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1 //===- CodeGeneration.cpp - Code generate the Scops using ISL. ---------======//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 //
9 // The CodeGeneration pass takes a Scop created by ScopInfo and translates it
10 // back to LLVM-IR using the ISL code generator.
11 //
12 // The Scop describes the high level memory behavior of a control flow region.
13 // Transformation passes can update the schedule (execution order) of statements
14 // in the Scop. ISL is used to generate an abstract syntax tree that reflects
15 // the updated execution order. This clast is used to create new LLVM-IR that is
16 // computationally equivalent to the original control flow region, but executes
17 // its code in the new execution order defined by the changed schedule.
18 //
19 //===----------------------------------------------------------------------===//
45 #include <cassert>
74 /// Mark a basic block unreachable.
75 ///
76 /// Marks the basic block @p Block unreachable by equipping it with an
77 /// UnreachableInst.
83 }
98 });
102 }
104 // CodeGeneration adds a lot of BBs without updating the RegionInfo
105 // We make all created BBs belong to the scop's parent region without any
106 // nested structure to keep the RegionInfo verifier happy.
113 }
114 }
116 /// Remove all lifetime markers (llvm.lifetime.start, llvm.lifetime.end) from
117 /// @R.
118 ///
119 /// CodeGeneration does not copy lifetime markers into the optimized SCoP,
120 /// which would leave the them only in the original path. This can transform
121 /// code such as
122 ///
123 /// llvm.lifetime.start(%p)
124 /// llvm.lifetime.end(%p)
125 ///
126 /// into
127 ///
128 /// if (RTC) {
129 /// // generated code
130 /// } else {
131 /// // original code
132 /// llvm.lifetime.start(%p)
133 /// }
134 /// llvm.lifetime.end(%p)
135 ///
136 /// The current StackColoring algorithm cannot handle if some, but not all,
137 /// paths from the end marker to the entry block cross the start marker. Same
138 /// for start markers that do not always cross the end markers. We avoid any
139 /// issues by removing all lifetime markers, even from the original code.
140 ///
141 /// A better solution could be to hoist all llvm.lifetime.start to the split
142 /// node and all llvm.lifetime.end to the merge node, which should be
143 /// conservatively correct.
161 }
162 }
165 }
166 }
167 }
172 // Check whether IslAstInfo uses the same isl_ctx. Since -polly-codegen
173 // reports itself to preserve DependenceInfo and IslAstInfo, we might get
174 // those analysis that were computed by a different ScopInfo for a different
175 // Scop structure. When the ScopInfo/Scop object is freed, there is a high
176 // probability that the new ScopInfo/Scop object will be created at the same
177 // heap position with the same address. Comparing whether the Scop or ScopInfo
178 // address is the expected therefore is unreliable.
179 // Instead, we compare the address of the isl_ctx object. Both, DependenceInfo
180 // and IslAstInfo must hold a reference to the isl_ctx object to ensure it is
181 // not freed before the destruction of those analyses which might happen after
182 // the destruction of the Scop/ScopInfo they refer to. Hence, the isl_ctx
183 // will not be freed and its space not reused as long there is a
184 // DependenceInfo or IslAstInfo around.
189 }
191 // Check if we created an isl_ast root node, otherwise exit.
196 // Collect statistics. Do it before we modify the IR to avoid having it any
197 // influence on the result.
199 ScopsProcessed++;
205 ScopAnnotator Annotator;
215 // Only build the run-time condition and parameters _after_ having
216 // introduced the conditional branch. This is important as the conditional
217 // branch will guard the original scop from new induction variables that
218 // the SCEVExpander may introduce while code generating the parameters and
219 // which may introduce scalar dependences that prevent us from correctly
220 // code generating this scop.
221 BBPair StartExitBlocks =
231 // All arrays must have their base pointers known before
232 // ScopAnnotator::buildAliasScopes.
243 }
245 // First generate code for the hoisted invariant loads and transitively the
246 // parameters they reference. Afterwards, for the remaining parameters that
247 // might reference the hoisted loads. Finally, build the runtime check
248 // that might reference both hoisted loads as well as parameters.
249 // If the hoisting fails we have to bail and execute the original code.
252 // Patch the introduced branch condition to ensure that we always execute
253 // the original SCoP.
258 // Since the other branch is hence ignored we mark it as unreachable and
259 // adjust the dominator tree accordingly.
276 // Explicitly set the insert point to the end of the block to avoid that a
277 // split at the builder's current
278 // insert position would move the malloc calls to the wrong BasicBlock.
279 // Ideally we would just split the block during allocation of the new
280 // arrays, but this would break the assumption that there are no blocks
281 // between polly.start and polly.exiting (at this point).
288 CodegenedScops++;
291 }
298 // Mark the function such that we run additional cleanup passes on this
299 // function (e.g. mem2reg to rediscover phi nodes).
302 }
310 /// The data layout used.
313 /// @name The analysis passes we need to generate code.
314 ///
315 ///{
321 ///}
325 /// Generate LLVM-IR for the SCoP @p S.
334 }
336 /// Register all analyses and transformation required.
351 // FIXME: We do not yet add regions for the newly generated code to the
352 // region tree.
353 }
354 };
364 }
367 }