Mercurial > hg > graal-compiler
view src/share/vm/opto/superword.cpp @ 1941:79d04223b8a5
Added caching for resolved types and resolved fields.
This is crucial, because the local load elimination will lead to wrong results, if field equality (of two RiField objects with the same object and the same RiType) is not given. The caching makes sure that the default equals implementation is sufficient.
| author | Thomas Wuerthinger <wuerthinger@ssw.jku.at> |
|---|---|
| date | Tue, 28 Dec 2010 18:33:26 +0100 |
| parents | 6027dddc26c6 |
| children | f95d63e2154a |
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/* * Copyright (c) 2007, 2010, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. * * This code 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 * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. */ #include "incls/_precompiled.incl" #include "incls/_superword.cpp.incl" // // S U P E R W O R D T R A N S F O R M //============================================================================= //------------------------------SuperWord--------------------------- SuperWord::SuperWord(PhaseIdealLoop* phase) : _phase(phase), _igvn(phase->_igvn), _arena(phase->C->comp_arena()), _packset(arena(), 8, 0, NULL), // packs for the current block _bb_idx(arena(), (int)(1.10 * phase->C->unique()), 0, 0), // node idx to index in bb _block(arena(), 8, 0, NULL), // nodes in current block _data_entry(arena(), 8, 0, NULL), // nodes with all inputs from outside _mem_slice_head(arena(), 8, 0, NULL), // memory slice heads _mem_slice_tail(arena(), 8, 0, NULL), // memory slice tails _node_info(arena(), 8, 0, SWNodeInfo::initial), // info needed per node _align_to_ref(NULL), // memory reference to align vectors to _disjoint_ptrs(arena(), 8, 0, OrderedPair::initial), // runtime disambiguated pointer pairs _dg(_arena), // dependence graph _visited(arena()), // visited node set _post_visited(arena()), // post visited node set _n_idx_list(arena(), 8), // scratch list of (node,index) pairs _stk(arena(), 8, 0, NULL), // scratch stack of nodes _nlist(arena(), 8, 0, NULL), // scratch list of nodes _lpt(NULL), // loop tree node _lp(NULL), // LoopNode _bb(NULL), // basic block _iv(NULL) // induction var {} //------------------------------transform_loop--------------------------- void SuperWord::transform_loop(IdealLoopTree* lpt) { assert(lpt->_head->is_CountedLoop(), "must be"); CountedLoopNode *cl = lpt->_head->as_CountedLoop(); if (!cl->is_main_loop() ) return; // skip normal, pre, and post loops // Check for no control flow in body (other than exit) Node *cl_exit = cl->loopexit(); if (cl_exit->in(0) != lpt->_head) return; // Make sure the are no extra control users of the loop backedge if (cl->back_control()->outcnt() != 1) { return; } // Check for pre-loop ending with CountedLoopEnd(Bool(Cmp(x,Opaque1(limit)))) CountedLoopEndNode* pre_end = get_pre_loop_end(cl); if (pre_end == NULL) return; Node *pre_opaq1 = pre_end->limit(); if (pre_opaq1->Opcode() != Op_Opaque1) return; // Do vectors exist on this architecture? if (vector_width_in_bytes() == 0) return; init(); // initialize data structures set_lpt(lpt); set_lp(cl); // For now, define one block which is the entire loop body set_bb(cl); assert(_packset.length() == 0, "packset must be empty"); SLP_extract(); } //------------------------------SLP_extract--------------------------- // Extract the superword level parallelism // // 1) A reverse post-order of nodes in the block is constructed. By scanning // this list from first to last, all definitions are visited before their uses. // // 2) A point-to-point dependence graph is constructed between memory references. // This simplies the upcoming "independence" checker. // // 3) The maximum depth in the node graph from the beginning of the block // to each node is computed. This is used to prune the graph search // in the independence checker. // // 4) For integer types, the necessary bit width is propagated backwards // from stores to allow packed operations on byte, char, and short // integers. This reverses the promotion to type "int" that javac // did for operations like: char c1,c2,c3; c1 = c2 + c3. // // 5) One of the memory references is picked to be an aligned vector reference. // The pre-loop trip count is adjusted to align this reference in the // unrolled body. // // 6) The initial set of pack pairs is seeded with memory references. // // 7) The set of pack pairs is extended by following use->def and def->use links. // // 8) The pairs are combined into vector sized packs. // // 9) Reorder the memory slices to co-locate members of the memory packs. // // 10) Generate ideal vector nodes for the final set of packs and where necessary, // inserting scalar promotion, vector creation from multiple scalars, and // extraction of scalar values from vectors. // void SuperWord::SLP_extract() { // Ready the block construct_bb(); dependence_graph(); compute_max_depth(); compute_vector_element_type(); // Attempt vectorization find_adjacent_refs(); extend_packlist(); combine_packs(); construct_my_pack_map(); filter_packs(); schedule(); output(); } //------------------------------find_adjacent_refs--------------------------- // Find the adjacent memory references and create pack pairs for them. // This is the initial set of packs that will then be extended by // following use->def and def->use links. The align positions are // assigned relative to the reference "align_to_ref" void SuperWord::find_adjacent_refs() { // Get list of memory operations Node_List memops; for (int i = 0; i < _block.length(); i++) { Node* n = _block.at(i); if (n->is_Mem() && in_bb(n) && is_java_primitive(n->as_Mem()->memory_type())) { int align = memory_alignment(n->as_Mem(), 0); if (align != bottom_align) { memops.push(n); } } } if (memops.size() == 0) return; // Find a memory reference to align to. The pre-loop trip count // is modified to align this reference to a vector-aligned address find_align_to_ref(memops); if (align_to_ref() == NULL) return; SWPointer align_to_ref_p(align_to_ref(), this); int offset = align_to_ref_p.offset_in_bytes(); int scale = align_to_ref_p.scale_in_bytes(); int vw = vector_width_in_bytes(); int stride_sign = (scale * iv_stride()) > 0 ? 1 : -1; int iv_adjustment = (stride_sign * vw - (offset % vw)) % vw; #ifndef PRODUCT if (TraceSuperWord) tty->print_cr("\noffset = %d iv_adjustment = %d elt_align = %d scale = %d iv_stride = %d", offset, iv_adjustment, align_to_ref_p.memory_size(), align_to_ref_p.scale_in_bytes(), iv_stride()); #endif // Set alignment relative to "align_to_ref" for (int i = memops.size() - 1; i >= 0; i--) { MemNode* s = memops.at(i)->as_Mem(); SWPointer p2(s, this); if (p2.comparable(align_to_ref_p)) { int align = memory_alignment(s, iv_adjustment); set_alignment(s, align); } else { memops.remove(i); } } // Create initial pack pairs of memory operations for (uint i = 0; i < memops.size(); i++) { Node* s1 = memops.at(i); for (uint j = 0; j < memops.size(); j++) { Node* s2 = memops.at(j); if (s1 != s2 && are_adjacent_refs(s1, s2)) { int align = alignment(s1); if (stmts_can_pack(s1, s2, align)) { Node_List* pair = new Node_List(); pair->push(s1); pair->push(s2); _packset.append(pair); } } } } #ifndef PRODUCT if (TraceSuperWord) { tty->print_cr("\nAfter find_adjacent_refs"); print_packset(); } #endif } //------------------------------find_align_to_ref--------------------------- // Find a memory reference to align the loop induction variable to. // Looks first at stores then at loads, looking for a memory reference // with the largest number of references similar to it. void SuperWord::find_align_to_ref(Node_List &memops) { GrowableArray<int> cmp_ct(arena(), memops.size(), memops.size(), 0); // Count number of comparable memory ops for (uint i = 0; i < memops.size(); i++) { MemNode* s1 = memops.at(i)->as_Mem(); SWPointer p1(s1, this); // Discard if pre loop can't align this reference if (!ref_is_alignable(p1)) { *cmp_ct.adr_at(i) = 0; continue; } for (uint j = i+1; j < memops.size(); j++) { MemNode* s2 = memops.at(j)->as_Mem(); if (isomorphic(s1, s2)) { SWPointer p2(s2, this); if (p1.comparable(p2)) { (*cmp_ct.adr_at(i))++; (*cmp_ct.adr_at(j))++; } } } } // Find Store (or Load) with the greatest number of "comparable" references int max_ct = 0; int max_idx = -1; int min_size = max_jint; int min_iv_offset = max_jint; for (uint j = 0; j < memops.size(); j++) { MemNode* s = memops.at(j)->as_Mem(); if (s->is_Store()) { SWPointer p(s, this); if (cmp_ct.at(j) > max_ct || cmp_ct.at(j) == max_ct && (data_size(s) < min_size || data_size(s) == min_size && p.offset_in_bytes() < min_iv_offset)) { max_ct = cmp_ct.at(j); max_idx = j; min_size = data_size(s); min_iv_offset = p.offset_in_bytes(); } } } // If no stores, look at loads if (max_ct == 0) { for (uint j = 0; j < memops.size(); j++) { MemNode* s = memops.at(j)->as_Mem(); if (s->is_Load()) { SWPointer p(s, this); if (cmp_ct.at(j) > max_ct || cmp_ct.at(j) == max_ct && (data_size(s) < min_size || data_size(s) == min_size && p.offset_in_bytes() < min_iv_offset)) { max_ct = cmp_ct.at(j); max_idx = j; min_size = data_size(s); min_iv_offset = p.offset_in_bytes(); } } } } if (max_ct > 0) set_align_to_ref(memops.at(max_idx)->as_Mem()); #ifndef PRODUCT if (TraceSuperWord && Verbose) { tty->print_cr("\nVector memops after find_align_to_refs"); for (uint i = 0; i < memops.size(); i++) { MemNode* s = memops.at(i)->as_Mem(); s->dump(); } } #endif } //------------------------------ref_is_alignable--------------------------- // Can the preloop align the reference to position zero in the vector? bool SuperWord::ref_is_alignable(SWPointer& p) { if (!p.has_iv()) { return true; // no induction variable } CountedLoopEndNode* pre_end = get_pre_loop_end(lp()->as_CountedLoop()); assert(pre_end->stride_is_con(), "pre loop stride is constant"); int preloop_stride = pre_end->stride_con(); int span = preloop_stride * p.scale_in_bytes(); // Stride one accesses are alignable. if (ABS(span) == p.memory_size()) return true; // If initial offset from start of object is computable, // compute alignment within the vector. int vw = vector_width_in_bytes(); if (vw % span == 0) { Node* init_nd = pre_end->init_trip(); if (init_nd->is_Con() && p.invar() == NULL) { int init = init_nd->bottom_type()->is_int()->get_con(); int init_offset = init * p.scale_in_bytes() + p.offset_in_bytes(); assert(init_offset >= 0, "positive offset from object start"); if (span > 0) { return (vw - (init_offset % vw)) % span == 0; } else { assert(span < 0, "nonzero stride * scale"); return (init_offset % vw) % -span == 0; } } } return false; } //---------------------------dependence_graph--------------------------- // Construct dependency graph. // Add dependence edges to load/store nodes for memory dependence // A.out()->DependNode.in(1) and DependNode.out()->B.prec(x) void SuperWord::dependence_graph() { // First, assign a dependence node to each memory node for (int i = 0; i < _block.length(); i++ ) { Node *n = _block.at(i); if (n->is_Mem() || n->is_Phi() && n->bottom_type() == Type::MEMORY) { _dg.make_node(n); } } // For each memory slice, create the dependences for (int i = 0; i < _mem_slice_head.length(); i++) { Node* n = _mem_slice_head.at(i); Node* n_tail = _mem_slice_tail.at(i); // Get slice in predecessor order (last is first) mem_slice_preds(n_tail, n, _nlist); // Make the slice dependent on the root DepMem* slice = _dg.dep(n); _dg.make_edge(_dg.root(), slice); // Create a sink for the slice DepMem* slice_sink = _dg.make_node(NULL); _dg.make_edge(slice_sink, _dg.tail()); // Now visit each pair of memory ops, creating the edges for (int j = _nlist.length() - 1; j >= 0 ; j--) { Node* s1 = _nlist.at(j); // If no dependency yet, use slice if (_dg.dep(s1)->in_cnt() == 0) { _dg.make_edge(slice, s1); } SWPointer p1(s1->as_Mem(), this); bool sink_dependent = true; for (int k = j - 1; k >= 0; k--) { Node* s2 = _nlist.at(k); if (s1->is_Load() && s2->is_Load()) continue; SWPointer p2(s2->as_Mem(), this); int cmp = p1.cmp(p2); if (SuperWordRTDepCheck && p1.base() != p2.base() && p1.valid() && p2.valid()) { // Create a runtime check to disambiguate OrderedPair pp(p1.base(), p2.base()); _disjoint_ptrs.append_if_missing(pp); } else if (!SWPointer::not_equal(cmp)) { // Possibly same address _dg.make_edge(s1, s2); sink_dependent = false; } } if (sink_dependent) { _dg.make_edge(s1, slice_sink); } } #ifndef PRODUCT if (TraceSuperWord) { tty->print_cr("\nDependence graph for slice: %d", n->_idx); for (int q = 0; q < _nlist.length(); q++) { _dg.print(_nlist.at(q)); } tty->cr(); } #endif _nlist.clear(); } #ifndef PRODUCT if (TraceSuperWord) { tty->print_cr("\ndisjoint_ptrs: %s", _disjoint_ptrs.length() > 0 ? "" : "NONE"); for (int r = 0; r < _disjoint_ptrs.length(); r++) { _disjoint_ptrs.at(r).print(); tty->cr(); } tty->cr(); } #endif } //---------------------------mem_slice_preds--------------------------- // Return a memory slice (node list) in predecessor order starting at "start" void SuperWord::mem_slice_preds(Node* start, Node* stop, GrowableArray<Node*> &preds) { assert(preds.length() == 0, "start empty"); Node* n = start; Node* prev = NULL; while (true) { assert(in_bb(n), "must be in block"); for (DUIterator_Fast imax, i = n->fast_outs(imax); i < imax; i++) { Node* out = n->fast_out(i); if (out->is_Load()) { if (in_bb(out)) { preds.push(out); } } else { // FIXME if (out->is_MergeMem() && !in_bb(out)) { // Either unrolling is causing a memory edge not to disappear, // or need to run igvn.optimize() again before SLP } else if (out->is_Phi() && out->bottom_type() == Type::MEMORY && !in_bb(out)) { // Ditto. Not sure what else to check further. } else if (out->Opcode() == Op_StoreCM && out->in(MemNode::OopStore) == n) { // StoreCM has an input edge used as a precedence edge. // Maybe an issue when oop stores are vectorized. } else { assert(out == prev || prev == NULL, "no branches off of store slice"); } } } if (n == stop) break; preds.push(n); prev = n; n = n->in(MemNode::Memory); } } //------------------------------stmts_can_pack--------------------------- // Can s1 and s2 be in a pack with s1 immediately preceding s2 and // s1 aligned at "align" bool SuperWord::stmts_can_pack(Node* s1, Node* s2, int align) { // Do not use superword for non-primitives if((s1->is_Mem() && !is_java_primitive(s1->as_Mem()->memory_type())) || (s2->is_Mem() && !is_java_primitive(s2->as_Mem()->memory_type()))) return false; if (isomorphic(s1, s2)) { if (independent(s1, s2)) { if (!exists_at(s1, 0) && !exists_at(s2, 1)) { if (!s1->is_Mem() || are_adjacent_refs(s1, s2)) { int s1_align = alignment(s1); int s2_align = alignment(s2); if (s1_align == top_align || s1_align == align) { if (s2_align == top_align || s2_align == align + data_size(s1)) { return true; } } } } } } return false; } //------------------------------exists_at--------------------------- // Does s exist in a pack at position pos? bool SuperWord::exists_at(Node* s, uint pos) { for (int i = 0; i < _packset.length(); i++) { Node_List* p = _packset.at(i); if (p->at(pos) == s) { return true; } } return false; } //------------------------------are_adjacent_refs--------------------------- // Is s1 immediately before s2 in memory? bool SuperWord::are_adjacent_refs(Node* s1, Node* s2) { if (!s1->is_Mem() || !s2->is_Mem()) return false; if (!in_bb(s1) || !in_bb(s2)) return false; // Do not use superword for non-primitives if (!is_java_primitive(s1->as_Mem()->memory_type()) || !is_java_primitive(s2->as_Mem()->memory_type())) { return false; } // FIXME - co_locate_pack fails on Stores in different mem-slices, so // only pack memops that are in the same alias set until that's fixed. if (_phase->C->get_alias_index(s1->as_Mem()->adr_type()) != _phase->C->get_alias_index(s2->as_Mem()->adr_type())) return false; SWPointer p1(s1->as_Mem(), this); SWPointer p2(s2->as_Mem(), this); if (p1.base() != p2.base() || !p1.comparable(p2)) return false; int diff = p2.offset_in_bytes() - p1.offset_in_bytes(); return diff == data_size(s1); } //------------------------------isomorphic--------------------------- // Are s1 and s2 similar? bool SuperWord::isomorphic(Node* s1, Node* s2) { if (s1->Opcode() != s2->Opcode()) return false; if (s1->req() != s2->req()) return false; if (s1->in(0) != s2->in(0)) return false; if (velt_type(s1) != velt_type(s2)) return false; return true; } //------------------------------independent--------------------------- // Is there no data path from s1 to s2 or s2 to s1? bool SuperWord::independent(Node* s1, Node* s2) { // assert(s1->Opcode() == s2->Opcode(), "check isomorphic first"); int d1 = depth(s1); int d2 = depth(s2); if (d1 == d2) return s1 != s2; Node* deep = d1 > d2 ? s1 : s2; Node* shallow = d1 > d2 ? s2 : s1; visited_clear(); return independent_path(shallow, deep); } //------------------------------independent_path------------------------------ // Helper for independent bool SuperWord::independent_path(Node* shallow, Node* deep, uint dp) { if (dp >= 1000) return false; // stop deep recursion visited_set(deep); int shal_depth = depth(shallow); assert(shal_depth <= depth(deep), "must be"); for (DepPreds preds(deep, _dg); !preds.done(); preds.next()) { Node* pred = preds.current(); if (in_bb(pred) && !visited_test(pred)) { if (shallow == pred) { return false; } if (shal_depth < depth(pred) && !independent_path(shallow, pred, dp+1)) { return false; } } } return true; } //------------------------------set_alignment--------------------------- void SuperWord::set_alignment(Node* s1, Node* s2, int align) { set_alignment(s1, align); set_alignment(s2, align + data_size(s1)); } //------------------------------data_size--------------------------- int SuperWord::data_size(Node* s) { const Type* t = velt_type(s); BasicType bt = t->array_element_basic_type(); int bsize = type2aelembytes(bt); assert(bsize != 0, "valid size"); return bsize; } //------------------------------extend_packlist--------------------------- // Extend packset by following use->def and def->use links from pack members. void SuperWord::extend_packlist() { bool changed; do { changed = false; for (int i = 0; i < _packset.length(); i++) { Node_List* p = _packset.at(i); changed |= follow_use_defs(p); changed |= follow_def_uses(p); } } while (changed); #ifndef PRODUCT if (TraceSuperWord) { tty->print_cr("\nAfter extend_packlist"); print_packset(); } #endif } //------------------------------follow_use_defs--------------------------- // Extend the packset by visiting operand definitions of nodes in pack p bool SuperWord::follow_use_defs(Node_List* p) { Node* s1 = p->at(0); Node* s2 = p->at(1); assert(p->size() == 2, "just checking"); assert(s1->req() == s2->req(), "just checking"); assert(alignment(s1) + data_size(s1) == alignment(s2), "just checking"); if (s1->is_Load()) return false; int align = alignment(s1); bool changed = false; int start = s1->is_Store() ? MemNode::ValueIn : 1; int end = s1->is_Store() ? MemNode::ValueIn+1 : s1->req(); for (int j = start; j < end; j++) { Node* t1 = s1->in(j); Node* t2 = s2->in(j); if (!in_bb(t1) || !in_bb(t2)) continue; if (stmts_can_pack(t1, t2, align)) { if (est_savings(t1, t2) >= 0) { Node_List* pair = new Node_List(); pair->push(t1); pair->push(t2); _packset.append(pair); set_alignment(t1, t2, align); changed = true; } } } return changed; } //------------------------------follow_def_uses--------------------------- // Extend the packset by visiting uses of nodes in pack p bool SuperWord::follow_def_uses(Node_List* p) { bool changed = false; Node* s1 = p->at(0); Node* s2 = p->at(1); assert(p->size() == 2, "just checking"); assert(s1->req() == s2->req(), "just checking"); assert(alignment(s1) + data_size(s1) == alignment(s2), "just checking"); if (s1->is_Store()) return false; int align = alignment(s1); int savings = -1; Node* u1 = NULL; Node* u2 = NULL; for (DUIterator_Fast imax, i = s1->fast_outs(imax); i < imax; i++) { Node* t1 = s1->fast_out(i); if (!in_bb(t1)) continue; for (DUIterator_Fast jmax, j = s2->fast_outs(jmax); j < jmax; j++) { Node* t2 = s2->fast_out(j); if (!in_bb(t2)) continue; if (!opnd_positions_match(s1, t1, s2, t2)) continue; if (stmts_can_pack(t1, t2, align)) { int my_savings = est_savings(t1, t2); if (my_savings > savings) { savings = my_savings; u1 = t1; u2 = t2; } } } } if (savings >= 0) { Node_List* pair = new Node_List(); pair->push(u1); pair->push(u2); _packset.append(pair); set_alignment(u1, u2, align); changed = true; } return changed; } //---------------------------opnd_positions_match------------------------- // Is the use of d1 in u1 at the same operand position as d2 in u2? bool SuperWord::opnd_positions_match(Node* d1, Node* u1, Node* d2, Node* u2) { uint ct = u1->req(); if (ct != u2->req()) return false; uint i1 = 0; uint i2 = 0; do { for (i1++; i1 < ct; i1++) if (u1->in(i1) == d1) break; for (i2++; i2 < ct; i2++) if (u2->in(i2) == d2) break; if (i1 != i2) { return false; } } while (i1 < ct); return true; } //------------------------------est_savings--------------------------- // Estimate the savings from executing s1 and s2 as a pack int SuperWord::est_savings(Node* s1, Node* s2) { int save = 2 - 1; // 2 operations per instruction in packed form // inputs for (uint i = 1; i < s1->req(); i++) { Node* x1 = s1->in(i); Node* x2 = s2->in(i); if (x1 != x2) { if (are_adjacent_refs(x1, x2)) { save += adjacent_profit(x1, x2); } else if (!in_packset(x1, x2)) { save -= pack_cost(2); } else { save += unpack_cost(2); } } } // uses of result uint ct = 0; for (DUIterator_Fast imax, i = s1->fast_outs(imax); i < imax; i++) { Node* s1_use = s1->fast_out(i); for (int j = 0; j < _packset.length(); j++) { Node_List* p = _packset.at(j); if (p->at(0) == s1_use) { for (DUIterator_Fast kmax, k = s2->fast_outs(kmax); k < kmax; k++) { Node* s2_use = s2->fast_out(k); if (p->at(p->size()-1) == s2_use) { ct++; if (are_adjacent_refs(s1_use, s2_use)) { save += adjacent_profit(s1_use, s2_use); } } } } } } if (ct < s1->outcnt()) save += unpack_cost(1); if (ct < s2->outcnt()) save += unpack_cost(1); return save; } //------------------------------costs--------------------------- int SuperWord::adjacent_profit(Node* s1, Node* s2) { return 2; } int SuperWord::pack_cost(int ct) { return ct; } int SuperWord::unpack_cost(int ct) { return ct; } //------------------------------combine_packs--------------------------- // Combine packs A and B with A.last == B.first into A.first..,A.last,B.second,..B.last void SuperWord::combine_packs() { bool changed; do { changed = false; for (int i = 0; i < _packset.length(); i++) { Node_List* p1 = _packset.at(i); if (p1 == NULL) continue; for (int j = 0; j < _packset.length(); j++) { Node_List* p2 = _packset.at(j); if (p2 == NULL) continue; if (p1->at(p1->size()-1) == p2->at(0)) { for (uint k = 1; k < p2->size(); k++) { p1->push(p2->at(k)); } _packset.at_put(j, NULL); changed = true; } } } } while (changed); for (int i = _packset.length() - 1; i >= 0; i--) { Node_List* p1 = _packset.at(i); if (p1 == NULL) { _packset.remove_at(i); } } #ifndef PRODUCT if (TraceSuperWord) { tty->print_cr("\nAfter combine_packs"); print_packset(); } #endif } //-----------------------------construct_my_pack_map-------------------------- // Construct the map from nodes to packs. Only valid after the // point where a node is only in one pack (after combine_packs). void SuperWord::construct_my_pack_map() { Node_List* rslt = NULL; for (int i = 0; i < _packset.length(); i++) { Node_List* p = _packset.at(i); for (uint j = 0; j < p->size(); j++) { Node* s = p->at(j); assert(my_pack(s) == NULL, "only in one pack"); set_my_pack(s, p); } } } //------------------------------filter_packs--------------------------- // Remove packs that are not implemented or not profitable. void SuperWord::filter_packs() { // Remove packs that are not implemented for (int i = _packset.length() - 1; i >= 0; i--) { Node_List* pk = _packset.at(i); bool impl = implemented(pk); if (!impl) { #ifndef PRODUCT if (TraceSuperWord && Verbose) { tty->print_cr("Unimplemented"); pk->at(0)->dump(); } #endif remove_pack_at(i); } } // Remove packs that are not profitable bool changed; do { changed = false; for (int i = _packset.length() - 1; i >= 0; i--) { Node_List* pk = _packset.at(i); bool prof = profitable(pk); if (!prof) { #ifndef PRODUCT if (TraceSuperWord && Verbose) { tty->print_cr("Unprofitable"); pk->at(0)->dump(); } #endif remove_pack_at(i); changed = true; } } } while (changed); #ifndef PRODUCT if (TraceSuperWord) { tty->print_cr("\nAfter filter_packs"); print_packset(); tty->cr(); } #endif } //------------------------------implemented--------------------------- // Can code be generated for pack p? bool SuperWord::implemented(Node_List* p) { Node* p0 = p->at(0); int vopc = VectorNode::opcode(p0->Opcode(), p->size(), velt_type(p0)); return vopc > 0 && Matcher::has_match_rule(vopc); } //------------------------------profitable--------------------------- // For pack p, are all operands and all uses (with in the block) vector? bool SuperWord::profitable(Node_List* p) { Node* p0 = p->at(0); uint start, end; vector_opd_range(p0, &start, &end); // Return false if some input is not vector and inside block for (uint i = start; i < end; i++) { if (!is_vector_use(p0, i)) { // For now, return false if not scalar promotion case (inputs are the same.) // Later, implement PackNode and allow differing, non-vector inputs // (maybe just the ones from outside the block.) Node* p0_def = p0->in(i); for (uint j = 1; j < p->size(); j++) { Node* use = p->at(j); Node* def = use->in(i); if (p0_def != def) return false; } } } if (!p0->is_Store()) { // For now, return false if not all uses are vector. // Later, implement ExtractNode and allow non-vector uses (maybe // just the ones outside the block.) for (uint i = 0; i < p->size(); i++) { Node* def = p->at(i); for (DUIterator_Fast jmax, j = def->fast_outs(jmax); j < jmax; j++) { Node* use = def->fast_out(j); for (uint k = 0; k < use->req(); k++) { Node* n = use->in(k); if (def == n) { if (!is_vector_use(use, k)) { return false; } } } } } } return true; } //------------------------------schedule--------------------------- // Adjust the memory graph for the packed operations void SuperWord::schedule() { // Co-locate in the memory graph the members of each memory pack for (int i = 0; i < _packset.length(); i++) { co_locate_pack(_packset.at(i)); } } //-------------------------------remove_and_insert------------------- //remove "current" from its current position in the memory graph and insert //it after the appropriate insertion point (lip or uip) void SuperWord::remove_and_insert(MemNode *current, MemNode *prev, MemNode *lip, Node *uip, Unique_Node_List &sched_before) { Node* my_mem = current->in(MemNode::Memory); _igvn.hash_delete(current); _igvn.hash_delete(my_mem); //remove current_store from its current position in the memmory graph for (DUIterator i = current->outs(); current->has_out(i); i++) { Node* use = current->out(i); if (use->is_Mem()) { assert(use->in(MemNode::Memory) == current, "must be"); _igvn.hash_delete(use); if (use == prev) { // connect prev to my_mem use->set_req(MemNode::Memory, my_mem); } else if (sched_before.member(use)) { _igvn.hash_delete(uip); use->set_req(MemNode::Memory, uip); } else { _igvn.hash_delete(lip); use->set_req(MemNode::Memory, lip); } _igvn._worklist.push(use); --i; //deleted this edge; rescan position } } bool sched_up = sched_before.member(current); Node *insert_pt = sched_up ? uip : lip; _igvn.hash_delete(insert_pt); // all uses of insert_pt's memory state should use current's instead for (DUIterator i = insert_pt->outs(); insert_pt->has_out(i); i++) { Node* use = insert_pt->out(i); if (use->is_Mem()) { assert(use->in(MemNode::Memory) == insert_pt, "must be"); _igvn.hash_delete(use); use->set_req(MemNode::Memory, current); _igvn._worklist.push(use); --i; //deleted this edge; rescan position } else if (!sched_up && use->is_Phi() && use->bottom_type() == Type::MEMORY) { uint pos; //lip (lower insert point) must be the last one in the memory slice _igvn.hash_delete(use); for (pos=1; pos < use->req(); pos++) { if (use->in(pos) == insert_pt) break; } use->set_req(pos, current); _igvn._worklist.push(use); --i; } } //connect current to insert_pt current->set_req(MemNode::Memory, insert_pt); _igvn._worklist.push(current); } //------------------------------co_locate_pack---------------------------------- // To schedule a store pack, we need to move any sandwiched memory ops either before // or after the pack, based upon dependence information: // (1) If any store in the pack depends on the sandwiched memory op, the // sandwiched memory op must be scheduled BEFORE the pack; // (2) If a sandwiched memory op depends on any store in the pack, the // sandwiched memory op must be scheduled AFTER the pack; // (3) If a sandwiched memory op (say, memA) depends on another sandwiched // memory op (say memB), memB must be scheduled before memA. So, if memA is // scheduled before the pack, memB must also be scheduled before the pack; // (4) If there is no dependence restriction for a sandwiched memory op, we simply // schedule this store AFTER the pack // (5) We know there is no dependence cycle, so there in no other case; // (6) Finally, all memory ops in another single pack should be moved in the same direction. // // To schedule a load pack, we use the memory state of either the first or the last load in // the pack, based on the dependence constraint. void SuperWord::co_locate_pack(Node_List* pk) { if (pk->at(0)->is_Store()) { MemNode* first = executed_first(pk)->as_Mem(); MemNode* last = executed_last(pk)->as_Mem(); Unique_Node_List schedule_before_pack; Unique_Node_List memops; MemNode* current = last->in(MemNode::Memory)->as_Mem(); MemNode* previous = last; while (true) { assert(in_bb(current), "stay in block"); memops.push(previous); for (DUIterator i = current->outs(); current->has_out(i); i++) { Node* use = current->out(i); if (use->is_Mem() && use != previous) memops.push(use); } if(current == first) break; previous = current; current = current->in(MemNode::Memory)->as_Mem(); } // determine which memory operations should be scheduled before the pack for (uint i = 1; i < memops.size(); i++) { Node *s1 = memops.at(i); if (!in_pack(s1, pk) && !schedule_before_pack.member(s1)) { for (uint j = 0; j< i; j++) { Node *s2 = memops.at(j); if (!independent(s1, s2)) { if (in_pack(s2, pk) || schedule_before_pack.member(s2)) { schedule_before_pack.push(s1); //s1 must be scheduled before Node_List* mem_pk = my_pack(s1); if (mem_pk != NULL) { for (uint ii = 0; ii < mem_pk->size(); ii++) { Node* s = mem_pk->at(ii); // follow partner if (memops.member(s) && !schedule_before_pack.member(s)) schedule_before_pack.push(s); } } } } } } } MemNode* lower_insert_pt = last; Node* upper_insert_pt = first->in(MemNode::Memory); previous = last; //previous store in pk current = last->in(MemNode::Memory)->as_Mem(); //start scheduling from "last" to "first" while (true) { assert(in_bb(current), "stay in block"); assert(in_pack(previous, pk), "previous stays in pack"); Node* my_mem = current->in(MemNode::Memory); if (in_pack(current, pk)) { // Forward users of my memory state (except "previous) to my input memory state _igvn.hash_delete(current); for (DUIterator i = current->outs(); current->has_out(i); i++) { Node* use = current->out(i); if (use->is_Mem() && use != previous) { assert(use->in(MemNode::Memory) == current, "must be"); _igvn.hash_delete(use); if (schedule_before_pack.member(use)) { _igvn.hash_delete(upper_insert_pt); use->set_req(MemNode::Memory, upper_insert_pt); } else { _igvn.hash_delete(lower_insert_pt); use->set_req(MemNode::Memory, lower_insert_pt); } _igvn._worklist.push(use); --i; // deleted this edge; rescan position } } previous = current; } else { // !in_pack(current, pk) ==> a sandwiched store remove_and_insert(current, previous, lower_insert_pt, upper_insert_pt, schedule_before_pack); } if (current == first) break; current = my_mem->as_Mem(); } // end while } else if (pk->at(0)->is_Load()) { //load // all loads in the pack should have the same memory state. By default, // we use the memory state of the last load. However, if any load could // not be moved down due to the dependence constraint, we use the memory // state of the first load. Node* last_mem = executed_last(pk)->in(MemNode::Memory); Node* first_mem = executed_first(pk)->in(MemNode::Memory); bool schedule_last = true; for (uint i = 0; i < pk->size(); i++) { Node* ld = pk->at(i); for (Node* current = last_mem; current != ld->in(MemNode::Memory); current=current->in(MemNode::Memory)) { assert(current != first_mem, "corrupted memory graph"); if(current->is_Mem() && !independent(current, ld)){ schedule_last = false; // a later store depends on this load break; } } } Node* mem_input = schedule_last ? last_mem : first_mem; _igvn.hash_delete(mem_input); // Give each load the same memory state for (uint i = 0; i < pk->size(); i++) { LoadNode* ld = pk->at(i)->as_Load(); _igvn.hash_delete(ld); ld->set_req(MemNode::Memory, mem_input); _igvn._worklist.push(ld); } } } //------------------------------output--------------------------- // Convert packs into vector node operations void SuperWord::output() { if (_packset.length() == 0) return; // MUST ENSURE main loop's initial value is properly aligned: // (iv_initial_value + min_iv_offset) % vector_width_in_bytes() == 0 align_initial_loop_index(align_to_ref()); // Insert extract (unpack) operations for scalar uses for (int i = 0; i < _packset.length(); i++) { insert_extracts(_packset.at(i)); } for (int i = 0; i < _block.length(); i++) { Node* n = _block.at(i); Node_List* p = my_pack(n); if (p && n == executed_last(p)) { uint vlen = p->size(); Node* vn = NULL; Node* low_adr = p->at(0); Node* first = executed_first(p); if (n->is_Load()) { int opc = n->Opcode(); Node* ctl = n->in(MemNode::Control); Node* mem = first->in(MemNode::Memory); Node* adr = low_adr->in(MemNode::Address); const TypePtr* atyp = n->adr_type(); vn = VectorLoadNode::make(_phase->C, opc, ctl, mem, adr, atyp, vlen); } else if (n->is_Store()) { // Promote value to be stored to vector VectorNode* val = vector_opd(p, MemNode::ValueIn); int opc = n->Opcode(); Node* ctl = n->in(MemNode::Control); Node* mem = first->in(MemNode::Memory); Node* adr = low_adr->in(MemNode::Address); const TypePtr* atyp = n->adr_type(); vn = VectorStoreNode::make(_phase->C, opc, ctl, mem, adr, atyp, val, vlen); } else if (n->req() == 3) { // Promote operands to vector Node* in1 = vector_opd(p, 1); Node* in2 = vector_opd(p, 2); vn = VectorNode::make(_phase->C, n->Opcode(), in1, in2, vlen, velt_type(n)); } else { ShouldNotReachHere(); } _phase->_igvn.register_new_node_with_optimizer(vn); _phase->set_ctrl(vn, _phase->get_ctrl(p->at(0))); for (uint j = 0; j < p->size(); j++) { Node* pm = p->at(j); _igvn.replace_node(pm, vn); } _igvn._worklist.push(vn); } } } //------------------------------vector_opd--------------------------- // Create a vector operand for the nodes in pack p for operand: in(opd_idx) VectorNode* SuperWord::vector_opd(Node_List* p, int opd_idx) { Node* p0 = p->at(0); uint vlen = p->size(); Node* opd = p0->in(opd_idx); bool same_opd = true; for (uint i = 1; i < vlen; i++) { Node* pi = p->at(i); Node* in = pi->in(opd_idx); if (opd != in) { same_opd = false; break; } } if (same_opd) { if (opd->is_Vector()) { return (VectorNode*)opd; // input is matching vector } // Convert scalar input to vector. Use p0's type because it's container // maybe smaller than the operand's container. const Type* opd_t = velt_type(!in_bb(opd) ? p0 : opd); const Type* p0_t = velt_type(p0); if (p0_t->higher_equal(opd_t)) opd_t = p0_t; VectorNode* vn = VectorNode::scalar2vector(_phase->C, opd, vlen, opd_t); _phase->_igvn.register_new_node_with_optimizer(vn); _phase->set_ctrl(vn, _phase->get_ctrl(opd)); return vn; } // Insert pack operation const Type* opd_t = velt_type(!in_bb(opd) ? p0 : opd); PackNode* pk = PackNode::make(_phase->C, opd, opd_t); for (uint i = 1; i < vlen; i++) { Node* pi = p->at(i); Node* in = pi->in(opd_idx); assert(my_pack(in) == NULL, "Should already have been unpacked"); assert(opd_t == velt_type(!in_bb(in) ? pi : in), "all same type"); pk->add_opd(in); } _phase->_igvn.register_new_node_with_optimizer(pk); _phase->set_ctrl(pk, _phase->get_ctrl(opd)); return pk; } //------------------------------insert_extracts--------------------------- // If a use of pack p is not a vector use, then replace the // use with an extract operation. void SuperWord::insert_extracts(Node_List* p) { if (p->at(0)->is_Store()) return; assert(_n_idx_list.is_empty(), "empty (node,index) list"); // Inspect each use of each pack member. For each use that is // not a vector use, replace the use with an extract operation. for (uint i = 0; i < p->size(); i++) { Node* def = p->at(i); for (DUIterator_Fast jmax, j = def->fast_outs(jmax); j < jmax; j++) { Node* use = def->fast_out(j); for (uint k = 0; k < use->req(); k++) { Node* n = use->in(k); if (def == n) { if (!is_vector_use(use, k)) { _n_idx_list.push(use, k); } } } } } while (_n_idx_list.is_nonempty()) { Node* use = _n_idx_list.node(); int idx = _n_idx_list.index(); _n_idx_list.pop(); Node* def = use->in(idx); // Insert extract operation _igvn.hash_delete(def); _igvn.hash_delete(use); int def_pos = alignment(def) / data_size(def); const Type* def_t = velt_type(def); Node* ex = ExtractNode::make(_phase->C, def, def_pos, def_t); _phase->_igvn.register_new_node_with_optimizer(ex); _phase->set_ctrl(ex, _phase->get_ctrl(def)); use->set_req(idx, ex); _igvn._worklist.push(def); _igvn._worklist.push(use); bb_insert_after(ex, bb_idx(def)); set_velt_type(ex, def_t); } } //------------------------------is_vector_use--------------------------- // Is use->in(u_idx) a vector use? bool SuperWord::is_vector_use(Node* use, int u_idx) { Node_List* u_pk = my_pack(use); if (u_pk == NULL) return false; Node* def = use->in(u_idx); Node_List* d_pk = my_pack(def); if (d_pk == NULL) { // check for scalar promotion Node* n = u_pk->at(0)->in(u_idx); for (uint i = 1; i < u_pk->size(); i++) { if (u_pk->at(i)->in(u_idx) != n) return false; } return true; } if (u_pk->size() != d_pk->size()) return false; for (uint i = 0; i < u_pk->size(); i++) { Node* ui = u_pk->at(i); Node* di = d_pk->at(i); if (ui->in(u_idx) != di || alignment(ui) != alignment(di)) return false; } return true; } //------------------------------construct_bb--------------------------- // Construct reverse postorder list of block members void SuperWord::construct_bb() { Node* entry = bb(); assert(_stk.length() == 0, "stk is empty"); assert(_block.length() == 0, "block is empty"); assert(_data_entry.length() == 0, "data_entry is empty"); assert(_mem_slice_head.length() == 0, "mem_slice_head is empty"); assert(_mem_slice_tail.length() == 0, "mem_slice_tail is empty"); // Find non-control nodes with no inputs from within block, // create a temporary map from node _idx to bb_idx for use // by the visited and post_visited sets, // and count number of nodes in block. int bb_ct = 0; for (uint i = 0; i < lpt()->_body.size(); i++ ) { Node *n = lpt()->_body.at(i); set_bb_idx(n, i); // Create a temporary map if (in_bb(n)) { bb_ct++; if (!n->is_CFG()) { bool found = false; for (uint j = 0; j < n->req(); j++) { Node* def = n->in(j); if (def && in_bb(def)) { found = true; break; } } if (!found) { assert(n != entry, "can't be entry"); _data_entry.push(n); } } } } // Find memory slices (head and tail) for (DUIterator_Fast imax, i = lp()->fast_outs(imax); i < imax; i++) { Node *n = lp()->fast_out(i); if (in_bb(n) && (n->is_Phi() && n->bottom_type() == Type::MEMORY)) { Node* n_tail = n->in(LoopNode::LoopBackControl); if (n_tail != n->in(LoopNode::EntryControl)) { _mem_slice_head.push(n); _mem_slice_tail.push(n_tail); } } } // Create an RPO list of nodes in block visited_clear(); post_visited_clear(); // Push all non-control nodes with no inputs from within block, then control entry for (int j = 0; j < _data_entry.length(); j++) { Node* n = _data_entry.at(j); visited_set(n); _stk.push(n); } visited_set(entry); _stk.push(entry); // Do a depth first walk over out edges int rpo_idx = bb_ct - 1; int size; while ((size = _stk.length()) > 0) { Node* n = _stk.top(); // Leave node on stack if (!visited_test_set(n)) { // forward arc in graph } else if (!post_visited_test(n)) { // cross or back arc for (DUIterator_Fast imax, i = n->fast_outs(imax); i < imax; i++) { Node *use = n->fast_out(i); if (in_bb(use) && !visited_test(use) && // Don't go around backedge (!use->is_Phi() || n == entry)) { _stk.push(use); } } if (_stk.length() == size) { // There were no additional uses, post visit node now _stk.pop(); // Remove node from stack assert(rpo_idx >= 0, ""); _block.at_put_grow(rpo_idx, n); rpo_idx--; post_visited_set(n); assert(rpo_idx >= 0 || _stk.is_empty(), ""); } } else { _stk.pop(); // Remove post-visited node from stack } } // Create real map of block indices for nodes for (int j = 0; j < _block.length(); j++) { Node* n = _block.at(j); set_bb_idx(n, j); } initialize_bb(); // Ensure extra info is allocated. #ifndef PRODUCT if (TraceSuperWord) { print_bb(); tty->print_cr("\ndata entry nodes: %s", _data_entry.length() > 0 ? "" : "NONE"); for (int m = 0; m < _data_entry.length(); m++) { tty->print("%3d ", m); _data_entry.at(m)->dump(); } tty->print_cr("\nmemory slices: %s", _mem_slice_head.length() > 0 ? "" : "NONE"); for (int m = 0; m < _mem_slice_head.length(); m++) { tty->print("%3d ", m); _mem_slice_head.at(m)->dump(); tty->print(" "); _mem_slice_tail.at(m)->dump(); } } #endif assert(rpo_idx == -1 && bb_ct == _block.length(), "all block members found"); } //------------------------------initialize_bb--------------------------- // Initialize per node info void SuperWord::initialize_bb() { Node* last = _block.at(_block.length() - 1); grow_node_info(bb_idx(last)); } //------------------------------bb_insert_after--------------------------- // Insert n into block after pos void SuperWord::bb_insert_after(Node* n, int pos) { int n_pos = pos + 1; // Make room for (int i = _block.length() - 1; i >= n_pos; i--) { _block.at_put_grow(i+1, _block.at(i)); } for (int j = _node_info.length() - 1; j >= n_pos; j--) { _node_info.at_put_grow(j+1, _node_info.at(j)); } // Set value _block.at_put_grow(n_pos, n); _node_info.at_put_grow(n_pos, SWNodeInfo::initial); // Adjust map from node->_idx to _block index for (int i = n_pos; i < _block.length(); i++) { set_bb_idx(_block.at(i), i); } } //------------------------------compute_max_depth--------------------------- // Compute max depth for expressions from beginning of block // Use to prune search paths during test for independence. void SuperWord::compute_max_depth() { int ct = 0; bool again; do { again = false; for (int i = 0; i < _block.length(); i++) { Node* n = _block.at(i); if (!n->is_Phi()) { int d_orig = depth(n); int d_in = 0; for (DepPreds preds(n, _dg); !preds.done(); preds.next()) { Node* pred = preds.current(); if (in_bb(pred)) { d_in = MAX2(d_in, depth(pred)); } } if (d_in + 1 != d_orig) { set_depth(n, d_in + 1); again = true; } } } ct++; } while (again); #ifndef PRODUCT if (TraceSuperWord && Verbose) tty->print_cr("compute_max_depth iterated: %d times", ct); #endif } //-------------------------compute_vector_element_type----------------------- // Compute necessary vector element type for expressions // This propagates backwards a narrower integer type when the // upper bits of the value are not needed. // Example: char a,b,c; a = b + c; // Normally the type of the add is integer, but for packed character // operations the type of the add needs to be char. void SuperWord::compute_vector_element_type() { #ifndef PRODUCT if (TraceSuperWord && Verbose) tty->print_cr("\ncompute_velt_type:"); #endif // Initial type for (int i = 0; i < _block.length(); i++) { Node* n = _block.at(i); const Type* t = n->is_Mem() ? Type::get_const_basic_type(n->as_Mem()->memory_type()) : _igvn.type(n); const Type* vt = container_type(t); set_velt_type(n, vt); } // Propagate narrowed type backwards through operations // that don't depend on higher order bits for (int i = _block.length() - 1; i >= 0; i--) { Node* n = _block.at(i); // Only integer types need be examined if (n->bottom_type()->isa_int()) { uint start, end; vector_opd_range(n, &start, &end); const Type* vt = velt_type(n); for (uint j = start; j < end; j++) { Node* in = n->in(j); // Don't propagate through a type conversion if (n->bottom_type() != in->bottom_type()) continue; switch(in->Opcode()) { case Op_AddI: case Op_AddL: case Op_SubI: case Op_SubL: case Op_MulI: case Op_MulL: case Op_AndI: case Op_AndL: case Op_OrI: case Op_OrL: case Op_XorI: case Op_XorL: case Op_LShiftI: case Op_LShiftL: case Op_CMoveI: case Op_CMoveL: if (in_bb(in)) { bool same_type = true; for (DUIterator_Fast kmax, k = in->fast_outs(kmax); k < kmax; k++) { Node *use = in->fast_out(k); if (!in_bb(use) || velt_type(use) != vt) { same_type = false; break; } } if (same_type) { set_velt_type(in, vt); } } } } } } #ifndef PRODUCT if (TraceSuperWord && Verbose) { for (int i = 0; i < _block.length(); i++) { Node* n = _block.at(i); velt_type(n)->dump(); tty->print("\t"); n->dump(); } } #endif } //------------------------------memory_alignment--------------------------- // Alignment within a vector memory reference int SuperWord::memory_alignment(MemNode* s, int iv_adjust_in_bytes) { SWPointer p(s, this); if (!p.valid()) { return bottom_align; } int offset = p.offset_in_bytes(); offset += iv_adjust_in_bytes; int off_rem = offset % vector_width_in_bytes(); int off_mod = off_rem >= 0 ? off_rem : off_rem + vector_width_in_bytes(); return off_mod; } //---------------------------container_type--------------------------- // Smallest type containing range of values const Type* SuperWord::container_type(const Type* t) { const Type* tp = t->make_ptr(); if (tp && tp->isa_aryptr()) { t = tp->is_aryptr()->elem(); } if (t->basic_type() == T_INT) { if (t->higher_equal(TypeInt::BOOL)) return TypeInt::BOOL; if (t->higher_equal(TypeInt::BYTE)) return TypeInt::BYTE; if (t->higher_equal(TypeInt::CHAR)) return TypeInt::CHAR; if (t->higher_equal(TypeInt::SHORT)) return TypeInt::SHORT; return TypeInt::INT; } return t; } //-------------------------vector_opd_range----------------------- // (Start, end] half-open range defining which operands are vector void SuperWord::vector_opd_range(Node* n, uint* start, uint* end) { switch (n->Opcode()) { case Op_LoadB: case Op_LoadUS: case Op_LoadI: case Op_LoadL: case Op_LoadF: case Op_LoadD: case Op_LoadP: *start = 0; *end = 0; return; case Op_StoreB: case Op_StoreC: case Op_StoreI: case Op_StoreL: case Op_StoreF: case Op_StoreD: case Op_StoreP: *start = MemNode::ValueIn; *end = *start + 1; return; case Op_LShiftI: case Op_LShiftL: *start = 1; *end = 2; return; case Op_CMoveI: case Op_CMoveL: case Op_CMoveF: case Op_CMoveD: *start = 2; *end = n->req(); return; } *start = 1; *end = n->req(); // default is all operands } //------------------------------in_packset--------------------------- // Are s1 and s2 in a pack pair and ordered as s1,s2? bool SuperWord::in_packset(Node* s1, Node* s2) { for (int i = 0; i < _packset.length(); i++) { Node_List* p = _packset.at(i); assert(p->size() == 2, "must be"); if (p->at(0) == s1 && p->at(p->size()-1) == s2) { return true; } } return false; } //------------------------------in_pack--------------------------- // Is s in pack p? Node_List* SuperWord::in_pack(Node* s, Node_List* p) { for (uint i = 0; i < p->size(); i++) { if (p->at(i) == s) { return p; } } return NULL; } //------------------------------remove_pack_at--------------------------- // Remove the pack at position pos in the packset void SuperWord::remove_pack_at(int pos) { Node_List* p = _packset.at(pos); for (uint i = 0; i < p->size(); i++) { Node* s = p->at(i); set_my_pack(s, NULL); } _packset.remove_at(pos); } //------------------------------executed_first--------------------------- // Return the node executed first in pack p. Uses the RPO block list // to determine order. Node* SuperWord::executed_first(Node_List* p) { Node* n = p->at(0); int n_rpo = bb_idx(n); for (uint i = 1; i < p->size(); i++) { Node* s = p->at(i); int s_rpo = bb_idx(s); if (s_rpo < n_rpo) { n = s; n_rpo = s_rpo; } } return n; } //------------------------------executed_last--------------------------- // Return the node executed last in pack p. Node* SuperWord::executed_last(Node_List* p) { Node* n = p->at(0); int n_rpo = bb_idx(n); for (uint i = 1; i < p->size(); i++) { Node* s = p->at(i); int s_rpo = bb_idx(s); if (s_rpo > n_rpo) { n = s; n_rpo = s_rpo; } } return n; } //----------------------------align_initial_loop_index--------------------------- // Adjust pre-loop limit so that in main loop, a load/store reference // to align_to_ref will be a position zero in the vector. // (iv + k) mod vector_align == 0 void SuperWord::align_initial_loop_index(MemNode* align_to_ref) { CountedLoopNode *main_head = lp()->as_CountedLoop(); assert(main_head->is_main_loop(), ""); CountedLoopEndNode* pre_end = get_pre_loop_end(main_head); assert(pre_end != NULL, ""); Node *pre_opaq1 = pre_end->limit(); assert(pre_opaq1->Opcode() == Op_Opaque1, ""); Opaque1Node *pre_opaq = (Opaque1Node*)pre_opaq1; Node *lim0 = pre_opaq->in(1); // Where we put new limit calculations Node *pre_ctrl = pre_end->loopnode()->in(LoopNode::EntryControl); // Ensure the original loop limit is available from the // pre-loop Opaque1 node. Node *orig_limit = pre_opaq->original_loop_limit(); assert(orig_limit != NULL && _igvn.type(orig_limit) != Type::TOP, ""); SWPointer align_to_ref_p(align_to_ref, this); // Given: // lim0 == original pre loop limit // V == v_align (power of 2) // invar == extra invariant piece of the address expression // e == k [ +/- invar ] // // When reassociating expressions involving '%' the basic rules are: // (a - b) % k == 0 => a % k == b % k // and: // (a + b) % k == 0 => a % k == (k - b) % k // // For stride > 0 && scale > 0, // Derive the new pre-loop limit "lim" such that the two constraints: // (1) lim = lim0 + N (where N is some positive integer < V) // (2) (e + lim) % V == 0 // are true. // // Substituting (1) into (2), // (e + lim0 + N) % V == 0 // solve for N: // N = (V - (e + lim0)) % V // substitute back into (1), so that new limit // lim = lim0 + (V - (e + lim0)) % V // // For stride > 0 && scale < 0 // Constraints: // lim = lim0 + N // (e - lim) % V == 0 // Solving for lim: // (e - lim0 - N) % V == 0 // N = (e - lim0) % V // lim = lim0 + (e - lim0) % V // // For stride < 0 && scale > 0 // Constraints: // lim = lim0 - N // (e + lim) % V == 0 // Solving for lim: // (e + lim0 - N) % V == 0 // N = (e + lim0) % V // lim = lim0 - (e + lim0) % V // // For stride < 0 && scale < 0 // Constraints: // lim = lim0 - N // (e - lim) % V == 0 // Solving for lim: // (e - lim0 + N) % V == 0 // N = (V - (e - lim0)) % V // lim = lim0 - (V - (e - lim0)) % V int stride = iv_stride(); int scale = align_to_ref_p.scale_in_bytes(); int elt_size = align_to_ref_p.memory_size(); int v_align = vector_width_in_bytes() / elt_size; int k = align_to_ref_p.offset_in_bytes() / elt_size; Node *kn = _igvn.intcon(k); Node *e = kn; if (align_to_ref_p.invar() != NULL) { // incorporate any extra invariant piece producing k +/- invar >>> log2(elt) Node* log2_elt = _igvn.intcon(exact_log2(elt_size)); Node* aref = new (_phase->C, 3) URShiftINode(align_to_ref_p.invar(), log2_elt); _phase->_igvn.register_new_node_with_optimizer(aref); _phase->set_ctrl(aref, pre_ctrl); if (align_to_ref_p.negate_invar()) { e = new (_phase->C, 3) SubINode(e, aref); } else { e = new (_phase->C, 3) AddINode(e, aref); } _phase->_igvn.register_new_node_with_optimizer(e); _phase->set_ctrl(e, pre_ctrl); } // compute e +/- lim0 if (scale < 0) { e = new (_phase->C, 3) SubINode(e, lim0); } else { e = new (_phase->C, 3) AddINode(e, lim0); } _phase->_igvn.register_new_node_with_optimizer(e); _phase->set_ctrl(e, pre_ctrl); if (stride * scale > 0) { // compute V - (e +/- lim0) Node* va = _igvn.intcon(v_align); e = new (_phase->C, 3) SubINode(va, e); _phase->_igvn.register_new_node_with_optimizer(e); _phase->set_ctrl(e, pre_ctrl); } // compute N = (exp) % V Node* va_msk = _igvn.intcon(v_align - 1); Node* N = new (_phase->C, 3) AndINode(e, va_msk); _phase->_igvn.register_new_node_with_optimizer(N); _phase->set_ctrl(N, pre_ctrl); // substitute back into (1), so that new limit // lim = lim0 + N Node* lim; if (stride < 0) { lim = new (_phase->C, 3) SubINode(lim0, N); } else { lim = new (_phase->C, 3) AddINode(lim0, N); } _phase->_igvn.register_new_node_with_optimizer(lim); _phase->set_ctrl(lim, pre_ctrl); Node* constrained = (stride > 0) ? (Node*) new (_phase->C,3) MinINode(lim, orig_limit) : (Node*) new (_phase->C,3) MaxINode(lim, orig_limit); _phase->_igvn.register_new_node_with_optimizer(constrained); _phase->set_ctrl(constrained, pre_ctrl); _igvn.hash_delete(pre_opaq); pre_opaq->set_req(1, constrained); } //----------------------------get_pre_loop_end--------------------------- // Find pre loop end from main loop. Returns null if none. CountedLoopEndNode* SuperWord::get_pre_loop_end(CountedLoopNode *cl) { Node *ctrl = cl->in(LoopNode::EntryControl); if (!ctrl->is_IfTrue() && !ctrl->is_IfFalse()) return NULL; Node *iffm = ctrl->in(0); if (!iffm->is_If()) return NULL; Node *p_f = iffm->in(0); if (!p_f->is_IfFalse()) return NULL; if (!p_f->in(0)->is_CountedLoopEnd()) return NULL; CountedLoopEndNode *pre_end = p_f->in(0)->as_CountedLoopEnd(); if (!pre_end->loopnode()->is_pre_loop()) return NULL; return pre_end; } //------------------------------init--------------------------- void SuperWord::init() { _dg.init(); _packset.clear(); _disjoint_ptrs.clear(); _block.clear(); _data_entry.clear(); _mem_slice_head.clear(); _mem_slice_tail.clear(); _node_info.clear(); _align_to_ref = NULL; _lpt = NULL; _lp = NULL; _bb = NULL; _iv = NULL; } //------------------------------print_packset--------------------------- void SuperWord::print_packset() { #ifndef PRODUCT tty->print_cr("packset"); for (int i = 0; i < _packset.length(); i++) { tty->print_cr("Pack: %d", i); Node_List* p = _packset.at(i); print_pack(p); } #endif } //------------------------------print_pack--------------------------- void SuperWord::print_pack(Node_List* p) { for (uint i = 0; i < p->size(); i++) { print_stmt(p->at(i)); } } //------------------------------print_bb--------------------------- void SuperWord::print_bb() { #ifndef PRODUCT tty->print_cr("\nBlock"); for (int i = 0; i < _block.length(); i++) { Node* n = _block.at(i); tty->print("%d ", i); if (n) { n->dump(); } } #endif } //------------------------------print_stmt--------------------------- void SuperWord::print_stmt(Node* s) { #ifndef PRODUCT tty->print(" align: %d \t", alignment(s)); s->dump(); #endif } //------------------------------blank--------------------------- char* SuperWord::blank(uint depth) { static char blanks[101]; assert(depth < 101, "too deep"); for (uint i = 0; i < depth; i++) blanks[i] = ' '; blanks[depth] = '\0'; return blanks; } //==============================SWPointer=========================== //----------------------------SWPointer------------------------ SWPointer::SWPointer(MemNode* mem, SuperWord* slp) : _mem(mem), _slp(slp), _base(NULL), _adr(NULL), _scale(0), _offset(0), _invar(NULL), _negate_invar(false) { Node* adr = mem->in(MemNode::Address); if (!adr->is_AddP()) { assert(!valid(), "too complex"); return; } // Match AddP(base, AddP(ptr, k*iv [+ invariant]), constant) Node* base = adr->in(AddPNode::Base); //unsafe reference could not be aligned appropriately without runtime checking if (base == NULL || base->bottom_type() == Type::TOP) { assert(!valid(), "unsafe access"); return; } for (int i = 0; i < 3; i++) { if (!scaled_iv_plus_offset(adr->in(AddPNode::Offset))) { assert(!valid(), "too complex"); return; } adr = adr->in(AddPNode::Address); if (base == adr || !adr->is_AddP()) { break; // stop looking at addp's } } _base = base; _adr = adr; assert(valid(), "Usable"); } // Following is used to create a temporary object during // the pattern match of an address expression. SWPointer::SWPointer(SWPointer* p) : _mem(p->_mem), _slp(p->_slp), _base(NULL), _adr(NULL), _scale(0), _offset(0), _invar(NULL), _negate_invar(false) {} //------------------------scaled_iv_plus_offset-------------------- // Match: k*iv + offset // where: k is a constant that maybe zero, and // offset is (k2 [+/- invariant]) where k2 maybe zero and invariant is optional bool SWPointer::scaled_iv_plus_offset(Node* n) { if (scaled_iv(n)) { return true; } if (offset_plus_k(n)) { return true; } int opc = n->Opcode(); if (opc == Op_AddI) { if (scaled_iv(n->in(1)) && offset_plus_k(n->in(2))) { return true; } if (scaled_iv(n->in(2)) && offset_plus_k(n->in(1))) { return true; } } else if (opc == Op_SubI) { if (scaled_iv(n->in(1)) && offset_plus_k(n->in(2), true)) { return true; } if (scaled_iv(n->in(2)) && offset_plus_k(n->in(1))) { _scale *= -1; return true; } } return false; } //----------------------------scaled_iv------------------------ // Match: k*iv where k is a constant that's not zero bool SWPointer::scaled_iv(Node* n) { if (_scale != 0) { return false; // already found a scale } if (n == iv()) { _scale = 1; return true; } int opc = n->Opcode(); if (opc == Op_MulI) { if (n->in(1) == iv() && n->in(2)->is_Con()) { _scale = n->in(2)->get_int(); return true; } else if (n->in(2) == iv() && n->in(1)->is_Con()) { _scale = n->in(1)->get_int(); return true; } } else if (opc == Op_LShiftI) { if (n->in(1) == iv() && n->in(2)->is_Con()) { _scale = 1 << n->in(2)->get_int(); return true; } } else if (opc == Op_ConvI2L) { if (scaled_iv_plus_offset(n->in(1))) { return true; } } else if (opc == Op_LShiftL) { if (!has_iv() && _invar == NULL) { // Need to preserve the current _offset value, so // create a temporary object for this expression subtree. // Hacky, so should re-engineer the address pattern match. SWPointer tmp(this); if (tmp.scaled_iv_plus_offset(n->in(1))) { if (tmp._invar == NULL) { int mult = 1 << n->in(2)->get_int(); _scale = tmp._scale * mult; _offset += tmp._offset * mult; return true; } } } } return false; } //----------------------------offset_plus_k------------------------ // Match: offset is (k [+/- invariant]) // where k maybe zero and invariant is optional, but not both. bool SWPointer::offset_plus_k(Node* n, bool negate) { int opc = n->Opcode(); if (opc == Op_ConI) { _offset += negate ? -(n->get_int()) : n->get_int(); return true; } else if (opc == Op_ConL) { // Okay if value fits into an int const TypeLong* t = n->find_long_type(); if (t->higher_equal(TypeLong::INT)) { jlong loff = n->get_long(); jint off = (jint)loff; _offset += negate ? -off : loff; return true; } return false; } if (_invar != NULL) return false; // already have an invariant if (opc == Op_AddI) { if (n->in(2)->is_Con() && invariant(n->in(1))) { _negate_invar = negate; _invar = n->in(1); _offset += negate ? -(n->in(2)->get_int()) : n->in(2)->get_int(); return true; } else if (n->in(1)->is_Con() && invariant(n->in(2))) { _offset += negate ? -(n->in(1)->get_int()) : n->in(1)->get_int(); _negate_invar = negate; _invar = n->in(2); return true; } } if (opc == Op_SubI) { if (n->in(2)->is_Con() && invariant(n->in(1))) { _negate_invar = negate; _invar = n->in(1); _offset += !negate ? -(n->in(2)->get_int()) : n->in(2)->get_int(); return true; } else if (n->in(1)->is_Con() && invariant(n->in(2))) { _offset += negate ? -(n->in(1)->get_int()) : n->in(1)->get_int(); _negate_invar = !negate; _invar = n->in(2); return true; } } if (invariant(n)) { _negate_invar = negate; _invar = n; return true; } return false; } //----------------------------print------------------------ void SWPointer::print() { #ifndef PRODUCT tty->print("base: %d adr: %d scale: %d offset: %d invar: %c%d\n", _base != NULL ? _base->_idx : 0, _adr != NULL ? _adr->_idx : 0, _scale, _offset, _negate_invar?'-':'+', _invar != NULL ? _invar->_idx : 0); #endif } // ========================= OrderedPair ===================== const OrderedPair OrderedPair::initial; // ========================= SWNodeInfo ===================== const SWNodeInfo SWNodeInfo::initial; // ============================ DepGraph =========================== //------------------------------make_node--------------------------- // Make a new dependence graph node for an ideal node. DepMem* DepGraph::make_node(Node* node) { DepMem* m = new (_arena) DepMem(node); if (node != NULL) { assert(_map.at_grow(node->_idx) == NULL, "one init only"); _map.at_put_grow(node->_idx, m); } return m; } //------------------------------make_edge--------------------------- // Make a new dependence graph edge from dpred -> dsucc DepEdge* DepGraph::make_edge(DepMem* dpred, DepMem* dsucc) { DepEdge* e = new (_arena) DepEdge(dpred, dsucc, dsucc->in_head(), dpred->out_head()); dpred->set_out_head(e); dsucc->set_in_head(e); return e; } // ========================== DepMem ======================== //------------------------------in_cnt--------------------------- int DepMem::in_cnt() { int ct = 0; for (DepEdge* e = _in_head; e != NULL; e = e->next_in()) ct++; return ct; } //------------------------------out_cnt--------------------------- int DepMem::out_cnt() { int ct = 0; for (DepEdge* e = _out_head; e != NULL; e = e->next_out()) ct++; return ct; } //------------------------------print----------------------------- void DepMem::print() { #ifndef PRODUCT tty->print(" DepNode %d (", _node->_idx); for (DepEdge* p = _in_head; p != NULL; p = p->next_in()) { Node* pred = p->pred()->node(); tty->print(" %d", pred != NULL ? pred->_idx : 0); } tty->print(") ["); for (DepEdge* s = _out_head; s != NULL; s = s->next_out()) { Node* succ = s->succ()->node(); tty->print(" %d", succ != NULL ? succ->_idx : 0); } tty->print_cr(" ]"); #endif } // =========================== DepEdge ========================= //------------------------------DepPreds--------------------------- void DepEdge::print() { #ifndef PRODUCT tty->print_cr("DepEdge: %d [ %d ]", _pred->node()->_idx, _succ->node()->_idx); #endif } // =========================== DepPreds ========================= // Iterator over predecessor edges in the dependence graph. //------------------------------DepPreds--------------------------- DepPreds::DepPreds(Node* n, DepGraph& dg) { _n = n; _done = false; if (_n->is_Store() || _n->is_Load()) { _next_idx = MemNode::Address; _end_idx = n->req(); _dep_next = dg.dep(_n)->in_head(); } else if (_n->is_Mem()) { _next_idx = 0; _end_idx = 0; _dep_next = dg.dep(_n)->in_head(); } else { _next_idx = 1; _end_idx = _n->req(); _dep_next = NULL; } next(); } //------------------------------next--------------------------- void DepPreds::next() { if (_dep_next != NULL) { _current = _dep_next->pred()->node(); _dep_next = _dep_next->next_in(); } else if (_next_idx < _end_idx) { _current = _n->in(_next_idx++); } else { _done = true; } } // =========================== DepSuccs ========================= // Iterator over successor edges in the dependence graph. //------------------------------DepSuccs--------------------------- DepSuccs::DepSuccs(Node* n, DepGraph& dg) { _n = n; _done = false; if (_n->is_Load()) { _next_idx = 0; _end_idx = _n->outcnt(); _dep_next = dg.dep(_n)->out_head(); } else if (_n->is_Mem() || _n->is_Phi() && _n->bottom_type() == Type::MEMORY) { _next_idx = 0; _end_idx = 0; _dep_next = dg.dep(_n)->out_head(); } else { _next_idx = 0; _end_idx = _n->outcnt(); _dep_next = NULL; } next(); } //-------------------------------next--------------------------- void DepSuccs::next() { if (_dep_next != NULL) { _current = _dep_next->succ()->node(); _dep_next = _dep_next->next_out(); } else if (_next_idx < _end_idx) { _current = _n->raw_out(_next_idx++); } else { _done = true; } }