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[/] [openrisc/] [trunk/] [gnu-stable/] [gcc-4.5.1/] [gcc/] [tree-ssa-loop-prefetch.c] - Rev 280
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/* Array prefetching. Copyright (C) 2005, 2007, 2008 Free Software Foundation, Inc. This file is part of GCC. GCC 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. GCC 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 GCC; see the file COPYING3. If not see <http://www.gnu.org/licenses/>. */ #include "config.h" #include "system.h" #include "coretypes.h" #include "tm.h" #include "tree.h" #include "rtl.h" #include "tm_p.h" #include "hard-reg-set.h" #include "basic-block.h" #include "output.h" #include "diagnostic.h" #include "tree-flow.h" #include "tree-dump.h" #include "timevar.h" #include "cfgloop.h" #include "varray.h" #include "expr.h" #include "tree-pass.h" #include "ggc.h" #include "insn-config.h" #include "recog.h" #include "hashtab.h" #include "tree-chrec.h" #include "tree-scalar-evolution.h" #include "toplev.h" #include "params.h" #include "langhooks.h" #include "tree-inline.h" #include "tree-data-ref.h" #include "optabs.h" /* This pass inserts prefetch instructions to optimize cache usage during accesses to arrays in loops. It processes loops sequentially and: 1) Gathers all memory references in the single loop. 2) For each of the references it decides when it is profitable to prefetch it. To do it, we evaluate the reuse among the accesses, and determines two values: PREFETCH_BEFORE (meaning that it only makes sense to do prefetching in the first PREFETCH_BEFORE iterations of the loop) and PREFETCH_MOD (meaning that it only makes sense to prefetch in the iterations of the loop that are zero modulo PREFETCH_MOD). For example (assuming cache line size is 64 bytes, char has size 1 byte and there is no hardware sequential prefetch): char *a; for (i = 0; i < max; i++) { a[255] = ...; (0) a[i] = ...; (1) a[i + 64] = ...; (2) a[16*i] = ...; (3) a[187*i] = ...; (4) a[187*i + 50] = ...; (5) } (0) obviously has PREFETCH_BEFORE 1 (1) has PREFETCH_BEFORE 64, since (2) accesses the same memory location 64 iterations before it, and PREFETCH_MOD 64 (since it hits the same cache line otherwise). (2) has PREFETCH_MOD 64 (3) has PREFETCH_MOD 4 (4) has PREFETCH_MOD 1. We do not set PREFETCH_BEFORE here, since the cache line accessed by (4) is the same with probability only 7/32. (5) has PREFETCH_MOD 1 as well. Additionally, we use data dependence analysis to determine for each reference the distance till the first reuse; this information is used to determine the temporality of the issued prefetch instruction. 3) We determine how much ahead we need to prefetch. The number of iterations needed is time to fetch / time spent in one iteration of the loop. The problem is that we do not know either of these values, so we just make a heuristic guess based on a magic (possibly) target-specific constant and size of the loop. 4) Determine which of the references we prefetch. We take into account that there is a maximum number of simultaneous prefetches (provided by machine description). We prefetch as many prefetches as possible while still within this bound (starting with those with lowest prefetch_mod, since they are responsible for most of the cache misses). 5) We unroll and peel loops so that we are able to satisfy PREFETCH_MOD and PREFETCH_BEFORE requirements (within some bounds), and to avoid prefetching nonaccessed memory. TODO -- actually implement peeling. 6) We actually emit the prefetch instructions. ??? Perhaps emit the prefetch instructions with guards in cases where 5) was not sufficient to satisfy the constraints? The function is_loop_prefetching_profitable() implements a cost model to determine if prefetching is profitable for a given loop. The cost model has two heuristcs: 1. A heuristic that determines whether the given loop has enough CPU ops that can be overlapped with cache missing memory ops. If not, the loop won't benefit from prefetching. This is implemented by requirung the ratio between the instruction count and the mem ref count to be above a certain minimum. 2. A heuristic that disables prefetching in a loop with an unknown trip count if the prefetching cost is above a certain limit. The relative prefetching cost is estimated by taking the ratio between the prefetch count and the total intruction count (this models the I-cache cost). The limits used in these heuristics are defined as parameters with reasonable default values. Machine-specific default values will be added later. Some other TODO: -- write and use more general reuse analysis (that could be also used in other cache aimed loop optimizations) -- make it behave sanely together with the prefetches given by user (now we just ignore them; at the very least we should avoid optimizing loops in that user put his own prefetches) -- we assume cache line size alignment of arrays; this could be improved. */ /* Magic constants follow. These should be replaced by machine specific numbers. */ /* True if write can be prefetched by a read prefetch. */ #ifndef WRITE_CAN_USE_READ_PREFETCH #define WRITE_CAN_USE_READ_PREFETCH 1 #endif /* True if read can be prefetched by a write prefetch. */ #ifndef READ_CAN_USE_WRITE_PREFETCH #define READ_CAN_USE_WRITE_PREFETCH 0 #endif /* The size of the block loaded by a single prefetch. Usually, this is the same as cache line size (at the moment, we only consider one level of cache hierarchy). */ #ifndef PREFETCH_BLOCK #define PREFETCH_BLOCK L1_CACHE_LINE_SIZE #endif /* Do we have a forward hardware sequential prefetching? */ #ifndef HAVE_FORWARD_PREFETCH #define HAVE_FORWARD_PREFETCH 0 #endif /* Do we have a backward hardware sequential prefetching? */ #ifndef HAVE_BACKWARD_PREFETCH #define HAVE_BACKWARD_PREFETCH 0 #endif /* In some cases we are only able to determine that there is a certain probability that the two accesses hit the same cache line. In this case, we issue the prefetches for both of them if this probability is less then (1000 - ACCEPTABLE_MISS_RATE) per thousand. */ #ifndef ACCEPTABLE_MISS_RATE #define ACCEPTABLE_MISS_RATE 50 #endif #ifndef HAVE_prefetch #define HAVE_prefetch 0 #endif #define L1_CACHE_SIZE_BYTES ((unsigned) (L1_CACHE_SIZE * 1024)) #define L2_CACHE_SIZE_BYTES ((unsigned) (L2_CACHE_SIZE * 1024)) /* We consider a memory access nontemporal if it is not reused sooner than after L2_CACHE_SIZE_BYTES of memory are accessed. However, we ignore accesses closer than L1_CACHE_SIZE_BYTES / NONTEMPORAL_FRACTION, so that we use nontemporal prefetches e.g. if single memory location is accessed several times in a single iteration of the loop. */ #define NONTEMPORAL_FRACTION 16 /* In case we have to emit a memory fence instruction after the loop that uses nontemporal stores, this defines the builtin to use. */ #ifndef FENCE_FOLLOWING_MOVNT #define FENCE_FOLLOWING_MOVNT NULL_TREE #endif /* The group of references between that reuse may occur. */ struct mem_ref_group { tree base; /* Base of the reference. */ HOST_WIDE_INT step; /* Step of the reference. */ struct mem_ref *refs; /* References in the group. */ struct mem_ref_group *next; /* Next group of references. */ }; /* Assigned to PREFETCH_BEFORE when all iterations are to be prefetched. */ #define PREFETCH_ALL (~(unsigned HOST_WIDE_INT) 0) /* The memory reference. */ struct mem_ref { gimple stmt; /* Statement in that the reference appears. */ tree mem; /* The reference. */ HOST_WIDE_INT delta; /* Constant offset of the reference. */ struct mem_ref_group *group; /* The group of references it belongs to. */ unsigned HOST_WIDE_INT prefetch_mod; /* Prefetch only each PREFETCH_MOD-th iteration. */ unsigned HOST_WIDE_INT prefetch_before; /* Prefetch only first PREFETCH_BEFORE iterations. */ unsigned reuse_distance; /* The amount of data accessed before the first reuse of this value. */ struct mem_ref *next; /* The next reference in the group. */ unsigned write_p : 1; /* Is it a write? */ unsigned independent_p : 1; /* True if the reference is independent on all other references inside the loop. */ unsigned issue_prefetch_p : 1; /* Should we really issue the prefetch? */ unsigned storent_p : 1; /* True if we changed the store to a nontemporal one. */ }; /* Dumps information about reference REF to FILE. */ static void dump_mem_ref (FILE *file, struct mem_ref *ref) { fprintf (file, "Reference %p:\n", (void *) ref); fprintf (file, " group %p (base ", (void *) ref->group); print_generic_expr (file, ref->group->base, TDF_SLIM); fprintf (file, ", step "); fprintf (file, HOST_WIDE_INT_PRINT_DEC, ref->group->step); fprintf (file, ")\n"); fprintf (file, " delta "); fprintf (file, HOST_WIDE_INT_PRINT_DEC, ref->delta); fprintf (file, "\n"); fprintf (file, " %s\n", ref->write_p ? "write" : "read"); fprintf (file, "\n"); } /* Finds a group with BASE and STEP in GROUPS, or creates one if it does not exist. */ static struct mem_ref_group * find_or_create_group (struct mem_ref_group **groups, tree base, HOST_WIDE_INT step) { struct mem_ref_group *group; for (; *groups; groups = &(*groups)->next) { if ((*groups)->step == step && operand_equal_p ((*groups)->base, base, 0)) return *groups; /* Keep the list of groups sorted by decreasing step. */ if ((*groups)->step < step) break; } group = XNEW (struct mem_ref_group); group->base = base; group->step = step; group->refs = NULL; group->next = *groups; *groups = group; return group; } /* Records a memory reference MEM in GROUP with offset DELTA and write status WRITE_P. The reference occurs in statement STMT. */ static void record_ref (struct mem_ref_group *group, gimple stmt, tree mem, HOST_WIDE_INT delta, bool write_p) { struct mem_ref **aref; /* Do not record the same address twice. */ for (aref = &group->refs; *aref; aref = &(*aref)->next) { /* It does not have to be possible for write reference to reuse the read prefetch, or vice versa. */ if (!WRITE_CAN_USE_READ_PREFETCH && write_p && !(*aref)->write_p) continue; if (!READ_CAN_USE_WRITE_PREFETCH && !write_p && (*aref)->write_p) continue; if ((*aref)->delta == delta) return; } (*aref) = XNEW (struct mem_ref); (*aref)->stmt = stmt; (*aref)->mem = mem; (*aref)->delta = delta; (*aref)->write_p = write_p; (*aref)->prefetch_before = PREFETCH_ALL; (*aref)->prefetch_mod = 1; (*aref)->reuse_distance = 0; (*aref)->issue_prefetch_p = false; (*aref)->group = group; (*aref)->next = NULL; (*aref)->independent_p = false; (*aref)->storent_p = false; if (dump_file && (dump_flags & TDF_DETAILS)) dump_mem_ref (dump_file, *aref); } /* Release memory references in GROUPS. */ static void release_mem_refs (struct mem_ref_group *groups) { struct mem_ref_group *next_g; struct mem_ref *ref, *next_r; for (; groups; groups = next_g) { next_g = groups->next; for (ref = groups->refs; ref; ref = next_r) { next_r = ref->next; free (ref); } free (groups); } } /* A structure used to pass arguments to idx_analyze_ref. */ struct ar_data { struct loop *loop; /* Loop of the reference. */ gimple stmt; /* Statement of the reference. */ HOST_WIDE_INT *step; /* Step of the memory reference. */ HOST_WIDE_INT *delta; /* Offset of the memory reference. */ }; /* Analyzes a single INDEX of a memory reference to obtain information described at analyze_ref. Callback for for_each_index. */ static bool idx_analyze_ref (tree base, tree *index, void *data) { struct ar_data *ar_data = (struct ar_data *) data; tree ibase, step, stepsize; HOST_WIDE_INT istep, idelta = 0, imult = 1; affine_iv iv; if (TREE_CODE (base) == MISALIGNED_INDIRECT_REF || TREE_CODE (base) == ALIGN_INDIRECT_REF) return false; if (!simple_iv (ar_data->loop, loop_containing_stmt (ar_data->stmt), *index, &iv, false)) return false; ibase = iv.base; step = iv.step; if (!cst_and_fits_in_hwi (step)) return false; istep = int_cst_value (step); if (TREE_CODE (ibase) == POINTER_PLUS_EXPR && cst_and_fits_in_hwi (TREE_OPERAND (ibase, 1))) { idelta = int_cst_value (TREE_OPERAND (ibase, 1)); ibase = TREE_OPERAND (ibase, 0); } if (cst_and_fits_in_hwi (ibase)) { idelta += int_cst_value (ibase); ibase = build_int_cst (TREE_TYPE (ibase), 0); } if (TREE_CODE (base) == ARRAY_REF) { stepsize = array_ref_element_size (base); if (!cst_and_fits_in_hwi (stepsize)) return false; imult = int_cst_value (stepsize); istep *= imult; idelta *= imult; } *ar_data->step += istep; *ar_data->delta += idelta; *index = ibase; return true; } /* Tries to express REF_P in shape &BASE + STEP * iter + DELTA, where DELTA and STEP are integer constants and iter is number of iterations of LOOP. The reference occurs in statement STMT. Strips nonaddressable component references from REF_P. */ static bool analyze_ref (struct loop *loop, tree *ref_p, tree *base, HOST_WIDE_INT *step, HOST_WIDE_INT *delta, gimple stmt) { struct ar_data ar_data; tree off; HOST_WIDE_INT bit_offset; tree ref = *ref_p; *step = 0; *delta = 0; /* First strip off the component references. Ignore bitfields. */ if (TREE_CODE (ref) == COMPONENT_REF && DECL_NONADDRESSABLE_P (TREE_OPERAND (ref, 1))) ref = TREE_OPERAND (ref, 0); *ref_p = ref; for (; TREE_CODE (ref) == COMPONENT_REF; ref = TREE_OPERAND (ref, 0)) { off = DECL_FIELD_BIT_OFFSET (TREE_OPERAND (ref, 1)); bit_offset = TREE_INT_CST_LOW (off); gcc_assert (bit_offset % BITS_PER_UNIT == 0); *delta += bit_offset / BITS_PER_UNIT; } *base = unshare_expr (ref); ar_data.loop = loop; ar_data.stmt = stmt; ar_data.step = step; ar_data.delta = delta; return for_each_index (base, idx_analyze_ref, &ar_data); } /* Record a memory reference REF to the list REFS. The reference occurs in LOOP in statement STMT and it is write if WRITE_P. Returns true if the reference was recorded, false otherwise. */ static bool gather_memory_references_ref (struct loop *loop, struct mem_ref_group **refs, tree ref, bool write_p, gimple stmt) { tree base; HOST_WIDE_INT step, delta; struct mem_ref_group *agrp; if (get_base_address (ref) == NULL) return false; if (!analyze_ref (loop, &ref, &base, &step, &delta, stmt)) return false; /* Now we know that REF = &BASE + STEP * iter + DELTA, where DELTA and STEP are integer constants. */ agrp = find_or_create_group (refs, base, step); record_ref (agrp, stmt, ref, delta, write_p); return true; } /* Record the suitable memory references in LOOP. NO_OTHER_REFS is set to true if there are no other memory references inside the loop. */ static struct mem_ref_group * gather_memory_references (struct loop *loop, bool *no_other_refs, unsigned *ref_count) { basic_block *body = get_loop_body_in_dom_order (loop); basic_block bb; unsigned i; gimple_stmt_iterator bsi; gimple stmt; tree lhs, rhs; struct mem_ref_group *refs = NULL; *no_other_refs = true; *ref_count = 0; /* Scan the loop body in order, so that the former references precede the later ones. */ for (i = 0; i < loop->num_nodes; i++) { bb = body[i]; if (bb->loop_father != loop) continue; for (bsi = gsi_start_bb (bb); !gsi_end_p (bsi); gsi_next (&bsi)) { stmt = gsi_stmt (bsi); if (gimple_code (stmt) != GIMPLE_ASSIGN) { if (gimple_vuse (stmt) || (is_gimple_call (stmt) && !(gimple_call_flags (stmt) & ECF_CONST))) *no_other_refs = false; continue; } lhs = gimple_assign_lhs (stmt); rhs = gimple_assign_rhs1 (stmt); if (REFERENCE_CLASS_P (rhs)) { *no_other_refs &= gather_memory_references_ref (loop, &refs, rhs, false, stmt); *ref_count += 1; } if (REFERENCE_CLASS_P (lhs)) { *no_other_refs &= gather_memory_references_ref (loop, &refs, lhs, true, stmt); *ref_count += 1; } } } free (body); return refs; } /* Prune the prefetch candidate REF using the self-reuse. */ static void prune_ref_by_self_reuse (struct mem_ref *ref) { HOST_WIDE_INT step = ref->group->step; bool backward = step < 0; if (step == 0) { /* Prefetch references to invariant address just once. */ ref->prefetch_before = 1; return; } if (backward) step = -step; if (step > PREFETCH_BLOCK) return; if ((backward && HAVE_BACKWARD_PREFETCH) || (!backward && HAVE_FORWARD_PREFETCH)) { ref->prefetch_before = 1; return; } ref->prefetch_mod = PREFETCH_BLOCK / step; } /* Divides X by BY, rounding down. */ static HOST_WIDE_INT ddown (HOST_WIDE_INT x, unsigned HOST_WIDE_INT by) { gcc_assert (by > 0); if (x >= 0) return x / by; else return (x + by - 1) / by; } /* Given a CACHE_LINE_SIZE and two inductive memory references with a common STEP greater than CACHE_LINE_SIZE and an address difference DELTA, compute the probability that they will fall in different cache lines. DISTINCT_ITERS is the number of distinct iterations after which the pattern repeats itself. ALIGN_UNIT is the unit of alignment in bytes. */ static int compute_miss_rate (unsigned HOST_WIDE_INT cache_line_size, HOST_WIDE_INT step, HOST_WIDE_INT delta, unsigned HOST_WIDE_INT distinct_iters, int align_unit) { unsigned align, iter; int total_positions, miss_positions, miss_rate; int address1, address2, cache_line1, cache_line2; total_positions = 0; miss_positions = 0; /* Iterate through all possible alignments of the first memory reference within its cache line. */ for (align = 0; align < cache_line_size; align += align_unit) /* Iterate through all distinct iterations. */ for (iter = 0; iter < distinct_iters; iter++) { address1 = align + step * iter; address2 = address1 + delta; cache_line1 = address1 / cache_line_size; cache_line2 = address2 / cache_line_size; total_positions += 1; if (cache_line1 != cache_line2) miss_positions += 1; } miss_rate = 1000 * miss_positions / total_positions; return miss_rate; } /* Prune the prefetch candidate REF using the reuse with BY. If BY_IS_BEFORE is true, BY is before REF in the loop. */ static void prune_ref_by_group_reuse (struct mem_ref *ref, struct mem_ref *by, bool by_is_before) { HOST_WIDE_INT step = ref->group->step; bool backward = step < 0; HOST_WIDE_INT delta_r = ref->delta, delta_b = by->delta; HOST_WIDE_INT delta = delta_b - delta_r; HOST_WIDE_INT hit_from; unsigned HOST_WIDE_INT prefetch_before, prefetch_block; int miss_rate; HOST_WIDE_INT reduced_step; unsigned HOST_WIDE_INT reduced_prefetch_block; tree ref_type; int align_unit; if (delta == 0) { /* If the references has the same address, only prefetch the former. */ if (by_is_before) ref->prefetch_before = 0; return; } if (!step) { /* If the reference addresses are invariant and fall into the same cache line, prefetch just the first one. */ if (!by_is_before) return; if (ddown (ref->delta, PREFETCH_BLOCK) != ddown (by->delta, PREFETCH_BLOCK)) return; ref->prefetch_before = 0; return; } /* Only prune the reference that is behind in the array. */ if (backward) { if (delta > 0) return; /* Transform the data so that we may assume that the accesses are forward. */ delta = - delta; step = -step; delta_r = PREFETCH_BLOCK - 1 - delta_r; delta_b = PREFETCH_BLOCK - 1 - delta_b; } else { if (delta < 0) return; } /* Check whether the two references are likely to hit the same cache line, and how distant the iterations in that it occurs are from each other. */ if (step <= PREFETCH_BLOCK) { /* The accesses are sure to meet. Let us check when. */ hit_from = ddown (delta_b, PREFETCH_BLOCK) * PREFETCH_BLOCK; prefetch_before = (hit_from - delta_r + step - 1) / step; if (prefetch_before < ref->prefetch_before) ref->prefetch_before = prefetch_before; return; } /* A more complicated case with step > prefetch_block. First reduce the ratio between the step and the cache line size to its simplest terms. The resulting denominator will then represent the number of distinct iterations after which each address will go back to its initial location within the cache line. This computation assumes that PREFETCH_BLOCK is a power of two. */ prefetch_block = PREFETCH_BLOCK; reduced_prefetch_block = prefetch_block; reduced_step = step; while ((reduced_step & 1) == 0 && reduced_prefetch_block > 1) { reduced_step >>= 1; reduced_prefetch_block >>= 1; } prefetch_before = delta / step; delta %= step; ref_type = TREE_TYPE (ref->mem); align_unit = TYPE_ALIGN (ref_type) / 8; miss_rate = compute_miss_rate(prefetch_block, step, delta, reduced_prefetch_block, align_unit); if (miss_rate <= ACCEPTABLE_MISS_RATE) { if (prefetch_before < ref->prefetch_before) ref->prefetch_before = prefetch_before; return; } /* Try also the following iteration. */ prefetch_before++; delta = step - delta; miss_rate = compute_miss_rate(prefetch_block, step, delta, reduced_prefetch_block, align_unit); if (miss_rate <= ACCEPTABLE_MISS_RATE) { if (prefetch_before < ref->prefetch_before) ref->prefetch_before = prefetch_before; return; } /* The ref probably does not reuse by. */ return; } /* Prune the prefetch candidate REF using the reuses with other references in REFS. */ static void prune_ref_by_reuse (struct mem_ref *ref, struct mem_ref *refs) { struct mem_ref *prune_by; bool before = true; prune_ref_by_self_reuse (ref); for (prune_by = refs; prune_by; prune_by = prune_by->next) { if (prune_by == ref) { before = false; continue; } if (!WRITE_CAN_USE_READ_PREFETCH && ref->write_p && !prune_by->write_p) continue; if (!READ_CAN_USE_WRITE_PREFETCH && !ref->write_p && prune_by->write_p) continue; prune_ref_by_group_reuse (ref, prune_by, before); } } /* Prune the prefetch candidates in GROUP using the reuse analysis. */ static void prune_group_by_reuse (struct mem_ref_group *group) { struct mem_ref *ref_pruned; for (ref_pruned = group->refs; ref_pruned; ref_pruned = ref_pruned->next) { prune_ref_by_reuse (ref_pruned, group->refs); if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "Reference %p:", (void *) ref_pruned); if (ref_pruned->prefetch_before == PREFETCH_ALL && ref_pruned->prefetch_mod == 1) fprintf (dump_file, " no restrictions"); else if (ref_pruned->prefetch_before == 0) fprintf (dump_file, " do not prefetch"); else if (ref_pruned->prefetch_before <= ref_pruned->prefetch_mod) fprintf (dump_file, " prefetch once"); else { if (ref_pruned->prefetch_before != PREFETCH_ALL) { fprintf (dump_file, " prefetch before "); fprintf (dump_file, HOST_WIDE_INT_PRINT_DEC, ref_pruned->prefetch_before); } if (ref_pruned->prefetch_mod != 1) { fprintf (dump_file, " prefetch mod "); fprintf (dump_file, HOST_WIDE_INT_PRINT_DEC, ref_pruned->prefetch_mod); } } fprintf (dump_file, "\n"); } } } /* Prune the list of prefetch candidates GROUPS using the reuse analysis. */ static void prune_by_reuse (struct mem_ref_group *groups) { for (; groups; groups = groups->next) prune_group_by_reuse (groups); } /* Returns true if we should issue prefetch for REF. */ static bool should_issue_prefetch_p (struct mem_ref *ref) { /* For now do not issue prefetches for only first few of the iterations. */ if (ref->prefetch_before != PREFETCH_ALL) return false; /* Do not prefetch nontemporal stores. */ if (ref->storent_p) return false; return true; } /* Decide which of the prefetch candidates in GROUPS to prefetch. AHEAD is the number of iterations to prefetch ahead (which corresponds to the number of simultaneous instances of one prefetch running at a time). UNROLL_FACTOR is the factor by that the loop is going to be unrolled. Returns true if there is anything to prefetch. */ static bool schedule_prefetches (struct mem_ref_group *groups, unsigned unroll_factor, unsigned ahead) { unsigned remaining_prefetch_slots, n_prefetches, prefetch_slots; unsigned slots_per_prefetch; struct mem_ref *ref; bool any = false; /* At most SIMULTANEOUS_PREFETCHES should be running at the same time. */ remaining_prefetch_slots = SIMULTANEOUS_PREFETCHES; /* The prefetch will run for AHEAD iterations of the original loop, i.e., AHEAD / UNROLL_FACTOR iterations of the unrolled loop. In each iteration, it will need a prefetch slot. */ slots_per_prefetch = (ahead + unroll_factor / 2) / unroll_factor; if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "Each prefetch instruction takes %u prefetch slots.\n", slots_per_prefetch); /* For now we just take memory references one by one and issue prefetches for as many as possible. The groups are sorted starting with the largest step, since the references with large step are more likely to cause many cache misses. */ for (; groups; groups = groups->next) for (ref = groups->refs; ref; ref = ref->next) { if (!should_issue_prefetch_p (ref)) continue; /* If we need to prefetch the reference each PREFETCH_MOD iterations, and we unroll the loop UNROLL_FACTOR times, we need to insert ceil (UNROLL_FACTOR / PREFETCH_MOD) instructions in each iteration. */ n_prefetches = ((unroll_factor + ref->prefetch_mod - 1) / ref->prefetch_mod); prefetch_slots = n_prefetches * slots_per_prefetch; /* If more than half of the prefetches would be lost anyway, do not issue the prefetch. */ if (2 * remaining_prefetch_slots < prefetch_slots) continue; ref->issue_prefetch_p = true; if (remaining_prefetch_slots <= prefetch_slots) return true; remaining_prefetch_slots -= prefetch_slots; any = true; } return any; } /* Estimate the number of prefetches in the given GROUPS. */ static int estimate_prefetch_count (struct mem_ref_group *groups) { struct mem_ref *ref; int prefetch_count = 0; for (; groups; groups = groups->next) for (ref = groups->refs; ref; ref = ref->next) if (should_issue_prefetch_p (ref)) prefetch_count++; return prefetch_count; } /* Issue prefetches for the reference REF into loop as decided before. HEAD is the number of iterations to prefetch ahead. UNROLL_FACTOR is the factor by which LOOP was unrolled. */ static void issue_prefetch_ref (struct mem_ref *ref, unsigned unroll_factor, unsigned ahead) { HOST_WIDE_INT delta; tree addr, addr_base, write_p, local; gimple prefetch; gimple_stmt_iterator bsi; unsigned n_prefetches, ap; bool nontemporal = ref->reuse_distance >= L2_CACHE_SIZE_BYTES; if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "Issued%s prefetch for %p.\n", nontemporal ? " nontemporal" : "", (void *) ref); bsi = gsi_for_stmt (ref->stmt); n_prefetches = ((unroll_factor + ref->prefetch_mod - 1) / ref->prefetch_mod); addr_base = build_fold_addr_expr_with_type (ref->mem, ptr_type_node); addr_base = force_gimple_operand_gsi (&bsi, unshare_expr (addr_base), true, NULL, true, GSI_SAME_STMT); write_p = ref->write_p ? integer_one_node : integer_zero_node; local = build_int_cst (integer_type_node, nontemporal ? 0 : 3); for (ap = 0; ap < n_prefetches; ap++) { /* Determine the address to prefetch. */ delta = (ahead + ap * ref->prefetch_mod) * ref->group->step; addr = fold_build2 (POINTER_PLUS_EXPR, ptr_type_node, addr_base, size_int (delta)); addr = force_gimple_operand_gsi (&bsi, unshare_expr (addr), true, NULL, true, GSI_SAME_STMT); /* Create the prefetch instruction. */ prefetch = gimple_build_call (built_in_decls[BUILT_IN_PREFETCH], 3, addr, write_p, local); gsi_insert_before (&bsi, prefetch, GSI_SAME_STMT); } } /* Issue prefetches for the references in GROUPS into loop as decided before. HEAD is the number of iterations to prefetch ahead. UNROLL_FACTOR is the factor by that LOOP was unrolled. */ static void issue_prefetches (struct mem_ref_group *groups, unsigned unroll_factor, unsigned ahead) { struct mem_ref *ref; for (; groups; groups = groups->next) for (ref = groups->refs; ref; ref = ref->next) if (ref->issue_prefetch_p) issue_prefetch_ref (ref, unroll_factor, ahead); } /* Returns true if REF is a memory write for that a nontemporal store insn can be used. */ static bool nontemporal_store_p (struct mem_ref *ref) { enum machine_mode mode; enum insn_code code; /* REF must be a write that is not reused. We require it to be independent on all other memory references in the loop, as the nontemporal stores may be reordered with respect to other memory references. */ if (!ref->write_p || !ref->independent_p || ref->reuse_distance < L2_CACHE_SIZE_BYTES) return false; /* Check that we have the storent instruction for the mode. */ mode = TYPE_MODE (TREE_TYPE (ref->mem)); if (mode == BLKmode) return false; code = optab_handler (storent_optab, mode)->insn_code; return code != CODE_FOR_nothing; } /* If REF is a nontemporal store, we mark the corresponding modify statement and return true. Otherwise, we return false. */ static bool mark_nontemporal_store (struct mem_ref *ref) { if (!nontemporal_store_p (ref)) return false; if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "Marked reference %p as a nontemporal store.\n", (void *) ref); gimple_assign_set_nontemporal_move (ref->stmt, true); ref->storent_p = true; return true; } /* Issue a memory fence instruction after LOOP. */ static void emit_mfence_after_loop (struct loop *loop) { VEC (edge, heap) *exits = get_loop_exit_edges (loop); edge exit; gimple call; gimple_stmt_iterator bsi; unsigned i; for (i = 0; VEC_iterate (edge, exits, i, exit); i++) { call = gimple_build_call (FENCE_FOLLOWING_MOVNT, 0); if (!single_pred_p (exit->dest) /* If possible, we prefer not to insert the fence on other paths in cfg. */ && !(exit->flags & EDGE_ABNORMAL)) split_loop_exit_edge (exit); bsi = gsi_after_labels (exit->dest); gsi_insert_before (&bsi, call, GSI_NEW_STMT); mark_virtual_ops_for_renaming (call); } VEC_free (edge, heap, exits); update_ssa (TODO_update_ssa_only_virtuals); } /* Returns true if we can use storent in loop, false otherwise. */ static bool may_use_storent_in_loop_p (struct loop *loop) { bool ret = true; if (loop->inner != NULL) return false; /* If we must issue a mfence insn after using storent, check that there is a suitable place for it at each of the loop exits. */ if (FENCE_FOLLOWING_MOVNT != NULL_TREE) { VEC (edge, heap) *exits = get_loop_exit_edges (loop); unsigned i; edge exit; for (i = 0; VEC_iterate (edge, exits, i, exit); i++) if ((exit->flags & EDGE_ABNORMAL) && exit->dest == EXIT_BLOCK_PTR) ret = false; VEC_free (edge, heap, exits); } return ret; } /* Marks nontemporal stores in LOOP. GROUPS contains the description of memory references in the loop. */ static void mark_nontemporal_stores (struct loop *loop, struct mem_ref_group *groups) { struct mem_ref *ref; bool any = false; if (!may_use_storent_in_loop_p (loop)) return; for (; groups; groups = groups->next) for (ref = groups->refs; ref; ref = ref->next) any |= mark_nontemporal_store (ref); if (any && FENCE_FOLLOWING_MOVNT != NULL_TREE) emit_mfence_after_loop (loop); } /* Determines whether we can profitably unroll LOOP FACTOR times, and if this is the case, fill in DESC by the description of number of iterations. */ static bool should_unroll_loop_p (struct loop *loop, struct tree_niter_desc *desc, unsigned factor) { if (!can_unroll_loop_p (loop, factor, desc)) return false; /* We only consider loops without control flow for unrolling. This is not a hard restriction -- tree_unroll_loop works with arbitrary loops as well; but the unrolling/prefetching is usually more profitable for loops consisting of a single basic block, and we want to limit the code growth. */ if (loop->num_nodes > 2) return false; return true; } /* Determine the coefficient by that unroll LOOP, from the information contained in the list of memory references REFS. Description of umber of iterations of LOOP is stored to DESC. NINSNS is the number of insns of the LOOP. EST_NITER is the estimated number of iterations of the loop, or -1 if no estimate is available. */ static unsigned determine_unroll_factor (struct loop *loop, struct mem_ref_group *refs, unsigned ninsns, struct tree_niter_desc *desc, HOST_WIDE_INT est_niter) { unsigned upper_bound; unsigned nfactor, factor, mod_constraint; struct mem_ref_group *agp; struct mem_ref *ref; /* First check whether the loop is not too large to unroll. We ignore PARAM_MAX_UNROLL_TIMES, because for small loops, it prevented us from unrolling them enough to make exactly one cache line covered by each iteration. Also, the goal of PARAM_MAX_UNROLL_TIMES is to prevent us from unrolling the loops too many times in cases where we only expect gains from better scheduling and decreasing loop overhead, which is not the case here. */ upper_bound = PARAM_VALUE (PARAM_MAX_UNROLLED_INSNS) / ninsns; /* If we unrolled the loop more times than it iterates, the unrolled version of the loop would be never entered. */ if (est_niter >= 0 && est_niter < (HOST_WIDE_INT) upper_bound) upper_bound = est_niter; if (upper_bound <= 1) return 1; /* Choose the factor so that we may prefetch each cache just once, but bound the unrolling by UPPER_BOUND. */ factor = 1; for (agp = refs; agp; agp = agp->next) for (ref = agp->refs; ref; ref = ref->next) if (should_issue_prefetch_p (ref)) { mod_constraint = ref->prefetch_mod; nfactor = least_common_multiple (mod_constraint, factor); if (nfactor <= upper_bound) factor = nfactor; } if (!should_unroll_loop_p (loop, desc, factor)) return 1; return factor; } /* Returns the total volume of the memory references REFS, taking into account reuses in the innermost loop and cache line size. TODO -- we should also take into account reuses across the iterations of the loops in the loop nest. */ static unsigned volume_of_references (struct mem_ref_group *refs) { unsigned volume = 0; struct mem_ref_group *gr; struct mem_ref *ref; for (gr = refs; gr; gr = gr->next) for (ref = gr->refs; ref; ref = ref->next) { /* Almost always reuses another value? */ if (ref->prefetch_before != PREFETCH_ALL) continue; /* If several iterations access the same cache line, use the size of the line divided by this number. Otherwise, a cache line is accessed in each iteration. TODO -- in the latter case, we should take the size of the reference into account, rounding it up on cache line size multiple. */ volume += L1_CACHE_LINE_SIZE / ref->prefetch_mod; } return volume; } /* Returns the volume of memory references accessed across VEC iterations of loops, whose sizes are described in the LOOP_SIZES array. N is the number of the loops in the nest (length of VEC and LOOP_SIZES vectors). */ static unsigned volume_of_dist_vector (lambda_vector vec, unsigned *loop_sizes, unsigned n) { unsigned i; for (i = 0; i < n; i++) if (vec[i] != 0) break; if (i == n) return 0; gcc_assert (vec[i] > 0); /* We ignore the parts of the distance vector in subloops, since usually the numbers of iterations are much smaller. */ return loop_sizes[i] * vec[i]; } /* Add the steps of ACCESS_FN multiplied by STRIDE to the array STRIDE at the position corresponding to the loop of the step. N is the depth of the considered loop nest, and, LOOP is its innermost loop. */ static void add_subscript_strides (tree access_fn, unsigned stride, HOST_WIDE_INT *strides, unsigned n, struct loop *loop) { struct loop *aloop; tree step; HOST_WIDE_INT astep; unsigned min_depth = loop_depth (loop) - n; while (TREE_CODE (access_fn) == POLYNOMIAL_CHREC) { aloop = get_chrec_loop (access_fn); step = CHREC_RIGHT (access_fn); access_fn = CHREC_LEFT (access_fn); if ((unsigned) loop_depth (aloop) <= min_depth) continue; if (host_integerp (step, 0)) astep = tree_low_cst (step, 0); else astep = L1_CACHE_LINE_SIZE; strides[n - 1 - loop_depth (loop) + loop_depth (aloop)] += astep * stride; } } /* Returns the volume of memory references accessed between two consecutive self-reuses of the reference DR. We consider the subscripts of DR in N loops, and LOOP_SIZES contains the volumes of accesses in each of the loops. LOOP is the innermost loop of the current loop nest. */ static unsigned self_reuse_distance (data_reference_p dr, unsigned *loop_sizes, unsigned n, struct loop *loop) { tree stride, access_fn; HOST_WIDE_INT *strides, astride; VEC (tree, heap) *access_fns; tree ref = DR_REF (dr); unsigned i, ret = ~0u; /* In the following example: for (i = 0; i < N; i++) for (j = 0; j < N; j++) use (a[j][i]); the same cache line is accessed each N steps (except if the change from i to i + 1 crosses the boundary of the cache line). Thus, for self-reuse, we cannot rely purely on the results of the data dependence analysis. Instead, we compute the stride of the reference in each loop, and consider the innermost loop in that the stride is less than cache size. */ strides = XCNEWVEC (HOST_WIDE_INT, n); access_fns = DR_ACCESS_FNS (dr); for (i = 0; VEC_iterate (tree, access_fns, i, access_fn); i++) { /* Keep track of the reference corresponding to the subscript, so that we know its stride. */ while (handled_component_p (ref) && TREE_CODE (ref) != ARRAY_REF) ref = TREE_OPERAND (ref, 0); if (TREE_CODE (ref) == ARRAY_REF) { stride = TYPE_SIZE_UNIT (TREE_TYPE (ref)); if (host_integerp (stride, 1)) astride = tree_low_cst (stride, 1); else astride = L1_CACHE_LINE_SIZE; ref = TREE_OPERAND (ref, 0); } else astride = 1; add_subscript_strides (access_fn, astride, strides, n, loop); } for (i = n; i-- > 0; ) { unsigned HOST_WIDE_INT s; s = strides[i] < 0 ? -strides[i] : strides[i]; if (s < (unsigned) L1_CACHE_LINE_SIZE && (loop_sizes[i] > (unsigned) (L1_CACHE_SIZE_BYTES / NONTEMPORAL_FRACTION))) { ret = loop_sizes[i]; break; } } free (strides); return ret; } /* Determines the distance till the first reuse of each reference in REFS in the loop nest of LOOP. NO_OTHER_REFS is true if there are no other memory references in the loop. */ static void determine_loop_nest_reuse (struct loop *loop, struct mem_ref_group *refs, bool no_other_refs) { struct loop *nest, *aloop; VEC (data_reference_p, heap) *datarefs = NULL; VEC (ddr_p, heap) *dependences = NULL; struct mem_ref_group *gr; struct mem_ref *ref, *refb; VEC (loop_p, heap) *vloops = NULL; unsigned *loop_data_size; unsigned i, j, n; unsigned volume, dist, adist; HOST_WIDE_INT vol; data_reference_p dr; ddr_p dep; if (loop->inner) return; /* Find the outermost loop of the loop nest of loop (we require that there are no sibling loops inside the nest). */ nest = loop; while (1) { aloop = loop_outer (nest); if (aloop == current_loops->tree_root || aloop->inner->next) break; nest = aloop; } /* For each loop, determine the amount of data accessed in each iteration. We use this to estimate whether the reference is evicted from the cache before its reuse. */ find_loop_nest (nest, &vloops); n = VEC_length (loop_p, vloops); loop_data_size = XNEWVEC (unsigned, n); volume = volume_of_references (refs); i = n; while (i-- != 0) { loop_data_size[i] = volume; /* Bound the volume by the L2 cache size, since above this bound, all dependence distances are equivalent. */ if (volume > L2_CACHE_SIZE_BYTES) continue; aloop = VEC_index (loop_p, vloops, i); vol = estimated_loop_iterations_int (aloop, false); if (vol < 0) vol = expected_loop_iterations (aloop); volume *= vol; } /* Prepare the references in the form suitable for data dependence analysis. We ignore unanalyzable data references (the results are used just as a heuristics to estimate temporality of the references, hence we do not need to worry about correctness). */ for (gr = refs; gr; gr = gr->next) for (ref = gr->refs; ref; ref = ref->next) { dr = create_data_ref (nest, ref->mem, ref->stmt, !ref->write_p); if (dr) { ref->reuse_distance = volume; dr->aux = ref; VEC_safe_push (data_reference_p, heap, datarefs, dr); } else no_other_refs = false; } for (i = 0; VEC_iterate (data_reference_p, datarefs, i, dr); i++) { dist = self_reuse_distance (dr, loop_data_size, n, loop); ref = (struct mem_ref *) dr->aux; if (ref->reuse_distance > dist) ref->reuse_distance = dist; if (no_other_refs) ref->independent_p = true; } compute_all_dependences (datarefs, &dependences, vloops, true); for (i = 0; VEC_iterate (ddr_p, dependences, i, dep); i++) { if (DDR_ARE_DEPENDENT (dep) == chrec_known) continue; ref = (struct mem_ref *) DDR_A (dep)->aux; refb = (struct mem_ref *) DDR_B (dep)->aux; if (DDR_ARE_DEPENDENT (dep) == chrec_dont_know || DDR_NUM_DIST_VECTS (dep) == 0) { /* If the dependence cannot be analyzed, assume that there might be a reuse. */ dist = 0; ref->independent_p = false; refb->independent_p = false; } else { /* The distance vectors are normalized to be always lexicographically positive, hence we cannot tell just from them whether DDR_A comes before DDR_B or vice versa. However, it is not important, anyway -- if DDR_A is close to DDR_B, then it is either reused in DDR_B (and it is not nontemporal), or it reuses the value of DDR_B in cache (and marking it as nontemporal would not affect anything). */ dist = volume; for (j = 0; j < DDR_NUM_DIST_VECTS (dep); j++) { adist = volume_of_dist_vector (DDR_DIST_VECT (dep, j), loop_data_size, n); /* If this is a dependence in the innermost loop (i.e., the distances in all superloops are zero) and it is not the trivial self-dependence with distance zero, record that the references are not completely independent. */ if (lambda_vector_zerop (DDR_DIST_VECT (dep, j), n - 1) && (ref != refb || DDR_DIST_VECT (dep, j)[n-1] != 0)) { ref->independent_p = false; refb->independent_p = false; } /* Ignore accesses closer than L1_CACHE_SIZE_BYTES / NONTEMPORAL_FRACTION, so that we use nontemporal prefetches e.g. if single memory location is accessed several times in a single iteration of the loop. */ if (adist < L1_CACHE_SIZE_BYTES / NONTEMPORAL_FRACTION) continue; if (adist < dist) dist = adist; } } if (ref->reuse_distance > dist) ref->reuse_distance = dist; if (refb->reuse_distance > dist) refb->reuse_distance = dist; } free_dependence_relations (dependences); free_data_refs (datarefs); free (loop_data_size); if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "Reuse distances:\n"); for (gr = refs; gr; gr = gr->next) for (ref = gr->refs; ref; ref = ref->next) fprintf (dump_file, " ref %p distance %u\n", (void *) ref, ref->reuse_distance); } } /* Do a cost-benefit analysis to determine if prefetching is profitable for the current loop given the following parameters: AHEAD: the iteration ahead distance, EST_NITER: the estimated trip count, NINSNS: estimated number of instructions in the loop, PREFETCH_COUNT: an estimate of the number of prefetches MEM_REF_COUNT: total number of memory references in the loop. */ static bool is_loop_prefetching_profitable (unsigned ahead, HOST_WIDE_INT est_niter, unsigned ninsns, unsigned prefetch_count, unsigned mem_ref_count) { int insn_to_mem_ratio, insn_to_prefetch_ratio; if (mem_ref_count == 0) return false; /* Prefetching improves performance by overlapping cache missing memory accesses with CPU operations. If the loop does not have enough CPU operations to overlap with memory operations, prefetching won't give a significant benefit. One approximate way of checking this is to require the ratio of instructions to memory references to be above a certain limit. This approximation works well in practice. TODO: Implement a more precise computation by estimating the time for each CPU or memory op in the loop. Time estimates for memory ops should account for cache misses. */ insn_to_mem_ratio = ninsns / mem_ref_count; if (insn_to_mem_ratio < PREFETCH_MIN_INSN_TO_MEM_RATIO) return false; /* Profitability of prefetching is highly dependent on the trip count. For a given AHEAD distance, the first AHEAD iterations do not benefit from prefetching, and the last AHEAD iterations execute useless prefetches. So, if the trip count is not large enough relative to AHEAD, prefetching may cause serious performance degradation. To avoid this problem when the trip count is not known at compile time, we conservatively skip loops with high prefetching costs. For now, only the I-cache cost is considered. The relative I-cache cost is estimated by taking the ratio between the number of prefetches and the total number of instructions. Since we are using integer arithmetic, we compute the reciprocal of this ratio. TODO: Account for loop unrolling, which may reduce the costs of shorter stride prefetches. Note that not accounting for loop unrolling over-estimates the cost and hence gives more conservative results. */ if (est_niter < 0) { insn_to_prefetch_ratio = ninsns / prefetch_count; return insn_to_prefetch_ratio >= MIN_INSN_TO_PREFETCH_RATIO; } if (est_niter <= (HOST_WIDE_INT) ahead) { if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "Not prefetching -- loop estimated to roll only %d times\n", (int) est_niter); return false; } return true; } /* Issue prefetch instructions for array references in LOOP. Returns true if the LOOP was unrolled. */ static bool loop_prefetch_arrays (struct loop *loop) { struct mem_ref_group *refs; unsigned ahead, ninsns, time, unroll_factor; HOST_WIDE_INT est_niter; struct tree_niter_desc desc; bool unrolled = false, no_other_refs; unsigned prefetch_count; unsigned mem_ref_count; if (optimize_loop_nest_for_size_p (loop)) { if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, " ignored (cold area)\n"); return false; } /* Step 1: gather the memory references. */ refs = gather_memory_references (loop, &no_other_refs, &mem_ref_count); /* Step 2: estimate the reuse effects. */ prune_by_reuse (refs); prefetch_count = estimate_prefetch_count (refs); if (prefetch_count == 0) goto fail; determine_loop_nest_reuse (loop, refs, no_other_refs); /* Step 3: determine the ahead and unroll factor. */ /* FIXME: the time should be weighted by the probabilities of the blocks in the loop body. */ time = tree_num_loop_insns (loop, &eni_time_weights); ahead = (PREFETCH_LATENCY + time - 1) / time; est_niter = estimated_loop_iterations_int (loop, false); ninsns = tree_num_loop_insns (loop, &eni_size_weights); unroll_factor = determine_unroll_factor (loop, refs, ninsns, &desc, est_niter); if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "Ahead %d, unroll factor %d, trip count " HOST_WIDE_INT_PRINT_DEC "\n" "insn count %d, mem ref count %d, prefetch count %d\n", ahead, unroll_factor, est_niter, ninsns, mem_ref_count, prefetch_count); if (!is_loop_prefetching_profitable (ahead, est_niter, ninsns, prefetch_count, mem_ref_count)) goto fail; mark_nontemporal_stores (loop, refs); /* Step 4: what to prefetch? */ if (!schedule_prefetches (refs, unroll_factor, ahead)) goto fail; /* Step 5: unroll the loop. TODO -- peeling of first and last few iterations so that we do not issue superfluous prefetches. */ if (unroll_factor != 1) { tree_unroll_loop (loop, unroll_factor, single_dom_exit (loop), &desc); unrolled = true; } /* Step 6: issue the prefetches. */ issue_prefetches (refs, unroll_factor, ahead); fail: release_mem_refs (refs); return unrolled; } /* Issue prefetch instructions for array references in loops. */ unsigned int tree_ssa_prefetch_arrays (void) { loop_iterator li; struct loop *loop; bool unrolled = false; int todo_flags = 0; if (!HAVE_prefetch /* It is possible to ask compiler for say -mtune=i486 -march=pentium4. -mtune=i486 causes us having PREFETCH_BLOCK 0, since this is part of processor costs and i486 does not have prefetch, but -march=pentium4 causes HAVE_prefetch to be true. Ugh. */ || PREFETCH_BLOCK == 0) return 0; if (dump_file && (dump_flags & TDF_DETAILS)) { fprintf (dump_file, "Prefetching parameters:\n"); fprintf (dump_file, " simultaneous prefetches: %d\n", SIMULTANEOUS_PREFETCHES); fprintf (dump_file, " prefetch latency: %d\n", PREFETCH_LATENCY); fprintf (dump_file, " prefetch block size: %d\n", PREFETCH_BLOCK); fprintf (dump_file, " L1 cache size: %d lines, %d kB\n", L1_CACHE_SIZE_BYTES / L1_CACHE_LINE_SIZE, L1_CACHE_SIZE); fprintf (dump_file, " L1 cache line size: %d\n", L1_CACHE_LINE_SIZE); fprintf (dump_file, " L2 cache size: %d kB\n", L2_CACHE_SIZE); fprintf (dump_file, " min insn-to-prefetch ratio: %d \n", MIN_INSN_TO_PREFETCH_RATIO); fprintf (dump_file, " min insn-to-mem ratio: %d \n", PREFETCH_MIN_INSN_TO_MEM_RATIO); fprintf (dump_file, "\n"); } initialize_original_copy_tables (); if (!built_in_decls[BUILT_IN_PREFETCH]) { tree type = build_function_type (void_type_node, tree_cons (NULL_TREE, const_ptr_type_node, NULL_TREE)); tree decl = add_builtin_function ("__builtin_prefetch", type, BUILT_IN_PREFETCH, BUILT_IN_NORMAL, NULL, NULL_TREE); DECL_IS_NOVOPS (decl) = true; built_in_decls[BUILT_IN_PREFETCH] = decl; } /* We assume that size of cache line is a power of two, so verify this here. */ gcc_assert ((PREFETCH_BLOCK & (PREFETCH_BLOCK - 1)) == 0); FOR_EACH_LOOP (li, loop, LI_FROM_INNERMOST) { if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "Processing loop %d:\n", loop->num); unrolled |= loop_prefetch_arrays (loop); if (dump_file && (dump_flags & TDF_DETAILS)) fprintf (dump_file, "\n\n"); } if (unrolled) { scev_reset (); todo_flags |= TODO_cleanup_cfg; } free_original_copy_tables (); return todo_flags; }
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