
error( "LName must be at least 1 character" );
if ( '_' != front && !isAlpha( front ) )
error( "Invalid character in LName" );
foreach (char e; buf[pos + 1 .. pos + n] )
{
if ( '_' != e && !isAlpha( e ) && !isDigit( e ) )
error( "Invalid character in LName" );
}
put( buf[pos .. pos + n] );
pos += n;
}
/*
Type:
Shared
Const
Immutable
Wild
TypeArray
TypeVector
TypeStaticArray
TypeAssocArray
TypePointer
TypeFunction
TypeIdent
TypeClass
TypeStruct
TypeEnum
TypeTypedef
TypeDelegate
TypeNone
TypeVoid
TypeByte
TypeUbyte
TypeShort
TypeUshort
TypeInt
TypeUint
TypeLong
TypeUlong
TypeCent
TypeUcent
TypeFloat
TypeDouble
TypeReal
TypeIfloat
TypeIdouble
TypeIreal
TypeCfloat
TypeCdouble
TypeCreal
TypeBool
TypeChar
TypeWchar
TypeDchar
TypeTuple
Shared:
O Type
Const:
x Type
Immutable:
y Type
Wild:
Ng Type
TypeArray:
A Type
TypeVector:
Nh Type
TypeStaticArray:
G Number Type
TypeAssocArray:
H Type Type
TypePointer:
P Type
TypeFunction:
CallConvention FuncAttrs Arguments ArgClose Type
TypeIdent:
I LName
TypeClass:
C LName
TypeStruct:
S LName
TypeEnum:
E LName
TypeTypedef:
T LName
TypeDelegate:
D TypeFunction
TypeNone:
n
TypeVoid:
v
TypeByte:
g
TypeUbyte:
h
TypeShort:
s
TypeUshort:
t
TypeInt:
i
TypeUint:
k
TypeLong:
l
TypeUlong:
m
TypeCent
zi
TypeUcent
zk
TypeFloat:
f
TypeDouble:
d
TypeReal:
e
TypeIfloat:
o
TypeIdouble:
p
TypeIreal:
j
TypeCfloat:
q
TypeCdouble:
r
TypeCreal:
c
TypeBool:
b
TypeChar:
a
TypeWchar:
u
TypeDchar:
w
TypeTuple:
B Number Arguments
*/
char[] parseType( char[] name = null )
{
static immutable string[23] primitives = [
"char", // a
"bool", // b
"creal", // c
"double", // d
"real", // e
"float", // f
"byte", // g
"ubyte", // h
"int", // i
"ireal", // j
"uint", // k
"long", // l
"ulong", // m
null, // n
"ifloat", // o
"idouble", // p
"cfloat", // q
"cdouble", // r
"short", // s
"ushort", // t
"wchar", // u
"void", // v
"dchar", // w
];
static if (__traits(hasMember, Hooks, "parseType"))
if (auto n = hooks.parseType(this, name))
return n;
debug(trace) printf( "parseType+\n" );
debug(trace) scope(success) printf( "parseType-\n" );
auto beg = len;
auto t = front;
char[] parseBackrefType(scope char[] delegate() pure @safe parseDg) pure @safe
{
if (pos == brp)
error("recursive back reference");
auto refPos = pos;
popFront();
auto n = decodeBackref();
if (n == 0 || n > pos)
error("invalid back reference");
if ( mute )
return null;
auto savePos = pos;
auto saveBrp = brp;
scope(success) { pos = savePos; brp = saveBrp; }
pos = refPos - n;
brp = refPos;
auto ret = parseDg();
return ret;
}
switch ( t )
{
case 'Q': // Type back reference
return parseBackrefType( () => parseType( name ) );
case 'O': // Shared (O Type)
popFront();
put( "shared(" );
parseType();
put( ')' );
pad( name );
return dst[beg .. len];
case 'x': // Const (x Type)
popFront();
put( "const(" );
parseType();
put( ')' );
pad( name );
return dst[beg .. len];
case 'y': // Immutable (y Type)
popFront();
put( "immutable(" );
parseType();
put( ')' );
pad( name );
return dst[beg .. len];
case 'N':
popFront();
switch ( front )
{
case 'g': // Wild (Ng Type)
popFront();
// TODO: Anything needed here?
put( "inout(" );
parseType();
put( ')' );
return dst[beg .. len];
case 'h': // TypeVector (Nh Type)
popFront();
put( "__vector(" );
parseType();
put( ')' );
return dst[beg .. len];
default:
error();
assert( 0 );
}
case 'A': // TypeArray (A Type)
popFront();
parseType();
put( "[]" );
pad( name );
return dst[beg .. len];
case 'G': // TypeStaticArray (G Number Type)
popFront();
auto num = sliceNumber();
parseType();
put( '[' );
put( num );
put( ']' );
pad( name );
return dst[beg .. len];
case 'H': // TypeAssocArray (H Type Type)
popFront();
// skip t1
auto tx = parseType();
parseType();
put( '[' );
put( tx );
put( ']' );
pad( name );
return dst[beg .. len];
case 'P': // TypePointer (P Type)
popFront();
parseType();
put( '*' );
pad( name );
return dst[beg .. len];
case 'F': case 'U': case 'W': case 'V': case 'R': // TypeFunction
return parseTypeFunction( name );
case 'I': // TypeIdent (I LName)
case 'C': // TypeClass (C LName)
case 'S': // TypeStruct (S LName)
case 'E': // TypeEnum (E LName)
case 'T': // TypeTypedef (T LName)
popFront();
parseQualifiedName();
pad( name );
return dst[beg .. len];
case 'D': // TypeDelegate (D TypeFunction)
popFront();
auto modbeg = len;
parseModifier();
auto modend = len;
if ( front == 'Q' )
parseBackrefType( () => parseTypeFunction( name, IsDelegate.yes ) );
else
parseTypeFunction( name, IsDelegate.yes );
if (modend > modbeg)
{
// move modifiers behind the function arguments
shift(dst[modend-1 .. modend]); // trailing space
shift(dst[modbeg .. modend-1]);
}
return dst[beg .. len];
case 'n': // TypeNone (n)
popFront();
// TODO: Anything needed here?
return dst[beg .. len];
case 'B': // TypeTuple (B Number Arguments)
popFront();
// TODO: Handle this.
return dst[beg .. len];
case 'Z': // Internal symbol
// This 'type' is used for untyped internal symbols, i.e.:
// __array
// __init
// __vtbl
// __Class
// __Interface
// __ModuleInfo
popFront();
return dst[beg .. len];
default:
if (t >= 'a' && t <= 'w')
{
popFront();
put( primitives[cast(size_t)(t - 'a')] );
pad( name );
return dst[beg .. len];
}
else if (t == 'z')
{
popFront();
switch ( front )
{
case 'i':
popFront();
put( "cent" );
pad( name );
return dst[beg .. len];
case 'k':
popFront();
put( "ucent" );
pad( name );
return dst[beg .. len];
default:
error();
assert( 0 );
}
}
error();
return null;
}
}
/*
TypeFunction:
CallConvention FuncAttrs Arguments ArgClose Type
CallConvention:
F // D
U // C
W // Windows
V // Pascal
R // C++
FuncAttrs:
FuncAttr
FuncAttr FuncAttrs
FuncAttr:
empty
FuncAttrPure
FuncAttrNothrow
FuncAttrProperty
FuncAttrRef
FuncAttrReturn
FuncAttrScope
FuncAttrTrusted
FuncAttrSafe
FuncAttrPure:
Na
FuncAttrNothrow:
Nb
FuncAttrRef:
Nc
FuncAttrProperty:
Nd
FuncAttrTrusted:
Ne
FuncAttrSafe:
Nf
FuncAttrNogc:
Ni
FuncAttrReturn:
Nj
FuncAttrScope:
Nl
Arguments:
Argument
Argument Arguments
Argument:
Argument2
M Argument2 // scope
Argument2:
Type
J Type // out
K Type // ref
L Type // lazy
ArgClose
X // variadic T t,...) style
Y // variadic T t...) style
Z // not variadic
*/
void parseCallConvention()
{
// CallConvention
switch ( front )
{
case 'F': // D
popFront();
break;
case 'U': // C
popFront();
put( "extern (C) " );
break;
case 'W': // Windows
popFront();
put( "extern (Windows) " );
break;
case 'V': // Pascal
popFront();
put( "extern (Pascal) " );
break;
case 'R': // C++
popFront();
put( "extern (C++) " );
break;
default:
error();
}
}
void parseModifier()
{
switch ( front )
{
case 'y':
popFront();
put( "immutable " );
break;
case 'O':
popFront();
put( "shared " );
if ( front == 'x' )
goto case 'x';
if ( front == 'N' )
goto case 'N';
break;
case 'N':
if ( peek( 1 ) != 'g' )
break;
popFront();
popFront();
put( "inout " );
if ( front == 'x' )
goto case 'x';
break;
case 'x':
popFront();
put( "const " );
break;
default: break;
}
}
void parseFuncAttr()
{
// FuncAttrs
breakFuncAttrs:
while ('N' == front)
{
popFront();
switch ( front )
{
case 'a': // FuncAttrPure
popFront();
put( "pure " );
continue;
case 'b': // FuncAttrNoThrow
popFront();
put( "nothrow " );
continue;
case 'c': // FuncAttrRef
popFront();
put( "ref " );
continue;
case 'd': // FuncAttrProperty
popFront();
put( "@property " );
continue;
case 'e': // FuncAttrTrusted
popFront();
put( "@trusted " );
continue;
case 'f': // FuncAttrSafe
popFront();
put( "@safe " );
continue;
case 'g':
case 'h':
case 'k':
// NOTE: The inout parameter type is represented as "Ng".
// The vector parameter type is represented as "Nh".
// The return parameter type is represented as "Nk".
// These make it look like a FuncAttr, but infact
// if we see these, then we know we're really in
// the parameter list. Rewind and break.
pos--;
break breakFuncAttrs;
case 'i': // FuncAttrNogc
popFront();
put( "@nogc " );
continue;
case 'j': // FuncAttrReturn
popFront();
put( "return " );
continue;
case 'l': // FuncAttrScope
popFront();
put( "scope " );
continue;
default:
error();
}
}
}
void parseFuncArguments()
{
// Arguments
for ( size_t n = 0; true; n++ )
{
debug(info) printf( "tok (%c)\n", front );
switch ( front )
{
case 'X': // ArgClose (variadic T t...) style)
popFront();
put( "..." );
return;
case 'Y': // ArgClose (variadic T t,...) style)
popFront();
put( ", ..." );
return;
case 'Z': // ArgClose (not variadic)
popFront();
return;
default:
break;
}
putComma(n);
if ( 'M' == front )
{
popFront();
put( "scope " );
}
if ( 'N' == front )
{
popFront();
if ( 'k' == front ) // Return (Nk Parameter2)
{
popFront();
put( "return " );
}
else
pos--;
}
switch ( front )
{
case 'J': // out (J Type)
popFront();
put( "out " );
parseType();
continue;
case 'K': // ref (K Type)
popFront();
put( "ref " );
parseType();
continue;
case 'L': // lazy (L Type)
popFront();
put( "lazy " );
parseType();
continue;
default:
parseType();
}
}
}
enum IsDelegate { no, yes }
/*
TypeFunction:
CallConvention FuncAttrs Arguments ArgClose Type
*/
char[] parseTypeFunction( char[] name = null, IsDelegate isdg = IsDelegate.no )
{
debug(trace) printf( "parseTypeFunction+\n" );
debug(trace) scope(success) printf( "parseTypeFunction-\n" );
auto beg = len;
parseCallConvention();
auto attrbeg = len;
parseFuncAttr();
auto argbeg = len;
put( '(' );
parseFuncArguments();
put( ')' );
if (attrbeg < argbeg)
{
// move function attributes behind arguments
shift( dst[argbeg - 1 .. argbeg] ); // trailing space
shift( dst[attrbeg .. argbeg - 1] ); // attributes
argbeg = attrbeg;
}
auto retbeg = len;
parseType();
put( ' ' );
// append name/delegate/function
if ( name.length )
{
if ( !contains( dst[0 .. len], name ) )
put( name );
else if ( shift( name ).ptr != name.ptr )
{
argbeg -= name.length;
retbeg -= name.length;
}
}
else if ( IsDelegate.yes == isdg )
put( "delegate" );
else
put( "function" );
// move arguments and attributes behind name
shift( dst[argbeg .. retbeg] );
return dst[beg..len];
}
static bool isCallConvention( char ch )
{
switch ( ch )
{
case 'F', 'U', 'V', 'W', 'R':
return true;
default:
return false;
}
}
/*
Value:
n
Number
i Number
N Number
e HexFloat
c HexFloat c HexFloat
A Number Value...
HexFloat:
NAN
INF
NINF
N HexDigits P Exponent
HexDigits P Exponent
Exponent:
N Number
Number
HexDigits:
HexDigit
HexDigit HexDigits
HexDigit:
Digit
A
B
C
D
E
F
*/
void parseValue( char[] name = null, char type = '\0' )
{
debug(trace) printf( "parseValue+\n" );
debug(trace) scope(success) printf( "parseValue-\n" );
// printf( "*** %c\n", front );
switch ( front )
{
case 'n':
popFront();
put( "null" );
return;
case 'i':
popFront();
if ( '0' > front || '9' < front )
error( "Number expected" );
goto case;
case '0': .. case '9':
parseIntegerValue( name, type );
return;
case 'N':
popFront();
put( '-' );
parseIntegerValue( name, type );
return;
case 'e':
popFront();
parseReal();
return;
case 'c':
popFront();
parseReal();
put( '+' );
match( 'c' );
parseReal();
put( 'i' );
return;
case 'a': case 'w': case 'd':
char t = front;
popFront();
auto n = decodeNumber();
match( '_' );
put( '"' );
foreach (i; 0..n)
{
auto a = ascii2hex( front ); popFront();
auto b = ascii2hex( front ); popFront();
auto v = cast(char)((a << 4) | b);
if (' ' <= v && v <= '~') // ASCII printable
{
put(v);
}
else
{
put("\\x");
putAsHex(v, 2);
}
}
put( '"' );
if ( 'a' != t )
put(t);
return;
case 'A':
// NOTE: This is kind of a hack. An associative array literal
// [1:2, 3:4] is represented as HiiA2i1i2i3i4, so the type
// is "Hii" and the value is "A2i1i2i3i4". Thus the only
// way to determine that this is an AA value rather than an
// array value is for the caller to supply the type char.
// Hopefully, this will change so that the value is
// "H2i1i2i3i4", rendering this unnecesary.
if ( 'H' == type )
goto LassocArray;
// A Number Value...
// An array literal. Value is repeated Number times.
popFront();
put( '[' );
auto n = decodeNumber();
foreach ( i; 0 .. n )
{
putComma(i);
parseValue();
}
put( ']' );
return;
case 'H':
LassocArray:
// H Number Value...
// An associative array literal. Value is repeated 2*Number times.
popFront();
put( '[' );
auto n = decodeNumber();
foreach ( i; 0 .. n )
{
putComma(i);
parseValue();
put(':');
parseValue();
}
put( ']' );
return;
case 'S':
// S Number Value...
// A struct literal. Value is repeated Number times.
popFront();
if ( name.length )
put( name );
put( '(' );
auto n = decodeNumber();
foreach ( i; 0 .. n )
{
putComma(i);
parseValue();
}
put( ')' );
return;
default:
error();
}
}
void parseIntegerValue( char[] name = null, char type = '\0' )
{
debug(trace) printf( "parseIntegerValue+\n" );
debug(trace) scope(success) printf( "parseIntegerValue-\n" );
switch ( type )
{
case 'a': // char
case 'u': // wchar
case 'w': // dchar
{
auto val = sliceNumber();
auto num = decodeNumber( val );
switch ( num )
{
case '\'':
put( "'\\''" );
return;
// \", \?
case '\\':
put( "'\\\\'" );
return;
case '\a':
put( "'\\a'" );
return;
case '\b':
put( "'\\b'" );
return;
case '\f':
put( "'\\f'" );
return;
case '\n':
put( "'\\n'" );
return;
case '\r':
put( "'\\r'" );
return;
case '\t':
put( "'\\t'" );
return;
case '\v':
put( "'\\v'" );
return;
default:
switch ( type )
{
case 'a':
if ( num >= 0x20 && num < 0x7F )
{
put( '\'' );
put( cast(char)num );
put( '\'' );
return;
}
put( "\\x" );
putAsHex( num, 2 );
return;
case 'u':
put( "'\\u" );
putAsHex( num, 4 );
put( '\'' );
return;
case 'w':
put( "'\\U" );
putAsHex( num, 8 );
put( '\'' );
return;
default:
assert( 0 );
}
}
}
case 'b': // bool
put( decodeNumber() ? "true" : "false" );
return;
case 'h', 't', 'k': // ubyte, ushort, uint
put( sliceNumber() );
put( 'u' );
return;
case 'l': // long
put( sliceNumber() );
put( 'L' );
return;
case 'm': // ulong
put( sliceNumber() );
put( "uL" );
return;
default:
put( sliceNumber() );
return;
}
}
/*
TemplateArgs:
TemplateArg
TemplateArg TemplateArgs
TemplateArg:
TemplateArgX
H TemplateArgX
TemplateArgX:
T Type
V Type Value
S Number_opt QualifiedName
X ExternallyMangledName
*/
void parseTemplateArgs()
{
debug(trace) printf( "parseTemplateArgs+\n" );
debug(trace) scope(success) printf( "parseTemplateArgs-\n" );
L_nextArg:
for ( size_t n = 0; true; n++ )
{
if ( front == 'H' )
popFront();
switch ( front )
{
case 'T':
popFront();
putComma(n);
parseType();
continue;
case 'V':
popFront();
putComma(n);
// NOTE: In the few instances where the type is actually
// desired in the output it should precede the value
// generated by parseValue, so it is safe to simply
// decrement len and let put/append do its thing.
char t = front; // peek at type for parseValue
if ( t == 'Q' )
t = peekBackref();
char[] name; silent( name = parseType() );
parseValue( name, t );
continue;
case 'S':
popFront();
putComma(n);
if ( mayBeMangledNameArg() )
{
auto l = len;
auto p = pos;
auto b = brp;
try
{
debug(trace) printf( "may be mangled name arg\n" );
parseMangledNameArg();
continue;
}
catch ( ParseException e )
{
len = l;
pos = p;
brp = b;
debug(trace) printf( "not a mangled name arg\n" );
}
}
if ( isDigit( front ) && isDigit( peek( 1 ) ) )
{
// ambiguity: length followed by qualified name (starting with number)
// try all possible pairs of numbers
auto qlen = decodeNumber() / 10; // last digit needed for QualifiedName
pos--;
auto l = len;
auto p = pos;
auto b = brp;
while ( qlen > 0 )
{
try
{
parseQualifiedName();
if ( pos == p + qlen )
continue L_nextArg;
}
catch ( ParseException e )
{
}
qlen /= 10; // retry with one digit less
pos = --p;
len = l;
brp = b;
}
}
parseQualifiedName();
continue;
case 'X':
popFront();
putComma(n);
parseLName();
continue;
default:
return;
}
}
}
bool mayBeMangledNameArg()
{
debug(trace) printf( "mayBeMangledNameArg+\n" );
debug(trace) scope(success) printf( "mayBeMangledNameArg-\n" );
auto p = pos;
scope(exit) pos = p;
if ( isDigit( buf[pos] ) )
{
auto n = decodeNumber();
return n >= 4 &&
pos < buf.length && '_' == buf[pos++] &&
pos < buf.length && 'D' == buf[pos++] &&
isDigit( buf[pos] );
}
else
{
return pos < buf.length && '_' == buf[pos++] &&
pos < buf.length && 'D' == buf[pos++] &&
isSymbolNameFront();
}
}
void parseMangledNameArg()
{
debug(trace) printf( "parseMangledNameArg+\n" );
debug(trace) scope(success) printf( "parseMangledNameArg-\n" );
size_t n = 0;
if ( isDigit( front ) )
n = decodeNumber();
parseMangledName( false, n );
}
/*
TemplateInstanceName:
Number __T LName TemplateArgs Z
*/
void parseTemplateInstanceName(bool hasNumber)
{
debug(trace) printf( "parseTemplateInstanceName+\n" );
debug(trace) scope(success) printf( "parseTemplateInstanceName-\n" );
auto sav = pos;
auto saveBrp = brp;
scope(failure)
{
pos = sav;
brp = saveBrp;
}
auto n = hasNumber ? decodeNumber() : 0;
auto beg = pos;
match( "__T" );
parseLName();
put( "!(" );
parseTemplateArgs();
match( 'Z' );
if ( hasNumber && pos - beg != n )
error( "Template name length mismatch" );
put( ')' );
}
bool mayBeTemplateInstanceName()
{
debug(trace) printf( "mayBeTemplateInstanceName+\n" );
debug(trace) scope(success) printf( "mayBeTemplateInstanceName-\n" );
auto p = pos;
scope(exit) pos = p;
auto n = decodeNumber();
return n >= 5 &&
pos < buf.length && '_' == buf[pos++] &&
pos < buf.length && '_' == buf[pos++] &&
pos < buf.length && 'T' == buf[pos++];
}
/*
SymbolName:
LName
TemplateInstanceName
*/
void parseSymbolName()
{
debug(trace) printf( "parseSymbolName+\n" );
debug(trace) scope(success) printf( "parseSymbolName-\n" );
// LName -> Number
// TemplateInstanceName -> Number "__T"
switch ( front )
{
case '_':
// no length encoding for templates for new mangling
parseTemplateInstanceName(false);
return;
case '0': .. case '9':
if ( mayBeTemplateInstanceName() )
{
auto t = len;
try
{
debug(trace) printf( "may be template instance name\n" );
parseTemplateInstanceName(true);
return;
}
catch ( ParseException e )
{
debug(trace) printf( "not a template instance name\n" );
len = t;
}
}
goto case;
case 'Q':
parseLName();
return;
default:
error();
}
}
// parse optional function arguments as part of a symbol name, i.e without return type
// if keepAttr, the calling convention and function attributes are not discarded, but returned
char[] parseFunctionTypeNoReturn( bool keepAttr = false )
{
// try to demangle a function, in case we are pointing to some function local
auto prevpos = pos;
auto prevlen = len;
auto prevbrp = brp;
char[] attr;
try
{
if ( 'M' == front )
{
// do not emit "needs this"
popFront();
parseModifier();
}
if ( isCallConvention( front ) )
{
// we don't want calling convention and attributes in the qualified name
parseCallConvention();
parseFuncAttr();
if ( keepAttr )
{
attr = dst[prevlen .. len];
}
else
{
len = prevlen;
}
put( '(' );
parseFuncArguments();
put( ')' );
}
}
catch ( ParseException )
{
// not part of a qualified name, so back up
pos = prevpos;
len = prevlen;
brp = prevbrp;
attr = null;
}
return attr;
}
/*
QualifiedName:
SymbolName
SymbolName QualifiedName
*/
char[] parseQualifiedName()
{
debug(trace) printf( "parseQualifiedName+\n" );
debug(trace) scope(success) printf( "parseQualifiedName-\n" );
size_t beg = len;
size_t n = 0;
do
{
if ( n++ )
put( '.' );
parseSymbolName();
parseFunctionTypeNoReturn();
} while ( isSymbolNameFront() );
return dst[beg .. len];
}
/*
MangledName:
_D QualifiedName Type
_D QualifiedName M Type
*/
void parseMangledName( bool displayType, size_t n = 0 )
{
debug(trace) printf( "parseMangledName+\n" );
debug(trace) scope(success) printf( "parseMangledName-\n" );
char[] name = null;
auto end = pos + n;
eat( '_' );
match( 'D' );
do
{
size_t beg = len;
size_t nameEnd = len;
char[] attr;
do
{
if ( attr )
remove( attr ); // dump attributes of parent symbols
if ( beg != len )
put( '.' );
parseSymbolName();
nameEnd = len;
attr = parseFunctionTypeNoReturn( displayType );
} while ( isSymbolNameFront() );
if ( displayType )
{
attr = shift( attr );
nameEnd = len - attr.length; // name includes function arguments
}
name = dst[beg .. nameEnd];
debug(info) printf( "name (%.*s)\n", cast(int) name.length, name.ptr );
if ( 'M' == front )
popFront(); // has 'this' pointer
auto lastlen = len;
auto type = parseType();
if ( displayType )
{
if ( type.length )
put( ' ' );
// sort (name,attr,type) -> (attr,type,name)
shift( name );
}
else
{
// remove type
assert( attr.length == 0 );
len = lastlen;
}
if ( pos >= buf.length || (n != 0 && pos >= end) )
return;
switch ( front )
{
case 'T': // terminators when used as template alias parameter
case 'V':
case 'S':
case 'Z':
return;
default:
}
put( '.' );
} while ( true );
}
void parseMangledName()
{
parseMangledName( AddType.yes == addType );
}
char[] doDemangle(alias FUNC)()
{
while ( true )
{
try
{
debug(info) printf( "demangle(%.*s)\n", cast(int) buf.length, buf.ptr );
FUNC();
return dst[0 .. len];
}
catch ( OverflowException e )
{
debug(trace) printf( "overflow... restarting\n" );
auto a = minBufSize;
auto b = 2 * dst.length;
auto newsz = a < b ? b : a;
debug(info) printf( "growing dst to %lu bytes\n", newsz );
dst.length = newsz;
pos = len = brp = 0;
continue;
}
catch ( ParseException e )
{
debug(info)
{
auto msg = e.toString();
printf( "error: %.*s\n", cast(int) msg.length, msg.ptr );
}
if ( dst.length < buf.length )
dst.length = buf.length;
dst[0 .. buf.length] = buf[];
return dst[0 .. buf.length];
}
catch ( Exception e )
{
assert( false ); // no other exceptions thrown
}
}
}
char[] demangleName() nothrow
{
return doDemangle!parseMangledName();
}
char[] demangleType() nothrow
{
return doDemangle!parseType();
}
}
/**
* Demangles D mangled names. If it is not a D mangled name, it returns its
* argument name.
*
* Params:
* buf = The string to demangle.
* dst = An optional destination buffer.
*
* Returns:
* The demangled name or the original string if the name is not a mangled D
* name.
*/
char[] demangle( const(char)[] buf, char[] dst = null ) nothrow pure @safe
{
//return Demangle(buf, dst)();
auto d = Demangle!()(buf, dst);
return d.demangleName();
}
/**
* Demangles a D mangled type.
*
* Params:
* buf = The string to demangle.
* dst = An optional destination buffer.
*
* Returns:
* The demangled type name or the original string if the name is not a
* mangled D type.
*/
char[] demangleType( const(char)[] buf, char[] dst = null ) nothrow pure @safe
{
auto d = Demangle!()(buf, dst);
return d.demangleType();
}
/**
* reencode a mangled symbol name that might include duplicate occurrences
* of the same identifier by replacing all but the first occurence with
* a back reference.
*
* Params:
* mangled = The mangled string representing the type
*
* Returns:
* The mangled name with deduplicated identifiers
*/
char[] reencodeMangled(const(char)[] mangled) nothrow pure @safe
{
static struct PrependHooks
{
size_t lastpos;
char[] result;
size_t[const(char)[]] idpos; // identifier positions
static struct Replacement
{
size_t pos; // postion in original mangled string
size_t respos; // postion in result string
}
Replacement [] replacements;
pure @safe:
size_t positionInResult(size_t pos)
{
foreach_reverse (r; replacements)
if (pos >= r.pos)
return r.respos + pos - r.pos;
return pos;
}
alias Remangle = Demangle!(PrependHooks);
void flushPosition(ref Remangle d)
{
if (lastpos < d.pos)
{
result ~= d.buf[lastpos .. d.pos];
}
else if (lastpos > d.pos)
{
// roll back to earlier position
while (replacements.length > 0 && replacements[$-1].pos > d.pos)
replacements = replacements[0 .. $-1];
if (replacements.length > 0)
result.length = replacements[$-1].respos + d.pos - replacements[$-1].pos;
else
result.length = d.pos;
}
}
bool parseLName(ref Remangle d)
{
flushPosition(d);
auto reslen = result.length;
auto refpos = d.pos;
if (d.front == 'Q')
{
size_t npos;
{
scope(exit) result.length = reslen; // remove all intermediate additions
// only support identifier back references
d.popFront();
size_t n = d.decodeBackref();
if (!n || n > refpos)
d.error("invalid back reference");
auto savepos = d.pos;
scope(exit) d.pos = savepos;
size_t srcpos = refpos - n;
auto idlen = d.decodeNumber();
if (d.pos + idlen > d.buf.length)
d.error("invalid back reference");
auto id = d.buf[d.pos .. d.pos + idlen];
auto pid = id in idpos;
if (!pid)
d.error("invalid back reference");
npos = positionInResult(*pid);
}
encodeBackref(reslen - npos);
replacements ~= Replacement(d.pos, result.length);
}
else
{
auto n = d.decodeNumber();
if (!n || n > d.buf.length || n > d.buf.length - d.pos)
d.error("LName too shot or too long");
auto id = d.buf[d.pos .. d.pos + n];
d.pos += n;
if (auto pid = id in idpos)
{
size_t npos = positionInResult(*pid);
result.length = reslen;
encodeBackref(reslen - npos);
replacements ~= Replacement(d.pos, result.length);
}
else
{
idpos[id] = refpos;
result ~= d.buf[refpos .. d.pos];
}
}
lastpos = d.pos;
return true;
}
char[] parseType( ref Remangle d, char[] name = null )
{
if (d.front != 'Q')
return null;
flushPosition(d);
auto refPos = d.pos;
d.popFront();
auto n = d.decodeBackref();
if (n == 0 || n > refPos)
d.error("invalid back reference");
size_t npos = positionInResult(refPos - n);
size_t reslen = result.length;
encodeBackref(reslen - npos);
lastpos = d.pos;
return result[reslen .. $]; // anything but null
}
void encodeBackref(size_t relpos)
{
result ~= 'Q';
enum base = 26;
size_t div = 1;
while (relpos >= div * base)
div *= base;
while (div >= base)
{
auto dig = (relpos / div);
result ~= cast(char)('A' + dig);
relpos -= dig * div;
div /= base;
}
result ~= cast(char)('a' + relpos);
}
}
auto d = Demangle!(PrependHooks)(mangled, null);
d.hooks = PrependHooks();
d.mute = true; // no demangled output
try
{
d.parseMangledName();
if (d.hooks.lastpos < d.pos)
d.hooks.result ~= d.buf[d.hooks.lastpos .. d.pos];
return d.hooks.result;
}
catch (Exception)
{
// overflow exception cannot occur
return mangled.dup;
}
}
/**
* Mangles a D symbol.
*
* Params:
* T = The type of the symbol.
* fqn = The fully qualified name of the symbol.
* dst = An optional destination buffer.
*
* Returns:
* The mangled name for a symbols of type T and the given fully
* qualified name.
*/
char[] mangle(T)(const(char)[] fqn, char[] dst = null) @safe pure nothrow
{
import core.internal.string : numDigits, unsignedToTempString;
static struct DotSplitter
{
@safe pure nothrow:
const(char)[] s;
@property bool empty() const { return !s.length; }
@property const(char)[] front() const
{
immutable i = indexOfDot();
return i == -1 ? s[0 .. $] : s[0 .. i];
}
void popFront()
{
immutable i = indexOfDot();
s = i == -1 ? s[$ .. $] : s[i+1 .. $];
}
private ptrdiff_t indexOfDot() const
{
foreach (i, c; s) if (c == '.') return i;
return -1;
}
}
size_t len = "_D".length;
foreach (comp; DotSplitter(fqn))
len += numDigits(comp.length) + comp.length;
len += T.mangleof.length;
if (dst.length < len) dst.length = len;
size_t i = "_D".length;
dst[0 .. i] = "_D";
foreach (comp; DotSplitter(fqn))
{
const ndigits = numDigits(comp.length);
unsignedToTempString(comp.length, dst[i .. i + ndigits]);
i += ndigits;
dst[i .. i + comp.length] = comp[];
i += comp.length;
}
dst[i .. i + T.mangleof.length] = T.mangleof[];
i += T.mangleof.length;
static if (hasTypeBackRef)
return reencodeMangled(dst[0 .. i]);
else
return dst[0 .. i];
}
///
@safe pure nothrow unittest
{
assert(mangle!int("a.b") == "_D1a1bi");
assert(mangle!(char[])("test.foo") == "_D4test3fooAa");
assert(mangle!(int function(int))("a.b") == "_D1a1bPFiZi");
}
@safe pure nothrow unittest
{
static assert(mangle!int("a.b") == "_D1a1bi");
auto buf = new char[](10);
buf = mangle!int("a.b", buf);
assert(buf == "_D1a1bi");
buf = mangle!(char[])("test.foo", buf);
assert(buf == "_D4test3fooAa");
buf = mangle!(real delegate(int))("modµ.dg");
assert(buf == "_D5modµ2dgDFiZe", buf);
}
/**
* Mangles a D function.
*
* Params:
* T = function pointer type.
* fqn = The fully qualified name of the symbol.
* dst = An optional destination buffer.
*
* Returns:
* The mangled name for a function with function pointer type T and
* the given fully qualified name.
*/
char[] mangleFunc(T:FT*, FT)(const(char)[] fqn, char[] dst = null) @safe pure nothrow if (is(FT == function))
{
static if (isExternD!FT)
{
return mangle!FT(fqn, dst);
}
else static if (hasPlainMangling!FT)
{
dst.length = fqn.length;
dst[] = fqn[];
return dst;
}
else static if (isExternCPP!FT)
{
static assert(0, "Can't mangle extern(C++) functions.");
}
else
{
static assert(0, "Can't mangle function with unknown linkage ("~FT.stringof~").");
}
}
private enum hasTypeBackRef = (int function(void**,void**)).mangleof[$-4 .. $] == "QdZi";
///
@safe pure nothrow unittest
{
assert(mangleFunc!(int function(int))("a.b") == "_D1a1bFiZi");
static if (hasTypeBackRef)
{
assert(mangleFunc!(int function(Object))("object.Object.opEquals") == "_D6object6Object8opEqualsFCQsZi");
assert(mangleFunc!(int function(Object, Object))("object.Object.opEquals") == "_D6object6Object8opEqualsFCQsQdZi");
}
else
{
auto mngl = mangleFunc!(int function(Object))("object.Object.opEquals");
assert(mngl == "_D6object6Object8opEqualsFC6ObjectZi");
auto remngl = reencodeMangled(mngl);
assert(remngl == "_D6object6Object8opEqualsFCQsZi");
}
// trigger back tracking with ambiguity on '__T', template or identifier
assert(reencodeMangled("_D3std4conv4conv7__T3std4convi") == "_D3std4convQf7__T3stdQpi");
}
@safe pure nothrow unittest
{
int function(lazy int[], ...) fp;
assert(mangle!(typeof(fp))("demangle.test") == "_D8demangle4testPFLAiYi");
assert(mangle!(typeof(*fp))("demangle.test") == "_D8demangle4testFLAiYi");
}
private template isExternD(FT) if (is(FT == function))
{
enum isExternD = __traits(getLinkage, FT) == "D";
}
private template isExternCPP(FT) if (is(FT == function))
{
enum isExternCPP = __traits(getLinkage, FT) == "C++";
}
private template hasPlainMangling(FT) if (is(FT == function))
{
enum lnk = __traits(getLinkage, FT);
// C || Pascal || Windows
enum hasPlainMangling = lnk == "C" || lnk == "Pascal" || lnk == "Windows";
}
@safe pure nothrow unittest
{
static extern(D) void fooD();
static extern(C) void fooC();
static extern(Pascal) void fooP();
static extern(Windows) void fooW();
static extern(C++) void fooCPP();
bool check(FT)(bool isD, bool isCPP, bool isPlain)
{
return isExternD!FT == isD && isExternCPP!FT == isCPP &&
hasPlainMangling!FT == isPlain;
}
static assert(check!(typeof(fooD))(true, false, false));
static assert(check!(typeof(fooC))(false, false, true));
static assert(check!(typeof(fooP))(false, false, true));
static assert(check!(typeof(fooW))(false, false, true));
static assert(check!(typeof(fooCPP))(false, true, false));
static assert(__traits(compiles, mangleFunc!(typeof(&fooD))("")));
static assert(__traits(compiles, mangleFunc!(typeof(&fooC))("")));
static assert(__traits(compiles, mangleFunc!(typeof(&fooP))("")));
static assert(__traits(compiles, mangleFunc!(typeof(&fooW))("")));
static assert(!__traits(compiles, mangleFunc!(typeof(&fooCPP))("")));
}
/***
* C name mangling is done by adding a prefix on some platforms.
*/
version (Win32)
enum string cPrefix = "_";
else version (Darwin)
enum string cPrefix = "_";
else
enum string cPrefix = "";
version (unittest)
{
immutable string[2][] table =
[
["printf", "printf"],
["_foo", "_foo"],
["_D88", "_D88"],
["_D4test3fooAa", "char[] test.foo"],
["_D8demangle8demangleFAaZAa", "char[] demangle.demangle(char[])"],
["_D6object6Object8opEqualsFC6ObjectZi", "int object.Object.opEquals(Object)"],
["_D4test2dgDFiYd", "double delegate(int, ...) test.dg"],
["_D4test2dgDxFNfiYd", "double delegate(int, ...) @safe const test.dg"],
//["_D4test58__T9factorialVde67666666666666860140VG5aa5_68656c6c6fVPvnZ9factorialf", ""],
//["_D4test101__T9factorialVde67666666666666860140Vrc9a999999999999d9014000000000000000c00040VG5aa5_68656c6c6fVPvnZ9factorialf", ""],
["_D4test34__T3barVG3uw3_616263VG3wd3_646566Z1xi", "int test.bar!(\"abc\"w, \"def\"d).x"],
["_D8demangle4testFLC6ObjectLDFLiZiZi", "int demangle.test(lazy Object, lazy int delegate(lazy int))"],
["_D8demangle4testFAiXi", "int demangle.test(int[]...)"],
["_D8demangle4testFAiYi", "int demangle.test(int[], ...)"],
["_D8demangle4testFLAiXi", "int demangle.test(lazy int[]...)"],
["_D8demangle4testFLAiYi", "int demangle.test(lazy int[], ...)"],
["_D6plugin8generateFiiZAya", "immutable(char)[] plugin.generate(int, int)"],
["_D6plugin8generateFiiZAxa", "const(char)[] plugin.generate(int, int)"],
["_D6plugin8generateFiiZAOa", "shared(char)[] plugin.generate(int, int)"],
["_D8demangle3fnAFZ3fnBMFZv", "void demangle.fnA().fnB()"],
["_D8demangle4mainFZ1S3fnCMFZv", "void demangle.main().S.fnC()"],
["_D8demangle4mainFZ1S3fnDMFZv", "void demangle.main().S.fnD()"],
["_D8demangle20__T2fnVAiA4i1i2i3i4Z2fnFZv", "void demangle.fn!([1, 2, 3, 4]).fn()"],
["_D8demangle10__T2fnVi1Z2fnFZv", "void demangle.fn!(1).fn()"],
["_D8demangle26__T2fnVS8demangle1SS2i1i2Z2fnFZv", "void demangle.fn!(demangle.S(1, 2)).fn()"],
["_D8demangle13__T2fnVeeNANZ2fnFZv", "void demangle.fn!(real.nan).fn()"],
["_D8demangle14__T2fnVeeNINFZ2fnFZv", "void demangle.fn!(-real.infinity).fn()"],
["_D8demangle13__T2fnVeeINFZ2fnFZv", "void demangle.fn!(real.infinity).fn()"],
["_D8demangle21__T2fnVHiiA2i1i2i3i4Z2fnFZv", "void demangle.fn!([1:2, 3:4]).fn()"],
["_D8demangle2fnFNgiZNgi", "inout(int) demangle.fn(inout(int))"],
["_D8demangle29__T2fnVa97Va9Va0Vu257Vw65537Z2fnFZv", "void demangle.fn!('a', '\\t', \\x00, '\\u0101', '\\U00010001').fn()"],
["_D2gc11gctemplates56__T8mkBitmapTS3std5range13__T4iotaTiTiZ4iotaFiiZ6ResultZ8mkBitmapFNbNiNfPmmZv",
"nothrow @nogc @safe void gc.gctemplates.mkBitmap!(std.range.iota!(int, int).iota(int, int).Result).mkBitmap(ulong*, ulong)"],
["_D8serenity9persister6Sqlite69__T15SqlitePersisterTS8serenity9persister6Sqlite11__unittest6FZ4TestZ15SqlitePersister12__T7opIndexZ7opIndexMFmZS8serenity9persister6Sqlite11__unittest6FZ4Test",
"serenity.persister.Sqlite.__unittest6().Test serenity.persister.Sqlite.SqlitePersister!(serenity.persister.Sqlite.__unittest6().Test).SqlitePersister.opIndex!().opIndex(ulong)"],
["_D8bug100274mainFZ5localMFZi","int bug10027.main().local()"],
["_D8demangle4testFNhG16gZv", "void demangle.test(__vector(byte[16]))"],
["_D8demangle4testFNhG8sZv", "void demangle.test(__vector(short[8]))"],
["_D8demangle4testFNhG4iZv", "void demangle.test(__vector(int[4]))"],
["_D8demangle4testFNhG2lZv", "void demangle.test(__vector(long[2]))"],
["_D8demangle4testFNhG4fZv", "void demangle.test(__vector(float[4]))"],
["_D8demangle4testFNhG2dZv", "void demangle.test(__vector(double[2]))"],
["_D8demangle4testFNhG4fNhG4fZv", "void demangle.test(__vector(float[4]), __vector(float[4]))"],
["_D8bug1119234__T3fooS23_D8bug111924mainFZ3bariZ3fooMFZv","void bug11192.foo!(bug11192.main().bar).foo()"],
["_D13libd_demangle12__ModuleInfoZ", "libd_demangle.__ModuleInfo"],
["_D15TypeInfo_Struct6__vtblZ", "TypeInfo_Struct.__vtbl"],
["_D3std5stdio12__ModuleInfoZ", "std.stdio.__ModuleInfo"],
["_D3std6traits15__T8DemangleTkZ8Demangle6__initZ", "std.traits.Demangle!(uint).Demangle.__init"],
["_D3foo3Bar7__ClassZ", "foo.Bar.__Class"],
["_D3foo3Bar6__vtblZ", "foo.Bar.__vtbl"],
["_D3foo3Bar11__interfaceZ", "foo.Bar.__interface"],
["_D3foo7__arrayZ", "foo.__array"],
["_D8link657428__T3fooVE8link65746Methodi0Z3fooFZi", "int link6574.foo!(0).foo()"],
["_D8link657429__T3fooHVE8link65746Methodi0Z3fooFZi", "int link6574.foo!(0).foo()"],
["_D4test22__T4funcVAyaa3_610a62Z4funcFNaNbNiNfZAya", `pure nothrow @nogc @safe immutable(char)[] test.func!("a\x0ab").func()`],
["_D3foo3barFzkZzi", "cent foo.bar(ucent)"],
["_D5bug145Class3fooMFNlZPv", "scope void* bug14.Class.foo()"],
["_D5bug145Class3barMFNjZPv", "return void* bug14.Class.bar()"],
["_D5bug143fooFMPvZPv", "void* bug14.foo(scope void*)"],
["_D5bug143barFMNkPvZPv", "void* bug14.bar(scope return void*)"],
["_D3std5range15__T4iotaTtTtTtZ4iotaFtttZ6Result7opIndexMNgFNaNbNiNfmZNgt",
"inout pure nothrow @nogc @safe inout(ushort) std.range.iota!(ushort, ushort, ushort).iota(ushort, ushort, ushort).Result.opIndex(ulong)"],
["_D3std6format77__T6getNthVAyaa13_696e7465676572207769647468S233std6traits10isIntegralTiTkTkZ6getNthFNaNfkkkZi",
"pure @safe int std.format.getNth!(\"integer width\", std.traits.isIntegral, int, uint, uint).getNth(uint, uint, uint)"],
["_D3std11parallelism42__T16RoundRobinBufferTDFKAaZvTDxFNaNdNeZbZ16RoundRobinBuffer5primeMFZv",
"void std.parallelism.RoundRobinBuffer!(void delegate(ref char[]), bool delegate() pure @property @trusted const).RoundRobinBuffer.prime()"],
// Lname '0'
["_D3std9algorithm9iteration__T9MapResultSQBmQBlQBe005stripTAAyaZQBi7opSliceMFNaNbNiNfmmZSQDiQDhQDa__TQCtSQDyQDxQDq00QCmTQCjZQDq",
"pure nothrow @nogc @safe std.algorithm.iteration.MapResult!(std.algorithm.iteration.__anonymous.strip, "
~"immutable(char)[][]).MapResult std.algorithm.iteration.MapResult!(std.algorithm.iteration.strip, immutable(char)[][]).MapResult.opSlice(ulong, ulong)"],
// back references
["_D4core4stdc5errnoQgFZi", "int core.stdc.errno.errno()"], // identifier back reference
["_D4testFS10structnameQnZb", "bool test(structname, structname)"], // type back reference
["_D3std11parallelism__T4TaskS8unittest3cmpTAyaTQeZQBb6__dtorMFNfZv",
"@safe void std.parallelism.Task!(unittest.cmp, immutable(char)[], immutable(char)[]).Task.__dtor()"],
// 1.s.s.foo from https://issues.dlang.org/show_bug.cgi?id=15831
["_D13testexpansion44__T1sTS13testexpansion8__T1sTiZ1sFiZ6ResultZ1sFS13testexpansion8__T1sTiZ1sFiZ6ResultZ6Result3fooMFNaNfZv",
"pure @safe void testexpansion.s!(testexpansion.s!(int).s(int).Result).s(testexpansion.s!(int).s(int).Result).Result.foo()"],
["_D13testexpansion__T1sTSQw__TQjTiZQoFiZ6ResultZQBbFQBcZQq3fooMFNaNfZv",
"pure @safe void testexpansion.s!(testexpansion.s!(int).s(int).Result).s(testexpansion.s!(int).s(int).Result).Result.foo()"],
// ambiguity on 'V', template value argument or pascal function
["_D3std4conv__T7enumRepTyAaTEQBa12experimental9allocator15building_blocks15stats_collector7OptionsVQCti64ZQDnyQDh",
"immutable(char[]) std.conv.enumRep!(immutable(char[]), std.experimental.allocator.building_blocks.stats_collector.Options, 64).enumRep"],
// symbol back reference to location with symbol back reference
["_D3std12experimental9allocator6common__T10reallocateTSQCaQBzQBo15building_blocks17kernighan_ritchie__T8KRRegionTSQEhQEgQDvQCh14null_allocator13NullAllocatorZQCdZQErFNaNbNiKQEpKAvmZb",
"pure nothrow @nogc bool std.experimental.allocator.common.reallocate!(std.experimental.allocator.building_blocks.kernighan_ritchie.KRRegion!("
~"std.experimental.allocator.building_blocks.null_allocator.NullAllocator).KRRegion).reallocate(ref "
~"std.experimental.allocator.building_blocks.kernighan_ritchie.KRRegion!(std.experimental.allocator.building_blocks.null_allocator.NullAllocator).KRRegion, ref void[], ulong)"],
["_D3std9exception__T11doesPointToTASQBh5regex8internal2ir10NamedGroupTQBkTvZQCeFNaNbNiNeKxASQDlQCeQCbQBvQBvKxQtZb",
"pure nothrow @nogc @trusted bool std.exception.doesPointTo!(std.regex.internal.ir.NamedGroup[], "
~"std.regex.internal.ir.NamedGroup[], void).doesPointTo(ref const(std.regex.internal.ir.NamedGroup[]), ref const(std.regex.internal.ir.NamedGroup[]))"],
["_D3std9algorithm9iteration__T14SplitterResultS_DQBu3uni7isWhiteFNaNbNiNfwZbTAyaZQBz9__xtoHashFNbNeKxSQDvQDuQDn__TQDgS_DQEnQCtQCsQCnTQCeZQEdZm",
"nothrow @trusted ulong std.algorithm.iteration.SplitterResult!(std.uni.isWhite(dchar), immutable(char)[]).SplitterResult."
~"__xtoHash(ref const(std.algorithm.iteration.SplitterResult!(std.uni.isWhite, immutable(char)[]).SplitterResult))"],
["_D3std8typecons__T7TypedefTCQBaQz19__unittestL6513_208FNfZ7MyClassVQBonVAyanZQCh6__ctorMFNaNbNcNiNfQCuZSQDyQDx__TQDrTQDmVQDqnVQCcnZQEj",
"pure nothrow ref @nogc @safe std.typecons.Typedef!(std.typecons.__unittestL6513_208().MyClass, null, null).Typedef "
~"std.typecons.Typedef!(std.typecons.__unittestL6513_208().MyClass, null, null).Typedef.__ctor(std.typecons.__unittestL6513_208().MyClass)"],
["_D3std6getopt__TQkTAyaTDFNaNbNiNfQoZvTQtTDQsZQBnFNfKAQBiQBlQBkQBrQyZSQCpQCo12GetoptResult",
"@safe std.getopt.GetoptResult std.getopt.getopt!(immutable(char)[], void delegate(immutable(char)[]) pure nothrow @nogc @safe, "
~"immutable(char)[], void delegate(immutable(char)[]) pure nothrow @nogc @safe)."
~"getopt(ref immutable(char)[][], immutable(char)[], void delegate(immutable(char)[]) pure nothrow @nogc @safe, "
~"immutable(char)[], void delegate(immutable(char)[]) pure nothrow @nogc @safe)"],
["_D3std5regex8internal9kickstart__T7ShiftOrTaZQl11ShiftThread__T3setS_DQCqQCpQCmQCg__TQBzTaZQCfQBv10setInvMaskMFNaNbNiNfkkZvZQCjMFNaNfwZv",
"pure @safe void std.regex.internal.kickstart.ShiftOr!(char).ShiftOr.ShiftThread.set!(std.regex.internal.kickstart.ShiftOr!(char).ShiftOr.ShiftThread.setInvMask(uint, uint)).set(dchar)"],
["_D3std5stdio4File__T8lockImplX10LockFileExTykZQBaMFmmykZi", // C function as template alias parameter
"int std.stdio.File.lockImpl!(LockFileEx, immutable(uint)).lockImpl(ulong, ulong, immutable(uint))"],
// back reference for type in template AA parameter value
["_D3std9algorithm9iteration__T12FilterResultSQBq8typecons__T5TupleTiVAyaa1_61TiVQla1_62TiVQva1_63ZQBm__T6renameVHiQBtA2i0a1_63i2a1_61ZQBeMFNcZ9__lambda1TAiZQEw9__xtoHashFNbNeKxSQGsQGrQGk__TQGdSQHiQFs__TQFmTiVQFja1_61TiVQFua1_62TiVQGfa1_63ZQGx__TQFlVQFhA2i0a1_63i2a1_61ZQGjMFNcZQFfTQEyZQJvZm",
`nothrow @trusted ulong std.algorithm.iteration.FilterResult!(std.typecons.Tuple!(int, "a", int, "b", int, "c").`
~`Tuple.rename!([0:"c", 2:"a"]).rename().__lambda1, int[]).FilterResult.__xtoHash(ref const(std.algorithm.iteration.`
~`FilterResult!(std.typecons.Tuple!(int, "a", int, "b", int, "c").Tuple.rename!([0:"c", 2:"a"]).rename().__lambda1, int[]).FilterResult))`],
];
template staticIota(int x)
{
template Seq(T...){ alias Seq = T; }
static if (x == 0)
alias staticIota = Seq!();
else
alias staticIota = Seq!(staticIota!(x - 1), x - 1);
}
}
@safe pure nothrow unittest
{
foreach ( i, name; table )
{
auto r = demangle( name[0] );
assert( r == name[1],
"demangled \"" ~ name[0] ~ "\" as \"" ~ r ~ "\" but expected \"" ~ name[1] ~ "\"");
}
foreach ( i; staticIota!(table.length) )
{
enum r = demangle( table[i][0] );
static assert( r == table[i][1],
"demangled \"" ~ table[i][0] ~ "\" as \"" ~ r ~ "\" but expected \"" ~ table[i][1] ~ "\"");
}
}
/*
*
*/
string decodeDmdString( const(char)[] ln, ref size_t p ) nothrow pure @safe
{
string s;
uint zlen, zpos;
// decompress symbol
while ( p < ln.length )
{
int ch = cast(ubyte) ln[p++];
if ( (ch & 0xc0) == 0xc0 )
{
zlen = (ch & 0x7) + 1;
zpos = ((ch >> 3) & 7) + 1; // + zlen;
if ( zpos > s.length )
break;
s ~= s[$ - zpos .. $ - zpos + zlen];
}
else if ( ch >= 0x80 )
{
if ( p >= ln.length )
break;
int ch2 = cast(ubyte) ln[p++];
zlen = (ch2 & 0x7f) | ((ch & 0x38) << 4);
if ( p >= ln.length )
break;
int ch3 = cast(ubyte) ln[p++];
zpos = (ch3 & 0x7f) | ((ch & 7) << 7);
if ( zpos > s.length )
break;
s ~= s[$ - zpos .. $ - zpos + zlen];
}
else if ( Demangle!().isAlpha(cast(char)ch) || Demangle!().isDigit(cast(char)ch) || ch == '_' )
s ~= cast(char) ch;
else
{
p--;
break;
}
}
return s;
}
// locally purified for internal use here only
extern (C) private
{
pure @trusted @nogc nothrow pragma(mangle, "fakePureReprintReal") void pureReprintReal(char[] nptr);
void fakePureReprintReal(char[] nptr)
{
import core.stdc.stdlib : strtold;
import core.stdc.stdio : snprintf;
import core.stdc.errno : errno;
const err = errno;
real val = strtold(nptr.ptr, null);
snprintf(nptr.ptr, nptr.length, "%#Lg", val);
errno = err;
}
}