Python/jit.c - external/github.com/python/cpython - Git at Google

 #ifdef _Py_JIT

 #include "Python.h"

 #include "pycore_abstract.h"
 #include "pycore_bitutils.h"
 #include "pycore_call.h"
 #include "pycore_ceval.h"
 #include "pycore_critical_section.h"
 #include "pycore_dict.h"
 #include "pycore_floatobject.h"
 #include "pycore_frame.h"
 #include "pycore_function.h"
 #include "pycore_interpframe.h"
 #include "pycore_interpolation.h"
 #include "pycore_intrinsics.h"
 #include "pycore_list.h"
 #include "pycore_long.h"
 #include "pycore_opcode_metadata.h"
 #include "pycore_opcode_utils.h"
 #include "pycore_optimizer.h"
 #include "pycore_pyerrors.h"
 #include "pycore_setobject.h"
 #include "pycore_sliceobject.h"
 #include "pycore_template.h"
 #include "pycore_tuple.h"
 #include "pycore_unicodeobject.h"

 #include "pycore_jit.h"

 // Memory management stuff: ////////////////////////////////////////////////////

 #ifndef MS_WINDOWS
     #include <sys/mman.h>
 #endif

 static size_t
 get_page_size(void)
 {
 #ifdef MS_WINDOWS
     SYSTEM_INFO si;
     GetSystemInfo(&si);
     return si.dwPageSize;
 #else
     return sysconf(_SC_PAGESIZE);
 #endif
 }

 static void
 jit_error(const char *message)
 {
 #ifdef MS_WINDOWS
     int hint = GetLastError();
 #else
     int hint = errno;
 #endif
     PyErr_Format(PyExc_RuntimeWarning, "JIT %s (%d)", message, hint);
 }

 static unsigned char *
 jit_alloc(size_t size)
 {
     assert(size);
     assert(size % get_page_size() == 0);
 #ifdef MS_WINDOWS
     int flags = MEM_COMMIT | MEM_RESERVE;
     unsigned char *memory = VirtualAlloc(NULL, size, flags, PAGE_READWRITE);
     int failed = memory == NULL;
 #else
     int flags = MAP_ANONYMOUS | MAP_PRIVATE;
     int prot = PROT_READ | PROT_WRITE;
 # ifdef MAP_JIT
     flags |= MAP_JIT;
     prot |= PROT_EXEC;
 # endif
     unsigned char *memory = mmap(NULL, size, prot, flags, -1, 0);
     int failed = memory == MAP_FAILED;
 #endif
     if (failed) {
         jit_error("unable to allocate memory");
         return NULL;
     }
     return memory;
 }

 static int
 jit_free(unsigned char *memory, size_t size)
 {
     assert(size);
     assert(size % get_page_size() == 0);
 #ifdef MS_WINDOWS
     int failed = !VirtualFree(memory, 0, MEM_RELEASE);
 #else
     int failed = munmap(memory, size);
 #endif
     if (failed) {
         jit_error("unable to free memory");
         return -1;
     }
     OPT_STAT_ADD(jit_freed_memory_size, size);
     return 0;
 }

 static int
 mark_executable(unsigned char *memory, size_t size)
 {
     if (size == 0) {
         return 0;
     }
     assert(size % get_page_size() == 0);
     // Do NOT ever leave the memory writable! Also, don't forget to flush the
     // i-cache (I cannot begin to tell you how horrible that is to debug):
 #ifdef MS_WINDOWS
     if (!FlushInstructionCache(GetCurrentProcess(), memory, size)) {
         jit_error("unable to flush instruction cache");
         return -1;
     }
     int old;
     int failed = !VirtualProtect(memory, size, PAGE_EXECUTE_READ, &old);
 #else
     int failed = 0;
     __builtin___clear_cache((char *)memory, (char *)memory + size);
 #ifndef MAP_JIT
     failed = mprotect(memory, size, PROT_EXEC | PROT_READ);
 #endif
 #endif
     if (failed) {
         jit_error("unable to protect executable memory");
         return -1;
     }
     return 0;
 }

 // JIT compiler stuff: /////////////////////////////////////////////////////////

 #define SYMBOL_MASK_WORDS 4

 typedef uint32_t symbol_mask[SYMBOL_MASK_WORDS];

 typedef struct {
     unsigned char *mem;
     symbol_mask mask;
     size_t size;
 } trampoline_state;

 typedef struct {
     trampoline_state trampolines;
     uintptr_t instruction_starts[UOP_MAX_TRACE_LENGTH];
 } jit_state;

 // Warning! AArch64 requires you to get your hands dirty. These are your gloves:

 // value[value_start : value_start + len]
 static uint32_t
 get_bits(uint64_t value, uint8_t value_start, uint8_t width)
 {
     assert(width <= 32);
     return (value >> value_start) & ((1ULL << width) - 1);
 }

 // *loc[loc_start : loc_start + width] = value[value_start : value_start + width]
 static void
 set_bits(uint32_t *loc, uint8_t loc_start, uint64_t value, uint8_t value_start,
          uint8_t width)
 {
     assert(loc_start + width <= 32);
     // Clear the bits we're about to patch:
     *loc &= ~(((1ULL << width) - 1) << loc_start);
     assert(get_bits(*loc, loc_start, width) == 0);
     // Patch the bits:
     *loc |= get_bits(value, value_start, width) << loc_start;
     assert(get_bits(*loc, loc_start, width) == get_bits(value, value_start, width));
 }

 // See https://developer.arm.com/documentation/ddi0602/2023-09/Base-Instructions
 // for instruction encodings:
 #define IS_AARCH64_ADD_OR_SUB(I) (((I) & 0x11C00000) == 0x11000000)
 #define IS_AARCH64_ADRP(I)       (((I) & 0x9F000000) == 0x90000000)
 #define IS_AARCH64_BRANCH(I)     (((I) & 0x7C000000) == 0x14000000)
 #define IS_AARCH64_LDR_OR_STR(I) (((I) & 0x3B000000) == 0x39000000)
 #define IS_AARCH64_MOV(I)        (((I) & 0x9F800000) == 0x92800000)

 // LLD is a great reference for performing relocations... just keep in
 // mind that Tools/jit/build.py does filtering and preprocessing for us!
 // Here's a good place to start for each platform:
 // - aarch64-apple-darwin:
 //   - https://github.com/llvm/llvm-project/blob/main/lld/MachO/Arch/ARM64.cpp
 //   - https://github.com/llvm/llvm-project/blob/main/lld/MachO/Arch/ARM64Common.cpp
 //   - https://github.com/llvm/llvm-project/blob/main/lld/MachO/Arch/ARM64Common.h
 // - aarch64-pc-windows-msvc:
 //   - https://github.com/llvm/llvm-project/blob/main/lld/COFF/Chunks.cpp
 // - aarch64-unknown-linux-gnu:
 //   - https://github.com/llvm/llvm-project/blob/main/lld/ELF/Arch/AArch64.cpp
 // - i686-pc-windows-msvc:
 //   - https://github.com/llvm/llvm-project/blob/main/lld/COFF/Chunks.cpp
 // - x86_64-apple-darwin:
 //   - https://github.com/llvm/llvm-project/blob/main/lld/MachO/Arch/X86_64.cpp
 // - x86_64-pc-windows-msvc:
 //   - https://github.com/llvm/llvm-project/blob/main/lld/COFF/Chunks.cpp
 // - x86_64-unknown-linux-gnu:
 //   - https://github.com/llvm/llvm-project/blob/main/lld/ELF/Arch/X86_64.cpp

 // Many of these patches are "relaxing", meaning that they can rewrite the
 // code they're patching to be more efficient (like turning a 64-bit memory
 // load into a 32-bit immediate load). These patches have an "x" in their name.
 // Relative patches have an "r" in their name.

 // 32-bit absolute address.
 void
 patch_32(unsigned char *location, uint64_t value)
 {
     uint32_t *loc32 = (uint32_t *)location;
     // Check that we're not out of range of 32 unsigned bits:
     assert(value < (1ULL << 32));
     *loc32 = (uint32_t)value;
 }

 // 32-bit relative address.
 void
 patch_32r(unsigned char *location, uint64_t value)
 {
     uint32_t *loc32 = (uint32_t *)location;
     value -= (uintptr_t)location;
     // Check that we're not out of range of 32 signed bits:
     assert((int64_t)value >= -(1LL << 31));
     assert((int64_t)value < (1LL << 31));
     *loc32 = (uint32_t)value;
 }

 // 64-bit absolute address.
 void
 patch_64(unsigned char *location, uint64_t value)
 {
     uint64_t *loc64 = (uint64_t *)location;
     *loc64 = value;
 }

 // 12-bit low part of an absolute address. Pairs nicely with patch_aarch64_21r
 // (below).
 void
 patch_aarch64_12(unsigned char *location, uint64_t value)
 {
     uint32_t *loc32 = (uint32_t *)location;
     assert(IS_AARCH64_LDR_OR_STR(*loc32) || IS_AARCH64_ADD_OR_SUB(*loc32));
     // There might be an implicit shift encoded in the instruction:
     uint8_t shift = 0;
     if (IS_AARCH64_LDR_OR_STR(*loc32)) {
         shift = (uint8_t)get_bits(*loc32, 30, 2);
         // If both of these are set, the shift is supposed to be 4.
         // That's pretty weird, and it's never actually been observed...
         assert(get_bits(*loc32, 23, 1) == 0 || get_bits(*loc32, 26, 1) == 0);
     }
     value = get_bits(value, 0, 12);
     assert(get_bits(value, 0, shift) == 0);
     set_bits(loc32, 10, value, shift, 12);
 }

 // Relaxable 12-bit low part of an absolute address. Pairs nicely with
 // patch_aarch64_21rx (below).
 void
 patch_aarch64_12x(unsigned char *location, uint64_t value)
 {
     // This can *only* be relaxed if it occurs immediately before a matching
     // patch_aarch64_21rx. If that happens, the JIT build step will replace both
     // calls with a single call to patch_aarch64_33rx. Otherwise, we end up
     // here, and the instruction is patched normally:
     patch_aarch64_12(location, value);
 }

 // 16-bit low part of an absolute address.
 void
 patch_aarch64_16a(unsigned char *location, uint64_t value)
 {
     uint32_t *loc32 = (uint32_t *)location;
     assert(IS_AARCH64_MOV(*loc32));
     // Check the implicit shift (this is "part 0 of 3"):
     assert(get_bits(*loc32, 21, 2) == 0);
     set_bits(loc32, 5, value, 0, 16);
 }

 // 16-bit middle-low part of an absolute address.
 void
 patch_aarch64_16b(unsigned char *location, uint64_t value)
 {
     uint32_t *loc32 = (uint32_t *)location;
     assert(IS_AARCH64_MOV(*loc32));
     // Check the implicit shift (this is "part 1 of 3"):
     assert(get_bits(*loc32, 21, 2) == 1);
     set_bits(loc32, 5, value, 16, 16);
 }

 // 16-bit middle-high part of an absolute address.
 void
 patch_aarch64_16c(unsigned char *location, uint64_t value)
 {
     uint32_t *loc32 = (uint32_t *)location;
     assert(IS_AARCH64_MOV(*loc32));
     // Check the implicit shift (this is "part 2 of 3"):
     assert(get_bits(*loc32, 21, 2) == 2);
     set_bits(loc32, 5, value, 32, 16);
 }

 // 16-bit high part of an absolute address.
 void
 patch_aarch64_16d(unsigned char *location, uint64_t value)
 {
     uint32_t *loc32 = (uint32_t *)location;
     assert(IS_AARCH64_MOV(*loc32));
     // Check the implicit shift (this is "part 3 of 3"):
     assert(get_bits(*loc32, 21, 2) == 3);
     set_bits(loc32, 5, value, 48, 16);
 }

 // 21-bit count of pages between this page and an absolute address's page... I
 // know, I know, it's weird. Pairs nicely with patch_aarch64_12 (above).
 void
 patch_aarch64_21r(unsigned char *location, uint64_t value)
 {
     uint32_t *loc32 = (uint32_t *)location;
     value = (value >> 12) - ((uintptr_t)location >> 12);
     // Check that we're not out of range of 21 signed bits:
     assert((int64_t)value >= -(1 << 20));
     assert((int64_t)value < (1 << 20));
     // value[0:2] goes in loc[29:31]:
     set_bits(loc32, 29, value, 0, 2);
     // value[2:21] goes in loc[5:26]:
     set_bits(loc32, 5, value, 2, 19);
 }

 // Relaxable 21-bit count of pages between this page and an absolute address's
 // page. Pairs nicely with patch_aarch64_12x (above).
 void
 patch_aarch64_21rx(unsigned char *location, uint64_t value)
 {
     // This can *only* be relaxed if it occurs immediately before a matching
     // patch_aarch64_12x. If that happens, the JIT build step will replace both
     // calls with a single call to patch_aarch64_33rx. Otherwise, we end up
     // here, and the instruction is patched normally:
     patch_aarch64_21r(location, value);
 }

 // 28-bit relative branch.
 void
 patch_aarch64_26r(unsigned char *location, uint64_t value)
 {
     uint32_t *loc32 = (uint32_t *)location;
     assert(IS_AARCH64_BRANCH(*loc32));
     value -= (uintptr_t)location;
     // Check that we're not out of range of 28 signed bits:
     assert((int64_t)value >= -(1 << 27));
     assert((int64_t)value < (1 << 27));
     // Since instructions are 4-byte aligned, only use 26 bits:
     assert(get_bits(value, 0, 2) == 0);
     set_bits(loc32, 0, value, 2, 26);
 }

 // A pair of patch_aarch64_21rx and patch_aarch64_12x.
 void
 patch_aarch64_33rx(unsigned char *location, uint64_t value)
 {
     uint32_t *loc32 = (uint32_t *)location;
     // Try to relax the pair of GOT loads into an immediate value:
     assert(IS_AARCH64_ADRP(*loc32));
     unsigned char reg = get_bits(loc32[0], 0, 5);
     assert(IS_AARCH64_LDR_OR_STR(loc32[1]));
     // There should be only one register involved:
     assert(reg == get_bits(loc32[1], 0, 5));  // ldr's output register.
     assert(reg == get_bits(loc32[1], 5, 5));  // ldr's input register.
     uint64_t relaxed = *(uint64_t *)value;
     if (relaxed < (1UL << 16)) {
         // adrp reg, AAA; ldr reg, [reg + BBB] -> movz reg, XXX; nop
         loc32[0] = 0xD2800000 | (get_bits(relaxed, 0, 16) << 5) | reg;
         loc32[1] = 0xD503201F;
         return;
     }
     if (relaxed < (1ULL << 32)) {
         // adrp reg, AAA; ldr reg, [reg + BBB] -> movz reg, XXX; movk reg, YYY
         loc32[0] = 0xD2800000 | (get_bits(relaxed,  0, 16) << 5) | reg;
         loc32[1] = 0xF2A00000 | (get_bits(relaxed, 16, 16) << 5) | reg;
         return;
     }
     relaxed = value - (uintptr_t)location;
     if ((relaxed & 0x3) == 0 &&
         (int64_t)relaxed >= -(1L << 19) &&
         (int64_t)relaxed < (1L << 19))
     {
         // adrp reg, AAA; ldr reg, [reg + BBB] -> ldr reg, XXX; nop
         loc32[0] = 0x58000000 | (get_bits(relaxed, 2, 19) << 5) | reg;
         loc32[1] = 0xD503201F;
         return;
     }
     // Couldn't do it. Just patch the two instructions normally:
     patch_aarch64_21rx(location, value);
     patch_aarch64_12x(location + 4, value);
 }

 // Relaxable 32-bit relative address.
 void
 patch_x86_64_32rx(unsigned char *location, uint64_t value)
 {
     uint8_t *loc8 = (uint8_t *)location;
     // Try to relax the GOT load into an immediate value:
     uint64_t relaxed = *(uint64_t *)(value + 4) - 4;
     if ((int64_t)relaxed - (int64_t)location >= -(1LL << 31) &&
         (int64_t)relaxed - (int64_t)location + 1 < (1LL << 31))
     {
         if (loc8[-2] == 0x8B) {
             // mov reg, dword ptr [rip + AAA] -> lea reg, [rip + XXX]
             loc8[-2] = 0x8D;
             value = relaxed;
         }
         else if (loc8[-2] == 0xFF && loc8[-1] == 0x15) {
             // call qword ptr [rip + AAA] -> nop; call XXX
             loc8[-2] = 0x90;
             loc8[-1] = 0xE8;
             value = relaxed;
         }
         else if (loc8[-2] == 0xFF && loc8[-1] == 0x25) {
             // jmp qword ptr [rip + AAA] -> nop; jmp XXX
             loc8[-2] = 0x90;
             loc8[-1] = 0xE9;
             value = relaxed;
         }
     }
     patch_32r(location, value);
 }

 void patch_aarch64_trampoline(unsigned char *location, int ordinal, jit_state *state);

 #include "jit_stencils.h"

 #if defined(__aarch64__) || defined(_M_ARM64)
     #define TRAMPOLINE_SIZE 16
 #else
     #define TRAMPOLINE_SIZE 0
 #endif

 // Generate and patch AArch64 trampolines. The symbols to jump to are stored
 // in the jit_stencils.h in the symbols_map.
 void
 patch_aarch64_trampoline(unsigned char *location, int ordinal, jit_state *state)
 {

     uint64_t value = (uintptr_t)symbols_map[ordinal];
     int64_t range = value - (uintptr_t)location;

     // If we are in range of 28 signed bits, we patch the instruction with
     // the address of the symbol.
     if (range >= -(1 << 27) && range < (1 << 27)) {
         patch_aarch64_26r(location, (uintptr_t)value);
         return;
     }

     // Masking is done modulo 32 as the mask is stored as an array of uint32_t
     const uint32_t symbol_mask = 1 << (ordinal % 32);
     const uint32_t trampoline_mask = state->trampolines.mask[ordinal / 32];
     assert(symbol_mask & trampoline_mask);

     // Count the number of set bits in the trampoline mask lower than ordinal,
     // this gives the index into the array of trampolines.
     int index = _Py_popcount32(trampoline_mask & (symbol_mask - 1));
     for (int i = 0; i < ordinal / 32; i++) {
         index += _Py_popcount32(state->trampolines.mask[i]);
     }

     uint32_t *p = (uint32_t*)(state->trampolines.mem + index * TRAMPOLINE_SIZE);
     assert((size_t)(index + 1) * TRAMPOLINE_SIZE <= state->trampolines.size);


     /* Generate the trampoline
        0: 58000048      ldr     x8, 8
        4: d61f0100      br      x8
        8: 00000000      // The next two words contain the 64-bit address to jump to.
        c: 00000000
     */
     p[0] = 0x58000048;
     p[1] = 0xD61F0100;
     p[2] = value & 0xffffffff;
     p[3] = value >> 32;

     patch_aarch64_26r(location, (uintptr_t)p);
 }

 static void
 combine_symbol_mask(const symbol_mask src, symbol_mask dest)
 {
     // Calculate the union of the trampolines required by each StencilGroup
     for (size_t i = 0; i < SYMBOL_MASK_WORDS; i++) {
         dest[i] |= src[i];
     }
 }

 // Compiles executor in-place. Don't forget to call _PyJIT_Free later!
 int
 _PyJIT_Compile(_PyExecutorObject *executor, const _PyUOpInstruction trace[], size_t length)
 {
     const StencilGroup *group;
     // Loop once to find the total compiled size:
     size_t code_size = 0;
     size_t data_size = 0;
     jit_state state = {0};
     group = &shim;
     code_size += group->code_size;
     data_size += group->data_size;
     combine_symbol_mask(group->trampoline_mask, state.trampolines.mask);
     for (size_t i = 0; i < length; i++) {
         const _PyUOpInstruction *instruction = &trace[i];
         group = &stencil_groups[instruction->opcode];
         state.instruction_starts[i] = code_size;
         code_size += group->code_size;
         data_size += group->data_size;
         combine_symbol_mask(group->trampoline_mask, state.trampolines.mask);
     }
     group = &stencil_groups[_FATAL_ERROR];
     code_size += group->code_size;
     data_size += group->data_size;
     combine_symbol_mask(group->trampoline_mask, state.trampolines.mask);
     // Calculate the size of the trampolines required by the whole trace
     for (size_t i = 0; i < Py_ARRAY_LENGTH(state.trampolines.mask); i++) {
         state.trampolines.size += _Py_popcount32(state.trampolines.mask[i]) * TRAMPOLINE_SIZE;
     }
     // Round up to the nearest page:
     size_t page_size = get_page_size();
     assert((page_size & (page_size - 1)) == 0);
     size_t padding = page_size - ((code_size + state.trampolines.size + data_size) & (page_size - 1));
     size_t total_size = code_size + state.trampolines.size + data_size  + padding;
     unsigned char *memory = jit_alloc(total_size);
     if (memory == NULL) {
         return -1;
     }
 #ifdef MAP_JIT
     pthread_jit_write_protect_np(0);
 #endif
     // Collect memory stats
     OPT_STAT_ADD(jit_total_memory_size, total_size);
     OPT_STAT_ADD(jit_code_size, code_size);
     OPT_STAT_ADD(jit_trampoline_size, state.trampolines.size);
     OPT_STAT_ADD(jit_data_size, data_size);
     OPT_STAT_ADD(jit_padding_size, padding);
     OPT_HIST(total_size, trace_total_memory_hist);
     // Update the offsets of each instruction:
     for (size_t i = 0; i < length; i++) {
         state.instruction_starts[i] += (uintptr_t)memory;
     }
     // Loop again to emit the code:
     unsigned char *code = memory;
     state.trampolines.mem = memory + code_size;
     unsigned char *data = memory + code_size + state.trampolines.size;
     // Compile the shim, which handles converting between the native
     // calling convention and the calling convention used by jitted code
     // (which may be different for efficiency reasons).
     group = &shim;
     group->emit(code, data, executor, NULL, &state);
     code += group->code_size;
     data += group->data_size;
     assert(trace[0].opcode == _START_EXECUTOR);
     for (size_t i = 0; i < length; i++) {
         const _PyUOpInstruction *instruction = &trace[i];
         group = &stencil_groups[instruction->opcode];
         group->emit(code, data, executor, instruction, &state);
         code += group->code_size;
         data += group->data_size;
     }
     // Protect against accidental buffer overrun into data:
     group = &stencil_groups[_FATAL_ERROR];
     group->emit(code, data, executor, NULL, &state);
     code += group->code_size;
     data += group->data_size;
     assert(code == memory + code_size);
     assert(data == memory + code_size + state.trampolines.size + data_size);
 #ifdef MAP_JIT
     pthread_jit_write_protect_np(1);
 #endif
     if (mark_executable(memory, total_size)) {
         jit_free(memory, total_size);
         return -1;
     }
     executor->jit_code = memory;
     executor->jit_side_entry = memory + shim.code_size;
     executor->jit_size = total_size;
     return 0;
 }

 void
 _PyJIT_Free(_PyExecutorObject *executor)
 {
     unsigned char *memory = (unsigned char *)executor->jit_code;
     size_t size = executor->jit_size;
     if (memory) {
         executor->jit_code = NULL;
         executor->jit_side_entry = NULL;
         executor->jit_size = 0;
         if (jit_free(memory, size)) {
             PyErr_FormatUnraisable("Exception ignored while "
                                    "freeing JIT memory");
         }
     }
 }

 #endif  // _Py_JIT
	#ifdef _Py_JIT

	#include "Python.h"

	#include "pycore_abstract.h"
	#include "pycore_bitutils.h"
	#include "pycore_call.h"
	#include "pycore_ceval.h"
	#include "pycore_critical_section.h"
	#include "pycore_dict.h"
	#include "pycore_floatobject.h"
	#include "pycore_frame.h"
	#include "pycore_function.h"
	#include "pycore_interpframe.h"
	#include "pycore_interpolation.h"
	#include "pycore_intrinsics.h"
	#include "pycore_list.h"
	#include "pycore_long.h"
	#include "pycore_opcode_metadata.h"
	#include "pycore_opcode_utils.h"
	#include "pycore_optimizer.h"
	#include "pycore_pyerrors.h"
	#include "pycore_setobject.h"
	#include "pycore_sliceobject.h"
	#include "pycore_template.h"
	#include "pycore_tuple.h"
	#include "pycore_unicodeobject.h"

	#include "pycore_jit.h"

	// Memory management stuff: ////////////////////////////////////////////////////

	#ifndef MS_WINDOWS
	#include <sys/mman.h>
	#endif

	static size_t
	get_page_size(void)
	{
	#ifdef MS_WINDOWS
	SYSTEM_INFO si;
	GetSystemInfo(&si);
	return si.dwPageSize;
	#else
	return sysconf(_SC_PAGESIZE);
	#endif
	}

	static void
	jit_error(const char *message)
	{
	#ifdef MS_WINDOWS
	int hint = GetLastError();
	#else
	int hint = errno;
	#endif
	PyErr_Format(PyExc_RuntimeWarning, "JIT %s (%d)", message, hint);
	}

	static unsigned char *
	jit_alloc(size_t size)
	{
	assert(size);
	assert(size % get_page_size() == 0);
	#ifdef MS_WINDOWS
	int flags = MEM_COMMIT \| MEM_RESERVE;
	unsigned char *memory = VirtualAlloc(NULL, size, flags, PAGE_READWRITE);
	int failed = memory == NULL;
	#else
	int flags = MAP_ANONYMOUS \| MAP_PRIVATE;
	int prot = PROT_READ \| PROT_WRITE;
	# ifdef MAP_JIT
	flags \|= MAP_JIT;
	prot \|= PROT_EXEC;
	# endif
	unsigned char *memory = mmap(NULL, size, prot, flags, -1, 0);
	int failed = memory == MAP_FAILED;
	#endif
	if (failed) {
	jit_error("unable to allocate memory");
	return NULL;
	}
	return memory;
	}

	static int
	jit_free(unsigned char *memory, size_t size)
	{
	assert(size);
	assert(size % get_page_size() == 0);
	#ifdef MS_WINDOWS
	int failed = !VirtualFree(memory, 0, MEM_RELEASE);
	#else
	int failed = munmap(memory, size);
	#endif
	if (failed) {
	jit_error("unable to free memory");
	return -1;
	}
	OPT_STAT_ADD(jit_freed_memory_size, size);
	return 0;
	}

	static int
	mark_executable(unsigned char *memory, size_t size)
	{
	if (size == 0) {
	return 0;
	}
	assert(size % get_page_size() == 0);
	// Do NOT ever leave the memory writable! Also, don't forget to flush the
	// i-cache (I cannot begin to tell you how horrible that is to debug):
	#ifdef MS_WINDOWS
	if (!FlushInstructionCache(GetCurrentProcess(), memory, size)) {
	jit_error("unable to flush instruction cache");
	return -1;
	}
	int old;
	int failed = !VirtualProtect(memory, size, PAGE_EXECUTE_READ, &old);
	#else
	int failed = 0;
	__builtin___clear_cache((char )memory, (char )memory + size);
	#ifndef MAP_JIT
	failed = mprotect(memory, size, PROT_EXEC \| PROT_READ);
	#endif
	#endif
	if (failed) {
	jit_error("unable to protect executable memory");
	return -1;
	}
	return 0;
	}

	// JIT compiler stuff: /////////////////////////////////////////////////////////

	#define SYMBOL_MASK_WORDS 4

	typedef uint32_t symbol_mask[SYMBOL_MASK_WORDS];

	typedef struct {
	unsigned char *mem;
	symbol_mask mask;
	size_t size;
	} trampoline_state;

	typedef struct {
	trampoline_state trampolines;
	uintptr_t instruction_starts[UOP_MAX_TRACE_LENGTH];
	} jit_state;

	// Warning! AArch64 requires you to get your hands dirty. These are your gloves:

	// value[value_start : value_start + len]
	static uint32_t
	get_bits(uint64_t value, uint8_t value_start, uint8_t width)
	{
	assert(width <= 32);
	return (value >> value_start) & ((1ULL << width) - 1);
	}

	// *loc[loc_start : loc_start + width] = value[value_start : value_start + width]
	static void
	set_bits(uint32_t *loc, uint8_t loc_start, uint64_t value, uint8_t value_start,
	uint8_t width)
	{
	assert(loc_start + width <= 32);
	// Clear the bits we're about to patch:
	*loc &= ~(((1ULL << width) - 1) << loc_start);
	assert(get_bits(*loc, loc_start, width) == 0);
	// Patch the bits:
	*loc \|= get_bits(value, value_start, width) << loc_start;
	assert(get_bits(*loc, loc_start, width) == get_bits(value, value_start, width));
	}

	// See https://developer.arm.com/documentation/ddi0602/2023-09/Base-Instructions
	// for instruction encodings:
	#define IS_AARCH64_ADD_OR_SUB(I) (((I) & 0x11C00000) == 0x11000000)
	#define IS_AARCH64_ADRP(I) (((I) & 0x9F000000) == 0x90000000)
	#define IS_AARCH64_BRANCH(I) (((I) & 0x7C000000) == 0x14000000)
	#define IS_AARCH64_LDR_OR_STR(I) (((I) & 0x3B000000) == 0x39000000)
	#define IS_AARCH64_MOV(I) (((I) & 0x9F800000) == 0x92800000)

	// LLD is a great reference for performing relocations... just keep in
	// mind that Tools/jit/build.py does filtering and preprocessing for us!
	// Here's a good place to start for each platform:
	// - aarch64-apple-darwin:
	// - https://github.com/llvm/llvm-project/blob/main/lld/MachO/Arch/ARM64.cpp
	// - https://github.com/llvm/llvm-project/blob/main/lld/MachO/Arch/ARM64Common.cpp
	// - https://github.com/llvm/llvm-project/blob/main/lld/MachO/Arch/ARM64Common.h
	// - aarch64-pc-windows-msvc:
	// - https://github.com/llvm/llvm-project/blob/main/lld/COFF/Chunks.cpp
	// - aarch64-unknown-linux-gnu:
	// - https://github.com/llvm/llvm-project/blob/main/lld/ELF/Arch/AArch64.cpp
	// - i686-pc-windows-msvc:
	// - https://github.com/llvm/llvm-project/blob/main/lld/COFF/Chunks.cpp
	// - x86_64-apple-darwin:
	// - https://github.com/llvm/llvm-project/blob/main/lld/MachO/Arch/X86_64.cpp
	// - x86_64-pc-windows-msvc:
	// - https://github.com/llvm/llvm-project/blob/main/lld/COFF/Chunks.cpp
	// - x86_64-unknown-linux-gnu:
	// - https://github.com/llvm/llvm-project/blob/main/lld/ELF/Arch/X86_64.cpp

	// Many of these patches are "relaxing", meaning that they can rewrite the
	// code they're patching to be more efficient (like turning a 64-bit memory
	// load into a 32-bit immediate load). These patches have an "x" in their name.
	// Relative patches have an "r" in their name.

	// 32-bit absolute address.
	void
	patch_32(unsigned char *location, uint64_t value)
	{
	uint32_t loc32 = (uint32_t )location;
	// Check that we're not out of range of 32 unsigned bits:
	assert(value < (1ULL << 32));
	*loc32 = (uint32_t)value;
	}

	// 32-bit relative address.
	void
	patch_32r(unsigned char *location, uint64_t value)
	{
	uint32_t loc32 = (uint32_t )location;
	value -= (uintptr_t)location;
	// Check that we're not out of range of 32 signed bits:
	assert((int64_t)value >= -(1LL << 31));
	assert((int64_t)value < (1LL << 31));
	*loc32 = (uint32_t)value;
	}

	// 64-bit absolute address.
	void
	patch_64(unsigned char *location, uint64_t value)
	{
	uint64_t loc64 = (uint64_t )location;
	*loc64 = value;
	}

	// 12-bit low part of an absolute address. Pairs nicely with patch_aarch64_21r
	// (below).
	void
	patch_aarch64_12(unsigned char *location, uint64_t value)
	{
	uint32_t loc32 = (uint32_t )location;
	assert(IS_AARCH64_LDR_OR_STR(loc32) \|\| IS_AARCH64_ADD_OR_SUB(loc32));
	// There might be an implicit shift encoded in the instruction:
	uint8_t shift = 0;
	if (IS_AARCH64_LDR_OR_STR(*loc32)) {
	shift = (uint8_t)get_bits(*loc32, 30, 2);
	// If both of these are set, the shift is supposed to be 4.
	// That's pretty weird, and it's never actually been observed...
	assert(get_bits(loc32, 23, 1) == 0 \|\| get_bits(loc32, 26, 1) == 0);
	}
	value = get_bits(value, 0, 12);
	assert(get_bits(value, 0, shift) == 0);
	set_bits(loc32, 10, value, shift, 12);
	}

	// Relaxable 12-bit low part of an absolute address. Pairs nicely with
	// patch_aarch64_21rx (below).
	void
	patch_aarch64_12x(unsigned char *location, uint64_t value)
	{
	// This can only be relaxed if it occurs immediately before a matching
	// patch_aarch64_21rx. If that happens, the JIT build step will replace both
	// calls with a single call to patch_aarch64_33rx. Otherwise, we end up
	// here, and the instruction is patched normally:
	patch_aarch64_12(location, value);
	}

	// 16-bit low part of an absolute address.
	void
	patch_aarch64_16a(unsigned char *location, uint64_t value)
	{
	uint32_t loc32 = (uint32_t )location;
	assert(IS_AARCH64_MOV(*loc32));
	// Check the implicit shift (this is "part 0 of 3"):
	assert(get_bits(*loc32, 21, 2) == 0);
	set_bits(loc32, 5, value, 0, 16);
	}

	// 16-bit middle-low part of an absolute address.
	void
	patch_aarch64_16b(unsigned char *location, uint64_t value)
	{
	uint32_t loc32 = (uint32_t )location;
	assert(IS_AARCH64_MOV(*loc32));
	// Check the implicit shift (this is "part 1 of 3"):
	assert(get_bits(*loc32, 21, 2) == 1);
	set_bits(loc32, 5, value, 16, 16);
	}

	// 16-bit middle-high part of an absolute address.
	void
	patch_aarch64_16c(unsigned char *location, uint64_t value)
	{
	uint32_t loc32 = (uint32_t )location;
	assert(IS_AARCH64_MOV(*loc32));
	// Check the implicit shift (this is "part 2 of 3"):
	assert(get_bits(*loc32, 21, 2) == 2);
	set_bits(loc32, 5, value, 32, 16);
	}

	// 16-bit high part of an absolute address.
	void
	patch_aarch64_16d(unsigned char *location, uint64_t value)
	{
	uint32_t loc32 = (uint32_t )location;
	assert(IS_AARCH64_MOV(*loc32));
	// Check the implicit shift (this is "part 3 of 3"):
	assert(get_bits(*loc32, 21, 2) == 3);
	set_bits(loc32, 5, value, 48, 16);
	}

	// 21-bit count of pages between this page and an absolute address's page... I
	// know, I know, it's weird. Pairs nicely with patch_aarch64_12 (above).
	void
	patch_aarch64_21r(unsigned char *location, uint64_t value)
	{
	uint32_t loc32 = (uint32_t )location;
	value = (value >> 12) - ((uintptr_t)location >> 12);
	// Check that we're not out of range of 21 signed bits:
	assert((int64_t)value >= -(1 << 20));
	assert((int64_t)value < (1 << 20));
	// value[0:2] goes in loc[29:31]:
	set_bits(loc32, 29, value, 0, 2);
	// value[2:21] goes in loc[5:26]:
	set_bits(loc32, 5, value, 2, 19);
	}

	// Relaxable 21-bit count of pages between this page and an absolute address's
	// page. Pairs nicely with patch_aarch64_12x (above).
	void
	patch_aarch64_21rx(unsigned char *location, uint64_t value)
	{
	// This can only be relaxed if it occurs immediately before a matching
	// patch_aarch64_12x. If that happens, the JIT build step will replace both
	// calls with a single call to patch_aarch64_33rx. Otherwise, we end up
	// here, and the instruction is patched normally:
	patch_aarch64_21r(location, value);
	}

	// 28-bit relative branch.
	void
	patch_aarch64_26r(unsigned char *location, uint64_t value)
	{
	uint32_t loc32 = (uint32_t )location;
	assert(IS_AARCH64_BRANCH(*loc32));
	value -= (uintptr_t)location;
	// Check that we're not out of range of 28 signed bits:
	assert((int64_t)value >= -(1 << 27));
	assert((int64_t)value < (1 << 27));
	// Since instructions are 4-byte aligned, only use 26 bits:
	assert(get_bits(value, 0, 2) == 0);
	set_bits(loc32, 0, value, 2, 26);
	}

	// A pair of patch_aarch64_21rx and patch_aarch64_12x.
	void
	patch_aarch64_33rx(unsigned char *location, uint64_t value)
	{
	uint32_t loc32 = (uint32_t )location;
	// Try to relax the pair of GOT loads into an immediate value:
	assert(IS_AARCH64_ADRP(*loc32));
	unsigned char reg = get_bits(loc32[0], 0, 5);
	assert(IS_AARCH64_LDR_OR_STR(loc32[1]));
	// There should be only one register involved:
	assert(reg == get_bits(loc32[1], 0, 5)); // ldr's output register.
	assert(reg == get_bits(loc32[1], 5, 5)); // ldr's input register.
	uint64_t relaxed = (uint64_t )value;
	if (relaxed < (1UL << 16)) {
	// adrp reg, AAA; ldr reg, [reg + BBB] -> movz reg, XXX; nop
	loc32[0] = 0xD2800000 \| (get_bits(relaxed, 0, 16) << 5) \| reg;
	loc32[1] = 0xD503201F;
	return;
	}
	if (relaxed < (1ULL << 32)) {
	// adrp reg, AAA; ldr reg, [reg + BBB] -> movz reg, XXX; movk reg, YYY
	loc32[0] = 0xD2800000 \| (get_bits(relaxed, 0, 16) << 5) \| reg;
	loc32[1] = 0xF2A00000 \| (get_bits(relaxed, 16, 16) << 5) \| reg;
	return;
	}
	relaxed = value - (uintptr_t)location;
	if ((relaxed & 0x3) == 0 &&
	(int64_t)relaxed >= -(1L << 19) &&
	(int64_t)relaxed < (1L << 19))
	{
	// adrp reg, AAA; ldr reg, [reg + BBB] -> ldr reg, XXX; nop
	loc32[0] = 0x58000000 \| (get_bits(relaxed, 2, 19) << 5) \| reg;
	loc32[1] = 0xD503201F;
	return;
	}
	// Couldn't do it. Just patch the two instructions normally:
	patch_aarch64_21rx(location, value);
	patch_aarch64_12x(location + 4, value);
	}

	// Relaxable 32-bit relative address.
	void
	patch_x86_64_32rx(unsigned char *location, uint64_t value)
	{
	uint8_t loc8 = (uint8_t )location;
	// Try to relax the GOT load into an immediate value:
	uint64_t relaxed = (uint64_t )(value + 4) - 4;
	if ((int64_t)relaxed - (int64_t)location >= -(1LL << 31) &&
	(int64_t)relaxed - (int64_t)location + 1 < (1LL << 31))
	{
	if (loc8[-2] == 0x8B) {
	// mov reg, dword ptr [rip + AAA] -> lea reg, [rip + XXX]
	loc8[-2] = 0x8D;
	value = relaxed;
	}
	else if (loc8[-2] == 0xFF && loc8[-1] == 0x15) {
	// call qword ptr [rip + AAA] -> nop; call XXX
	loc8[-2] = 0x90;
	loc8[-1] = 0xE8;
	value = relaxed;
	}
	else if (loc8[-2] == 0xFF && loc8[-1] == 0x25) {
	// jmp qword ptr [rip + AAA] -> nop; jmp XXX
	loc8[-2] = 0x90;
	loc8[-1] = 0xE9;
	value = relaxed;
	}
	}
	patch_32r(location, value);
	}

	void patch_aarch64_trampoline(unsigned char location, int ordinal, jit_state state);

	#include "jit_stencils.h"

	#if defined(__aarch64__) \|\| defined(_M_ARM64)
	#define TRAMPOLINE_SIZE 16
	#else
	#define TRAMPOLINE_SIZE 0
	#endif

	// Generate and patch AArch64 trampolines. The symbols to jump to are stored
	// in the jit_stencils.h in the symbols_map.
	void
	patch_aarch64_trampoline(unsigned char location, int ordinal, jit_state state)
	{

	uint64_t value = (uintptr_t)symbols_map[ordinal];
	int64_t range = value - (uintptr_t)location;

	// If we are in range of 28 signed bits, we patch the instruction with
	// the address of the symbol.
	if (range >= -(1 << 27) && range < (1 << 27)) {
	patch_aarch64_26r(location, (uintptr_t)value);
	return;
	}

	// Masking is done modulo 32 as the mask is stored as an array of uint32_t
	const uint32_t symbol_mask = 1 << (ordinal % 32);
	const uint32_t trampoline_mask = state->trampolines.mask[ordinal / 32];
	assert(symbol_mask & trampoline_mask);

	// Count the number of set bits in the trampoline mask lower than ordinal,
	// this gives the index into the array of trampolines.
	int index = _Py_popcount32(trampoline_mask & (symbol_mask - 1));
	for (int i = 0; i < ordinal / 32; i++) {
	index += _Py_popcount32(state->trampolines.mask[i]);
	}

	uint32_t p = (uint32_t)(state->trampolines.mem + index * TRAMPOLINE_SIZE);
	assert((size_t)(index + 1) * TRAMPOLINE_SIZE <= state->trampolines.size);


	/* Generate the trampoline
	0: 58000048 ldr x8, 8
	4: d61f0100 br x8
	8: 00000000 // The next two words contain the 64-bit address to jump to.
	c: 00000000
	*/
	p[0] = 0x58000048;
	p[1] = 0xD61F0100;
	p[2] = value & 0xffffffff;
	p[3] = value >> 32;

	patch_aarch64_26r(location, (uintptr_t)p);
	}

	static void
	combine_symbol_mask(const symbol_mask src, symbol_mask dest)
	{
	// Calculate the union of the trampolines required by each StencilGroup
	for (size_t i = 0; i < SYMBOL_MASK_WORDS; i++) {
	dest[i] \|= src[i];
	}
	}

	// Compiles executor in-place. Don't forget to call _PyJIT_Free later!
	int
	_PyJIT_Compile(_PyExecutorObject *executor, const _PyUOpInstruction trace[], size_t length)
	{
	const StencilGroup *group;
	// Loop once to find the total compiled size:
	size_t code_size = 0;
	size_t data_size = 0;
	jit_state state = {0};
	group = &shim;
	code_size += group->code_size;
	data_size += group->data_size;
	combine_symbol_mask(group->trampoline_mask, state.trampolines.mask);
	for (size_t i = 0; i < length; i++) {
	const _PyUOpInstruction *instruction = &trace[i];
	group = &stencil_groups[instruction->opcode];
	state.instruction_starts[i] = code_size;
	code_size += group->code_size;
	data_size += group->data_size;
	combine_symbol_mask(group->trampoline_mask, state.trampolines.mask);
	}
	group = &stencil_groups[_FATAL_ERROR];
	code_size += group->code_size;
	data_size += group->data_size;
	combine_symbol_mask(group->trampoline_mask, state.trampolines.mask);
	// Calculate the size of the trampolines required by the whole trace
	for (size_t i = 0; i < Py_ARRAY_LENGTH(state.trampolines.mask); i++) {
	state.trampolines.size += _Py_popcount32(state.trampolines.mask[i]) * TRAMPOLINE_SIZE;
	}
	// Round up to the nearest page:
	size_t page_size = get_page_size();
	assert((page_size & (page_size - 1)) == 0);
	size_t padding = page_size - ((code_size + state.trampolines.size + data_size) & (page_size - 1));
	size_t total_size = code_size + state.trampolines.size + data_size + padding;
	unsigned char *memory = jit_alloc(total_size);
	if (memory == NULL) {
	return -1;
	}
	#ifdef MAP_JIT
	pthread_jit_write_protect_np(0);
	#endif
	// Collect memory stats
	OPT_STAT_ADD(jit_total_memory_size, total_size);
	OPT_STAT_ADD(jit_code_size, code_size);
	OPT_STAT_ADD(jit_trampoline_size, state.trampolines.size);
	OPT_STAT_ADD(jit_data_size, data_size);
	OPT_STAT_ADD(jit_padding_size, padding);
	OPT_HIST(total_size, trace_total_memory_hist);
	// Update the offsets of each instruction:
	for (size_t i = 0; i < length; i++) {
	state.instruction_starts[i] += (uintptr_t)memory;
	}
	// Loop again to emit the code:
	unsigned char *code = memory;
	state.trampolines.mem = memory + code_size;
	unsigned char *data = memory + code_size + state.trampolines.size;
	// Compile the shim, which handles converting between the native
	// calling convention and the calling convention used by jitted code
	// (which may be different for efficiency reasons).
	group = &shim;
	group->emit(code, data, executor, NULL, &state);
	code += group->code_size;
	data += group->data_size;
	assert(trace[0].opcode == _START_EXECUTOR);
	for (size_t i = 0; i < length; i++) {
	const _PyUOpInstruction *instruction = &trace[i];
	group = &stencil_groups[instruction->opcode];
	group->emit(code, data, executor, instruction, &state);
	code += group->code_size;
	data += group->data_size;
	}
	// Protect against accidental buffer overrun into data:
	group = &stencil_groups[_FATAL_ERROR];
	group->emit(code, data, executor, NULL, &state);
	code += group->code_size;
	data += group->data_size;
	assert(code == memory + code_size);
	assert(data == memory + code_size + state.trampolines.size + data_size);
	#ifdef MAP_JIT
	pthread_jit_write_protect_np(1);
	#endif
	if (mark_executable(memory, total_size)) {
	jit_free(memory, total_size);
	return -1;
	}
	executor->jit_code = memory;
	executor->jit_side_entry = memory + shim.code_size;
	executor->jit_size = total_size;
	return 0;
	}

	void
	_PyJIT_Free(_PyExecutorObject *executor)
	{
	unsigned char memory = (unsigned char )executor->jit_code;
	size_t size = executor->jit_size;
	if (memory) {
	executor->jit_code = NULL;
	executor->jit_side_entry = NULL;
	executor->jit_size = 0;
	if (jit_free(memory, size)) {
	PyErr_FormatUnraisable("Exception ignored while "
	"freeing JIT memory");
	}
	}
	}

	#endif // _Py_JIT