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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