/* Copyright (C) 2021-2024 Free Software Foundation, Inc. Contributed by Oracle. This file is part of GNU Binutils. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, 51 Franklin Street - Fifth Floor, Boston, MA 02110-1301, USA. */ #include "config.h" #include #include "util.h" #include "CacheMap.h" #include "CallStack.h" #include "DbeSession.h" #include "DbeView.h" #include "DbeLinkList.h" #include "Experiment.h" #include "Exp_Layout.h" #include "Function.h" #include "LoadObject.h" #include "Module.h" Descendants::Descendants () { count = 0; limit = sizeof (first_data) / sizeof (CallStackNode *); data = first_data; } Descendants::~Descendants () { if (data != first_data) free (data); } CallStackNode * Descendants::find (Histable *hi, int *index) { int cnt = count; int left = 0; for (int right = cnt - 1; left <= right;) { int ind = (left + right) / 2; CallStackNode *node = data[ind]; Histable *instr = node->get_instr (); if (instr == hi) { if (index) *index = ind; return node; } if (instr->id < hi->id) right = ind - 1; else left = ind + 1; } if (index) *index = left; return NULL; } void Descendants::append (CallStackNode* item) { if (count < limit) data[count++] = item; else insert (count, item); } void Descendants::insert (int ind, CallStackNode* item) { CallStackNode **old_data = data; int old_cnt = count; if (old_cnt + 1 >= limit) { int new_limit = (limit == 0) ? DELTA : limit * 2; CallStackNode **new_data = (CallStackNode **) xmalloc (new_limit * sizeof (CallStackNode *)); for (int i = 0; i < ind; i++) new_data[i] = old_data[i]; new_data[ind] = item; for (int i = ind; i < old_cnt; i++) new_data[i + 1] = old_data[i]; limit = new_limit; data = new_data; if (old_data != first_data) free (old_data); } else { for (int i = ind; i < old_cnt; i++) old_data[i + 1] = old_data[i]; old_data[ind] = item; } count++; } /* * Private implementation of CallStack interface */ // When performing pipeline optimization on resolve_frame_info + add_stack // cstk_ctx structure contains the state (or context) for one iteration to pass on // from Phase 2 to Phase 3 (More details in Experiment.cc) class CallStackP : public CallStack { public: CallStackP (Experiment *exp); virtual ~CallStackP (); virtual void add_stack (DataDescriptor *dDscr, long idx, FramePacket *frp, cstk_ctx_chunk *cstCtxChunk); virtual void *add_stack (Vector *objs); virtual CallStackNode *get_node (int n); virtual void print (FILE *); private: static const int CHUNKSZ = 16384; Experiment *experiment; CallStackNode *root; CallStackNode *jvm_node; int nodes; int nchunks; CallStackNode **chunks; Map *cstackMap; DbeLock *cstackLock; CallStackNode *add_stack (long start, long end, Vector *objs, CallStackNode *myRoot); CallStackNode *new_Node (CallStackNode*, Histable*); CallStackNode *find_preg_stack (uint64_t); // objs are in the root..leaf order void *add_stack_d (Vector *objs); void add_stack_java (DataDescriptor *dDscr, long idx, FramePacket *frp, hrtime_t tstamp, uint32_t thrid, Vector* natpcs, bool natpc_added, cstk_ctx_chunk *cstCtxChunk); void add_stack_java_epilogue (DataDescriptor *dDscr, long idx, FramePacket *frp, hrtime_t tstamp, uint32_t thrid, Vector* natpcs, Vector* jpcs, bool natpc_added); // Adjust HW counter event to find better trigger PC, etc. DbeInstr *adjustEvent (DbeInstr *leafPC, DbeInstr * candPC, Vaddr &eventEA, int abst_type); Vector *natpcsP; Vector *jpcsP; }; CallStackP::CallStackP (Experiment *exp) { experiment = exp; nchunks = 0; chunks = NULL; nodes = 0; cstackMap = new CacheMap; cstackLock = new DbeLock (); Function *total = dbeSession->get_Total_Function (); root = new_Node (0, total->find_dbeinstr (0, 0)); jvm_node = NULL; natpcsP = NULL; jpcsP = NULL; } CallStackP::~CallStackP () { delete cstackLock; if (chunks) { for (int i = 0; i < nodes; i++) { CallStackNode *node = get_node (i); node->~CallStackNode (); } for (int i = 0; i < nchunks; i++) free (chunks[i]); free (chunks); } delete natpcsP; delete jpcsP; destroy_map (CallStackNode *, cstackMap); } CallStackNode * CallStackP::new_Node (CallStackNode *anc, Histable *pcval) { // cstackLock->aquireLock(); // Caller already locked it if (nodes >= nchunks * CHUNKSZ) { CallStackNode **old_chunks = chunks; nchunks++; // Reallocate Node chunk array chunks = (CallStackNode **) xmalloc (nchunks * sizeof (CallStackNode *)); for (int i = 0; i < nchunks - 1; i++) chunks[i] = old_chunks[i]; free (old_chunks); // Allocate new chunk for nodes. chunks[nchunks - 1] = (CallStackNode *) xmalloc (CHUNKSZ * sizeof (CallStackNode)); } nodes++; CallStackNode *node = get_node (nodes - 1); new (node) CallStackNode (anc, pcval); // cstackLock->releaseLock(); return node; } CallStackNode * CallStackP::find_preg_stack (uint64_t prid) { DataView *dview = experiment->getOpenMPdata (); dview->sort (PROP_CPRID); Datum tval; tval.setUINT64 (prid); long idx = dview->getIdxByVals (&tval, DataView::REL_EQ); if (idx < 0) return root; CallStackNode *node = (CallStackNode*) dview->getObjValue (PROP_USTACK, idx); if (node != NULL) return node; uint64_t pprid = dview->getLongValue (PROP_PPRID, idx); if (pprid == prid) return root; void *nat_stack = dview->getObjValue (PROP_MSTACK, idx); Vector *pcs = getStackPCs (nat_stack); // Find the bottom frame int btm; bool inOMP = false; DbeInstr *instr; Histable *hist; for (btm = 0; btm < pcs->size (); btm++) { hist = pcs->fetch (btm); if (hist->get_type () == Histable::INSTR) instr = (DbeInstr *) hist; else // DBELINE instr = (DbeInstr *) hist->convertto (Histable::INSTR); LoadObject *lo = instr->func->module->loadobject; if (!inOMP) { if (lo->flags & SEG_FLAG_OMP) inOMP = true; } else if (!(lo->flags & SEG_FLAG_OMP)) break; } // Find the top frame dview->sort (PROP_CPRID); int top; tval.setUINT64 (pprid); long pidx = dview->getIdxByVals (&tval, DataView::REL_EQ); if (pidx < 0) // No parent. Process the entire nat_stack top = pcs->size () - 1; else { uint32_t thrid = (uint32_t) dview->getIntValue (PROP_THRID, idx); uint32_t pthrid = (uint32_t) dview->getIntValue (PROP_THRID, pidx); if (thrid != pthrid) { // Parent is on a different stack. // Process the entire nat_stack. Skip libthread. for (top = pcs->size () - 1; top >= 0; top--) { hist = pcs->fetch (top); if (hist->get_type () == Histable::INSTR) instr = (DbeInstr *) hist; else // DBELINE instr = (DbeInstr *) hist->convertto (Histable::INSTR); if (instr->func->module->loadobject->flags & SEG_FLAG_OMP) break; } if (top < 0) // None found. May be incomplete call stack (x86) top = pcs->size () - 1; } else { // Parent is on the same stack. Find match. top = pcs->size () - 1; void *pnat_stack = dview->getObjValue (PROP_MSTACK, pidx); Vector *ppcs = getStackPCs (pnat_stack); for (int ptop = ppcs->size () - 1; top >= 0 && ptop >= 0; top--, ptop--) { if (pcs->fetch (top) != ppcs->fetch (ptop)) break; } delete ppcs; } } // Process the found range Vector *upcs = new Vector(128); for (int i = btm; i <= top; ++i) { hist = (DbeInstr*) pcs->fetch (i); if (hist->get_type () == Histable::INSTR) instr = (DbeInstr *) hist; else // DBELINE instr = (DbeInstr *) hist->convertto (Histable::INSTR); if (instr->func->module->loadobject->flags & SEG_FLAG_OMP) // Skip all frames from libmtsk continue; upcs->append (instr); } delete pcs; node = find_preg_stack (pprid); while (node != root) { upcs->append (node->instr); node = node->ancestor; } node = (CallStackNode *) add_stack (upcs); dview->setObjValue (PROP_USTACK, idx, node); delete upcs; return node; } #define JNI_MARKER -3 // This is one iteration if the third stage of // resolve_frame_info + add_stack pipeline. Works on building the java // stacks void CallStackP::add_stack_java (DataDescriptor *dDscr, long idx, FramePacket *frp, hrtime_t tstamp, uint32_t thrid, Vector* natpcs, bool natpc_added, cstk_ctx_chunk *cstCtxChunk) { Vector *jpcs = NULL; cstk_ctx *cstctx = NULL; if (cstCtxChunk != NULL) { cstctx = cstCtxChunk->cstCtxAr[idx % CSTCTX_CHUNK_SZ]; jpcs = cstctx->jpcs; jpcs->reset (); } if (jpcs == NULL) { // this is when we are not doing the pipeline optimization // Temporary array for resolved addresses // [leaf_pc .. root_pc] == [0..stack_size-1] // Leave room for a possible "truncated" frame if (jpcsP == NULL) jpcsP = new Vector; jpcs = jpcsP; jpcs->reset (); } // // Construct the user stack // // Construct Java user stack int jstack_size = frp->stackSize (true); if (jstack_size) { // jpcs = new Vector( jstack_size ); if (frp->isTruncatedStack (true)) { Function *truncf = dbeSession->getSpecialFunction (DbeSession::TruncatedStackFunc); jpcs->append (truncf->find_dbeinstr (0, 0)); } int nind = natpcs->size () - 1; // first native frame for (int jind = jstack_size - 1; jind >= 0; jind--) { bool jleaf = (jind == 0); // is current java frame a leaf? Vaddr mid = frp->getMthdFromStack (jind); int bci = frp->getBciFromStack (jind); DbeInstr *cur_instr = experiment->map_jmid_to_PC (mid, bci, tstamp); jpcs->append (cur_instr); if (bci == JNI_MARKER) { JMethod *j_method = (JMethod*) cur_instr->func; // Find matching native function on the native stack bool found = false; for (; nind >= 0; nind--) { DbeInstr *nat_addr = (DbeInstr *) natpcs->fetch (nind); if (0 == nat_addr) continue; Function *nat_func = nat_addr->func; if (!found && j_method->jni_match (nat_func)) found = true; if (found) { // XXX omazur: the following will skip JNI native method // implemented in JVM itself. // If we are back in JVM switch to processing Java // frames if there are any. if ((nat_func->module->loadobject->flags & SEG_FLAG_JVM) && !jleaf) break; jpcs->append (nat_addr); } } } } } add_stack_java_epilogue (dDscr, idx, frp, tstamp, thrid, natpcs, jpcs, natpc_added); } // This is one iteration if the fourth stage of // resolve_frame_info + add_stack pipeline. // It adds the native and java stacks to the stackmap void CallStackP::add_stack_java_epilogue (DataDescriptor *dDscr, long idx, FramePacket *frp, hrtime_t tstamp, uint32_t thrid, Vector* natpcs, Vector *jpcs, bool natpc_added) { CallStackNode *node = NULL; if (!natpc_added) { node = (CallStackNode *) add_stack (natpcs); dDscr->setObjValue (PROP_MSTACK, idx, node); dDscr->setObjValue (PROP_XSTACK, idx, node); dDscr->setObjValue (PROP_USTACK, idx, node); } int jstack_size = frp->stackSize (true); if (jstack_size) { if (jpcs != NULL) node = (CallStackNode *) add_stack_d (jpcs); if (node == NULL) node = (CallStackNode*) dDscr->getObjValue (PROP_USTACK, idx); dDscr->setObjValue (PROP_USTACK, idx, node); Function *func = (Function*) node->instr->convertto (Histable::FUNCTION); if (func != dbeSession->get_JUnknown_Function ()) dDscr->setObjValue (PROP_XSTACK, idx, node); } JThread *jthread = experiment->map_pckt_to_Jthread (thrid, tstamp); if (jthread == JTHREAD_NONE && jstack_size != 0 && node != NULL) { Function *func = (Function*) node->instr->convertto (Histable::FUNCTION); if (func != dbeSession->get_JUnknown_Function ()) jthread = JTHREAD_DEFAULT; } dDscr->setObjValue (PROP_JTHREAD, idx, jthread); if (jthread == JTHREAD_NONE || (jthread != JTHREAD_DEFAULT && jthread->is_system ())) { if (jvm_node == NULL) { Function *jvm = dbeSession->get_jvm_Function (); if (jvm) { jvm_node = new_Node (root, jvm->find_dbeinstr (0, 0)); CommonPacket::jvm_overhead = jvm_node; } } dDscr->setObjValue (PROP_USTACK, idx, jvm_node); } } // This is one iteration of the 2nd stage of // resolve_frame_info + add_stack() pipeline. Builds the stack for a given framepacket. // When pipeline optimization is turnd off, cstctxchunk passed is NULL void CallStackP::add_stack (DataDescriptor *dDscr, long idx, FramePacket *frp, cstk_ctx_chunk* cstCtxChunk) { Vector *natpcs = NULL; cstk_ctx *cstctx = NULL; int stack_size = frp->stackSize (); if (cstCtxChunk != NULL) { cstctx = cstCtxChunk->cstCtxAr[idx % CSTCTX_CHUNK_SZ]; natpcs = cstctx->natpcs; natpcs->reset (); } if (natpcs == NULL) { // this is when we are not doing the pipeline optimization // Temporary array for resolved addresses // [leaf_pc .. root_pc] == [0..stack_size-1] // Leave room for a possible "truncated" frame if (natpcsP == NULL) natpcsP = new Vector; natpcs = natpcsP; natpcs->reset (); } bool leaf = true; hrtime_t tstamp = (hrtime_t) dDscr->getLongValue (PROP_TSTAMP, idx); uint32_t thrid = (uint32_t) dDscr->getIntValue (PROP_THRID, idx); enum { NONE, CHECK_O7, USE_O7, SKIP_O7 } state = NONE; Vaddr o7_to_skip = 0; for (int index = 0; index < stack_size; index++) { if (frp->isLeafMark (index)) { state = CHECK_O7; continue; } if (state == SKIP_O7) { // remember this bad o7 value since OMP might not recognize it o7_to_skip = frp->getFromStack (index); state = NONE; continue; } Vaddr va = frp->getFromStack (index); DbeInstr *cur_instr = experiment->map_Vaddr_to_PC (va, tstamp); #if ARCH(Intel)// TBR? FIXUP_XXX_SPARC_LINUX: switch should be on experiment ARCH, not dbe ARCH // We need to adjust return addresses on intel // in order to attribute inclusive metrics to // proper call instructions. if (experiment->exp_maj_version <= 9) if (!leaf && cur_instr->addr != 0) cur_instr = cur_instr->func->find_dbeinstr (0, cur_instr->addr - 1); #endif // Skip PC's from PLT, update leaf and state accordingly if ((cur_instr->func->flags & FUNC_FLAG_PLT) && (leaf || state == CHECK_O7)) { if (state == CHECK_O7) state = USE_O7; leaf = false; continue; } if (state == CHECK_O7) { state = USE_O7; uint64_t saddr = cur_instr->func->save_addr; if (cur_instr->func->isOutlineFunction) // outline functions assume 'save' instruction // Note: they accidentally have saddr == FUNC_ROOT state = SKIP_O7; else if (saddr == FUNC_ROOT) { // If a function is statically determined as a root // but dynamically appears not, don't discard o7. // One such case is __misalign_trap_handler on sparcv9. if (stack_size == 3) state = SKIP_O7; } else if (saddr != FUNC_NO_SAVE && cur_instr->addr > saddr) state = SKIP_O7; } else if (state == USE_O7) { state = NONE; if (cur_instr->flags & PCInvlFlag) continue; } if (leaf) { Vaddr evpc = (Vaddr) dDscr->getLongValue (PROP_VIRTPC, idx); if (evpc != 0 && !(index > 0 && frp->isLeafMark (index - 1) && evpc == (Vaddr) (-1))) { /* contains hwcprof info */ cur_instr->func->module->read_hwcprof_info (); // complete ABS validation of candidate eventPC/eventEA // and correction/adjustment of collected callstack leaf PC DbeInstr *candPC = experiment->map_Vaddr_to_PC (evpc, tstamp); Vaddr vaddr = (Vaddr) dDscr->getLongValue (PROP_VADDR, idx); Vaddr tmp_vaddr = vaddr; int abst_type; uint32_t tag = dDscr->getIntValue (PROP_HWCTAG, idx); if (tag < 0 || tag >= MAX_HWCOUNT) abst_type = ABST_NOPC; else abst_type = experiment->coll_params.hw_tpc[tag]; // We need to adjust addresses for ABST_EXACT_PEBS_PLUS1 // (Nehalem/SandyBridge PEBS identifies PC+1, not PC) if (abst_type == ABST_EXACT_PEBS_PLUS1 && candPC->addr != 0) candPC = candPC->func->find_dbeinstr (0, candPC->func->find_previous_addr (candPC->addr)); cur_instr = adjustEvent (cur_instr, candPC, tmp_vaddr, abst_type); if (vaddr != tmp_vaddr) { if (tmp_vaddr < ABS_CODE_RANGE) { /* post processing backtrack failed */ dDscr->setValue (PROP_VADDR, idx, tmp_vaddr); dDscr->setValue (PROP_PADDR, idx, ABS_NULL); /* hwcp->eventVPC = xxxxx leave eventPC alone, * or can we set it to leafpc? */ dDscr->setValue (PROP_PHYSPC, idx, ABS_NULL); } else { /* internal error: why would post-processing modify vaddr? */ dDscr->setValue (PROP_PADDR, idx, (Vaddr) (-1)); dDscr->setValue (PROP_PHYSPC, idx, (Vaddr) (-1)); } } } } natpcs->append (cur_instr); leaf = false; // A hack to deceive the user into believing that outlined code // is called from the base function DbeInstr *drvd = cur_instr->func->derivedNode; if (drvd != NULL) natpcs->append (drvd); } if (frp->isTruncatedStack ()) { Function *truncf = dbeSession->getSpecialFunction (DbeSession::TruncatedStackFunc); natpcs->append (truncf->find_dbeinstr (0, 0)); } else if (frp->isFailedUnwindStack ()) { Function *funwf = dbeSession->getSpecialFunction (DbeSession::FailedUnwindFunc); natpcs->append (funwf->find_dbeinstr (0, 0)); } CallStackNode *node = (CallStackNode*) add_stack (natpcs); dDscr->setObjValue (PROP_MSTACK, idx, node); dDscr->setObjValue (PROP_XSTACK, idx, node); dDscr->setObjValue (PROP_USTACK, idx, node); // OpenMP 3.0 stacks stack_size = frp->ompstack->size (); if (stack_size > 0 || frp->omp_state == OMP_IDLE_STATE) { Function *func; Vector *omppcs = new Vector(stack_size); Vector *ompxpcs = new Vector(stack_size); switch (frp->omp_state) { case OMP_IDLE_STATE: case OMP_RDUC_STATE: case OMP_IBAR_STATE: case OMP_EBAR_STATE: case OMP_LKWT_STATE: case OMP_CTWT_STATE: case OMP_ODWT_STATE: case OMP_ATWT_STATE: { func = dbeSession->get_OMP_Function (frp->omp_state); DbeInstr *instr = func->find_dbeinstr (0, 0); omppcs->append (instr); ompxpcs->append (instr); break; } } Vector *stck = frp->ompstack; leaf = true; for (int index = 0; index < stack_size; index++) { if (stck->fetch (index) == SP_LEAF_CHECK_MARKER) { state = CHECK_O7; continue; } if (state == SKIP_O7) { state = NONE; continue; } // The OMP stack might not have enough information to know to discard a bad o7. // So just remember what the native stack skipped. if (o7_to_skip == stck->fetch (index)) { state = NONE; continue; } Vaddr va = stck->fetch (index); DbeInstr *cur_instr = experiment->map_Vaddr_to_PC (va, tstamp); // Skip PC's from PLT, update leaf and state accordingly if ((cur_instr->func->flags & FUNC_FLAG_PLT) && (leaf || state == CHECK_O7)) { if (state == CHECK_O7) state = USE_O7; leaf = false; continue; } if (state == CHECK_O7) { state = USE_O7; uint64_t saddr = cur_instr->func->save_addr; if (cur_instr->func->isOutlineFunction) // outline functions assume 'save' instruction // Note: they accidentally have saddr == FUNC_ROOT state = SKIP_O7; else if (saddr == FUNC_ROOT) { // If a function is statically determined as a root // but dynamically appears not, don't discard o7. // One such case is __misalign_trap_handler on sparcv9. if (stack_size == 3) state = SKIP_O7; } else if (saddr != FUNC_NO_SAVE && cur_instr->addr > saddr) state = SKIP_O7; } else if (state == USE_O7) { state = NONE; if (cur_instr->flags & PCInvlFlag) continue; } DbeLine *dbeline = (DbeLine*) cur_instr->convertto (Histable::LINE); if (cur_instr->func->usrfunc) { dbeline = dbeline->sourceFile->find_dbeline (cur_instr->func->usrfunc, dbeline->lineno); omppcs->append (dbeline); } else if (dbeline->lineno > 0) omppcs->append (dbeline); else omppcs->append (cur_instr); if (dbeline->is_set (DbeLine::OMPPRAGMA) && frp->omp_state == OMP_WORK_STATE) dDscr->setValue (PROP_OMPSTATE, idx, OMP_OVHD_STATE); ompxpcs->append (cur_instr); leaf = false; } if (frp->omptruncated == SP_TRUNC_STACK_MARKER) { func = dbeSession->getSpecialFunction (DbeSession::TruncatedStackFunc); DbeInstr *instr = func->find_dbeinstr (0, 0); omppcs->append (instr); ompxpcs->append (instr); } else if (frp->omptruncated == SP_FAILED_UNWIND_MARKER) { func = dbeSession->getSpecialFunction (DbeSession::FailedUnwindFunc); DbeInstr *instr = func->find_dbeinstr (0, 0); omppcs->append (instr); ompxpcs->append (instr); } // User model call stack node = (CallStackNode*) add_stack (omppcs); dDscr->setObjValue (PROP_USTACK, idx, node); delete omppcs; // Expert call stack node = (CallStackNode*) add_stack (ompxpcs); dDscr->setObjValue (PROP_XSTACK, idx, node); delete ompxpcs; dDscr->setObjValue (PROP_JTHREAD, idx, JTHREAD_DEFAULT); return; } // OpenMP 2.5 stacks if (frp->omp_cprid || frp->omp_state) { DataView *dview = experiment->getOpenMPdata (); if (dview == NULL) { // It appears we may get OMP_SERL_STATE from a passive libmtsk dDscr->setObjValue (PROP_JTHREAD, idx, JTHREAD_DEFAULT); return; } if (dview->getDataDescriptor () == dDscr) { // Don't process the user stack for OpenMP fork events yet dDscr->setObjValue (PROP_USTACK, idx, (void*) NULL); dDscr->setObjValue (PROP_JTHREAD, idx, JTHREAD_DEFAULT); return; } Vector *omppcs = new Vector(stack_size); // Construct OMP user stack // Find the bottom frame int btm = 0; switch (frp->omp_state) { case OMP_IDLE_STATE: { Function *func = dbeSession->get_OMP_Function (frp->omp_state); omppcs->append (func->find_dbeinstr (0, 0)); // XXX: workaround for inconsistency between OMP_IDLE_STATE // and omp_cprid != 0 frp->omp_cprid = 0; btm = natpcs->size (); break; } case OMP_RDUC_STATE: case OMP_IBAR_STATE: case OMP_EBAR_STATE: case OMP_LKWT_STATE: case OMP_CTWT_STATE: case OMP_ODWT_STATE: case OMP_ATWT_STATE: { Function *func = dbeSession->get_OMP_Function (frp->omp_state); omppcs->append (func->find_dbeinstr (0, 0)); bool inOMP = false; for (btm = 0; btm < natpcs->size (); btm++) { DbeInstr *instr = (DbeInstr *) natpcs->fetch (btm); LoadObject *lo = instr->func->module->loadobject; if (!inOMP) { if (lo->flags & SEG_FLAG_OMP) inOMP = true; } else if (!(lo->flags & SEG_FLAG_OMP)) break; } break; } case OMP_NO_STATE: case OMP_WORK_STATE: case OMP_SERL_STATE: default: break; } // Find the top frame int top = -1; switch (frp->omp_state) { case OMP_IDLE_STATE: break; default: { dview->sort (PROP_CPRID); Datum tval; tval.setUINT64 (frp->omp_cprid); long pidx = dview->getIdxByVals (&tval, DataView::REL_EQ); if (pidx < 0) // No parent. Process the entire nat_stack top = natpcs->size () - 1; else { uint32_t pthrid = (uint32_t) dview->getIntValue (PROP_THRID, pidx); if (thrid != pthrid) { // Parent is on a different stack. // Process the entire nat_stack. Skip libthread. for (top = natpcs->size () - 1; top >= 0; top--) { DbeInstr *instr = (DbeInstr *) natpcs->fetch (top); if (instr->func->module->loadobject->flags & SEG_FLAG_OMP) break; } if (top < 0) // None found. May be incomplete call stack top = natpcs->size () - 1; } else { // Parent is on the same stack. Find match. top = natpcs->size () - 1; void *pnat_stack = dview->getObjValue (PROP_MSTACK, pidx); Vector *ppcs = getStackPCs (pnat_stack); for (int ptop = ppcs->size () - 1; top >= 0 && ptop >= 0; top--, ptop--) { if (natpcs->fetch (top) != ppcs->fetch (ptop)) break; } delete ppcs; } } // If no frames are found for Barrier/Reduction save at least one if ((frp->omp_state == OMP_RDUC_STATE || frp->omp_state == OMP_IBAR_STATE || frp->omp_state == OMP_EBAR_STATE) && top < btm && btm < natpcs->size ()) top = btm; } } for (int i = btm; i <= top; ++i) { DbeInstr *instr = (DbeInstr *) natpcs->fetch (i); if (instr->func->module->loadobject->flags & SEG_FLAG_OMP) continue; // Skip all frames from libmtsk omppcs->append (instr); } node = find_preg_stack (frp->omp_cprid); while (node != root) { omppcs->append (node->instr); node = node->ancestor; } node = (CallStackNode *) add_stack (omppcs); dDscr->setObjValue (PROP_USTACK, idx, node); delete omppcs; dDscr->setObjValue (PROP_JTHREAD, idx, JTHREAD_DEFAULT); return; } // Construct Java user stack add_stack_java (dDscr, idx, frp, tstamp, thrid, natpcs, true, NULL); } // adjustment of leafPC/eventVA for XHWC packets with candidate eventPC // Called from CallStack during initial processing of the events DbeInstr * CallStackP::adjustEvent (DbeInstr *leafPC, DbeInstr *candPC, Vaddr &eventVA, int abst_type) { // increment counter of dataspace events experiment->dsevents++; bool isPrecise; if (abst_type == ABST_EXACT_PEBS_PLUS1) isPrecise = true; else if (abst_type == ABST_EXACT) isPrecise = true; else isPrecise = false; if (isPrecise) /* precise backtracking */ /* assume within 1 instruction of leaf (this could be checked here) */ // no change to eventVA or candPC return candPC; Function *func = leafPC->func; unsigned int bt_entries = func->module->bTargets.size (); DbeInstr *bestPC = NULL; // bt == branch target (potential destination of a branch if (bt_entries == 0) { // no XHWCprof info for this module // increment counter experiment->dsnoxhwcevents++; // see if event is to be processed anyway if (!dbeSession->check_ignore_no_xhwcprof ()) { // Don't ignore error // XXX -- set error code in event VA -- replace with other mechanism if (eventVA > ABS_CODE_RANGE) eventVA = ABS_NULL; eventVA |= ABS_NO_CTI_INFO; // => effective address can't be validated bestPC = leafPC; // => no PC correction possible } else bestPC = candPC; // assume the event valid } else { // we have the info to verify the backtracking target_info_t *bt; int bt_entry = bt_entries; uint64_t leafPC_offset = func->img_offset + leafPC->addr; uint64_t candPC_offset = candPC->func->img_offset + candPC->addr; do { bt_entry--; bt = func->module->bTargets.fetch (bt_entry); /* bts seem to be sorted by offset, smallest to largest */ } while (bt_entry > 0 && bt->offset > leafPC_offset); /* if bt_entry == 0, all items have been checked */ if (bt->offset > leafPC_offset) { /* XXXX isn't is possible that all bt's are after leafPC_offset? */ bestPC = leafPC; // actual event PC can't be determined if (eventVA > ABS_CODE_RANGE) eventVA = ABS_NULL; eventVA |= ABS_INFO_FAILED; // effective address can't be validated } else if (bt->offset > candPC_offset) { // use synthetic PC corresponding to bTarget bestPC = func->find_dbeinstr (PCTrgtFlag, bt->offset - func->img_offset); if (eventVA > ABS_CODE_RANGE) eventVA = ABS_NULL; eventVA |= ABS_CTI_TARGET; // effective address can't be validated } else bestPC = candPC; // accept provided virtual address as valid } return bestPC; } void * CallStackP::add_stack_d (Vector *objs) { // objs: root..leaf // Reverse objs for (int i = 0, j = objs->size () - 1; i < j; ++i, --j) objs->swap (i, j); return add_stack (objs); } CallStackNode::CallStackNode (CallStackNode *_ancestor, Histable *_instr) { ancestor = _ancestor; instr = _instr; alt_node = NULL; } CallStackNode::~CallStackNode () { } bool CallStackNode::compare (long start, long end, Vector *objs, CallStackNode *mRoot) { CallStackNode *p = this; for (long i = start; i < end; i++, p = p->get_ancestor ()) if (p == NULL || p->get_instr () != objs->get (i)) return false; return p == mRoot; } void CallStackNode::dump () { const char *s = ""; int sz = 0; for (CallStackNode *p = this; p; p = p->get_ancestor ()) { fprintf (stderr, NTXT ("%.*s 0x%08llx id=0x%08llx %s\n"), sz, s, (long long) p, (long long) p->get_instr ()->id, STR (p->get_instr ()->get_name ())); s = "-"; sz += 1; } } long total_calls_add_stack, total_stacks, total_nodes, call_stack_size[201]; void * CallStackP::add_stack (Vector *objs) { // objs: leaf..root uint64_t hash = objs->size (); for (long i = objs->size () - 1; i >= 0; --i) hash ^= (unsigned long long) objs->get (i); uint64_t key = hash ? hash : 1; CallStackNode *node = cstackMap->get (key); #ifdef DEBUG if (DUMP_CALL_STACK) { total_calls_add_stack++; call_stack_size[objs->size () > 200 ? 200 : objs->size ()]++; Dprintf (DUMP_CALL_STACK, "add_stack: %lld size=%lld key=0x%08llx cashNode=0x%08llx\n", (long long) total_calls_add_stack, (long long) objs->size (), (long long) key, (long long) node); for (long i = 0, sz = VecSize (objs); i < sz; i++) Dprintf (DUMP_CALL_STACK, " add_stack: %.*s 0x%08llx id=0x%08llx %s\n", (int) i, NTXT (" "), (long long) objs->get (i), (long long) objs->get (i)->id, STR (objs->get (i)->get_name ())); } #endif if (node && node->compare (0, objs->size (), objs, root)) { Dprintf (DUMP_CALL_STACK, NTXT ("STACK FOUND: key=0x%08llx 0x%08llx id=0x%08llx %s\n"), (long long) key, (long long) node, (long long) node->get_instr ()->id, STR (node->get_instr ()->get_name ())); return node; } node = root; for (long i = objs->size () - 1; i >= 0; i--) { Histable *instr = objs->get (i); int old_count = node->count; int left; CallStackNode *nd = node->find (instr, &left); if (nd) { node = nd; continue; } cstackLock->aquireLock (); // Use one lock for all nodes // node->aquireLock(); if (old_count != node->count) { nd = node->find (instr, &left); if (nd) { // the other thread has created this node cstackLock->releaseLock (); // node->releaseLock(); node = nd; continue; } } // New Call Stack total_stacks++; nd = node; CallStackNode *first = NULL; do { CallStackNode *anc = node; total_nodes++; node = new_Node (anc, objs->get (i)); if (first) anc->append (node); else first = node; } while (i-- > 0); nd->insert (left, first); cstackLock->releaseLock (); // nd->releaseLock(); break; } cstackMap->put (key, node); if (DUMP_CALL_STACK) node->dump (); return node; } CallStackNode * CallStackP::get_node (int n) { if (n < nodes) return &chunks[n / CHUNKSZ][n % CHUNKSZ]; return NULL; } /* * Debugging methods */ void CallStackP::print (FILE *fd) { FILE *f = (fd == NULL ? stderr : fd); fprintf (f, GTXT ("CallStack: nodes = %d\n\n"), nodes); int maxdepth = 0; int maxwidth = 0; const char *t; char *n; for (int i = 0; i < nodes; i++) { CallStackNode *node = &chunks[i / CHUNKSZ][i % CHUNKSZ]; Histable *instr = node->instr; if (instr->get_type () == Histable::LINE) { t = "L"; n = ((DbeLine *) instr)->func->get_name (); } else if (instr->get_type () == Histable::INSTR) { t = "I"; n = ((DbeInstr *) instr)->func->get_name (); } else { t = "O"; n = instr->get_name (); } long long addr = (long long) instr->get_addr (); fprintf (f, GTXT ("node: 0x%016llx anc: 0x%016llx -- 0x%016llX: %s %s\n"), (unsigned long long) node, (unsigned long long) node->ancestor, addr, t, n); } fprintf (f, GTXT ("md = %d, mw = %d\n"), maxdepth, maxwidth); } /* * Static CallStack methods */ CallStack * CallStack::getInstance (Experiment *exp) { return new CallStackP (exp); } int CallStack::stackSize (void *stack) { CallStackNode *node = (CallStackNode *) stack; int sz = 0; for (; node; node = node->ancestor) sz++; return sz - 1; // don't count the root node } Histable * CallStack::getStackPC (void *stack, int n) { CallStackNode *node = (CallStackNode *) stack; while (n-- && node) node = node->ancestor; if (node == NULL) return dbeSession->get_Unknown_Function ()->find_dbeinstr (PCInvlFlag, 0); return node->instr; } Vector * CallStack::getStackPCs (void *stack, bool get_hide_stack) { Vector *res = new Vector; CallStackNode *node = (CallStackNode *) stack; if (get_hide_stack && node->alt_node != NULL) node = node->alt_node; while (node && node->ancestor) { // skip the root node res->append (node->instr); node = node->ancestor; } return res; } int CallStack::compare (void *stack1, void *stack2) { // Quick comparision if (stack1 == stack2) return 0; CallStackNode *node1 = (CallStackNode *) stack1; CallStackNode *node2 = (CallStackNode *) stack2; while (node1 != NULL && node2 != NULL) { //to keep the result const on different platforms //we use instr->id instead of instr if (node1->instr->id < node2->instr->id) return -1; else if (node1->instr->id > node2->instr->id) return 1; node1 = node1->ancestor; node2 = node2->ancestor; } if (node1 == NULL && node2 != NULL) return -1; else if (node1 != NULL && node2 == NULL) return 1; else return 0; } // LIBRARY VISIBILITY void CallStack::setHideStack (void *stack, void *hideStack) { CallStackNode *hNode = (CallStackNode *) stack; hNode->alt_node = (CallStackNode *) hideStack; }