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/*****************************************************************************/
/* */
/* symtab.c */
/* */
/* Symbol table for the ca65 macroassembler */
/* */
/* */
/* */
/* (C) 1998-2014, Ullrich von Bassewitz */
/* Roemerstrasse 52 */
/* D-70794 Filderstadt */
/* EMail: uz@cc65.org */
/* */
/* */
/* This software is provided 'as-is', without any expressed or implied */
/* warranty. In no event will the authors be held liable for any damages */
/* arising from the use of this software. */
/* */
/* Permission is granted to anyone to use this software for any purpose, */
/* including commercial applications, and to alter it and redistribute it */
/* freely, subject to the following restrictions: */
/* */
/* 1. The origin of this software must not be misrepresented; you must not */
/* claim that you wrote the original software. If you use this software */
/* in a product, an acknowledgment in the product documentation would be */
/* appreciated but is not required. */
/* 2. Altered source versions must be plainly marked as such, and must not */
/* be misrepresented as being the original software. */
/* 3. This notice may not be removed or altered from any source */
/* distribution. */
/* */
/*****************************************************************************/
#include <string.h>
/* common */
#include "addrsize.h"
#include "check.h"
#include "hashfunc.h"
#include "mmodel.h"
#include "scopedefs.h"
#include "symdefs.h"
#include "xmalloc.h"
/* ca65 */
#include "dbginfo.h"
#include "error.h"
#include "expr.h"
#include "global.h"
#include "objfile.h"
#include "scanner.h"
#include "segment.h"
#include "sizeof.h"
#include "span.h"
#include "spool.h"
#include "studyexpr.h"
#include "symtab.h"
/*****************************************************************************/
/* Data */
/*****************************************************************************/
/* Combined symbol entry flags used within this module */
#define SF_UNDEFMASK (SF_REFERENCED | SF_DEFINED | SF_IMPORT)
#define SF_UNDEFVAL (SF_REFERENCED)
/* Symbol tables */
SymTable* CurrentScope = 0; /* Pointer to current symbol table */
SymTable* RootScope = 0; /* Root symbol table */
static SymTable* LastScope = 0; /* Pointer to last scope in list */
static unsigned ScopeCount = 0; /* Number of scopes */
/* Symbol table variables */
static unsigned ImportCount = 0; /* Counter for import symbols */
static unsigned ExportCount = 0; /* Counter for export symbols */
/*****************************************************************************/
/* Internally used functions */
/*****************************************************************************/
static int IsDbgSym (const SymEntry* S)
/* Return true if this is a debug symbol */
{
if ((S->Flags & (SF_DEFINED | SF_UNUSED)) == SF_DEFINED) {
/* Defined symbols are debug symbols if they aren't sizes */
return !IsSizeOfSymbol (S);
} else {
/* Others are debug symbols if they're referenced imports */
return ((S->Flags & SF_REFIMP) == SF_REFIMP);
}
}
static unsigned ScopeTableSize (unsigned Level)
/* Get the size of a table for the given lexical level */
{
switch (Level) {
case 0: return 213;
case 1: return 53;
default: return 29;
}
}
static SymTable* NewSymTable (SymTable* Parent, const StrBuf* Name)
/* Allocate a symbol table on the heap and return it */
{
/* Determine the lexical level and the number of table slots */
unsigned Level = Parent? Parent->Level + 1 : 0;
unsigned Slots = ScopeTableSize (Level);
/* Allocate memory */
SymTable* S = xmalloc (sizeof (SymTable) + (Slots-1) * sizeof (SymEntry*));
/* Set variables and clear hash table entries */
S->Next = 0;
S->Left = 0;
S->Right = 0;
S->Childs = 0;
S->Label = 0;
S->Spans = AUTO_COLLECTION_INITIALIZER;
S->Id = ScopeCount++;
S->Flags = ST_NONE;
S->AddrSize = ADDR_SIZE_DEFAULT;
S->Type = SCOPE_UNDEF;
S->Level = Level;
S->TableSlots = Slots;
S->TableEntries = 0;
S->Parent = Parent;
S->Name = GetStrBufId (Name);
while (Slots--) {
S->Table[Slots] = 0;
}
/* Insert the symbol table into the list of all symbol tables */
if (RootScope == 0) {
RootScope = S;
} else {
LastScope->Next = S;
}
LastScope = S;
/* Insert the symbol table into the child tree of the parent */
if (Parent) {
SymTable* T = Parent->Childs;
if (T == 0) {
/* First entry */
Parent->Childs = S;
} else {
while (1) {
/* Choose next entry */
int Cmp = SB_Compare (Name, GetStrBuf (T->Name));
if (Cmp < 0) {
if (T->Left) {
T = T->Left;
} else {
T->Left = S;
break;
}
} else if (Cmp > 0) {
if (T->Right) {
T = T->Right;
} else {
T->Right = S;
break;
}
} else {
/* Duplicate scope name */
Internal ("Duplicate scope name: `%m%p'", Name);
}
}
}
}
/* Return the prepared struct */
return S;
}
/*****************************************************************************/
/* Code */
/*****************************************************************************/
void SymEnterLevel (const StrBuf* ScopeName, unsigned char Type,
unsigned char AddrSize, SymEntry* ScopeLabel)
/* Enter a new lexical level */
{
/* Map a default address size to something real */
if (AddrSize == ADDR_SIZE_DEFAULT) {
/* Use the segment address size */
AddrSize = GetCurrentSegAddrSize ();
}
/* If we have a current scope, search for the given name and create a
** new one if it doesn't exist. If this is the root scope, just create it.
*/
if (CurrentScope) {
/* Search for the scope, create a new one */
CurrentScope = SymFindScope (CurrentScope, ScopeName, SYM_ALLOC_NEW);
/* Check if the scope has been defined before */
if (CurrentScope->Flags & ST_DEFINED) {
Error ("Duplicate scope `%m%p'", ScopeName);
}
} else {
CurrentScope = RootScope = NewSymTable (0, ScopeName);
}
/* Mark the scope as defined and set type, address size and owner symbol */
CurrentScope->Flags |= ST_DEFINED;
CurrentScope->AddrSize = AddrSize;
CurrentScope->Type = Type;
CurrentScope->Label = ScopeLabel;
/* If this is a scope that allows to emit data into segments, add spans
** for all currently existing segments. Doing this for just a few scope
** types is not really necessary but an optimization, because it does not
** allocate memory for useless data (unhandled types here don't occupy
** space in any segment).
*/
if (CurrentScope->Type <= SCOPE_HAS_DATA) {
OpenSpanList (&CurrentScope->Spans);
}
}
void SymLeaveLevel (void)
/* Leave the current lexical level */
{
/* If this is a scope that allows to emit data into segments, close the
** open the spans.
*/
if (CurrentScope->Type <= SCOPE_HAS_DATA) {
CloseSpanList (&CurrentScope->Spans);
}
/* If we have spans, the first one is the segment that was active, when the
** scope was opened. Set the size of the scope to the number of data bytes
** emitted into this segment. If we have an owner symbol set the size of
** this symbol, too.
*/
if (CollCount (&CurrentScope->Spans) > 0) {
const Span* S = CollAtUnchecked (&CurrentScope->Spans, 0);
unsigned long Size = GetSpanSize (S);
DefSizeOfScope (CurrentScope, Size);
if (CurrentScope->Label) {
DefSizeOfSymbol (CurrentScope->Label, Size);
}
}
/* Mark the scope as closed */
CurrentScope->Flags |= ST_CLOSED;
/* Leave the scope */
CurrentScope = CurrentScope->Parent;
}
SymTable* SymFindScope (SymTable* Parent, const StrBuf* Name, SymFindAction Action)
/* Find a scope in the given enclosing scope */
{
SymTable** T = &Parent->Childs;
while (*T) {
int Cmp = SB_Compare (Name, GetStrBuf ((*T)->Name));
if (Cmp < 0) {
T = &(*T)->Left;
} else if (Cmp > 0) {
T = &(*T)->Right;
} else {
/* Found the scope */
return *T;
}
}
/* Create a new scope if requested and we didn't find one */
if (*T == 0 && (Action & SYM_ALLOC_NEW) != 0) {
*T = NewSymTable (Parent, Name);
}
/* Return the scope */
return *T;
}
SymTable* SymFindAnyScope (SymTable* Parent, const StrBuf* Name)
/* Find a scope in the given or any of its parent scopes. The function will
** never create a new symbol, since this can only be done in one specific
** scope.
*/
{
SymTable* Scope;
do {
/* Search in the current table */
Scope = SymFindScope (Parent, Name, SYM_FIND_EXISTING);
if (Scope == 0) {
/* Not found, search in the parent scope, if we have one */
Parent = Parent->Parent;
}
} while (Scope == 0 && Parent != 0);
return Scope;
}
SymEntry* SymFindLocal (SymEntry* Parent, const StrBuf* Name, SymFindAction Action)
/* Find a cheap local symbol. If Action contains SYM_ALLOC_NEW and the entry is
** not found, create a new one. Return the entry found, or the new entry
** created, or - in case Action is SYM_FIND_EXISTING - return 0.
*/
{
SymEntry* S;
int Cmp;
/* Local symbol, get the table */
if (!Parent) {
/* No last global, so there's no local table */
Error ("No preceeding global symbol");
if (Action & SYM_ALLOC_NEW) {
return NewSymEntry (Name, SF_LOCAL);
} else {
return 0;
}
}
/* Search for the symbol if we have a table */
Cmp = SymSearchTree (Parent->Locals, Name, &S);
/* If we found an entry, return it */
if (Cmp == 0) {
return S;
}
if (Action & SYM_ALLOC_NEW) {
/* Otherwise create a new entry, insert and return it */
SymEntry* N = NewSymEntry (Name, SF_LOCAL);
N->Sym.Entry = Parent;
if (S == 0) {
Parent->Locals = N;
} else if (Cmp < 0) {
S->Left = N;
} else {
S->Right = N;
}
return N;
}
/* We did not find the entry and AllocNew is false. */
return 0;
}
SymEntry* SymFind (SymTable* Scope, const StrBuf* Name, SymFindAction Action)
/* Find a new symbol table entry in the given table. If Action contains
** SYM_ALLOC_NEW and the entry is not found, create a new one. Return the
** entry found, or the new entry created, or - in case Action is
** SYM_FIND_EXISTING - return 0.
*/
{
SymEntry* S;
/* Global symbol: Get the hash value for the name */
unsigned Hash = HashBuf (Name) % Scope->TableSlots;
/* Search for the entry */
int Cmp = SymSearchTree (Scope->Table[Hash], Name, &S);
/* If we found an entry, return it */
if (Cmp == 0) {
if ((Action & SYM_CHECK_ONLY) == 0 && SymTabIsClosed (Scope)) {
S->Flags |= SF_FIXED;
}
return S;
}
if (Action & SYM_ALLOC_NEW) {
/* Otherwise create a new entry, insert and return it. If the scope is
** already closed, mark the symbol as fixed so it won't be resolved
** by a symbol in the enclosing scopes later.
*/
SymEntry* N = NewSymEntry (Name, SF_NONE);
if (SymTabIsClosed (Scope)) {
N->Flags |= SF_FIXED;
}
N->Sym.Tab = Scope;
if (S == 0) {
Scope->Table[Hash] = N;
} else if (Cmp < 0) {
S->Left = N;
} else {
S->Right = N;
}
++Scope->TableEntries;
return N;
}
/* We did not find the entry and AllocNew is false. */
return 0;
}
SymEntry* SymFindAny (SymTable* Scope, const StrBuf* Name)
/* Find a symbol in the given or any of its parent scopes. The function will
** never create a new symbol, since this can only be done in one specific
** scope.
*/
{
/* Generate the name hash */
unsigned Hash = HashBuf (Name);
/* Search for the symbol */
SymEntry* Sym;
do {
/* Search in the current table. Ignore entries flagged with SF_UNUSED,
** because for such symbols there is a real entry in one of the parent
** scopes.
*/
if (SymSearchTree (Scope->Table[Hash % Scope->TableSlots], Name, &Sym) == 0) {
if (Sym->Flags & SF_UNUSED) {
Sym = 0;
} else {
/* Found, return it */
break;
}
} else {
Sym = 0;
}
/* Not found, search in the parent scope, if we have one */
Scope = Scope->Parent;
} while (Sym == 0 && Scope != 0);
/* Return the result */
return Sym;
}
static void SymCheckUndefined (SymEntry* S)
/* Handle an undefined symbol */
{
/* Undefined symbol. It may be...
**
** - An undefined symbol in a nested lexical level. If the symbol is not
** fixed to this level, search for the symbol in the higher levels and
** make the entry a trampoline entry if we find one.
**
** - If the symbol is not found, it is a real undefined symbol. If the
** AutoImport flag is set, make it an import. If the AutoImport flag is
** not set, it's an error.
*/
SymEntry* Sym = 0;
if ((S->Flags & SF_FIXED) == 0) {
SymTable* Tab = GetSymParentScope (S);
while (Tab) {
Sym = SymFind (Tab, GetStrBuf (S->Name), SYM_FIND_EXISTING | SYM_CHECK_ONLY);
if (Sym && (Sym->Flags & (SF_DEFINED | SF_IMPORT)) != 0) {
/* We've found a symbol in a higher level that is
** either defined in the source, or an import.
*/
break;
}
/* No matching symbol found in this level. Look further */
Tab = Tab->Parent;
}
}
if (Sym) {
/* We found the symbol in a higher level. Transfer the flags and
** address size from the local symbol to that in the higher level
** and check for problems.
*/
if (S->Flags & SF_EXPORT) {
if (Sym->Flags & SF_IMPORT) {
/* The symbol is already marked as import */
LIError (&S->RefLines,
"Symbol `%s' is already an import",
GetString (Sym->Name));
}
if ((Sym->Flags & SF_EXPORT) == 0) {
/* Mark the symbol as an export */
Sym->Flags |= SF_EXPORT;
Sym->ExportSize = S->ExportSize;
if (Sym->ExportSize == ADDR_SIZE_DEFAULT) {
/* Use the actual size of the symbol */
Sym->ExportSize = Sym->AddrSize;
}
if (Sym->AddrSize > Sym->ExportSize) {
/* We're exporting a symbol smaller than it actually is */
LIWarning (&Sym->DefLines, 1,
"Symbol `%m%p' is %s but exported %s",
GetSymName (Sym),
AddrSizeToStr (Sym->AddrSize),
AddrSizeToStr (Sym->ExportSize));
}
}
}
if (S->Flags & SF_REFERENCED) {
/* Mark as referenced and move the line info */
Sym->Flags |= SF_REFERENCED;
CollTransfer (&Sym->RefLines, &S->RefLines);
CollDeleteAll (&S->RefLines);
}
/* Transfer all expression references */
SymTransferExprRefs (S, Sym);
/* Mark the symbol as unused removing all other flags */
S->Flags = SF_UNUSED;
} else {
/* The symbol is definitely undefined */
if (S->Flags & SF_EXPORT) {
/* We will not auto-import an export */
LIError (&S->RefLines,
"Exported symbol `%m%p' was never defined",
GetSymName (S));
} else {
if (AutoImport) {
/* Mark as import, will be indexed later */
S->Flags |= SF_IMPORT;
/* Use the address size for code */
S->AddrSize = CodeAddrSize;
/* Mark point of import */
GetFullLineInfo (&S->DefLines);
} else {
/* Error */
LIError (&S->RefLines,
"Symbol `%m%p' is undefined",
GetSymName (S));
}
}
}
}
void SymCheck (void)
/* Run through all symbols and check for anomalies and errors */
{
SymEntry* S;
/* Check for open scopes */
if (CurrentScope->Parent != 0) {
Error ("Local scope was not closed");
}
/* First pass: Walk through all symbols, checking for undefined's and
** changing them to trampoline symbols or make them imports.
*/
S = SymList;
while (S) {
/* If the symbol is marked as global, mark it as export, if it is
** already defined, otherwise mark it as import.
*/
if (S->Flags & SF_GLOBAL) {
if (S->Flags & SF_DEFINED) {
SymExportFromGlobal (S);
} else {
SymImportFromGlobal (S);
}
}
/* Handle undefined symbols */
if ((S->Flags & SF_UNDEFMASK) == SF_UNDEFVAL) {
/* This is an undefined symbol. Handle it. */
SymCheckUndefined (S);
}
/* Next symbol */
S = S->List;
}
/* Second pass: Walk again through the symbols. Count exports and imports
** and set address sizes where this has not happened before. Ignore
** undefined's, since we handled them in the last pass, and ignore unused
** symbols, since we handled them in the last pass, too.
*/
S = SymList;
while (S) {
if ((S->Flags & SF_UNUSED) == 0 &&
(S->Flags & SF_UNDEFMASK) != SF_UNDEFVAL) {
/* Check for defined symbols that were never referenced */
if (IsSizeOfSymbol (S)) {
/* Remove line infos, we don't need them any longer */
ReleaseFullLineInfo (&S->DefLines);
ReleaseFullLineInfo (&S->RefLines);
} else if ((S->Flags & SF_DEFINED) != 0 && (S->Flags & SF_REFERENCED) == 0) {
LIWarning (&S->DefLines, 2,
"Symbol `%m%p' is defined but never used",
GetSymName (S));
}
/* Assign an index to all imports */
if (S->Flags & SF_IMPORT) {
if ((S->Flags & (SF_REFERENCED | SF_FORCED)) == SF_NONE) {
/* Imported symbol is not referenced */
LIWarning (&S->DefLines, 2,
"Symbol `%m%p' is imported but never used",
GetSymName (S));
} else {
/* Give the import an id, count imports */
S->ImportId = ImportCount++;
}
}
/* Count exports, assign the export ID */
if (S->Flags & SF_EXPORT) {
S->ExportId = ExportCount++;
}
/* If the symbol is defined but has an unknown address size,
** recalculate it.
*/
if (SymHasExpr (S) && S->AddrSize == ADDR_SIZE_DEFAULT) {
ExprDesc ED;
ED_Init (&ED);
StudyExpr (S->Expr, &ED);
S->AddrSize = ED.AddrSize;
if (SymIsExport (S)) {
if (S->ExportSize == ADDR_SIZE_DEFAULT) {
/* Use the real export size */
S->ExportSize = S->AddrSize;
} else if (S->AddrSize > S->ExportSize) {
/* We're exporting a symbol smaller than it actually is */
LIWarning (&S->DefLines, 1,
"Symbol `%m%p' is %s but exported %s",
GetSymName (S),
AddrSizeToStr (S->AddrSize),
AddrSizeToStr (S->ExportSize));
}
}
ED_Done (&ED);
}
/* If the address size of the symbol was guessed, check the guess
** against the actual address size and print a warning if the two
** differ.
*/
if (S->AddrSize != ADDR_SIZE_DEFAULT) {
/* Do we have data for this address size? */
if (S->AddrSize <= sizeof (S->GuessedUse) / sizeof (S->GuessedUse[0])) {
/* Get the file position where the symbol was used */
const FilePos* P = S->GuessedUse[S->AddrSize - 1];
if (P) {
PWarning (P, 0,
"Didn't use %s addressing for `%m%p'",
AddrSizeToStr (S->AddrSize),
GetSymName (S));
}
}
}
}
/* Next symbol */
S = S->List;
}
}
void SymDump (FILE* F)
/* Dump the symbol table */
{
SymEntry* S = SymList;
while (S) {
/* Ignore unused symbols */
if ((S->Flags & SF_UNUSED) == 0) {
fprintf (F,
"%-24s %s %s %s %s %s\n",
SB_GetConstBuf (GetSymName (S)),
(S->Flags & SF_DEFINED)? "DEF" : "---",
(S->Flags & SF_REFERENCED)? "REF" : "---",
(S->Flags & SF_IMPORT)? "IMP" : "---",
(S->Flags & SF_EXPORT)? "EXP" : "---",
AddrSizeToStr (S->AddrSize));
}
/* Next symbol */
S = S->List;
}
}
void WriteImports (void)
/* Write the imports list to the object file */
{
SymEntry* S;
/* Tell the object file module that we're about to start the imports */
ObjStartImports ();
/* Write the import count to the list */
ObjWriteVar (ImportCount);
/* Walk throught list and write all valid imports to the file. An import
** is considered valid, if it is either referenced, or the forced bit is
** set. Otherwise, the import is ignored (no need to link in something
** that isn't used).
*/
S = SymList;
while (S) {
if ((S->Flags & (SF_UNUSED | SF_IMPORT)) == SF_IMPORT &&
(S->Flags & (SF_REFERENCED | SF_FORCED)) != 0) {
ObjWrite8 (S->AddrSize);
ObjWriteVar (S->Name);
WriteLineInfo (&S->DefLines);
WriteLineInfo (&S->RefLines);
}
S = S->List;
}
/* Done writing imports */
ObjEndImports ();
}
void WriteExports (void)
/* Write the exports list to the object file */
{
SymEntry* S;
unsigned Type;
/* Tell the object file module that we're about to start the exports */
ObjStartExports ();
/* Write the export count to the list */
ObjWriteVar (ExportCount);
/* Walk throught list and write all exports to the file */
S = SymList;
while (S) {
if ((S->Flags & (SF_UNUSED | SF_EXPORT)) == SF_EXPORT) {
/* Get the expression bits and the value */
long ConstVal;
unsigned SymFlags = GetSymInfoFlags (S, &ConstVal);
/* Check if this symbol has a size. If so, remember it in the
** flags.
*/
long Size;
SymEntry* SizeSym = FindSizeOfSymbol (S);
if (SizeSym != 0 && SymIsConst (SizeSym, &Size)) {
SymFlags |= SYM_SIZE;
}
/* Count the number of ConDes types */
for (Type = 0; Type < CD_TYPE_COUNT; ++Type) {
if (S->ConDesPrio[Type] != CD_PRIO_NONE) {
SYM_INC_CONDES_COUNT (SymFlags);
}
}
/* Write the type and the export size */
ObjWriteVar (SymFlags);
ObjWrite8 (S->ExportSize);
/* Write any ConDes declarations */
if (SYM_GET_CONDES_COUNT (SymFlags) > 0) {
for (Type = 0; Type < CD_TYPE_COUNT; ++Type) {
unsigned char Prio = S->ConDesPrio[Type];
if (Prio != CD_PRIO_NONE) {
ObjWrite8 (CD_BUILD (Type, Prio));
}
}
}
/* Write the name */
ObjWriteVar (S->Name);
/* Write the value */
if (SYM_IS_CONST (SymFlags)) {
/* Constant value */
ObjWrite32 (ConstVal);
} else {
/* Expression involved */
WriteExpr (S->Expr);
}
/* If the symbol has a size, write it to the file */
if (SYM_HAS_SIZE (SymFlags)) {
ObjWriteVar (Size);
}
/* Write the line infos */
WriteLineInfo (&S->DefLines);
WriteLineInfo (&S->RefLines);
}
S = S->List;
}
/* Done writing exports */
ObjEndExports ();
}
void WriteDbgSyms (void)
/* Write a list of all symbols to the object file */
{
unsigned Count;
SymEntry* S;
/* Tell the object file module that we're about to start the debug info */
ObjStartDbgSyms ();
/* Check if debug info is requested */
if (DbgSyms) {
/* Walk through the list, give each symbol an id and count them */
Count = 0;
S = SymList;
while (S) {
if (IsDbgSym (S)) {
S->DebugSymId = Count++;
}
S = S->List;
}
/* Write the symbol count to the list */
ObjWriteVar (Count);
/* Walk through list and write all symbols to the file. Ignore size
** symbols.
*/
S = SymList;
while (S) {
if (IsDbgSym (S)) {
/* Get the expression bits and the value */
long ConstVal;
unsigned SymFlags = GetSymInfoFlags (S, &ConstVal);
/* Check if this symbol has a size. If so, remember it in the
** flags.
*/
long Size;
SymEntry* SizeSym = FindSizeOfSymbol (S);
if (SizeSym != 0 && SymIsConst (SizeSym, &Size)) {
SymFlags |= SYM_SIZE;
}
/* Write the type */
ObjWriteVar (SymFlags);
/* Write the address size */
ObjWrite8 (S->AddrSize);
/* Write the id of the parent. For normal symbols, this is a
** scope (symbol table), for cheap locals, it's a symbol.
*/
if (SYM_IS_STD (SymFlags)) {
ObjWriteVar (S->Sym.Tab->Id);
} else {
ObjWriteVar (S->Sym.Entry->DebugSymId);
}
/* Write the name */
ObjWriteVar (S->Name);
/* Write the value */
if (SYM_IS_CONST (SymFlags)) {
/* Constant value */
ObjWrite32 (ConstVal);
} else {
/* Expression involved */
WriteExpr (S->Expr);
}
/* If the symbol has a size, write it to the file */
if (SYM_HAS_SIZE (SymFlags)) {
ObjWriteVar (Size);
}
/* If the symbol is an im- or export, write out the ids */
if (SYM_IS_IMPORT (SymFlags)) {
ObjWriteVar (GetSymImportId (S));
}
if (SYM_IS_EXPORT (SymFlags)) {
ObjWriteVar (GetSymExportId (S));
}
/* Write the line infos */
WriteLineInfo (&S->DefLines);
WriteLineInfo (&S->RefLines);
}
S = S->List;
}
} else {
/* No debug symbols */
ObjWriteVar (0);
}
/* Write the high level symbols */
WriteHLLDbgSyms ();
/* Done writing debug symbols */
ObjEndDbgSyms ();
}
void WriteScopes (void)
/* Write the scope table to the object file */
{
/* Tell the object file module that we're about to start the scopes */
ObjStartScopes ();
/* We will write scopes only if debug symbols are requested */
if (DbgSyms) {
/* Get head of list */
SymTable* S = RootScope;
/* Write the scope count to the file */
ObjWriteVar (ScopeCount);
/* Walk through all scopes and write them to the file */
while (S) {
/* Flags for this scope */
unsigned Flags = 0;
/* Check if this scope has a size. If so, remember it in the
** flags.
*/
long Size;
SymEntry* SizeSym = FindSizeOfScope (S);
if (SizeSym != 0 && SymIsConst (SizeSym, &Size)) {
Flags |= SCOPE_SIZE;
}
/* Check if the scope has a label */
if (S->Label) {
Flags |= SCOPE_LABELED;
}
/* Scope must be defined */
CHECK (S->Type != SCOPE_UNDEF);
/* Id of parent scope */
if (S->Parent) {
ObjWriteVar (S->Parent->Id);
} else {
ObjWriteVar (0);
}
/* Lexical level */
ObjWriteVar (S->Level);
/* Scope flags */
ObjWriteVar (Flags);
/* Type of scope */
ObjWriteVar (S->Type);
/* Name of the scope */
ObjWriteVar (S->Name);
/* If the scope has a size, write it to the file */
if (SCOPE_HAS_SIZE (Flags)) {
ObjWriteVar (Size);
}
/* If the scope has a label, write its id to the file */
if (SCOPE_HAS_LABEL (Flags)) {
ObjWriteVar (S->Label->DebugSymId);
}
/* Spans for this scope */
WriteSpanList (&S->Spans);
/* Next scope */
S = S->Next;
}
} else {
/* No debug info requested */
ObjWriteVar (0);
}
/* Done writing the scopes */
ObjEndScopes ();
}