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 #include "jni_compiler.h" 18 19 #include <algorithm> 20 #include <ios> 21 #include <memory> 22 #include <vector> 23 #include <fstream> 24 25 #include "art_method.h" 26 #include "base/arena_allocator.h" 27 #include "base/enums.h" 28 #include "base/logging.h" 29 #include "base/macros.h" 30 #include "memory_region.h" 31 #include "calling_convention.h" 32 #include "class_linker.h" 33 #include "compiled_method.h" 34 #include "dex_file-inl.h" 35 #include "driver/compiler_driver.h" 36 #include "driver/compiler_options.h" 37 #include "entrypoints/quick/quick_entrypoints.h" 38 #include "jni_env_ext.h" 39 #include "debug/dwarf/debug_frame_opcode_writer.h" 40 #include "utils/assembler.h" 41 #include "utils/jni_macro_assembler.h" 42 #include "utils/managed_register.h" 43 #include "utils/arm/managed_register_arm.h" 44 #include "utils/arm64/managed_register_arm64.h" 45 #include "utils/mips/managed_register_mips.h" 46 #include "utils/mips64/managed_register_mips64.h" 47 #include "utils/x86/managed_register_x86.h" 48 #include "utils.h" 49 #include "thread.h" 50 51 #define __ jni_asm-> 52 53 namespace art { 54 55 using JniOptimizationFlags = Compiler::JniOptimizationFlags; 56 57 template <PointerSize kPointerSize> 58 static void CopyParameter(JNIMacroAssembler<kPointerSize>* jni_asm, 59 ManagedRuntimeCallingConvention* mr_conv, 60 JniCallingConvention* jni_conv, 61 size_t frame_size, size_t out_arg_size); 62 template <PointerSize kPointerSize> 63 static void SetNativeParameter(JNIMacroAssembler<kPointerSize>* jni_asm, 64 JniCallingConvention* jni_conv, 65 ManagedRegister in_reg); 66 67 template <PointerSize kPointerSize> 68 static std::unique_ptr<JNIMacroAssembler<kPointerSize>> GetMacroAssembler( 69 ArenaAllocator* arena, InstructionSet isa, const InstructionSetFeatures* features) { 70 return JNIMacroAssembler<kPointerSize>::Create(arena, isa, features); 71 } 72 73 enum class JniEntrypoint { 74 kStart, 75 kEnd 76 }; 77 78 template <PointerSize kPointerSize> 79 static ThreadOffset<kPointerSize> GetJniEntrypointThreadOffset(JniEntrypoint which, 80 bool reference_return, 81 bool is_synchronized, 82 bool is_fast_native) { 83 if (which == JniEntrypoint::kStart) { // JniMethodStart 84 ThreadOffset<kPointerSize> jni_start = 85 is_synchronized 86 ? QUICK_ENTRYPOINT_OFFSET(kPointerSize, pJniMethodStartSynchronized) 87 : (is_fast_native 88 ? QUICK_ENTRYPOINT_OFFSET(kPointerSize, pJniMethodFastStart) 89 : QUICK_ENTRYPOINT_OFFSET(kPointerSize, pJniMethodStart)); 90 91 return jni_start; 92 } else { // JniMethodEnd 93 ThreadOffset<kPointerSize> jni_end(-1); 94 if (reference_return) { 95 // Pass result. 96 jni_end = is_synchronized 97 ? QUICK_ENTRYPOINT_OFFSET(kPointerSize, pJniMethodEndWithReferenceSynchronized) 98 : (is_fast_native 99 ? QUICK_ENTRYPOINT_OFFSET(kPointerSize, pJniMethodFastEndWithReference) 100 : QUICK_ENTRYPOINT_OFFSET(kPointerSize, pJniMethodEndWithReference)); 101 } else { 102 jni_end = is_synchronized 103 ? QUICK_ENTRYPOINT_OFFSET(kPointerSize, pJniMethodEndSynchronized) 104 : (is_fast_native 105 ? QUICK_ENTRYPOINT_OFFSET(kPointerSize, pJniMethodFastEnd) 106 : QUICK_ENTRYPOINT_OFFSET(kPointerSize, pJniMethodEnd)); 107 } 108 109 return jni_end; 110 } 111 } 112 113 114 // Generate the JNI bridge for the given method, general contract: 115 // - Arguments are in the managed runtime format, either on stack or in 116 // registers, a reference to the method object is supplied as part of this 117 // convention. 118 // 119 template <PointerSize kPointerSize> 120 static CompiledMethod* ArtJniCompileMethodInternal(CompilerDriver* driver, 121 uint32_t access_flags, 122 uint32_t method_idx, 123 const DexFile& dex_file, 124 JniOptimizationFlags optimization_flags) { 125 const bool is_native = (access_flags & kAccNative) != 0; 126 CHECK(is_native); 127 const bool is_static = (access_flags & kAccStatic) != 0; 128 const bool is_synchronized = (access_flags & kAccSynchronized) != 0; 129 const char* shorty = dex_file.GetMethodShorty(dex_file.GetMethodId(method_idx)); 130 InstructionSet instruction_set = driver->GetInstructionSet(); 131 const InstructionSetFeatures* instruction_set_features = driver->GetInstructionSetFeatures(); 132 133 // i.e. if the method was annotated with @FastNative 134 const bool is_fast_native = (optimization_flags == Compiler::kFastNative); 135 136 // i.e. if the method was annotated with @CriticalNative 137 bool is_critical_native = (optimization_flags == Compiler::kCriticalNative); 138 139 VLOG(jni) << "JniCompile: Method :: " 140 << dex_file.PrettyMethod(method_idx, /* with signature */ true) 141 << " :: access_flags = " << std::hex << access_flags << std::dec; 142 143 if (UNLIKELY(is_fast_native)) { 144 VLOG(jni) << "JniCompile: Fast native method detected :: " 145 << dex_file.PrettyMethod(method_idx, /* with signature */ true); 146 } 147 148 if (UNLIKELY(is_critical_native)) { 149 VLOG(jni) << "JniCompile: Critical native method detected :: " 150 << dex_file.PrettyMethod(method_idx, /* with signature */ true); 151 } 152 153 if (kIsDebugBuild) { 154 // Don't allow both @FastNative and @CriticalNative. They are mutually exclusive. 155 if (UNLIKELY(is_fast_native && is_critical_native)) { 156 LOG(FATAL) << "JniCompile: Method cannot be both @CriticalNative and @FastNative" 157 << dex_file.PrettyMethod(method_idx, /* with_signature */ true); 158 } 159 160 // @CriticalNative - extra checks: 161 // -- Don't allow virtual criticals 162 // -- Don't allow synchronized criticals 163 // -- Don't allow any objects as parameter or return value 164 if (UNLIKELY(is_critical_native)) { 165 CHECK(is_static) 166 << "@CriticalNative functions cannot be virtual since that would" 167 << "require passing a reference parameter (this), which is illegal " 168 << dex_file.PrettyMethod(method_idx, /* with_signature */ true); 169 CHECK(!is_synchronized) 170 << "@CriticalNative functions cannot be synchronized since that would" 171 << "require passing a (class and/or this) reference parameter, which is illegal " 172 << dex_file.PrettyMethod(method_idx, /* with_signature */ true); 173 for (size_t i = 0; i < strlen(shorty); ++i) { 174 CHECK_NE(Primitive::kPrimNot, Primitive::GetType(shorty[i])) 175 << "@CriticalNative methods' shorty types must not have illegal references " 176 << dex_file.PrettyMethod(method_idx, /* with_signature */ true); 177 } 178 } 179 } 180 181 ArenaPool pool; 182 ArenaAllocator arena(&pool); 183 184 // Calling conventions used to iterate over parameters to method 185 std::unique_ptr<JniCallingConvention> main_jni_conv = 186 JniCallingConvention::Create(&arena, 187 is_static, 188 is_synchronized, 189 is_critical_native, 190 shorty, 191 instruction_set); 192 bool reference_return = main_jni_conv->IsReturnAReference(); 193 194 std::unique_ptr<ManagedRuntimeCallingConvention> mr_conv( 195 ManagedRuntimeCallingConvention::Create( 196 &arena, is_static, is_synchronized, shorty, instruction_set)); 197 198 // Calling conventions to call into JNI method "end" possibly passing a returned reference, the 199 // method and the current thread. 200 const char* jni_end_shorty; 201 if (reference_return && is_synchronized) { 202 jni_end_shorty = "ILL"; 203 } else if (reference_return) { 204 jni_end_shorty = "IL"; 205 } else if (is_synchronized) { 206 jni_end_shorty = "VL"; 207 } else { 208 jni_end_shorty = "V"; 209 } 210 211 std::unique_ptr<JniCallingConvention> end_jni_conv( 212 JniCallingConvention::Create(&arena, 213 is_static, 214 is_synchronized, 215 is_critical_native, 216 jni_end_shorty, 217 instruction_set)); 218 219 // Assembler that holds generated instructions 220 std::unique_ptr<JNIMacroAssembler<kPointerSize>> jni_asm = 221 GetMacroAssembler<kPointerSize>(&arena, instruction_set, instruction_set_features); 222 jni_asm->cfi().SetEnabled(driver->GetCompilerOptions().GenerateAnyDebugInfo()); 223 224 // Offsets into data structures 225 // TODO: if cross compiling these offsets are for the host not the target 226 const Offset functions(OFFSETOF_MEMBER(JNIEnvExt, functions)); 227 const Offset monitor_enter(OFFSETOF_MEMBER(JNINativeInterface, MonitorEnter)); 228 const Offset monitor_exit(OFFSETOF_MEMBER(JNINativeInterface, MonitorExit)); 229 230 // 1. Build the frame saving all callee saves, Method*, and PC return address. 231 const size_t frame_size(main_jni_conv->FrameSize()); // Excludes outgoing args. 232 ArrayRef<const ManagedRegister> callee_save_regs = main_jni_conv->CalleeSaveRegisters(); 233 __ BuildFrame(frame_size, mr_conv->MethodRegister(), callee_save_regs, mr_conv->EntrySpills()); 234 DCHECK_EQ(jni_asm->cfi().GetCurrentCFAOffset(), static_cast<int>(frame_size)); 235 236 if (LIKELY(!is_critical_native)) { 237 // NOTE: @CriticalNative methods don't have a HandleScope 238 // because they can't have any reference parameters or return values. 239 240 // 2. Set up the HandleScope 241 mr_conv->ResetIterator(FrameOffset(frame_size)); 242 main_jni_conv->ResetIterator(FrameOffset(0)); 243 __ StoreImmediateToFrame(main_jni_conv->HandleScopeNumRefsOffset(), 244 main_jni_conv->ReferenceCount(), 245 mr_conv->InterproceduralScratchRegister()); 246 247 __ CopyRawPtrFromThread(main_jni_conv->HandleScopeLinkOffset(), 248 Thread::TopHandleScopeOffset<kPointerSize>(), 249 mr_conv->InterproceduralScratchRegister()); 250 __ StoreStackOffsetToThread(Thread::TopHandleScopeOffset<kPointerSize>(), 251 main_jni_conv->HandleScopeOffset(), 252 mr_conv->InterproceduralScratchRegister()); 253 254 // 3. Place incoming reference arguments into handle scope 255 main_jni_conv->Next(); // Skip JNIEnv* 256 // 3.5. Create Class argument for static methods out of passed method 257 if (is_static) { 258 FrameOffset handle_scope_offset = main_jni_conv->CurrentParamHandleScopeEntryOffset(); 259 // Check handle scope offset is within frame 260 CHECK_LT(handle_scope_offset.Uint32Value(), frame_size); 261 // Note this LoadRef() doesn't need heap unpoisoning since it's from the ArtMethod. 262 // Note this LoadRef() does not include read barrier. It will be handled below. 263 // 264 // scratchRegister = *method[DeclaringClassOffset()]; 265 __ LoadRef(main_jni_conv->InterproceduralScratchRegister(), 266 mr_conv->MethodRegister(), ArtMethod::DeclaringClassOffset(), false); 267 __ VerifyObject(main_jni_conv->InterproceduralScratchRegister(), false); 268 // *handleScopeOffset = scratchRegister 269 __ StoreRef(handle_scope_offset, main_jni_conv->InterproceduralScratchRegister()); 270 main_jni_conv->Next(); // in handle scope so move to next argument 271 } 272 // Place every reference into the handle scope (ignore other parameters). 273 while (mr_conv->HasNext()) { 274 CHECK(main_jni_conv->HasNext()); 275 bool ref_param = main_jni_conv->IsCurrentParamAReference(); 276 CHECK(!ref_param || mr_conv->IsCurrentParamAReference()); 277 // References need placing in handle scope and the entry value passing 278 if (ref_param) { 279 // Compute handle scope entry, note null is placed in the handle scope but its boxed value 280 // must be null. 281 FrameOffset handle_scope_offset = main_jni_conv->CurrentParamHandleScopeEntryOffset(); 282 // Check handle scope offset is within frame and doesn't run into the saved segment state. 283 CHECK_LT(handle_scope_offset.Uint32Value(), frame_size); 284 CHECK_NE(handle_scope_offset.Uint32Value(), 285 main_jni_conv->SavedLocalReferenceCookieOffset().Uint32Value()); 286 bool input_in_reg = mr_conv->IsCurrentParamInRegister(); 287 bool input_on_stack = mr_conv->IsCurrentParamOnStack(); 288 CHECK(input_in_reg || input_on_stack); 289 290 if (input_in_reg) { 291 ManagedRegister in_reg = mr_conv->CurrentParamRegister(); 292 __ VerifyObject(in_reg, mr_conv->IsCurrentArgPossiblyNull()); 293 __ StoreRef(handle_scope_offset, in_reg); 294 } else if (input_on_stack) { 295 FrameOffset in_off = mr_conv->CurrentParamStackOffset(); 296 __ VerifyObject(in_off, mr_conv->IsCurrentArgPossiblyNull()); 297 __ CopyRef(handle_scope_offset, in_off, 298 mr_conv->InterproceduralScratchRegister()); 299 } 300 } 301 mr_conv->Next(); 302 main_jni_conv->Next(); 303 } 304 305 // 4. Write out the end of the quick frames. 306 __ StoreStackPointerToThread(Thread::TopOfManagedStackOffset<kPointerSize>()); 307 308 // NOTE: @CriticalNative does not need to store the stack pointer to the thread 309 // because garbage collections are disabled within the execution of a 310 // @CriticalNative method. 311 // (TODO: We could probably disable it for @FastNative too). 312 } // if (!is_critical_native) 313 314 // 5. Move frame down to allow space for out going args. 315 const size_t main_out_arg_size = main_jni_conv->OutArgSize(); 316 size_t current_out_arg_size = main_out_arg_size; 317 __ IncreaseFrameSize(main_out_arg_size); 318 319 // Call the read barrier for the declaring class loaded from the method for a static call. 320 // Skip this for @CriticalNative because we didn't build a HandleScope to begin with. 321 // Note that we always have outgoing param space available for at least two params. 322 if (kUseReadBarrier && is_static && !is_critical_native) { 323 const bool kReadBarrierFastPath = 324 (instruction_set != kMips) && (instruction_set != kMips64); 325 std::unique_ptr<JNIMacroLabel> skip_cold_path_label; 326 if (kReadBarrierFastPath) { 327 skip_cold_path_label = __ CreateLabel(); 328 // Fast path for supported targets. 329 // 330 // Check if gc_is_marking is set -- if it's not, we don't need 331 // a read barrier so skip it. 332 __ LoadFromThread(main_jni_conv->InterproceduralScratchRegister(), 333 Thread::IsGcMarkingOffset<kPointerSize>(), 334 Thread::IsGcMarkingSize()); 335 // Jump over the slow path if gc is marking is false. 336 __ Jump(skip_cold_path_label.get(), 337 JNIMacroUnaryCondition::kZero, 338 main_jni_conv->InterproceduralScratchRegister()); 339 } 340 341 // Construct slow path for read barrier: 342 // 343 // Call into the runtime's ReadBarrierJni and have it fix up 344 // the object address if it was moved. 345 346 ThreadOffset<kPointerSize> read_barrier = QUICK_ENTRYPOINT_OFFSET(kPointerSize, 347 pReadBarrierJni); 348 main_jni_conv->ResetIterator(FrameOffset(main_out_arg_size)); 349 main_jni_conv->Next(); // Skip JNIEnv. 350 FrameOffset class_handle_scope_offset = main_jni_conv->CurrentParamHandleScopeEntryOffset(); 351 main_jni_conv->ResetIterator(FrameOffset(main_out_arg_size)); 352 // Pass the handle for the class as the first argument. 353 if (main_jni_conv->IsCurrentParamOnStack()) { 354 FrameOffset out_off = main_jni_conv->CurrentParamStackOffset(); 355 __ CreateHandleScopeEntry(out_off, class_handle_scope_offset, 356 mr_conv->InterproceduralScratchRegister(), 357 false); 358 } else { 359 ManagedRegister out_reg = main_jni_conv->CurrentParamRegister(); 360 __ CreateHandleScopeEntry(out_reg, class_handle_scope_offset, 361 ManagedRegister::NoRegister(), false); 362 } 363 main_jni_conv->Next(); 364 // Pass the current thread as the second argument and call. 365 if (main_jni_conv->IsCurrentParamInRegister()) { 366 __ GetCurrentThread(main_jni_conv->CurrentParamRegister()); 367 __ Call(main_jni_conv->CurrentParamRegister(), 368 Offset(read_barrier), 369 main_jni_conv->InterproceduralScratchRegister()); 370 } else { 371 __ GetCurrentThread(main_jni_conv->CurrentParamStackOffset(), 372 main_jni_conv->InterproceduralScratchRegister()); 373 __ CallFromThread(read_barrier, main_jni_conv->InterproceduralScratchRegister()); 374 } 375 main_jni_conv->ResetIterator(FrameOffset(main_out_arg_size)); // Reset. 376 377 if (kReadBarrierFastPath) { 378 __ Bind(skip_cold_path_label.get()); 379 } 380 } 381 382 // 6. Call into appropriate JniMethodStart passing Thread* so that transition out of Runnable 383 // can occur. The result is the saved JNI local state that is restored by the exit call. We 384 // abuse the JNI calling convention here, that is guaranteed to support passing 2 pointer 385 // arguments. 386 FrameOffset locked_object_handle_scope_offset(0xBEEFDEAD); 387 if (LIKELY(!is_critical_native)) { 388 // Skip this for @CriticalNative methods. They do not call JniMethodStart. 389 ThreadOffset<kPointerSize> jni_start( 390 GetJniEntrypointThreadOffset<kPointerSize>(JniEntrypoint::kStart, 391 reference_return, 392 is_synchronized, 393 is_fast_native).SizeValue()); 394 main_jni_conv->ResetIterator(FrameOffset(main_out_arg_size)); 395 locked_object_handle_scope_offset = FrameOffset(0); 396 if (is_synchronized) { 397 // Pass object for locking. 398 main_jni_conv->Next(); // Skip JNIEnv. 399 locked_object_handle_scope_offset = main_jni_conv->CurrentParamHandleScopeEntryOffset(); 400 main_jni_conv->ResetIterator(FrameOffset(main_out_arg_size)); 401 if (main_jni_conv->IsCurrentParamOnStack()) { 402 FrameOffset out_off = main_jni_conv->CurrentParamStackOffset(); 403 __ CreateHandleScopeEntry(out_off, locked_object_handle_scope_offset, 404 mr_conv->InterproceduralScratchRegister(), false); 405 } else { 406 ManagedRegister out_reg = main_jni_conv->CurrentParamRegister(); 407 __ CreateHandleScopeEntry(out_reg, locked_object_handle_scope_offset, 408 ManagedRegister::NoRegister(), false); 409 } 410 main_jni_conv->Next(); 411 } 412 if (main_jni_conv->IsCurrentParamInRegister()) { 413 __ GetCurrentThread(main_jni_conv->CurrentParamRegister()); 414 __ Call(main_jni_conv->CurrentParamRegister(), 415 Offset(jni_start), 416 main_jni_conv->InterproceduralScratchRegister()); 417 } else { 418 __ GetCurrentThread(main_jni_conv->CurrentParamStackOffset(), 419 main_jni_conv->InterproceduralScratchRegister()); 420 __ CallFromThread(jni_start, main_jni_conv->InterproceduralScratchRegister()); 421 } 422 if (is_synchronized) { // Check for exceptions from monitor enter. 423 __ ExceptionPoll(main_jni_conv->InterproceduralScratchRegister(), main_out_arg_size); 424 } 425 } 426 427 // Store into stack_frame[saved_cookie_offset] the return value of JniMethodStart. 428 FrameOffset saved_cookie_offset( 429 FrameOffset(0xDEADBEEFu)); // @CriticalNative - use obviously bad value for debugging 430 if (LIKELY(!is_critical_native)) { 431 saved_cookie_offset = main_jni_conv->SavedLocalReferenceCookieOffset(); 432 __ Store(saved_cookie_offset, main_jni_conv->IntReturnRegister(), 4 /* sizeof cookie */); 433 } 434 435 // 7. Iterate over arguments placing values from managed calling convention in 436 // to the convention required for a native call (shuffling). For references 437 // place an index/pointer to the reference after checking whether it is 438 // null (which must be encoded as null). 439 // Note: we do this prior to materializing the JNIEnv* and static's jclass to 440 // give as many free registers for the shuffle as possible. 441 mr_conv->ResetIterator(FrameOffset(frame_size + main_out_arg_size)); 442 uint32_t args_count = 0; 443 while (mr_conv->HasNext()) { 444 args_count++; 445 mr_conv->Next(); 446 } 447 448 // Do a backward pass over arguments, so that the generated code will be "mov 449 // R2, R3; mov R1, R2" instead of "mov R1, R2; mov R2, R3." 450 // TODO: A reverse iterator to improve readability. 451 for (uint32_t i = 0; i < args_count; ++i) { 452 mr_conv->ResetIterator(FrameOffset(frame_size + main_out_arg_size)); 453 main_jni_conv->ResetIterator(FrameOffset(main_out_arg_size)); 454 455 // Skip the extra JNI parameters for now. 456 if (LIKELY(!is_critical_native)) { 457 main_jni_conv->Next(); // Skip JNIEnv*. 458 if (is_static) { 459 main_jni_conv->Next(); // Skip Class for now. 460 } 461 } 462 // Skip to the argument we're interested in. 463 for (uint32_t j = 0; j < args_count - i - 1; ++j) { 464 mr_conv->Next(); 465 main_jni_conv->Next(); 466 } 467 CopyParameter(jni_asm.get(), mr_conv.get(), main_jni_conv.get(), frame_size, main_out_arg_size); 468 } 469 if (is_static && !is_critical_native) { 470 // Create argument for Class 471 mr_conv->ResetIterator(FrameOffset(frame_size + main_out_arg_size)); 472 main_jni_conv->ResetIterator(FrameOffset(main_out_arg_size)); 473 main_jni_conv->Next(); // Skip JNIEnv* 474 FrameOffset handle_scope_offset = main_jni_conv->CurrentParamHandleScopeEntryOffset(); 475 if (main_jni_conv->IsCurrentParamOnStack()) { 476 FrameOffset out_off = main_jni_conv->CurrentParamStackOffset(); 477 __ CreateHandleScopeEntry(out_off, handle_scope_offset, 478 mr_conv->InterproceduralScratchRegister(), 479 false); 480 } else { 481 ManagedRegister out_reg = main_jni_conv->CurrentParamRegister(); 482 __ CreateHandleScopeEntry(out_reg, handle_scope_offset, 483 ManagedRegister::NoRegister(), false); 484 } 485 } 486 487 // Set the iterator back to the incoming Method*. 488 main_jni_conv->ResetIterator(FrameOffset(main_out_arg_size)); 489 if (LIKELY(!is_critical_native)) { 490 // 8. Create 1st argument, the JNI environment ptr. 491 // Register that will hold local indirect reference table 492 if (main_jni_conv->IsCurrentParamInRegister()) { 493 ManagedRegister jni_env = main_jni_conv->CurrentParamRegister(); 494 DCHECK(!jni_env.Equals(main_jni_conv->InterproceduralScratchRegister())); 495 __ LoadRawPtrFromThread(jni_env, Thread::JniEnvOffset<kPointerSize>()); 496 } else { 497 FrameOffset jni_env = main_jni_conv->CurrentParamStackOffset(); 498 __ CopyRawPtrFromThread(jni_env, 499 Thread::JniEnvOffset<kPointerSize>(), 500 main_jni_conv->InterproceduralScratchRegister()); 501 } 502 } 503 504 // 9. Plant call to native code associated with method. 505 MemberOffset jni_entrypoint_offset = 506 ArtMethod::EntryPointFromJniOffset(InstructionSetPointerSize(instruction_set)); 507 // FIXME: Not sure if MethodStackOffset will work here. What does it even do? 508 __ Call(main_jni_conv->MethodStackOffset(), 509 jni_entrypoint_offset, 510 // XX: Why not the jni conv scratch register? 511 mr_conv->InterproceduralScratchRegister()); 512 513 // 10. Fix differences in result widths. 514 if (main_jni_conv->RequiresSmallResultTypeExtension()) { 515 if (main_jni_conv->GetReturnType() == Primitive::kPrimByte || 516 main_jni_conv->GetReturnType() == Primitive::kPrimShort) { 517 __ SignExtend(main_jni_conv->ReturnRegister(), 518 Primitive::ComponentSize(main_jni_conv->GetReturnType())); 519 } else if (main_jni_conv->GetReturnType() == Primitive::kPrimBoolean || 520 main_jni_conv->GetReturnType() == Primitive::kPrimChar) { 521 __ ZeroExtend(main_jni_conv->ReturnRegister(), 522 Primitive::ComponentSize(main_jni_conv->GetReturnType())); 523 } 524 } 525 526 // 11. Process return value 527 FrameOffset return_save_location = main_jni_conv->ReturnValueSaveLocation(); 528 if (main_jni_conv->SizeOfReturnValue() != 0 && !reference_return) { 529 if (LIKELY(!is_critical_native)) { 530 // For normal JNI, store the return value on the stack because the call to 531 // JniMethodEnd will clobber the return value. It will be restored in (13). 532 if ((instruction_set == kMips || instruction_set == kMips64) && 533 main_jni_conv->GetReturnType() == Primitive::kPrimDouble && 534 return_save_location.Uint32Value() % 8 != 0) { 535 // Ensure doubles are 8-byte aligned for MIPS 536 return_save_location = FrameOffset(return_save_location.Uint32Value() 537 + static_cast<size_t>(kMipsPointerSize)); 538 // TODO: refactor this into the JniCallingConvention code 539 // as a return value alignment requirement. 540 } 541 CHECK_LT(return_save_location.Uint32Value(), frame_size + main_out_arg_size); 542 __ Store(return_save_location, 543 main_jni_conv->ReturnRegister(), 544 main_jni_conv->SizeOfReturnValue()); 545 } else { 546 // For @CriticalNative only, 547 // move the JNI return register into the managed return register (if they don't match). 548 ManagedRegister jni_return_reg = main_jni_conv->ReturnRegister(); 549 ManagedRegister mr_return_reg = mr_conv->ReturnRegister(); 550 551 // Check if the JNI return register matches the managed return register. 552 // If they differ, only then do we have to do anything about it. 553 // Otherwise the return value is already in the right place when we return. 554 if (!jni_return_reg.Equals(mr_return_reg)) { 555 // This is typically only necessary on ARM32 due to native being softfloat 556 // while managed is hardfloat. 557 // -- For example VMOV {r0, r1} -> D0; VMOV r0 -> S0. 558 __ Move(mr_return_reg, jni_return_reg, main_jni_conv->SizeOfReturnValue()); 559 } else if (jni_return_reg.IsNoRegister() && mr_return_reg.IsNoRegister()) { 560 // Sanity check: If the return value is passed on the stack for some reason, 561 // then make sure the size matches. 562 CHECK_EQ(main_jni_conv->SizeOfReturnValue(), mr_conv->SizeOfReturnValue()); 563 } 564 } 565 } 566 567 // Increase frame size for out args if needed by the end_jni_conv. 568 const size_t end_out_arg_size = end_jni_conv->OutArgSize(); 569 if (end_out_arg_size > current_out_arg_size) { 570 size_t out_arg_size_diff = end_out_arg_size - current_out_arg_size; 571 current_out_arg_size = end_out_arg_size; 572 // TODO: This is redundant for @CriticalNative but we need to 573 // conditionally do __DecreaseFrameSize below. 574 __ IncreaseFrameSize(out_arg_size_diff); 575 saved_cookie_offset = FrameOffset(saved_cookie_offset.SizeValue() + out_arg_size_diff); 576 locked_object_handle_scope_offset = 577 FrameOffset(locked_object_handle_scope_offset.SizeValue() + out_arg_size_diff); 578 return_save_location = FrameOffset(return_save_location.SizeValue() + out_arg_size_diff); 579 } 580 // thread. 581 end_jni_conv->ResetIterator(FrameOffset(end_out_arg_size)); 582 583 if (LIKELY(!is_critical_native)) { 584 // 12. Call JniMethodEnd 585 ThreadOffset<kPointerSize> jni_end( 586 GetJniEntrypointThreadOffset<kPointerSize>(JniEntrypoint::kEnd, 587 reference_return, 588 is_synchronized, 589 is_fast_native).SizeValue()); 590 if (reference_return) { 591 // Pass result. 592 SetNativeParameter(jni_asm.get(), end_jni_conv.get(), end_jni_conv->ReturnRegister()); 593 end_jni_conv->Next(); 594 } 595 // Pass saved local reference state. 596 if (end_jni_conv->IsCurrentParamOnStack()) { 597 FrameOffset out_off = end_jni_conv->CurrentParamStackOffset(); 598 __ Copy(out_off, saved_cookie_offset, end_jni_conv->InterproceduralScratchRegister(), 4); 599 } else { 600 ManagedRegister out_reg = end_jni_conv->CurrentParamRegister(); 601 __ Load(out_reg, saved_cookie_offset, 4); 602 } 603 end_jni_conv->Next(); 604 if (is_synchronized) { 605 // Pass object for unlocking. 606 if (end_jni_conv->IsCurrentParamOnStack()) { 607 FrameOffset out_off = end_jni_conv->CurrentParamStackOffset(); 608 __ CreateHandleScopeEntry(out_off, locked_object_handle_scope_offset, 609 end_jni_conv->InterproceduralScratchRegister(), 610 false); 611 } else { 612 ManagedRegister out_reg = end_jni_conv->CurrentParamRegister(); 613 __ CreateHandleScopeEntry(out_reg, locked_object_handle_scope_offset, 614 ManagedRegister::NoRegister(), false); 615 } 616 end_jni_conv->Next(); 617 } 618 if (end_jni_conv->IsCurrentParamInRegister()) { 619 __ GetCurrentThread(end_jni_conv->CurrentParamRegister()); 620 __ Call(end_jni_conv->CurrentParamRegister(), 621 Offset(jni_end), 622 end_jni_conv->InterproceduralScratchRegister()); 623 } else { 624 __ GetCurrentThread(end_jni_conv->CurrentParamStackOffset(), 625 end_jni_conv->InterproceduralScratchRegister()); 626 __ CallFromThread(jni_end, end_jni_conv->InterproceduralScratchRegister()); 627 } 628 629 // 13. Reload return value 630 if (main_jni_conv->SizeOfReturnValue() != 0 && !reference_return) { 631 __ Load(mr_conv->ReturnRegister(), return_save_location, mr_conv->SizeOfReturnValue()); 632 // NIT: If it's @CriticalNative then we actually only need to do this IF 633 // the calling convention's native return register doesn't match the managed convention's 634 // return register. 635 } 636 } // if (!is_critical_native) 637 638 // 14. Move frame up now we're done with the out arg space. 639 __ DecreaseFrameSize(current_out_arg_size); 640 641 // 15. Process pending exceptions from JNI call or monitor exit. 642 __ ExceptionPoll(main_jni_conv->InterproceduralScratchRegister(), 0 /* stack_adjust */); 643 644 // 16. Remove activation - need to restore callee save registers since the GC may have changed 645 // them. 646 DCHECK_EQ(jni_asm->cfi().GetCurrentCFAOffset(), static_cast<int>(frame_size)); 647 __ RemoveFrame(frame_size, callee_save_regs); 648 DCHECK_EQ(jni_asm->cfi().GetCurrentCFAOffset(), static_cast<int>(frame_size)); 649 650 // 17. Finalize code generation 651 __ FinalizeCode(); 652 size_t cs = __ CodeSize(); 653 std::vector<uint8_t> managed_code(cs); 654 MemoryRegion code(&managed_code[0], managed_code.size()); 655 __ FinalizeInstructions(code); 656 657 return CompiledMethod::SwapAllocCompiledMethod(driver, 658 instruction_set, 659 ArrayRef<const uint8_t>(managed_code), 660 frame_size, 661 main_jni_conv->CoreSpillMask(), 662 main_jni_conv->FpSpillMask(), 663 /* method_info */ ArrayRef<const uint8_t>(), 664 /* vmap_table */ ArrayRef<const uint8_t>(), 665 ArrayRef<const uint8_t>(*jni_asm->cfi().data()), 666 ArrayRef<const LinkerPatch>()); 667 } 668 669 // Copy a single parameter from the managed to the JNI calling convention. 670 template <PointerSize kPointerSize> 671 static void CopyParameter(JNIMacroAssembler<kPointerSize>* jni_asm, 672 ManagedRuntimeCallingConvention* mr_conv, 673 JniCallingConvention* jni_conv, 674 size_t frame_size, 675 size_t out_arg_size) { 676 bool input_in_reg = mr_conv->IsCurrentParamInRegister(); 677 bool output_in_reg = jni_conv->IsCurrentParamInRegister(); 678 FrameOffset handle_scope_offset(0); 679 bool null_allowed = false; 680 bool ref_param = jni_conv->IsCurrentParamAReference(); 681 CHECK(!ref_param || mr_conv->IsCurrentParamAReference()); 682 // input may be in register, on stack or both - but not none! 683 CHECK(input_in_reg || mr_conv->IsCurrentParamOnStack()); 684 if (output_in_reg) { // output shouldn't straddle registers and stack 685 CHECK(!jni_conv->IsCurrentParamOnStack()); 686 } else { 687 CHECK(jni_conv->IsCurrentParamOnStack()); 688 } 689 // References need placing in handle scope and the entry address passing. 690 if (ref_param) { 691 null_allowed = mr_conv->IsCurrentArgPossiblyNull(); 692 // Compute handle scope offset. Note null is placed in the handle scope but the jobject 693 // passed to the native code must be null (not a pointer into the handle scope 694 // as with regular references). 695 handle_scope_offset = jni_conv->CurrentParamHandleScopeEntryOffset(); 696 // Check handle scope offset is within frame. 697 CHECK_LT(handle_scope_offset.Uint32Value(), (frame_size + out_arg_size)); 698 } 699 if (input_in_reg && output_in_reg) { 700 ManagedRegister in_reg = mr_conv->CurrentParamRegister(); 701 ManagedRegister out_reg = jni_conv->CurrentParamRegister(); 702 if (ref_param) { 703 __ CreateHandleScopeEntry(out_reg, handle_scope_offset, in_reg, null_allowed); 704 } else { 705 if (!mr_conv->IsCurrentParamOnStack()) { 706 // regular non-straddling move 707 __ Move(out_reg, in_reg, mr_conv->CurrentParamSize()); 708 } else { 709 UNIMPLEMENTED(FATAL); // we currently don't expect to see this case 710 } 711 } 712 } else if (!input_in_reg && !output_in_reg) { 713 FrameOffset out_off = jni_conv->CurrentParamStackOffset(); 714 if (ref_param) { 715 __ CreateHandleScopeEntry(out_off, handle_scope_offset, mr_conv->InterproceduralScratchRegister(), 716 null_allowed); 717 } else { 718 FrameOffset in_off = mr_conv->CurrentParamStackOffset(); 719 size_t param_size = mr_conv->CurrentParamSize(); 720 CHECK_EQ(param_size, jni_conv->CurrentParamSize()); 721 __ Copy(out_off, in_off, mr_conv->InterproceduralScratchRegister(), param_size); 722 } 723 } else if (!input_in_reg && output_in_reg) { 724 FrameOffset in_off = mr_conv->CurrentParamStackOffset(); 725 ManagedRegister out_reg = jni_conv->CurrentParamRegister(); 726 // Check that incoming stack arguments are above the current stack frame. 727 CHECK_GT(in_off.Uint32Value(), frame_size); 728 if (ref_param) { 729 __ CreateHandleScopeEntry(out_reg, handle_scope_offset, ManagedRegister::NoRegister(), null_allowed); 730 } else { 731 size_t param_size = mr_conv->CurrentParamSize(); 732 CHECK_EQ(param_size, jni_conv->CurrentParamSize()); 733 __ Load(out_reg, in_off, param_size); 734 } 735 } else { 736 CHECK(input_in_reg && !output_in_reg); 737 ManagedRegister in_reg = mr_conv->CurrentParamRegister(); 738 FrameOffset out_off = jni_conv->CurrentParamStackOffset(); 739 // Check outgoing argument is within frame 740 CHECK_LT(out_off.Uint32Value(), frame_size); 741 if (ref_param) { 742 // TODO: recycle value in in_reg rather than reload from handle scope 743 __ CreateHandleScopeEntry(out_off, handle_scope_offset, mr_conv->InterproceduralScratchRegister(), 744 null_allowed); 745 } else { 746 size_t param_size = mr_conv->CurrentParamSize(); 747 CHECK_EQ(param_size, jni_conv->CurrentParamSize()); 748 if (!mr_conv->IsCurrentParamOnStack()) { 749 // regular non-straddling store 750 __ Store(out_off, in_reg, param_size); 751 } else { 752 // store where input straddles registers and stack 753 CHECK_EQ(param_size, 8u); 754 FrameOffset in_off = mr_conv->CurrentParamStackOffset(); 755 __ StoreSpanning(out_off, in_reg, in_off, mr_conv->InterproceduralScratchRegister()); 756 } 757 } 758 } 759 } 760 761 template <PointerSize kPointerSize> 762 static void SetNativeParameter(JNIMacroAssembler<kPointerSize>* jni_asm, 763 JniCallingConvention* jni_conv, 764 ManagedRegister in_reg) { 765 if (jni_conv->IsCurrentParamOnStack()) { 766 FrameOffset dest = jni_conv->CurrentParamStackOffset(); 767 __ StoreRawPtr(dest, in_reg); 768 } else { 769 if (!jni_conv->CurrentParamRegister().Equals(in_reg)) { 770 __ Move(jni_conv->CurrentParamRegister(), in_reg, jni_conv->CurrentParamSize()); 771 } 772 } 773 } 774 775 CompiledMethod* ArtQuickJniCompileMethod(CompilerDriver* compiler, 776 uint32_t access_flags, 777 uint32_t method_idx, 778 const DexFile& dex_file, 779 Compiler::JniOptimizationFlags optimization_flags) { 780 if (Is64BitInstructionSet(compiler->GetInstructionSet())) { 781 return ArtJniCompileMethodInternal<PointerSize::k64>( 782 compiler, access_flags, method_idx, dex_file, optimization_flags); 783 } else { 784 return ArtJniCompileMethodInternal<PointerSize::k32>( 785 compiler, access_flags, method_idx, dex_file, optimization_flags); 786 } 787 } 788 789 } // namespace art 790