/* ----------------------------------------------------------------------------- * * (c) The GHC Team, 1994-2000. * * Heap printer * * ---------------------------------------------------------------------------*/ #include "PosixSource.h" #include "Rts.h" #include "rts/Bytecodes.h" /* for InstrPtr */ #include "sm/Storage.h" #include "Printer.h" #include "RtsUtils.h" #include #ifdef DEBUG #include "Disassembler.h" #include "Apply.h" /* -------------------------------------------------------------------------- * local function decls * ------------------------------------------------------------------------*/ static void printStdObjPayload( StgClosure *obj ); #ifdef USING_LIBBFD static void reset_table ( int size ); static void prepare_table ( void ); static void insert ( StgWord value, const char *name ); #endif #if 0 /* unused but might be useful sometime */ static rtsBool lookup_name ( char *name, StgWord *result ); static void enZcode ( char *in, char *out ); #endif static char unZcode ( char ch ); static void printZcoded ( const char *raw ); /* -------------------------------------------------------------------------- * Printer * ------------------------------------------------------------------------*/ void printPtr( StgPtr p ) { const char *raw; raw = lookupGHCName(p); if (raw != NULL) { printZcoded(raw); } else { debugBelch("%p", p); } } void printObj( StgClosure *obj ) { debugBelch("Object "); printPtr((StgPtr)obj); debugBelch(" = "); printClosure(obj); } STATIC_INLINE void printStdObjHdr( StgClosure *obj, char* tag ) { debugBelch("%s(",tag); printPtr((StgPtr)obj->header.info); #ifdef PROFILING debugBelch(", %s", obj->header.prof.ccs->cc->label); #endif } static void printStdObjPayload( StgClosure *obj ) { StgWord i, j; const StgInfoTable* info; info = get_itbl(obj); for (i = 0; i < info->layout.payload.ptrs; ++i) { debugBelch(", "); printPtr((StgPtr)obj->payload[i]); } for (j = 0; j < info->layout.payload.nptrs; ++j) { debugBelch(", %pd#",obj->payload[i+j]); } debugBelch(")\n"); } static void printThunkPayload( StgThunk *obj ) { StgWord i, j; const StgInfoTable* info; info = get_itbl((StgClosure *)obj); for (i = 0; i < info->layout.payload.ptrs; ++i) { debugBelch(", "); printPtr((StgPtr)obj->payload[i]); } for (j = 0; j < info->layout.payload.nptrs; ++j) { debugBelch(", %pd#",obj->payload[i+j]); } debugBelch(")\n"); } static void printThunkObject( StgThunk *obj, char* tag ) { printStdObjHdr( (StgClosure *)obj, tag ); printThunkPayload( obj ); } void printClosure( StgClosure *obj ) { obj = UNTAG_CLOSURE(obj); StgInfoTable *info; info = get_itbl(obj); switch ( info->type ) { case INVALID_OBJECT: barf("Invalid object"); case CONSTR: case CONSTR_1_0: case CONSTR_0_1: case CONSTR_1_1: case CONSTR_0_2: case CONSTR_2_0: case CONSTR_STATIC: case CONSTR_NOCAF_STATIC: { StgWord i, j; StgConInfoTable *con_info = get_con_itbl (obj); debugBelch("%s(", GET_CON_DESC(con_info)); for (i = 0; i < info->layout.payload.ptrs; ++i) { if (i != 0) debugBelch(", "); printPtr((StgPtr)obj->payload[i]); } for (j = 0; j < info->layout.payload.nptrs; ++j) { if (i != 0 || j != 0) debugBelch(", "); debugBelch("%p#", obj->payload[i+j]); } debugBelch(")\n"); break; } case FUN: case FUN_1_0: case FUN_0_1: case FUN_1_1: case FUN_0_2: case FUN_2_0: case FUN_STATIC: debugBelch("FUN/%d(",(int)itbl_to_fun_itbl(info)->f.arity); printPtr((StgPtr)obj->header.info); #ifdef PROFILING debugBelch(", %s", obj->header.prof.ccs->cc->label); #endif printStdObjPayload(obj); break; case PRIM: debugBelch("PRIM("); printPtr((StgPtr)obj->header.info); printStdObjPayload(obj); break; case MUT_PRIM: debugBelch("MUT_PRIM("); printPtr((StgPtr)obj->header.info); printStdObjPayload(obj); break; case THUNK: case THUNK_1_0: case THUNK_0_1: case THUNK_1_1: case THUNK_0_2: case THUNK_2_0: case THUNK_STATIC: /* ToDo: will this work for THUNK_STATIC too? */ #ifdef PROFILING printThunkObject((StgThunk *)obj,GET_PROF_DESC(info)); #else printThunkObject((StgThunk *)obj,"THUNK"); #endif break; case THUNK_SELECTOR: printStdObjHdr(obj, "THUNK_SELECTOR"); debugBelch(", %p)\n", ((StgSelector *)obj)->selectee); break; case BCO: disassemble( (StgBCO*)obj ); break; case AP: { StgAP* ap = (StgAP*)obj; StgWord i; debugBelch("AP("); printPtr((StgPtr)ap->fun); for (i = 0; i < ap->n_args; ++i) { debugBelch(", "); printPtr((P_)ap->payload[i]); } debugBelch(")\n"); break; } case PAP: { StgPAP* pap = (StgPAP*)obj; StgWord i; debugBelch("PAP/%d(",(int)pap->arity); printPtr((StgPtr)pap->fun); for (i = 0; i < pap->n_args; ++i) { debugBelch(", "); printPtr((StgPtr)pap->payload[i]); } debugBelch(")\n"); break; } case AP_STACK: { StgAP_STACK* ap = (StgAP_STACK*)obj; StgWord i; debugBelch("AP_STACK("); printPtr((StgPtr)ap->fun); for (i = 0; i < ap->size; ++i) { debugBelch(", "); printPtr((P_)ap->payload[i]); } debugBelch(")\n"); break; } case IND: debugBelch("IND("); printPtr((StgPtr)((StgInd*)obj)->indirectee); debugBelch(")\n"); break; case IND_PERM: debugBelch("IND("); printPtr((StgPtr)((StgInd*)obj)->indirectee); debugBelch(")\n"); break; case IND_STATIC: debugBelch("IND_STATIC("); printPtr((StgPtr)((StgInd*)obj)->indirectee); debugBelch(")\n"); break; case BLACKHOLE: debugBelch("BLACKHOLE("); printPtr((StgPtr)((StgInd*)obj)->indirectee); debugBelch(")\n"); break; /* Cannot happen -- use default case. case RET_BCO: case RET_SMALL: case RET_BIG: case RET_FUN: */ case UPDATE_FRAME: { StgUpdateFrame* u = (StgUpdateFrame*)obj; debugBelch("UPDATE_FRAME("); printPtr((StgPtr)GET_INFO((StgClosure *)u)); debugBelch(","); printPtr((StgPtr)u->updatee); debugBelch(")\n"); break; } case CATCH_FRAME: { StgCatchFrame* u = (StgCatchFrame*)obj; debugBelch("CATCH_FRAME("); printPtr((StgPtr)GET_INFO((StgClosure *)u)); debugBelch(","); printPtr((StgPtr)u->handler); debugBelch(")\n"); break; } case UNDERFLOW_FRAME: { StgUnderflowFrame* u = (StgUnderflowFrame*)obj; debugBelch("UNDERFLOW_FRAME("); printPtr((StgPtr)u->next_chunk); debugBelch(")\n"); break; } case STOP_FRAME: { StgStopFrame* u = (StgStopFrame*)obj; debugBelch("STOP_FRAME("); printPtr((StgPtr)GET_INFO((StgClosure *)u)); debugBelch(")\n"); break; } case ARR_WORDS: { StgWord i; debugBelch("ARR_WORDS(\""); for (i=0; ipayload[i]); debugBelch("\")\n"); break; } case MUT_ARR_PTRS_CLEAN: debugBelch("MUT_ARR_PTRS_CLEAN(size=%" FMT_Word ")\n", (W_)((StgMutArrPtrs *)obj)->ptrs); break; case MUT_ARR_PTRS_DIRTY: debugBelch("MUT_ARR_PTRS_DIRTY(size=%" FMT_Word ")\n", (W_)((StgMutArrPtrs *)obj)->ptrs); break; case MUT_ARR_PTRS_FROZEN: debugBelch("MUT_ARR_PTRS_FROZEN(size=%" FMT_Word ")\n", (W_)((StgMutArrPtrs *)obj)->ptrs); break; case MVAR_CLEAN: case MVAR_DIRTY: { StgMVar* mv = (StgMVar*)obj; debugBelch("MVAR(head=%p, tail=%p, value=%p)\n", mv->head, mv->tail, mv->value); break; } case TVAR: { StgTVar* tv = (StgTVar*)obj; debugBelch("TVAR(value=%p, wq=%p, num_updates=%" FMT_Word ")\n", tv->current_value, tv->first_watch_queue_entry, tv->num_updates); break; } case MUT_VAR_CLEAN: { StgMutVar* mv = (StgMutVar*)obj; debugBelch("MUT_VAR_CLEAN(var=%p)\n", mv->var); break; } case MUT_VAR_DIRTY: { StgMutVar* mv = (StgMutVar*)obj; debugBelch("MUT_VAR_DIRTY(var=%p)\n", mv->var); break; } case WEAK: debugBelch("WEAK("); debugBelch(" key=%p value=%p finalizer=%p", (StgPtr)(((StgWeak*)obj)->key), (StgPtr)(((StgWeak*)obj)->value), (StgPtr)(((StgWeak*)obj)->finalizer)); debugBelch(")\n"); /* ToDo: chase 'link' ? */ break; case TSO: debugBelch("TSO("); debugBelch("%lu (%p)",(unsigned long)(((StgTSO*)obj)->id), (StgTSO*)obj); debugBelch(")\n"); break; case STACK: debugBelch("STACK"); break; #if 0 /* Symptomatic of a problem elsewhere, have it fall-through & fail */ case EVACUATED: debugBelch("EVACUATED("); printClosure((StgEvacuated*)obj->evacuee); debugBelch(")\n"); break; #endif default: //barf("printClosure %d",get_itbl(obj)->type); debugBelch("*** printClosure: unknown type %d ****\n", (int)get_itbl(obj)->type ); barf("printClosure %d",get_itbl(obj)->type); return; } } /* void printGraph( StgClosure *obj ) { printClosure(obj); } */ StgPtr printStackObj( StgPtr sp ) { /*debugBelch("Stack[%d] = ", &stgStack[STACK_SIZE] - sp); */ StgClosure* c = (StgClosure*)(*sp); printPtr((StgPtr)*sp); if (c == (StgClosure*)&stg_ctoi_R1p_info) { debugBelch("\t\t\tstg_ctoi_ret_R1p_info\n" ); } else if (c == (StgClosure*)&stg_ctoi_R1n_info) { debugBelch("\t\t\tstg_ctoi_ret_R1n_info\n" ); } else if (c == (StgClosure*)&stg_ctoi_F1_info) { debugBelch("\t\t\tstg_ctoi_ret_F1_info\n" ); } else if (c == (StgClosure*)&stg_ctoi_D1_info) { debugBelch("\t\t\tstg_ctoi_ret_D1_info\n" ); } else if (c == (StgClosure*)&stg_ctoi_V_info) { debugBelch("\t\t\tstg_ctoi_ret_V_info\n" ); } else if (get_itbl(c)->type == BCO) { debugBelch("\t\t\t"); debugBelch("BCO(...)\n"); } else { debugBelch("\t\t\t"); printClosure ( (StgClosure*)(*sp)); } sp += 1; return sp; } static void printSmallBitmap( StgPtr spBottom, StgPtr payload, StgWord bitmap, nat size ) { nat i; for(i = 0; i < size; i++, bitmap >>= 1 ) { debugBelch(" stk[%ld] (%p) = ", (long)(spBottom-(payload+i)), payload+i); if ((bitmap & 1) == 0) { printPtr((P_)payload[i]); debugBelch("\n"); } else { debugBelch("Word# %" FMT_Word "\n", (W_)payload[i]); } } } static void printLargeBitmap( StgPtr spBottom, StgPtr payload, StgLargeBitmap* large_bitmap, nat size ) { StgWord bmp; nat i, j; i = 0; for (bmp=0; i < size; bmp++) { StgWord bitmap = large_bitmap->bitmap[bmp]; j = 0; for(; i < size && j < BITS_IN(W_); j++, i++, bitmap >>= 1 ) { debugBelch(" stk[%" FMT_Word "] (%p) = ", (W_)(spBottom-(payload+i)), payload+i); if ((bitmap & 1) == 0) { printPtr((P_)payload[i]); debugBelch("\n"); } else { debugBelch("Word# %" FMT_Word "\n", (W_)payload[i]); } } } } void printStackChunk( StgPtr sp, StgPtr spBottom ) { StgWord bitmap; const StgInfoTable *info; ASSERT(sp <= spBottom); for (; sp < spBottom; sp += stack_frame_sizeW((StgClosure *)sp)) { info = get_itbl((StgClosure *)sp); switch (info->type) { case UPDATE_FRAME: case CATCH_FRAME: case UNDERFLOW_FRAME: case STOP_FRAME: printObj((StgClosure*)sp); continue; case RET_SMALL: debugBelch("RET_SMALL (%p)\n", info); bitmap = info->layout.bitmap; printSmallBitmap(spBottom, sp+1, BITMAP_BITS(bitmap), BITMAP_SIZE(bitmap)); continue; case RET_BCO: { StgBCO *bco; bco = ((StgBCO *)sp[1]); debugBelch("RET_BCO (%p)\n", sp); printLargeBitmap(spBottom, sp+2, BCO_BITMAP(bco), BCO_BITMAP_SIZE(bco)); continue; } case RET_BIG: barf("todo"); case RET_FUN: { StgFunInfoTable *fun_info; StgRetFun *ret_fun; ret_fun = (StgRetFun *)sp; fun_info = get_fun_itbl(ret_fun->fun); debugBelch("RET_FUN (%p) (type=%d)\n", ret_fun->fun, (int)fun_info->f.fun_type); switch (fun_info->f.fun_type) { case ARG_GEN: printSmallBitmap(spBottom, sp+2, BITMAP_BITS(fun_info->f.b.bitmap), BITMAP_SIZE(fun_info->f.b.bitmap)); break; case ARG_GEN_BIG: printLargeBitmap(spBottom, sp+2, GET_FUN_LARGE_BITMAP(fun_info), GET_FUN_LARGE_BITMAP(fun_info)->size); break; default: printSmallBitmap(spBottom, sp+2, BITMAP_BITS(stg_arg_bitmaps[fun_info->f.fun_type]), BITMAP_SIZE(stg_arg_bitmaps[fun_info->f.fun_type])); break; } continue; } default: debugBelch("unknown object %d\n", (int)info->type); barf("printStackChunk"); } } } void printTSO( StgTSO *tso ) { printStackChunk( tso->stackobj->sp, tso->stackobj->stack+tso->stackobj->stack_size); } /* -------------------------------------------------------------------------- * Address printing code * * Uses symbol table in (unstripped executable) * ------------------------------------------------------------------------*/ /* -------------------------------------------------------------------------- * Simple lookup table * * Current implementation is pretty dumb! * ------------------------------------------------------------------------*/ struct entry { StgWord value; const char *name; }; static nat table_size; static struct entry* table; #ifdef USING_LIBBFD static nat max_table_size; static void reset_table( int size ) { max_table_size = size; table_size = 0; table = (struct entry *)stgMallocBytes(size * sizeof(struct entry), "Printer.c:reset_table()"); } static void prepare_table( void ) { /* Could sort it... */ } static void insert( StgWord value, const char *name ) { if ( table_size >= max_table_size ) { barf( "Symbol table overflow\n" ); } table[table_size].value = value; table[table_size].name = name; table_size = table_size + 1; } #endif #if 0 static rtsBool lookup_name( char *name, StgWord *result ) { nat i; for( i = 0; i < table_size && strcmp(name,table[i].name) != 0; ++i ) { } if (i < table_size) { *result = table[i].value; return rtsTrue; } else { return rtsFalse; } } #endif /* Code from somewhere inside GHC (circa 1994) * * Z-escapes: * "std"++xs -> "Zstd"++xs * char_to_c 'Z' = "ZZ" * char_to_c '&' = "Za" * char_to_c '|' = "Zb" * char_to_c ':' = "Zc" * char_to_c '/' = "Zd" * char_to_c '=' = "Ze" * char_to_c '>' = "Zg" * char_to_c '#' = "Zh" * char_to_c '<' = "Zl" * char_to_c '-' = "Zm" * char_to_c '!' = "Zn" * char_to_c '.' = "Zo" * char_to_c '+' = "Zp" * char_to_c '\'' = "Zq" * char_to_c '*' = "Zt" * char_to_c '_' = "Zu" * char_to_c c = "Z" ++ show (ord c) */ static char unZcode( char ch ) { switch (ch) { case 'a' : return ('&'); case 'b' : return ('|'); case 'c' : return (':'); case 'd' : return ('/'); case 'e' : return ('='); case 'g' : return ('>'); case 'h' : return ('#'); case 'l' : return ('<'); case 'm' : return ('-'); case 'n' : return ('!'); case 'o' : return ('.'); case 'p' : return ('+'); case 'q' : return ('\''); case 't' : return ('*'); case 'u' : return ('_'); case 'Z' : case '\0' : return ('Z'); default : return (ch); } } #if 0 /* Precondition: out big enough to handle output (about twice length of in) */ static void enZcode( char *in, char *out ) { int i, j; j = 0; out[ j++ ] = '_'; for( i = 0; in[i] != '\0'; ++i ) { switch (in[i]) { case 'Z' : out[j++] = 'Z'; out[j++] = 'Z'; break; case '&' : out[j++] = 'Z'; out[j++] = 'a'; break; case '|' : out[j++] = 'Z'; out[j++] = 'b'; break; case ':' : out[j++] = 'Z'; out[j++] = 'c'; break; case '/' : out[j++] = 'Z'; out[j++] = 'd'; break; case '=' : out[j++] = 'Z'; out[j++] = 'e'; break; case '>' : out[j++] = 'Z'; out[j++] = 'g'; break; case '#' : out[j++] = 'Z'; out[j++] = 'h'; break; case '<' : out[j++] = 'Z'; out[j++] = 'l'; break; case '-' : out[j++] = 'Z'; out[j++] = 'm'; break; case '!' : out[j++] = 'Z'; out[j++] = 'n'; break; case '.' : out[j++] = 'Z'; out[j++] = 'o'; break; case '+' : out[j++] = 'Z'; out[j++] = 'p'; break; case '\'' : out[j++] = 'Z'; out[j++] = 'q'; break; case '*' : out[j++] = 'Z'; out[j++] = 't'; break; case '_' : out[j++] = 'Z'; out[j++] = 'u'; break; default : out[j++] = in[i]; break; } } out[j] = '\0'; } #endif const char *lookupGHCName( void *addr ) { nat i; for( i = 0; i < table_size && table[i].value != (StgWord) addr; ++i ) { } if (i < table_size) { return table[i].name; } else { return NULL; } } static void printZcoded( const char *raw ) { nat j = 0; while ( raw[j] != '\0' ) { if (raw[j] == 'Z') { debugBelch("%c", unZcode(raw[j+1])); j = j + 2; } else { debugBelch("%c", unZcode(raw[j+1])); j = j + 1; } } } /* -------------------------------------------------------------------------- * Symbol table loading * ------------------------------------------------------------------------*/ /* Causing linking trouble on Win32 plats, so I'm disabling this for now. */ #ifdef USING_LIBBFD #include /* Fairly ad-hoc piece of code that seems to filter out a lot of * rubbish like the obj-splitting symbols */ static rtsBool isReal( flagword flags STG_UNUSED, const char *name ) { #if 0 /* ToDo: make this work on BFD */ int tp = type & N_TYPE; if (tp == N_TEXT || tp == N_DATA) { return (name[0] == '_' && name[1] != '_'); } else { return rtsFalse; } #else if (*name == '\0' || (name[0] == 'g' && name[1] == 'c' && name[2] == 'c') || (name[0] == 'c' && name[1] == 'c' && name[2] == '.')) { return rtsFalse; } return rtsTrue; #endif } extern void DEBUG_LoadSymbols( char *name ) { bfd* abfd; char **matching; bfd_init(); abfd = bfd_openr(name, "default"); if (abfd == NULL) { barf("can't open executable %s to get symbol table", name); } if (!bfd_check_format_matches (abfd, bfd_object, &matching)) { barf("mismatch"); } { long storage_needed; asymbol **symbol_table; long number_of_symbols; long num_real_syms = 0; long i; storage_needed = bfd_get_symtab_upper_bound (abfd); if (storage_needed < 0) { barf("can't read symbol table"); } #if 0 if (storage_needed == 0) { debugBelch("no storage needed"); } #endif symbol_table = (asymbol **) stgMallocBytes(storage_needed,"DEBUG_LoadSymbols"); number_of_symbols = bfd_canonicalize_symtab (abfd, symbol_table); if (number_of_symbols < 0) { barf("can't canonicalise symbol table"); } for( i = 0; i != number_of_symbols; ++i ) { symbol_info info; bfd_get_symbol_info(abfd,symbol_table[i],&info); /*debugBelch("\t%c\t0x%x \t%s\n",info.type,(nat)info.value,info.name); */ if (isReal(info.type, info.name)) { num_real_syms += 1; } } IF_DEBUG(interpreter, debugBelch("Loaded %ld symbols. Of which %ld are real symbols\n", number_of_symbols, num_real_syms) ); reset_table( num_real_syms ); for( i = 0; i != number_of_symbols; ++i ) { symbol_info info; bfd_get_symbol_info(abfd,symbol_table[i],&info); if (isReal(info.type, info.name)) { insert( info.value, info.name ); } } stgFree(symbol_table); } prepare_table(); } #else /* HAVE_BFD_H */ extern void DEBUG_LoadSymbols( char *name STG_UNUSED ) { /* nothing, yet */ } #endif /* HAVE_BFD_H */ void findPtr(P_ p, int); /* keep gcc -Wall happy */ int searched = 0; static int findPtrBlocks (StgPtr p, bdescr *bd, StgPtr arr[], int arr_size, int i) { StgPtr q, r, end; for (; bd; bd = bd->link) { searched++; for (q = bd->start; q < bd->free; q++) { if (UNTAG_CLOSURE((StgClosure*)*q) == (StgClosure *)p) { if (i < arr_size) { for (r = bd->start; r < bd->free; r = end) { // skip over zeroed-out slop while (*r == 0) r++; if (!LOOKS_LIKE_CLOSURE_PTR(r)) { debugBelch("%p found at %p, no closure at %p\n", p, q, r); break; } end = r + closure_sizeW((StgClosure*)r); if (q < end) { debugBelch("%p = ", r); printClosure((StgClosure *)r); arr[i++] = r; break; } } if (r >= bd->free) { debugBelch("%p found at %p, closure?", p, q); } } else { return i; } } } } return i; } void findPtr(P_ p, int follow) { nat g, n; bdescr *bd; const int arr_size = 1024; StgPtr arr[arr_size]; int i = 0; searched = 0; for (n = 0; n < n_capabilities; n++) { bd = nurseries[i].blocks; i = findPtrBlocks(p,bd,arr,arr_size,i); if (i >= arr_size) return; } for (g = 0; g < RtsFlags.GcFlags.generations; g++) { bd = generations[g].blocks; i = findPtrBlocks(p,bd,arr,arr_size,i); bd = generations[g].large_objects; i = findPtrBlocks(p,bd,arr,arr_size,i); if (i >= arr_size) return; } if (follow && i == 1) { debugBelch("-->\n"); findPtr(arr[0], 1); } } /* prettyPrintClosure() is for printing out a closure using the data constructor names found in the info tables. Closures are printed in a fashion that resembles their Haskell representation. Useful during debugging. Todo: support for more closure types, and support for non pointer fields in the payload. */ void prettyPrintClosure_ (StgClosure *); void prettyPrintClosure (StgClosure *obj) { prettyPrintClosure_ (obj); debugBelch ("\n"); } void prettyPrintClosure_ (StgClosure *obj) { StgInfoTable *info; StgConInfoTable *con_info; /* collapse any indirections */ unsigned int type; type = get_itbl(obj)->type; while (type == IND || type == IND_STATIC || type == IND_PERM) { obj = ((StgInd *)obj)->indirectee; type = get_itbl(obj)->type; } /* find the info table for this object */ info = get_itbl(obj); /* determine what kind of object we have */ switch (info->type) { /* full applications of data constructors */ case CONSTR: case CONSTR_1_0: case CONSTR_0_1: case CONSTR_1_1: case CONSTR_0_2: case CONSTR_2_0: case CONSTR_STATIC: case CONSTR_NOCAF_STATIC: { nat i; char *descriptor; /* find the con_info for the constructor */ con_info = get_con_itbl (obj); /* obtain the name of the constructor */ descriptor = GET_CON_DESC(con_info); debugBelch ("(%s", descriptor); /* process the payload of the closure */ /* we don't handle non pointers at the moment */ for (i = 0; i < info->layout.payload.ptrs; i++) { debugBelch (" "); prettyPrintClosure_ ((StgClosure *) obj->payload[i]); } debugBelch (")"); break; } /* if it isn't a constructor then just print the closure type */ default: { debugBelch ("<%s>", info_type(obj)); break; } } } char *what_next_strs[] = { [0] = "(unknown)", [ThreadRunGHC] = "ThreadRunGHC", [ThreadInterpret] = "ThreadInterpret", [ThreadKilled] = "ThreadKilled", [ThreadComplete] = "ThreadComplete" }; #else /* DEBUG */ void printPtr( StgPtr p ) { debugBelch("ptr 0x%p (enable -DDEBUG for more info) " , p ); } void printObj( StgClosure *obj ) { debugBelch("obj 0x%p (enable -DDEBUG for more info) " , obj ); } #endif /* DEBUG */ /* ----------------------------------------------------------------------------- Closure types NOTE: must be kept in sync with the closure types in includes/ClosureTypes.h -------------------------------------------------------------------------- */ char *closure_type_names[] = { [INVALID_OBJECT] = "INVALID_OBJECT", [CONSTR] = "CONSTR", [CONSTR_1_0] = "CONSTR_1_0", [CONSTR_0_1] = "CONSTR_0_1", [CONSTR_2_0] = "CONSTR_2_0", [CONSTR_1_1] = "CONSTR_1_1", [CONSTR_0_2] = "CONSTR_0_2", [CONSTR_STATIC] = "CONSTR_STATIC", [CONSTR_NOCAF_STATIC] = "CONSTR_NOCAF_STATIC", [FUN] = "FUN", [FUN_1_0] = "FUN_1_0", [FUN_0_1] = "FUN_0_1", [FUN_2_0] = "FUN_2_0", [FUN_1_1] = "FUN_1_1", [FUN_0_2] = "FUN_0_2", [FUN_STATIC] = "FUN_STATIC", [THUNK] = "THUNK", [THUNK_1_0] = "THUNK_1_0", [THUNK_0_1] = "THUNK_0_1", [THUNK_2_0] = "THUNK_2_0", [THUNK_1_1] = "THUNK_1_1", [THUNK_0_2] = "THUNK_0_2", [THUNK_STATIC] = "THUNK_STATIC", [THUNK_SELECTOR] = "THUNK_SELECTOR", [BCO] = "BCO", [AP] = "AP", [PAP] = "PAP", [AP_STACK] = "AP_STACK", [IND] = "IND", [IND_PERM] = "IND_PERM", [IND_STATIC] = "IND_STATIC", [RET_BCO] = "RET_BCO", [RET_SMALL] = "RET_SMALL", [RET_BIG] = "RET_BIG", [RET_FUN] = "RET_FUN", [UPDATE_FRAME] = "UPDATE_FRAME", [CATCH_FRAME] = "CATCH_FRAME", [UNDERFLOW_FRAME] = "UNDERFLOW_FRAME", [STOP_FRAME] = "STOP_FRAME", [BLOCKING_QUEUE] = "BLOCKING_QUEUE", [BLACKHOLE] = "BLACKHOLE", [MVAR_CLEAN] = "MVAR_CLEAN", [MVAR_DIRTY] = "MVAR_DIRTY", [TVAR] = "TVAR", [ARR_WORDS] = "ARR_WORDS", [MUT_ARR_PTRS_CLEAN] = "MUT_ARR_PTRS_CLEAN", [MUT_ARR_PTRS_DIRTY] = "MUT_ARR_PTRS_DIRTY", [MUT_ARR_PTRS_FROZEN0] = "MUT_ARR_PTRS_FROZEN0", [MUT_ARR_PTRS_FROZEN] = "MUT_ARR_PTRS_FROZEN", [MUT_VAR_CLEAN] = "MUT_VAR_CLEAN", [MUT_VAR_DIRTY] = "MUT_VAR_DIRTY", [WEAK] = "WEAK", [PRIM] = "PRIM", [MUT_PRIM] = "MUT_PRIM", [TSO] = "TSO", [STACK] = "STACK", [TREC_CHUNK] = "TREC_CHUNK", [ATOMICALLY_FRAME] = "ATOMICALLY_FRAME", [CATCH_RETRY_FRAME] = "CATCH_RETRY_FRAME", [CATCH_STM_FRAME] = "CATCH_STM_FRAME", [WHITEHOLE] = "WHITEHOLE" }; char * info_type(StgClosure *closure){ return closure_type_names[get_itbl(closure)->type]; } char * info_type_by_ip(StgInfoTable *ip){ return closure_type_names[ip->type]; } void info_hdr_type(StgClosure *closure, char *res){ strcpy(res,closure_type_names[get_itbl(closure)->type]); }