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1 /*
2  * Copyright (C) 2011 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *      http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 
17 /* This file contains register alloction support. */
18 
19 #include "dex/compiler_ir.h"
20 #include "dex/compiler_internals.h"
21 #include "mir_to_lir-inl.h"
22 
23 namespace art {
24 
25 /*
26  * Free all allocated temps in the temp pools.  Note that this does
27  * not affect the "liveness" of a temp register, which will stay
28  * live until it is either explicitly killed or reallocated.
29  */
ResetRegPool()30 void Mir2Lir::ResetRegPool() {
31   for (int i = 0; i < reg_pool_->num_core_regs; i++) {
32     if (reg_pool_->core_regs[i].is_temp)
33       reg_pool_->core_regs[i].in_use = false;
34   }
35   for (int i = 0; i < reg_pool_->num_fp_regs; i++) {
36     if (reg_pool_->FPRegs[i].is_temp)
37       reg_pool_->FPRegs[i].in_use = false;
38   }
39   // Reset temp tracking sanity check.
40   if (kIsDebugBuild) {
41     live_sreg_ = INVALID_SREG;
42   }
43 }
44 
45  /*
46   * Set up temp & preserved register pools specialized by target.
47   * Note: num_regs may be zero.
48   */
CompilerInitPool(RegisterInfo * regs,int * reg_nums,int num)49 void Mir2Lir::CompilerInitPool(RegisterInfo* regs, int* reg_nums, int num) {
50   for (int i = 0; i < num; i++) {
51     regs[i].reg = reg_nums[i];
52     regs[i].in_use = false;
53     regs[i].is_temp = false;
54     regs[i].pair = false;
55     regs[i].live = false;
56     regs[i].dirty = false;
57     regs[i].s_reg = INVALID_SREG;
58   }
59 }
60 
DumpRegPool(RegisterInfo * p,int num_regs)61 void Mir2Lir::DumpRegPool(RegisterInfo* p, int num_regs) {
62   LOG(INFO) << "================================================";
63   for (int i = 0; i < num_regs; i++) {
64     LOG(INFO) << StringPrintf(
65         "R[%d]: T:%d, U:%d, P:%d, p:%d, LV:%d, D:%d, SR:%d, ST:%x, EN:%x",
66         p[i].reg, p[i].is_temp, p[i].in_use, p[i].pair, p[i].partner,
67         p[i].live, p[i].dirty, p[i].s_reg, reinterpret_cast<uintptr_t>(p[i].def_start),
68         reinterpret_cast<uintptr_t>(p[i].def_end));
69   }
70   LOG(INFO) << "================================================";
71 }
72 
DumpCoreRegPool()73 void Mir2Lir::DumpCoreRegPool() {
74   DumpRegPool(reg_pool_->core_regs, reg_pool_->num_core_regs);
75 }
76 
DumpFpRegPool()77 void Mir2Lir::DumpFpRegPool() {
78   DumpRegPool(reg_pool_->FPRegs, reg_pool_->num_fp_regs);
79 }
80 
ClobberSRegBody(RegisterInfo * p,int num_regs,int s_reg)81 void Mir2Lir::ClobberSRegBody(RegisterInfo* p, int num_regs, int s_reg) {
82   for (int i = 0; i< num_regs; i++) {
83     if (p[i].s_reg == s_reg) {
84       if (p[i].is_temp) {
85         p[i].live = false;
86       }
87       p[i].def_start = NULL;
88       p[i].def_end = NULL;
89     }
90   }
91 }
92 
93 /*
94  * Break the association between a Dalvik vreg and a physical temp register of either register
95  * class.
96  * TODO: Ideally, the public version of this code should not exist.  Besides its local usage
97  * in the register utilities, is is also used by code gen routines to work around a deficiency in
98  * local register allocation, which fails to distinguish between the "in" and "out" identities
99  * of Dalvik vregs.  This can result in useless register copies when the same Dalvik vreg
100  * is used both as the source and destination register of an operation in which the type
101  * changes (for example: INT_TO_FLOAT v1, v1).  Revisit when improved register allocation is
102  * addressed.
103  */
ClobberSReg(int s_reg)104 void Mir2Lir::ClobberSReg(int s_reg) {
105   /* Reset live temp tracking sanity checker */
106   if (kIsDebugBuild) {
107     if (s_reg == live_sreg_) {
108       live_sreg_ = INVALID_SREG;
109     }
110   }
111   ClobberSRegBody(reg_pool_->core_regs, reg_pool_->num_core_regs, s_reg);
112   ClobberSRegBody(reg_pool_->FPRegs, reg_pool_->num_fp_regs, s_reg);
113 }
114 
115 /*
116  * SSA names associated with the initial definitions of Dalvik
117  * registers are the same as the Dalvik register number (and
118  * thus take the same position in the promotion_map.  However,
119  * the special Method* and compiler temp resisters use negative
120  * v_reg numbers to distinguish them and can have an arbitrary
121  * ssa name (above the last original Dalvik register).  This function
122  * maps SSA names to positions in the promotion_map array.
123  */
SRegToPMap(int s_reg)124 int Mir2Lir::SRegToPMap(int s_reg) {
125   DCHECK_LT(s_reg, mir_graph_->GetNumSSARegs());
126   DCHECK_GE(s_reg, 0);
127   int v_reg = mir_graph_->SRegToVReg(s_reg);
128   if (v_reg >= 0) {
129     DCHECK_LT(v_reg, cu_->num_dalvik_registers);
130     return v_reg;
131   } else {
132     int pos = std::abs(v_reg) - std::abs(SSA_METHOD_BASEREG);
133     DCHECK_LE(pos, cu_->num_compiler_temps);
134     return cu_->num_dalvik_registers + pos;
135   }
136 }
137 
RecordCorePromotion(int reg,int s_reg)138 void Mir2Lir::RecordCorePromotion(int reg, int s_reg) {
139   int p_map_idx = SRegToPMap(s_reg);
140   int v_reg = mir_graph_->SRegToVReg(s_reg);
141   GetRegInfo(reg)->in_use = true;
142   core_spill_mask_ |= (1 << reg);
143   // Include reg for later sort
144   core_vmap_table_.push_back(reg << VREG_NUM_WIDTH | (v_reg & ((1 << VREG_NUM_WIDTH) - 1)));
145   num_core_spills_++;
146   promotion_map_[p_map_idx].core_location = kLocPhysReg;
147   promotion_map_[p_map_idx].core_reg = reg;
148 }
149 
150 /* Reserve a callee-save register.  Return -1 if none available */
AllocPreservedCoreReg(int s_reg)151 int Mir2Lir::AllocPreservedCoreReg(int s_reg) {
152   int res = -1;
153   RegisterInfo* core_regs = reg_pool_->core_regs;
154   for (int i = 0; i < reg_pool_->num_core_regs; i++) {
155     if (!core_regs[i].is_temp && !core_regs[i].in_use) {
156       res = core_regs[i].reg;
157       RecordCorePromotion(res, s_reg);
158       break;
159     }
160   }
161   return res;
162 }
163 
RecordFpPromotion(int reg,int s_reg)164 void Mir2Lir::RecordFpPromotion(int reg, int s_reg) {
165   int p_map_idx = SRegToPMap(s_reg);
166   int v_reg = mir_graph_->SRegToVReg(s_reg);
167   GetRegInfo(reg)->in_use = true;
168   MarkPreservedSingle(v_reg, reg);
169   promotion_map_[p_map_idx].fp_location = kLocPhysReg;
170   promotion_map_[p_map_idx].FpReg = reg;
171 }
172 
173 /*
174  * Reserve a callee-save fp single register.  Try to fullfill request for
175  * even/odd  allocation, but go ahead and allocate anything if not
176  * available.  If nothing's available, return -1.
177  */
AllocPreservedSingle(int s_reg,bool even)178 int Mir2Lir::AllocPreservedSingle(int s_reg, bool even) {
179   int res = -1;
180   RegisterInfo* FPRegs = reg_pool_->FPRegs;
181   for (int i = 0; i < reg_pool_->num_fp_regs; i++) {
182     if (!FPRegs[i].is_temp && !FPRegs[i].in_use &&
183       ((FPRegs[i].reg & 0x1) == 0) == even) {
184       res = FPRegs[i].reg;
185       RecordFpPromotion(res, s_reg);
186       break;
187     }
188   }
189   return res;
190 }
191 
192 /*
193  * Somewhat messy code here.  We want to allocate a pair of contiguous
194  * physical single-precision floating point registers starting with
195  * an even numbered reg.  It is possible that the paired s_reg (s_reg+1)
196  * has already been allocated - try to fit if possible.  Fail to
197  * allocate if we can't meet the requirements for the pair of
198  * s_reg<=sX[even] & (s_reg+1)<= sX+1.
199  */
AllocPreservedDouble(int s_reg)200 int Mir2Lir::AllocPreservedDouble(int s_reg) {
201   int res = -1;  // Assume failure
202   int v_reg = mir_graph_->SRegToVReg(s_reg);
203   int p_map_idx = SRegToPMap(s_reg);
204   if (promotion_map_[p_map_idx+1].fp_location == kLocPhysReg) {
205     // Upper reg is already allocated.  Can we fit?
206     int high_reg = promotion_map_[p_map_idx+1].FpReg;
207     if ((high_reg & 1) == 0) {
208       // High reg is even - fail.
209       return res;
210     }
211     // Is the low reg of the pair free?
212     RegisterInfo* p = GetRegInfo(high_reg-1);
213     if (p->in_use || p->is_temp) {
214       // Already allocated or not preserved - fail.
215       return res;
216     }
217     // OK - good to go.
218     res = p->reg;
219     p->in_use = true;
220     DCHECK_EQ((res & 1), 0);
221     MarkPreservedSingle(v_reg, res);
222   } else {
223     RegisterInfo* FPRegs = reg_pool_->FPRegs;
224     for (int i = 0; i < reg_pool_->num_fp_regs; i++) {
225       if (!FPRegs[i].is_temp && !FPRegs[i].in_use &&
226         ((FPRegs[i].reg & 0x1) == 0x0) &&
227         !FPRegs[i+1].is_temp && !FPRegs[i+1].in_use &&
228         ((FPRegs[i+1].reg & 0x1) == 0x1) &&
229         (FPRegs[i].reg + 1) == FPRegs[i+1].reg) {
230         res = FPRegs[i].reg;
231         FPRegs[i].in_use = true;
232         MarkPreservedSingle(v_reg, res);
233         FPRegs[i+1].in_use = true;
234         DCHECK_EQ(res + 1, FPRegs[i+1].reg);
235         MarkPreservedSingle(v_reg+1, res+1);
236         break;
237       }
238     }
239   }
240   if (res != -1) {
241     promotion_map_[p_map_idx].fp_location = kLocPhysReg;
242     promotion_map_[p_map_idx].FpReg = res;
243     promotion_map_[p_map_idx+1].fp_location = kLocPhysReg;
244     promotion_map_[p_map_idx+1].FpReg = res + 1;
245   }
246   return res;
247 }
248 
249 
250 /*
251  * Reserve a callee-save fp register.   If this register can be used
252  * as the first of a double, attempt to allocate an even pair of fp
253  * single regs (but if can't still attempt to allocate a single, preferring
254  * first to allocate an odd register.
255  */
AllocPreservedFPReg(int s_reg,bool double_start)256 int Mir2Lir::AllocPreservedFPReg(int s_reg, bool double_start) {
257   int res = -1;
258   if (double_start) {
259     res = AllocPreservedDouble(s_reg);
260   }
261   if (res == -1) {
262     res = AllocPreservedSingle(s_reg, false /* try odd # */);
263   }
264   if (res == -1)
265     res = AllocPreservedSingle(s_reg, true /* try even # */);
266   return res;
267 }
268 
AllocTempBody(RegisterInfo * p,int num_regs,int * next_temp,bool required)269 int Mir2Lir::AllocTempBody(RegisterInfo* p, int num_regs, int* next_temp,
270                            bool required) {
271   int next = *next_temp;
272   for (int i = 0; i< num_regs; i++) {
273     if (next >= num_regs)
274       next = 0;
275     if (p[next].is_temp && !p[next].in_use && !p[next].live) {
276       Clobber(p[next].reg);
277       p[next].in_use = true;
278       p[next].pair = false;
279       *next_temp = next + 1;
280       return p[next].reg;
281     }
282     next++;
283   }
284   next = *next_temp;
285   for (int i = 0; i< num_regs; i++) {
286     if (next >= num_regs)
287       next = 0;
288     if (p[next].is_temp && !p[next].in_use) {
289       Clobber(p[next].reg);
290       p[next].in_use = true;
291       p[next].pair = false;
292       *next_temp = next + 1;
293       return p[next].reg;
294     }
295     next++;
296   }
297   if (required) {
298     CodegenDump();
299     DumpRegPool(reg_pool_->core_regs,
300           reg_pool_->num_core_regs);
301     LOG(FATAL) << "No free temp registers";
302   }
303   return -1;  // No register available
304 }
305 
306 // REDO: too many assumptions.
AllocTempDouble()307 int Mir2Lir::AllocTempDouble() {
308   RegisterInfo* p = reg_pool_->FPRegs;
309   int num_regs = reg_pool_->num_fp_regs;
310   /* Start looking at an even reg */
311   int next = reg_pool_->next_fp_reg & ~0x1;
312 
313   // First try to avoid allocating live registers
314   for (int i = 0; i < num_regs; i+=2) {
315     if (next >= num_regs)
316       next = 0;
317     if ((p[next].is_temp && !p[next].in_use && !p[next].live) &&
318       (p[next+1].is_temp && !p[next+1].in_use && !p[next+1].live)) {
319       Clobber(p[next].reg);
320       Clobber(p[next+1].reg);
321       p[next].in_use = true;
322       p[next+1].in_use = true;
323       DCHECK_EQ((p[next].reg+1), p[next+1].reg);
324       DCHECK_EQ((p[next].reg & 0x1), 0);
325       reg_pool_->next_fp_reg = next + 2;
326       if (reg_pool_->next_fp_reg >= num_regs) {
327         reg_pool_->next_fp_reg = 0;
328       }
329       return p[next].reg;
330     }
331     next += 2;
332   }
333   next = reg_pool_->next_fp_reg & ~0x1;
334 
335   // No choice - find a pair and kill it.
336   for (int i = 0; i < num_regs; i+=2) {
337     if (next >= num_regs)
338       next = 0;
339     if (p[next].is_temp && !p[next].in_use && p[next+1].is_temp &&
340       !p[next+1].in_use) {
341       Clobber(p[next].reg);
342       Clobber(p[next+1].reg);
343       p[next].in_use = true;
344       p[next+1].in_use = true;
345       DCHECK_EQ((p[next].reg+1), p[next+1].reg);
346       DCHECK_EQ((p[next].reg & 0x1), 0);
347       reg_pool_->next_fp_reg = next + 2;
348       if (reg_pool_->next_fp_reg >= num_regs) {
349         reg_pool_->next_fp_reg = 0;
350       }
351       return p[next].reg;
352     }
353     next += 2;
354   }
355   LOG(FATAL) << "No free temp registers (pair)";
356   return -1;
357 }
358 
359 /* Return a temp if one is available, -1 otherwise */
AllocFreeTemp()360 int Mir2Lir::AllocFreeTemp() {
361   return AllocTempBody(reg_pool_->core_regs,
362              reg_pool_->num_core_regs,
363              &reg_pool_->next_core_reg, true);
364 }
365 
AllocTemp()366 int Mir2Lir::AllocTemp() {
367   return AllocTempBody(reg_pool_->core_regs,
368              reg_pool_->num_core_regs,
369              &reg_pool_->next_core_reg, true);
370 }
371 
AllocTempFloat()372 int Mir2Lir::AllocTempFloat() {
373   return AllocTempBody(reg_pool_->FPRegs,
374              reg_pool_->num_fp_regs,
375              &reg_pool_->next_fp_reg, true);
376 }
377 
AllocLiveBody(RegisterInfo * p,int num_regs,int s_reg)378 Mir2Lir::RegisterInfo* Mir2Lir::AllocLiveBody(RegisterInfo* p, int num_regs, int s_reg) {
379   if (s_reg == -1)
380     return NULL;
381   for (int i = 0; i < num_regs; i++) {
382     if (p[i].live && (p[i].s_reg == s_reg)) {
383       if (p[i].is_temp)
384         p[i].in_use = true;
385       return &p[i];
386     }
387   }
388   return NULL;
389 }
390 
AllocLive(int s_reg,int reg_class)391 Mir2Lir::RegisterInfo* Mir2Lir::AllocLive(int s_reg, int reg_class) {
392   RegisterInfo* res = NULL;
393   switch (reg_class) {
394     case kAnyReg:
395       res = AllocLiveBody(reg_pool_->FPRegs,
396                 reg_pool_->num_fp_regs, s_reg);
397       if (res)
398         break;
399       /* Intentional fallthrough */
400     case kCoreReg:
401       res = AllocLiveBody(reg_pool_->core_regs,
402                 reg_pool_->num_core_regs, s_reg);
403       break;
404     case kFPReg:
405       res = AllocLiveBody(reg_pool_->FPRegs,
406                 reg_pool_->num_fp_regs, s_reg);
407       break;
408     default:
409       LOG(FATAL) << "Invalid register type";
410   }
411   return res;
412 }
413 
FreeTemp(int reg)414 void Mir2Lir::FreeTemp(int reg) {
415   RegisterInfo* p = reg_pool_->core_regs;
416   int num_regs = reg_pool_->num_core_regs;
417   for (int i = 0; i< num_regs; i++) {
418     if (p[i].reg == reg) {
419       if (p[i].is_temp) {
420         p[i].in_use = false;
421       }
422       p[i].pair = false;
423       return;
424     }
425   }
426   p = reg_pool_->FPRegs;
427   num_regs = reg_pool_->num_fp_regs;
428   for (int i = 0; i< num_regs; i++) {
429     if (p[i].reg == reg) {
430       if (p[i].is_temp) {
431         p[i].in_use = false;
432       }
433       p[i].pair = false;
434       return;
435     }
436   }
437   LOG(FATAL) << "Tried to free a non-existant temp: r" << reg;
438 }
439 
IsLive(int reg)440 Mir2Lir::RegisterInfo* Mir2Lir::IsLive(int reg) {
441   RegisterInfo* p = reg_pool_->core_regs;
442   int num_regs = reg_pool_->num_core_regs;
443   for (int i = 0; i< num_regs; i++) {
444     if (p[i].reg == reg) {
445       return p[i].live ? &p[i] : NULL;
446     }
447   }
448   p = reg_pool_->FPRegs;
449   num_regs = reg_pool_->num_fp_regs;
450   for (int i = 0; i< num_regs; i++) {
451     if (p[i].reg == reg) {
452       return p[i].live ? &p[i] : NULL;
453     }
454   }
455   return NULL;
456 }
457 
IsTemp(int reg)458 Mir2Lir::RegisterInfo* Mir2Lir::IsTemp(int reg) {
459   RegisterInfo* p = GetRegInfo(reg);
460   return (p->is_temp) ? p : NULL;
461 }
462 
IsPromoted(int reg)463 Mir2Lir::RegisterInfo* Mir2Lir::IsPromoted(int reg) {
464   RegisterInfo* p = GetRegInfo(reg);
465   return (p->is_temp) ? NULL : p;
466 }
467 
IsDirty(int reg)468 bool Mir2Lir::IsDirty(int reg) {
469   RegisterInfo* p = GetRegInfo(reg);
470   return p->dirty;
471 }
472 
473 /*
474  * Similar to AllocTemp(), but forces the allocation of a specific
475  * register.  No check is made to see if the register was previously
476  * allocated.  Use with caution.
477  */
LockTemp(int reg)478 void Mir2Lir::LockTemp(int reg) {
479   RegisterInfo* p = reg_pool_->core_regs;
480   int num_regs = reg_pool_->num_core_regs;
481   for (int i = 0; i< num_regs; i++) {
482     if (p[i].reg == reg) {
483       DCHECK(p[i].is_temp);
484       p[i].in_use = true;
485       p[i].live = false;
486       return;
487     }
488   }
489   p = reg_pool_->FPRegs;
490   num_regs = reg_pool_->num_fp_regs;
491   for (int i = 0; i< num_regs; i++) {
492     if (p[i].reg == reg) {
493       DCHECK(p[i].is_temp);
494       p[i].in_use = true;
495       p[i].live = false;
496       return;
497     }
498   }
499   LOG(FATAL) << "Tried to lock a non-existant temp: r" << reg;
500 }
501 
ResetDef(int reg)502 void Mir2Lir::ResetDef(int reg) {
503   ResetDefBody(GetRegInfo(reg));
504 }
505 
NullifyRange(LIR * start,LIR * finish,int s_reg1,int s_reg2)506 void Mir2Lir::NullifyRange(LIR *start, LIR *finish, int s_reg1, int s_reg2) {
507   if (start && finish) {
508     LIR *p;
509     DCHECK_EQ(s_reg1, s_reg2);
510     for (p = start; ; p = p->next) {
511       NopLIR(p);
512       if (p == finish)
513         break;
514     }
515   }
516 }
517 
518 /*
519  * Mark the beginning and end LIR of a def sequence.  Note that
520  * on entry start points to the LIR prior to the beginning of the
521  * sequence.
522  */
MarkDef(RegLocation rl,LIR * start,LIR * finish)523 void Mir2Lir::MarkDef(RegLocation rl, LIR *start, LIR *finish) {
524   DCHECK(!rl.wide);
525   DCHECK(start && start->next);
526   DCHECK(finish);
527   RegisterInfo* p = GetRegInfo(rl.low_reg);
528   p->def_start = start->next;
529   p->def_end = finish;
530 }
531 
532 /*
533  * Mark the beginning and end LIR of a def sequence.  Note that
534  * on entry start points to the LIR prior to the beginning of the
535  * sequence.
536  */
MarkDefWide(RegLocation rl,LIR * start,LIR * finish)537 void Mir2Lir::MarkDefWide(RegLocation rl, LIR *start, LIR *finish) {
538   DCHECK(rl.wide);
539   DCHECK(start && start->next);
540   DCHECK(finish);
541   RegisterInfo* p = GetRegInfo(rl.low_reg);
542   ResetDef(rl.high_reg);  // Only track low of pair
543   p->def_start = start->next;
544   p->def_end = finish;
545 }
546 
WideToNarrow(RegLocation rl)547 RegLocation Mir2Lir::WideToNarrow(RegLocation rl) {
548   DCHECK(rl.wide);
549   if (rl.location == kLocPhysReg) {
550     RegisterInfo* info_lo = GetRegInfo(rl.low_reg);
551     RegisterInfo* info_hi = GetRegInfo(rl.high_reg);
552     if (info_lo->is_temp) {
553       info_lo->pair = false;
554       info_lo->def_start = NULL;
555       info_lo->def_end = NULL;
556     }
557     if (info_hi->is_temp) {
558       info_hi->pair = false;
559       info_hi->def_start = NULL;
560       info_hi->def_end = NULL;
561     }
562   }
563   rl.wide = false;
564   return rl;
565 }
566 
ResetDefLoc(RegLocation rl)567 void Mir2Lir::ResetDefLoc(RegLocation rl) {
568   DCHECK(!rl.wide);
569   RegisterInfo* p = IsTemp(rl.low_reg);
570   if (p && !(cu_->disable_opt & (1 << kSuppressLoads))) {
571     DCHECK(!p->pair);
572     NullifyRange(p->def_start, p->def_end, p->s_reg, rl.s_reg_low);
573   }
574   ResetDef(rl.low_reg);
575 }
576 
ResetDefLocWide(RegLocation rl)577 void Mir2Lir::ResetDefLocWide(RegLocation rl) {
578   DCHECK(rl.wide);
579   RegisterInfo* p_low = IsTemp(rl.low_reg);
580   RegisterInfo* p_high = IsTemp(rl.high_reg);
581   if (p_low && !(cu_->disable_opt & (1 << kSuppressLoads))) {
582     DCHECK(p_low->pair);
583     NullifyRange(p_low->def_start, p_low->def_end, p_low->s_reg, rl.s_reg_low);
584   }
585   if (p_high && !(cu_->disable_opt & (1 << kSuppressLoads))) {
586     DCHECK(p_high->pair);
587   }
588   ResetDef(rl.low_reg);
589   ResetDef(rl.high_reg);
590 }
591 
ResetDefTracking()592 void Mir2Lir::ResetDefTracking() {
593   for (int i = 0; i< reg_pool_->num_core_regs; i++) {
594     ResetDefBody(&reg_pool_->core_regs[i]);
595   }
596   for (int i = 0; i< reg_pool_->num_fp_regs; i++) {
597     ResetDefBody(&reg_pool_->FPRegs[i]);
598   }
599 }
600 
ClobberAllRegs()601 void Mir2Lir::ClobberAllRegs() {
602   for (int i = 0; i< reg_pool_->num_core_regs; i++) {
603     ClobberBody(&reg_pool_->core_regs[i]);
604   }
605   for (int i = 0; i< reg_pool_->num_fp_regs; i++) {
606     ClobberBody(&reg_pool_->FPRegs[i]);
607   }
608 }
609 
610 // Make sure nothing is live and dirty
FlushAllRegsBody(RegisterInfo * info,int num_regs)611 void Mir2Lir::FlushAllRegsBody(RegisterInfo* info, int num_regs) {
612   for (int i = 0; i < num_regs; i++) {
613     if (info[i].live && info[i].dirty) {
614       if (info[i].pair) {
615         FlushRegWide(info[i].reg, info[i].partner);
616       } else {
617         FlushReg(info[i].reg);
618       }
619     }
620   }
621 }
622 
FlushAllRegs()623 void Mir2Lir::FlushAllRegs() {
624   FlushAllRegsBody(reg_pool_->core_regs,
625            reg_pool_->num_core_regs);
626   FlushAllRegsBody(reg_pool_->FPRegs,
627            reg_pool_->num_fp_regs);
628   ClobberAllRegs();
629 }
630 
631 
632 // TUNING: rewrite all of this reg stuff.  Probably use an attribute table
RegClassMatches(int reg_class,int reg)633 bool Mir2Lir::RegClassMatches(int reg_class, int reg) {
634   if (reg_class == kAnyReg) {
635     return true;
636   } else if (reg_class == kCoreReg) {
637     return !IsFpReg(reg);
638   } else {
639     return IsFpReg(reg);
640   }
641 }
642 
MarkLive(int reg,int s_reg)643 void Mir2Lir::MarkLive(int reg, int s_reg) {
644   RegisterInfo* info = GetRegInfo(reg);
645   if ((info->reg == reg) && (info->s_reg == s_reg) && info->live) {
646     return;  /* already live */
647   } else if (s_reg != INVALID_SREG) {
648     ClobberSReg(s_reg);
649     if (info->is_temp) {
650       info->live = true;
651     }
652   } else {
653     /* Can't be live if no associated s_reg */
654     DCHECK(info->is_temp);
655     info->live = false;
656   }
657   info->s_reg = s_reg;
658 }
659 
MarkTemp(int reg)660 void Mir2Lir::MarkTemp(int reg) {
661   RegisterInfo* info = GetRegInfo(reg);
662   info->is_temp = true;
663 }
664 
UnmarkTemp(int reg)665 void Mir2Lir::UnmarkTemp(int reg) {
666   RegisterInfo* info = GetRegInfo(reg);
667   info->is_temp = false;
668 }
669 
MarkPair(int low_reg,int high_reg)670 void Mir2Lir::MarkPair(int low_reg, int high_reg) {
671   RegisterInfo* info_lo = GetRegInfo(low_reg);
672   RegisterInfo* info_hi = GetRegInfo(high_reg);
673   info_lo->pair = info_hi->pair = true;
674   info_lo->partner = high_reg;
675   info_hi->partner = low_reg;
676 }
677 
MarkClean(RegLocation loc)678 void Mir2Lir::MarkClean(RegLocation loc) {
679   RegisterInfo* info = GetRegInfo(loc.low_reg);
680   info->dirty = false;
681   if (loc.wide) {
682     info = GetRegInfo(loc.high_reg);
683     info->dirty = false;
684   }
685 }
686 
MarkDirty(RegLocation loc)687 void Mir2Lir::MarkDirty(RegLocation loc) {
688   if (loc.home) {
689     // If already home, can't be dirty
690     return;
691   }
692   RegisterInfo* info = GetRegInfo(loc.low_reg);
693   info->dirty = true;
694   if (loc.wide) {
695     info = GetRegInfo(loc.high_reg);
696     info->dirty = true;
697   }
698 }
699 
MarkInUse(int reg)700 void Mir2Lir::MarkInUse(int reg) {
701     RegisterInfo* info = GetRegInfo(reg);
702     info->in_use = true;
703 }
704 
CopyRegInfo(int new_reg,int old_reg)705 void Mir2Lir::CopyRegInfo(int new_reg, int old_reg) {
706   RegisterInfo* new_info = GetRegInfo(new_reg);
707   RegisterInfo* old_info = GetRegInfo(old_reg);
708   // Target temp status must not change
709   bool is_temp = new_info->is_temp;
710   *new_info = *old_info;
711   // Restore target's temp status
712   new_info->is_temp = is_temp;
713   new_info->reg = new_reg;
714 }
715 
CheckCorePoolSanity()716 bool Mir2Lir::CheckCorePoolSanity() {
717   for (static int i = 0; i < reg_pool_->num_core_regs; i++) {
718     if (reg_pool_->core_regs[i].pair) {
719       static int my_reg = reg_pool_->core_regs[i].reg;
720       static int my_sreg = reg_pool_->core_regs[i].s_reg;
721       static int partner_reg = reg_pool_->core_regs[i].partner;
722       static RegisterInfo* partner = GetRegInfo(partner_reg);
723       DCHECK(partner != NULL);
724       DCHECK(partner->pair);
725       DCHECK_EQ(my_reg, partner->partner);
726       static int partner_sreg = partner->s_reg;
727       if (my_sreg == INVALID_SREG) {
728         DCHECK_EQ(partner_sreg, INVALID_SREG);
729       } else {
730         int diff = my_sreg - partner_sreg;
731         DCHECK((diff == -1) || (diff == 1));
732       }
733     }
734     if (!reg_pool_->core_regs[i].live) {
735       DCHECK(reg_pool_->core_regs[i].def_start == NULL);
736       DCHECK(reg_pool_->core_regs[i].def_end == NULL);
737     }
738   }
739   return true;
740 }
741 
742 /*
743  * Return an updated location record with current in-register status.
744  * If the value lives in live temps, reflect that fact.  No code
745  * is generated.  If the live value is part of an older pair,
746  * clobber both low and high.
747  * TUNING: clobbering both is a bit heavy-handed, but the alternative
748  * is a bit complex when dealing with FP regs.  Examine code to see
749  * if it's worthwhile trying to be more clever here.
750  */
751 
UpdateLoc(RegLocation loc)752 RegLocation Mir2Lir::UpdateLoc(RegLocation loc) {
753   DCHECK(!loc.wide);
754   DCHECK(CheckCorePoolSanity());
755   if (loc.location != kLocPhysReg) {
756     DCHECK((loc.location == kLocDalvikFrame) ||
757          (loc.location == kLocCompilerTemp));
758     RegisterInfo* info_lo = AllocLive(loc.s_reg_low, kAnyReg);
759     if (info_lo) {
760       if (info_lo->pair) {
761         Clobber(info_lo->reg);
762         Clobber(info_lo->partner);
763         FreeTemp(info_lo->reg);
764       } else {
765         loc.low_reg = info_lo->reg;
766         loc.location = kLocPhysReg;
767       }
768     }
769   }
770 
771   return loc;
772 }
773 
774 /* see comments for update_loc */
UpdateLocWide(RegLocation loc)775 RegLocation Mir2Lir::UpdateLocWide(RegLocation loc) {
776   DCHECK(loc.wide);
777   DCHECK(CheckCorePoolSanity());
778   if (loc.location != kLocPhysReg) {
779     DCHECK((loc.location == kLocDalvikFrame) ||
780          (loc.location == kLocCompilerTemp));
781     // Are the dalvik regs already live in physical registers?
782     RegisterInfo* info_lo = AllocLive(loc.s_reg_low, kAnyReg);
783     RegisterInfo* info_hi = AllocLive(GetSRegHi(loc.s_reg_low), kAnyReg);
784     bool match = true;
785     match = match && (info_lo != NULL);
786     match = match && (info_hi != NULL);
787     // Are they both core or both FP?
788     match = match && (IsFpReg(info_lo->reg) == IsFpReg(info_hi->reg));
789     // If a pair of floating point singles, are they properly aligned?
790     if (match && IsFpReg(info_lo->reg)) {
791       match &= ((info_lo->reg & 0x1) == 0);
792       match &= ((info_hi->reg - info_lo->reg) == 1);
793     }
794     // If previously used as a pair, it is the same pair?
795     if (match && (info_lo->pair || info_hi->pair)) {
796       match = (info_lo->pair == info_hi->pair);
797       match &= ((info_lo->reg == info_hi->partner) &&
798             (info_hi->reg == info_lo->partner));
799     }
800     if (match) {
801       // Can reuse - update the register usage info
802       loc.low_reg = info_lo->reg;
803       loc.high_reg = info_hi->reg;
804       loc.location = kLocPhysReg;
805       MarkPair(loc.low_reg, loc.high_reg);
806       DCHECK(!IsFpReg(loc.low_reg) || ((loc.low_reg & 0x1) == 0));
807       return loc;
808     }
809     // Can't easily reuse - clobber and free any overlaps
810     if (info_lo) {
811       Clobber(info_lo->reg);
812       FreeTemp(info_lo->reg);
813       if (info_lo->pair)
814         Clobber(info_lo->partner);
815     }
816     if (info_hi) {
817       Clobber(info_hi->reg);
818       FreeTemp(info_hi->reg);
819       if (info_hi->pair)
820         Clobber(info_hi->partner);
821     }
822   }
823   return loc;
824 }
825 
826 
827 /* For use in cases we don't know (or care) width */
UpdateRawLoc(RegLocation loc)828 RegLocation Mir2Lir::UpdateRawLoc(RegLocation loc) {
829   if (loc.wide)
830     return UpdateLocWide(loc);
831   else
832     return UpdateLoc(loc);
833 }
834 
EvalLocWide(RegLocation loc,int reg_class,bool update)835 RegLocation Mir2Lir::EvalLocWide(RegLocation loc, int reg_class, bool update) {
836   DCHECK(loc.wide);
837   int new_regs;
838   int low_reg;
839   int high_reg;
840 
841   loc = UpdateLocWide(loc);
842 
843   /* If already in registers, we can assume proper form.  Right reg class? */
844   if (loc.location == kLocPhysReg) {
845     DCHECK_EQ(IsFpReg(loc.low_reg), IsFpReg(loc.high_reg));
846     DCHECK(!IsFpReg(loc.low_reg) || ((loc.low_reg & 0x1) == 0));
847     if (!RegClassMatches(reg_class, loc.low_reg)) {
848       /* Wrong register class.  Reallocate and copy */
849       new_regs = AllocTypedTempPair(loc.fp, reg_class);
850       low_reg = new_regs & 0xff;
851       high_reg = (new_regs >> 8) & 0xff;
852       OpRegCopyWide(low_reg, high_reg, loc.low_reg, loc.high_reg);
853       CopyRegInfo(low_reg, loc.low_reg);
854       CopyRegInfo(high_reg, loc.high_reg);
855       Clobber(loc.low_reg);
856       Clobber(loc.high_reg);
857       loc.low_reg = low_reg;
858       loc.high_reg = high_reg;
859       MarkPair(loc.low_reg, loc.high_reg);
860       DCHECK(!IsFpReg(loc.low_reg) || ((loc.low_reg & 0x1) == 0));
861     }
862     return loc;
863   }
864 
865   DCHECK_NE(loc.s_reg_low, INVALID_SREG);
866   DCHECK_NE(GetSRegHi(loc.s_reg_low), INVALID_SREG);
867 
868   new_regs = AllocTypedTempPair(loc.fp, reg_class);
869   loc.low_reg = new_regs & 0xff;
870   loc.high_reg = (new_regs >> 8) & 0xff;
871 
872   MarkPair(loc.low_reg, loc.high_reg);
873   if (update) {
874     loc.location = kLocPhysReg;
875     MarkLive(loc.low_reg, loc.s_reg_low);
876     MarkLive(loc.high_reg, GetSRegHi(loc.s_reg_low));
877   }
878   DCHECK(!IsFpReg(loc.low_reg) || ((loc.low_reg & 0x1) == 0));
879   return loc;
880 }
881 
EvalLoc(RegLocation loc,int reg_class,bool update)882 RegLocation Mir2Lir::EvalLoc(RegLocation loc, int reg_class, bool update) {
883   int new_reg;
884 
885   if (loc.wide)
886     return EvalLocWide(loc, reg_class, update);
887 
888   loc = UpdateLoc(loc);
889 
890   if (loc.location == kLocPhysReg) {
891     if (!RegClassMatches(reg_class, loc.low_reg)) {
892       /* Wrong register class.  Realloc, copy and transfer ownership */
893       new_reg = AllocTypedTemp(loc.fp, reg_class);
894       OpRegCopy(new_reg, loc.low_reg);
895       CopyRegInfo(new_reg, loc.low_reg);
896       Clobber(loc.low_reg);
897       loc.low_reg = new_reg;
898     }
899     return loc;
900   }
901 
902   DCHECK_NE(loc.s_reg_low, INVALID_SREG);
903 
904   new_reg = AllocTypedTemp(loc.fp, reg_class);
905   loc.low_reg = new_reg;
906 
907   if (update) {
908     loc.location = kLocPhysReg;
909     MarkLive(loc.low_reg, loc.s_reg_low);
910   }
911   return loc;
912 }
913 
914 /* USE SSA names to count references of base Dalvik v_regs. */
CountRefs(RefCounts * core_counts,RefCounts * fp_counts)915 void Mir2Lir::CountRefs(RefCounts* core_counts, RefCounts* fp_counts) {
916   for (int i = 0; i < mir_graph_->GetNumSSARegs(); i++) {
917     RegLocation loc = mir_graph_->reg_location_[i];
918     RefCounts* counts = loc.fp ? fp_counts : core_counts;
919     int p_map_idx = SRegToPMap(loc.s_reg_low);
920     // Don't count easily regenerated immediates
921     if (loc.fp || !IsInexpensiveConstant(loc)) {
922       counts[p_map_idx].count += mir_graph_->GetUseCount(i);
923     }
924     if (loc.wide && loc.fp && !loc.high_word) {
925       counts[p_map_idx].double_start = true;
926     }
927   }
928 }
929 
930 /* qsort callback function, sort descending */
SortCounts(const void * val1,const void * val2)931 static int SortCounts(const void *val1, const void *val2) {
932   const Mir2Lir::RefCounts* op1 = reinterpret_cast<const Mir2Lir::RefCounts*>(val1);
933   const Mir2Lir::RefCounts* op2 = reinterpret_cast<const Mir2Lir::RefCounts*>(val2);
934   // Note that we fall back to sorting on reg so we get stable output
935   // on differing qsort implementations (such as on host and target or
936   // between local host and build servers).
937   return (op1->count == op2->count)
938           ? (op1->s_reg - op2->s_reg)
939           : (op1->count < op2->count ? 1 : -1);
940 }
941 
DumpCounts(const RefCounts * arr,int size,const char * msg)942 void Mir2Lir::DumpCounts(const RefCounts* arr, int size, const char* msg) {
943   LOG(INFO) << msg;
944   for (int i = 0; i < size; i++) {
945     LOG(INFO) << "s_reg[" << arr[i].s_reg << "]: " << arr[i].count;
946   }
947 }
948 
949 /*
950  * Note: some portions of this code required even if the kPromoteRegs
951  * optimization is disabled.
952  */
DoPromotion()953 void Mir2Lir::DoPromotion() {
954   int reg_bias = cu_->num_compiler_temps + 1;
955   int dalvik_regs = cu_->num_dalvik_registers;
956   int num_regs = dalvik_regs + reg_bias;
957   const int promotion_threshold = 1;
958 
959   // Allow target code to add any special registers
960   AdjustSpillMask();
961 
962   /*
963    * Simple register promotion. Just do a static count of the uses
964    * of Dalvik registers.  Note that we examine the SSA names, but
965    * count based on original Dalvik register name.  Count refs
966    * separately based on type in order to give allocation
967    * preference to fp doubles - which must be allocated sequential
968    * physical single fp registers started with an even-numbered
969    * reg.
970    * TUNING: replace with linear scan once we have the ability
971    * to describe register live ranges for GC.
972    */
973   RefCounts *core_regs =
974       static_cast<RefCounts*>(arena_->Alloc(sizeof(RefCounts) * num_regs,
975                                             ArenaAllocator::kAllocRegAlloc));
976   RefCounts *FpRegs =
977       static_cast<RefCounts *>(arena_->Alloc(sizeof(RefCounts) * num_regs,
978                                              ArenaAllocator::kAllocRegAlloc));
979   // Set ssa names for original Dalvik registers
980   for (int i = 0; i < dalvik_regs; i++) {
981     core_regs[i].s_reg = FpRegs[i].s_reg = i;
982   }
983   // Set ssa name for Method*
984   core_regs[dalvik_regs].s_reg = mir_graph_->GetMethodSReg();
985   FpRegs[dalvik_regs].s_reg = mir_graph_->GetMethodSReg();  // For consistecy
986   // Set ssa names for compiler_temps
987   for (int i = 1; i <= cu_->num_compiler_temps; i++) {
988     CompilerTemp* ct = mir_graph_->compiler_temps_.Get(i);
989     core_regs[dalvik_regs + i].s_reg = ct->s_reg;
990     FpRegs[dalvik_regs + i].s_reg = ct->s_reg;
991   }
992 
993   // Sum use counts of SSA regs by original Dalvik vreg.
994   CountRefs(core_regs, FpRegs);
995 
996   /*
997    * Ideally, we'd allocate doubles starting with an even-numbered
998    * register.  Bias the counts to try to allocate any vreg that's
999    * used as the start of a pair first.
1000    */
1001   for (int i = 0; i < num_regs; i++) {
1002     if (FpRegs[i].double_start) {
1003       FpRegs[i].count *= 2;
1004     }
1005   }
1006 
1007   // Sort the count arrays
1008   qsort(core_regs, num_regs, sizeof(RefCounts), SortCounts);
1009   qsort(FpRegs, num_regs, sizeof(RefCounts), SortCounts);
1010 
1011   if (cu_->verbose) {
1012     DumpCounts(core_regs, num_regs, "Core regs after sort");
1013     DumpCounts(FpRegs, num_regs, "Fp regs after sort");
1014   }
1015 
1016   if (!(cu_->disable_opt & (1 << kPromoteRegs))) {
1017     // Promote FpRegs
1018     for (int i = 0; (i < num_regs) && (FpRegs[i].count >= promotion_threshold); i++) {
1019       int p_map_idx = SRegToPMap(FpRegs[i].s_reg);
1020       if (promotion_map_[p_map_idx].fp_location != kLocPhysReg) {
1021         int reg = AllocPreservedFPReg(FpRegs[i].s_reg,
1022           FpRegs[i].double_start);
1023         if (reg < 0) {
1024           break;  // No more left
1025         }
1026       }
1027     }
1028 
1029     // Promote core regs
1030     for (int i = 0; (i < num_regs) &&
1031             (core_regs[i].count >= promotion_threshold); i++) {
1032       int p_map_idx = SRegToPMap(core_regs[i].s_reg);
1033       if (promotion_map_[p_map_idx].core_location !=
1034           kLocPhysReg) {
1035         int reg = AllocPreservedCoreReg(core_regs[i].s_reg);
1036         if (reg < 0) {
1037            break;  // No more left
1038         }
1039       }
1040     }
1041   }
1042 
1043   // Now, update SSA names to new home locations
1044   for (int i = 0; i < mir_graph_->GetNumSSARegs(); i++) {
1045     RegLocation *curr = &mir_graph_->reg_location_[i];
1046     int p_map_idx = SRegToPMap(curr->s_reg_low);
1047     if (!curr->wide) {
1048       if (curr->fp) {
1049         if (promotion_map_[p_map_idx].fp_location == kLocPhysReg) {
1050           curr->location = kLocPhysReg;
1051           curr->low_reg = promotion_map_[p_map_idx].FpReg;
1052           curr->home = true;
1053         }
1054       } else {
1055         if (promotion_map_[p_map_idx].core_location == kLocPhysReg) {
1056           curr->location = kLocPhysReg;
1057           curr->low_reg = promotion_map_[p_map_idx].core_reg;
1058           curr->home = true;
1059         }
1060       }
1061       curr->high_reg = INVALID_REG;
1062     } else {
1063       if (curr->high_word) {
1064         continue;
1065       }
1066       if (curr->fp) {
1067         if ((promotion_map_[p_map_idx].fp_location == kLocPhysReg) &&
1068           (promotion_map_[p_map_idx+1].fp_location ==
1069           kLocPhysReg)) {
1070           int low_reg = promotion_map_[p_map_idx].FpReg;
1071           int high_reg = promotion_map_[p_map_idx+1].FpReg;
1072           // Doubles require pair of singles starting at even reg
1073           if (((low_reg & 0x1) == 0) && ((low_reg + 1) == high_reg)) {
1074             curr->location = kLocPhysReg;
1075             curr->low_reg = low_reg;
1076             curr->high_reg = high_reg;
1077             curr->home = true;
1078           }
1079         }
1080       } else {
1081         if ((promotion_map_[p_map_idx].core_location == kLocPhysReg)
1082            && (promotion_map_[p_map_idx+1].core_location ==
1083            kLocPhysReg)) {
1084           curr->location = kLocPhysReg;
1085           curr->low_reg = promotion_map_[p_map_idx].core_reg;
1086           curr->high_reg = promotion_map_[p_map_idx+1].core_reg;
1087           curr->home = true;
1088         }
1089       }
1090     }
1091   }
1092   if (cu_->verbose) {
1093     DumpPromotionMap();
1094   }
1095 }
1096 
1097 /* Returns sp-relative offset in bytes for a VReg */
VRegOffset(int v_reg)1098 int Mir2Lir::VRegOffset(int v_reg) {
1099   return StackVisitor::GetVRegOffset(cu_->code_item, core_spill_mask_,
1100                                      fp_spill_mask_, frame_size_, v_reg);
1101 }
1102 
1103 /* Returns sp-relative offset in bytes for a SReg */
SRegOffset(int s_reg)1104 int Mir2Lir::SRegOffset(int s_reg) {
1105   return VRegOffset(mir_graph_->SRegToVReg(s_reg));
1106 }
1107 
1108 /* Mark register usage state and return long retloc */
GetReturnWide(bool is_double)1109 RegLocation Mir2Lir::GetReturnWide(bool is_double) {
1110   RegLocation gpr_res = LocCReturnWide();
1111   RegLocation fpr_res = LocCReturnDouble();
1112   RegLocation res = is_double ? fpr_res : gpr_res;
1113   Clobber(res.low_reg);
1114   Clobber(res.high_reg);
1115   LockTemp(res.low_reg);
1116   LockTemp(res.high_reg);
1117   MarkPair(res.low_reg, res.high_reg);
1118   return res;
1119 }
1120 
GetReturn(bool is_float)1121 RegLocation Mir2Lir::GetReturn(bool is_float) {
1122   RegLocation gpr_res = LocCReturn();
1123   RegLocation fpr_res = LocCReturnFloat();
1124   RegLocation res = is_float ? fpr_res : gpr_res;
1125   Clobber(res.low_reg);
1126   if (cu_->instruction_set == kMips) {
1127     MarkInUse(res.low_reg);
1128   } else {
1129     LockTemp(res.low_reg);
1130   }
1131   return res;
1132 }
1133 
SimpleRegAlloc()1134 void Mir2Lir::SimpleRegAlloc() {
1135   DoPromotion();
1136 
1137   if (cu_->verbose && !(cu_->disable_opt & (1 << kPromoteRegs))) {
1138     LOG(INFO) << "After Promotion";
1139     mir_graph_->DumpRegLocTable(mir_graph_->reg_location_, mir_graph_->GetNumSSARegs());
1140   }
1141 
1142   /* Set the frame size */
1143   frame_size_ = ComputeFrameSize();
1144 }
1145 
1146 /*
1147  * Get the "real" sreg number associated with an s_reg slot.  In general,
1148  * s_reg values passed through codegen are the SSA names created by
1149  * dataflow analysis and refer to slot numbers in the mir_graph_->reg_location
1150  * array.  However, renaming is accomplished by simply replacing RegLocation
1151  * entries in the reglocation[] array.  Therefore, when location
1152  * records for operands are first created, we need to ask the locRecord
1153  * identified by the dataflow pass what it's new name is.
1154  */
GetSRegHi(int lowSreg)1155 int Mir2Lir::GetSRegHi(int lowSreg) {
1156   return (lowSreg == INVALID_SREG) ? INVALID_SREG : lowSreg + 1;
1157 }
1158 
oat_live_out(int s_reg)1159 bool Mir2Lir::oat_live_out(int s_reg) {
1160   // For now.
1161   return true;
1162 }
1163 
oatSSASrc(MIR * mir,int num)1164 int Mir2Lir::oatSSASrc(MIR* mir, int num) {
1165   DCHECK_GT(mir->ssa_rep->num_uses, num);
1166   return mir->ssa_rep->uses[num];
1167 }
1168 
1169 }  // namespace art
1170