1=================================== 2Stack maps and patch points in LLVM 3=================================== 4 5.. contents:: 6 :local: 7 :depth: 2 8 9Definitions 10=========== 11 12In this document we refer to the "runtime" collectively as all 13components that serve as the LLVM client, including the LLVM IR 14generator, object code consumer, and code patcher. 15 16A stack map records the location of ``live values`` at a particular 17instruction address. These ``live values`` do not refer to all the 18LLVM values live across the stack map. Instead, they are only the 19values that the runtime requires to be live at this point. For 20example, they may be the values the runtime will need to resume 21program execution at that point independent of the compiled function 22containing the stack map. 23 24LLVM emits stack map data into the object code within a designated 25:ref:`stackmap-section`. This stack map data contains a record for 26each stack map. The record stores the stack map's instruction address 27and contains a entry for each mapped value. Each entry encodes a 28value's location as a register, stack offset, or constant. 29 30A patch point is an instruction address at which space is reserved for 31patching a new instruction sequence at run time. Patch points look 32much like calls to LLVM. They take arguments that follow a calling 33convention and may return a value. They also imply stack map 34generation, which allows the runtime to locate the patchpoint and 35find the location of ``live values`` at that point. 36 37Motivation 38========== 39 40This functionality is currently experimental but is potentially useful 41in a variety of settings, the most obvious being a runtime (JIT) 42compiler. Example applications of the patchpoint intrinsics are 43implementing an inline call cache for polymorphic method dispatch or 44optimizing the retrieval of properties in dynamically typed languages 45such as JavaScript. 46 47The intrinsics documented here are currently used by the JavaScript 48compiler within the open source WebKit project, see the `FTL JIT 49<https://trac.webkit.org/wiki/FTLJIT>`_, but they are designed to be 50used whenever stack maps or code patching are needed. Because the 51intrinsics have experimental status, compatibility across LLVM 52releases is not guaranteed. 53 54The stack map functionality described in this document is separate 55from the functionality described in 56:ref:`stack-map`. `GCFunctionMetadata` provides the location of 57pointers into a collected heap captured by the `GCRoot` intrinsic, 58which can also be considered a "stack map". Unlike the stack maps 59defined above, the `GCFunctionMetadata` stack map interface does not 60provide a way to associate live register values of arbitrary type with 61an instruction address, nor does it specify a format for the resulting 62stack map. The stack maps described here could potentially provide 63richer information to a garbage collecting runtime, but that usage 64will not be discussed in this document. 65 66Intrinsics 67========== 68 69The following two kinds of intrinsics can be used to implement stack 70maps and patch points: ``llvm.experimental.stackmap`` and 71``llvm.experimental.patchpoint``. Both kinds of intrinsics generate a 72stack map record, and they both allow some form of code patching. They 73can be used independently (i.e. ``llvm.experimental.patchpoint`` 74implicitly generates a stack map without the need for an additional 75call to ``llvm.experimental.stackmap``). The choice of which to use 76depends on whether it is necessary to reserve space for code patching 77and whether any of the intrinsic arguments should be lowered according 78to calling conventions. ``llvm.experimental.stackmap`` does not 79reserve any space, nor does it expect any call arguments. If the 80runtime patches code at the stack map's address, it will destructively 81overwrite the program text. This is unlike 82``llvm.experimental.patchpoint``, which reserves space for in-place 83patching without overwriting surrounding code. The 84``llvm.experimental.patchpoint`` intrinsic also lowers a specified 85number of arguments according to its calling convention. This allows 86patched code to make in-place function calls without marshaling. 87 88Each instance of one of these intrinsics generates a stack map record 89in the :ref:`stackmap-section`. The record includes an ID, allowing 90the runtime to uniquely identify the stack map, and the offset within 91the code from the beginning of the enclosing function. 92 93'``llvm.experimental.stackmap``' Intrinsic 94^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ 95 96Syntax: 97""""""" 98 99:: 100 101 declare void 102 @llvm.experimental.stackmap(i64 <id>, i32 <numShadowBytes>, ...) 103 104Overview: 105""""""""" 106 107The '``llvm.experimental.stackmap``' intrinsic records the location of 108specified values in the stack map without generating any code. 109 110Operands: 111""""""""" 112 113The first operand is an ID to be encoded within the stack map. The 114second operand is the number of shadow bytes following the 115intrinsic. The variable number of operands that follow are the ``live 116values`` for which locations will be recorded in the stack map. 117 118To use this intrinsic as a bare-bones stack map, with no code patching 119support, the number of shadow bytes can be set to zero. 120 121Semantics: 122"""""""""" 123 124The stack map intrinsic generates no code in place, unless nops are 125needed to cover its shadow (see below). However, its offset from 126function entry is stored in the stack map. This is the relative 127instruction address immediately following the instructions that 128precede the stack map. 129 130The stack map ID allows a runtime to locate the desired stack map 131record. LLVM passes this ID through directly to the stack map 132record without checking uniqueness. 133 134LLVM guarantees a shadow of instructions following the stack map's 135instruction offset during which neither the end of the basic block nor 136another call to ``llvm.experimental.stackmap`` or 137``llvm.experimental.patchpoint`` may occur. This allows the runtime to 138patch the code at this point in response to an event triggered from 139outside the code. The code for instructions following the stack map 140may be emitted in the stack map's shadow, and these instructions may 141be overwritten by destructive patching. Without shadow bytes, this 142destructive patching could overwrite program text or data outside the 143current function. We disallow overlapping stack map shadows so that 144the runtime does not need to consider this corner case. 145 146For example, a stack map with 8 byte shadow: 147 148.. code-block:: llvm 149 150 call void @runtime() 151 call void (i64, i32, ...)* @llvm.experimental.stackmap(i64 77, i32 8, 152 i64* %ptr) 153 %val = load i64* %ptr 154 %add = add i64 %val, 3 155 ret i64 %add 156 157May require one byte of nop-padding: 158 159.. code-block:: none 160 161 0x00 callq _runtime 162 0x05 nop <--- stack map address 163 0x06 movq (%rdi), %rax 164 0x07 addq $3, %rax 165 0x0a popq %rdx 166 0x0b ret <---- end of 8-byte shadow 167 168Now, if the runtime needs to invalidate the compiled code, it may 169patch 8 bytes of code at the stack map's address at follows: 170 171.. code-block:: none 172 173 0x00 callq _runtime 174 0x05 movl $0xffff, %rax <--- patched code at stack map address 175 0x0a callq *%rax <---- end of 8-byte shadow 176 177This way, after the normal call to the runtime returns, the code will 178execute a patched call to a special entry point that can rebuild a 179stack frame from the values located by the stack map. 180 181'``llvm.experimental.patchpoint.*``' Intrinsic 182^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ 183 184Syntax: 185""""""" 186 187:: 188 189 declare void 190 @llvm.experimental.patchpoint.void(i64 <id>, i32 <numBytes>, 191 i8* <target>, i32 <numArgs>, ...) 192 declare i64 193 @llvm.experimental.patchpoint.i64(i64 <id>, i32 <numBytes>, 194 i8* <target>, i32 <numArgs>, ...) 195 196Overview: 197""""""""" 198 199The '``llvm.experimental.patchpoint.*``' intrinsics creates a function 200call to the specified ``<target>`` and records the location of specified 201values in the stack map. 202 203Operands: 204""""""""" 205 206The first operand is an ID, the second operand is the number of bytes 207reserved for the patchable region, the third operand is the target 208address of a function (optionally null), and the fourth operand 209specifies how many of the following variable operands are considered 210function call arguments. The remaining variable number of operands are 211the ``live values`` for which locations will be recorded in the stack 212map. 213 214Semantics: 215"""""""""" 216 217The patch point intrinsic generates a stack map. It also emits a 218function call to the address specified by ``<target>`` if the address 219is not a constant null. The function call and its arguments are 220lowered according to the calling convention specified at the 221intrinsic's callsite. Variants of the intrinsic with non-void return 222type also return a value according to calling convention. 223 224On PowerPC, note that ``<target>`` must be the ABI function pointer for the 225intended target of the indirect call. Specifically, when compiling for the 226ELF V1 ABI, ``<target>`` is the function-descriptor address normally used as 227the C/C++ function-pointer representation. 228 229Requesting zero patch point arguments is valid. In this case, all 230variable operands are handled just like 231``llvm.experimental.stackmap.*``. The difference is that space will 232still be reserved for patching, a call will be emitted, and a return 233value is allowed. 234 235The location of the arguments are not normally recorded in the stack 236map because they are already fixed by the calling convention. The 237remaining ``live values`` will have their location recorded, which 238could be a register, stack location, or constant. A special calling 239convention has been introduced for use with stack maps, anyregcc, 240which forces the arguments to be loaded into registers but allows 241those register to be dynamically allocated. These argument registers 242will have their register locations recorded in the stack map in 243addition to the remaining ``live values``. 244 245The patch point also emits nops to cover at least ``<numBytes>`` of 246instruction encoding space. Hence, the client must ensure that 247``<numBytes>`` is enough to encode a call to the target address on the 248supported targets. If the call target is constant null, then there is 249no minimum requirement. A zero-byte null target patchpoint is 250valid. 251 252The runtime may patch the code emitted for the patch point, including 253the call sequence and nops. However, the runtime may not assume 254anything about the code LLVM emits within the reserved space. Partial 255patching is not allowed. The runtime must patch all reserved bytes, 256padding with nops if necessary. 257 258This example shows a patch point reserving 15 bytes, with one argument 259in $rdi, and a return value in $rax per native calling convention: 260 261.. code-block:: llvm 262 263 %target = inttoptr i64 -281474976710654 to i8* 264 %val = call i64 (i64, i32, ...)* 265 @llvm.experimental.patchpoint.i64(i64 78, i32 15, 266 i8* %target, i32 1, i64* %ptr) 267 %add = add i64 %val, 3 268 ret i64 %add 269 270May generate: 271 272.. code-block:: none 273 274 0x00 movabsq $0xffff000000000002, %r11 <--- patch point address 275 0x0a callq *%r11 276 0x0d nop 277 0x0e nop <--- end of reserved 15-bytes 278 0x0f addq $0x3, %rax 279 0x10 movl %rax, 8(%rsp) 280 281Note that no stack map locations will be recorded. If the patched code 282sequence does not need arguments fixed to specific calling convention 283registers, then the ``anyregcc`` convention may be used: 284 285.. code-block:: none 286 287 %val = call anyregcc @llvm.experimental.patchpoint(i64 78, i32 15, 288 i8* %target, i32 1, 289 i64* %ptr) 290 291The stack map now indicates the location of the %ptr argument and 292return value: 293 294.. code-block:: none 295 296 Stack Map: ID=78, Loc0=%r9 Loc1=%r8 297 298The patch code sequence may now use the argument that happened to be 299allocated in %r8 and return a value allocated in %r9: 300 301.. code-block:: none 302 303 0x00 movslq 4(%r8) %r9 <--- patched code at patch point address 304 0x03 nop 305 ... 306 0x0e nop <--- end of reserved 15-bytes 307 0x0f addq $0x3, %r9 308 0x10 movl %r9, 8(%rsp) 309 310.. _stackmap-format: 311 312Stack Map Format 313================ 314 315The existence of a stack map or patch point intrinsic within an LLVM 316Module forces code emission to create a :ref:`stackmap-section`. The 317format of this section follows: 318 319.. code-block:: none 320 321 Header { 322 uint8 : Stack Map Version (current version is 3) 323 uint8 : Reserved (expected to be 0) 324 uint16 : Reserved (expected to be 0) 325 } 326 uint32 : NumFunctions 327 uint32 : NumConstants 328 uint32 : NumRecords 329 StkSizeRecord[NumFunctions] { 330 uint64 : Function Address 331 uint64 : Stack Size 332 uint64 : Record Count 333 } 334 Constants[NumConstants] { 335 uint64 : LargeConstant 336 } 337 StkMapRecord[NumRecords] { 338 uint64 : PatchPoint ID 339 uint32 : Instruction Offset 340 uint16 : Reserved (record flags) 341 uint16 : NumLocations 342 Location[NumLocations] { 343 uint8 : Register | Direct | Indirect | Constant | ConstantIndex 344 uint8 : Reserved (expected to be 0) 345 uint16 : Location Size 346 uint16 : Dwarf RegNum 347 uint16 : Reserved (expected to be 0) 348 int32 : Offset or SmallConstant 349 } 350 uint32 : Padding (only if required to align to 8 byte) 351 uint16 : Padding 352 uint16 : NumLiveOuts 353 LiveOuts[NumLiveOuts] 354 uint16 : Dwarf RegNum 355 uint8 : Reserved 356 uint8 : Size in Bytes 357 } 358 uint32 : Padding (only if required to align to 8 byte) 359 } 360 361The first byte of each location encodes a type that indicates how to 362interpret the ``RegNum`` and ``Offset`` fields as follows: 363 364======== ========== =================== =========================== 365Encoding Type Value Description 366-------- ---------- ------------------- --------------------------- 3670x1 Register Reg Value in a register 3680x2 Direct Reg + Offset Frame index value 3690x3 Indirect [Reg + Offset] Spilled value 3700x4 Constant Offset Small constant 3710x5 ConstIndex Constants[Offset] Large constant 372======== ========== =================== =========================== 373 374In the common case, a value is available in a register, and the 375``Offset`` field will be zero. Values spilled to the stack are encoded 376as ``Indirect`` locations. The runtime must load those values from a 377stack address, typically in the form ``[BP + Offset]``. If an 378``alloca`` value is passed directly to a stack map intrinsic, then 379LLVM may fold the frame index into the stack map as an optimization to 380avoid allocating a register or stack slot. These frame indices will be 381encoded as ``Direct`` locations in the form ``BP + Offset``. LLVM may 382also optimize constants by emitting them directly in the stack map, 383either in the ``Offset`` of a ``Constant`` location or in the constant 384pool, referred to by ``ConstantIndex`` locations. 385 386At each callsite, a "liveout" register list is also recorded. These 387are the registers that are live across the stackmap and therefore must 388be saved by the runtime. This is an important optimization when the 389patchpoint intrinsic is used with a calling convention that by default 390preserves most registers as callee-save. 391 392Each entry in the liveout register list contains a DWARF register 393number and size in bytes. The stackmap format deliberately omits 394specific subregister information. Instead the runtime must interpret 395this information conservatively. For example, if the stackmap reports 396one byte at ``%rax``, then the value may be in either ``%al`` or 397``%ah``. It doesn't matter in practice, because the runtime will 398simply save ``%rax``. However, if the stackmap reports 16 bytes at 399``%ymm0``, then the runtime can safely optimize by saving only 400``%xmm0``. 401 402The stack map format is a contract between an LLVM SVN revision and 403the runtime. It is currently experimental and may change in the short 404term, but minimizing the need to update the runtime is 405important. Consequently, the stack map design is motivated by 406simplicity and extensibility. Compactness of the representation is 407secondary because the runtime is expected to parse the data 408immediately after compiling a module and encode the information in its 409own format. Since the runtime controls the allocation of sections, it 410can reuse the same stack map space for multiple modules. 411 412Stackmap support is currently only implemented for 64-bit 413platforms. However, a 32-bit implementation should be able to use the 414same format with an insignificant amount of wasted space. 415 416.. _stackmap-section: 417 418Stack Map Section 419^^^^^^^^^^^^^^^^^ 420 421A JIT compiler can easily access this section by providing its own 422memory manager via the LLVM C API 423``LLVMCreateSimpleMCJITMemoryManager()``. When creating the memory 424manager, the JIT provides a callback: 425``LLVMMemoryManagerAllocateDataSectionCallback()``. When LLVM creates 426this section, it invokes the callback and passes the section name. The 427JIT can record the in-memory address of the section at this time and 428later parse it to recover the stack map data. 429 430On Darwin, the stack map section name is "__llvm_stackmaps". The 431segment name is "__LLVM_STACKMAPS". 432 433Stack Map Usage 434=============== 435 436The stack map support described in this document can be used to 437precisely determine the location of values at a specific position in 438the code. LLVM does not maintain any mapping between those values and 439any higher-level entity. The runtime must be able to interpret the 440stack map record given only the ID, offset, and the order of the 441locations, records, and functions, which LLVM preserves. 442 443Note that this is quite different from the goal of debug information, 444which is a best-effort attempt to track the location of named 445variables at every instruction. 446 447An important motivation for this design is to allow a runtime to 448commandeer a stack frame when execution reaches an instruction address 449associated with a stack map. The runtime must be able to rebuild a 450stack frame and resume program execution using the information 451provided by the stack map. For example, execution may resume in an 452interpreter or a recompiled version of the same function. 453 454This usage restricts LLVM optimization. Clearly, LLVM must not move 455stores across a stack map. However, loads must also be handled 456conservatively. If the load may trigger an exception, hoisting it 457above a stack map could be invalid. For example, the runtime may 458determine that a load is safe to execute without a type check given 459the current state of the type system. If the type system changes while 460some activation of the load's function exists on the stack, the load 461becomes unsafe. The runtime can prevent subsequent execution of that 462load by immediately patching any stack map location that lies between 463the current call site and the load (typically, the runtime would 464simply patch all stack map locations to invalidate the function). If 465the compiler had hoisted the load above the stack map, then the 466program could crash before the runtime could take back control. 467 468To enforce these semantics, stackmap and patchpoint intrinsics are 469considered to potentially read and write all memory. This may limit 470optimization more than some clients desire. This limitation may be 471avoided by marking the call site as "readonly". In the future we may 472also allow meta-data to be added to the intrinsic call to express 473aliasing, thereby allowing optimizations to hoist certain loads above 474stack maps. 475 476Direct Stack Map Entries 477^^^^^^^^^^^^^^^^^^^^^^^^ 478 479As shown in :ref:`stackmap-section`, a Direct stack map location 480records the address of frame index. This address is itself the value 481that the runtime requested. This differs from Indirect locations, 482which refer to a stack locations from which the requested values must 483be loaded. Direct locations can communicate the address if an alloca, 484while Indirect locations handle register spills. 485 486For example: 487 488.. code-block:: none 489 490 entry: 491 %a = alloca i64... 492 llvm.experimental.stackmap(i64 <ID>, i32 <shadowBytes>, i64* %a) 493 494The runtime can determine this alloca's relative location on the 495stack immediately after compilation, or at any time thereafter. This 496differs from Register and Indirect locations, because the runtime can 497only read the values in those locations when execution reaches the 498instruction address of the stack map. 499 500This functionality requires LLVM to treat entry-block allocas 501specially when they are directly consumed by an intrinsics. (This is 502the same requirement imposed by the llvm.gcroot intrinsic.) LLVM 503transformations must not substitute the alloca with any intervening 504value. This can be verified by the runtime simply by checking that the 505stack map's location is a Direct location type. 506 507 508Supported Architectures 509======================= 510 511Support for StackMap generation and the related intrinsics requires 512some code for each backend. Today, only a subset of LLVM's backends 513are supported. The currently supported architectures are X86_64, 514PowerPC, and Aarch64. 515