mirror of https://github.com/python/cpython
529 lines
17 KiB
C
529 lines
17 KiB
C
/*
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Perf trampoline instrumentation
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===============================
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This file contains instrumentation to allow to associate
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calls to the CPython eval loop back to the names of the Python
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functions and filename being executed.
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Many native performance profilers like the Linux perf tools are
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only available to 'see' the C stack when sampling from the profiled
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process. This means that if we have the following python code:
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import time
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def foo(n):
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# Some CPU intensive code
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def bar(n):
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foo(n)
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def baz(n):
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bar(n)
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baz(10000000)
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A performance profiler that is only able to see native frames will
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produce the following backtrace when sampling from foo():
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_PyEval_EvalFrameDefault -----> Evaluation frame of foo()
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_PyEval_Vector
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_PyFunction_Vectorcall
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PyObject_Vectorcall
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call_function
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_PyEval_EvalFrameDefault ------> Evaluation frame of bar()
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_PyEval_EvalFrame
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_PyEval_Vector
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_PyFunction_Vectorcall
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PyObject_Vectorcall
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call_function
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_PyEval_EvalFrameDefault -------> Evaluation frame of baz()
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_PyEval_EvalFrame
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_PyEval_Vector
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_PyFunction_Vectorcall
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PyObject_Vectorcall
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call_function
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...
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Py_RunMain
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Because the profiler is only able to see the native frames and the native
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function that runs the evaluation loop is the same (_PyEval_EvalFrameDefault)
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then the profiler and any reporter generated by it will not be able to
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associate the names of the Python functions and the filenames associated with
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those calls, rendering the results useless in the Python world.
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To fix this problem, we introduce the concept of a trampoline frame. A
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trampoline frame is a piece of code that is unique per Python code object that
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is executed before entering the CPython eval loop. This piece of code just
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calls the original Python evaluation function (_PyEval_EvalFrameDefault) and
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forwards all the arguments received. In this way, when a profiler samples
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frames from the previous example it will see;
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_PyEval_EvalFrameDefault -----> Evaluation frame of foo()
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[Jit compiled code 3]
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_PyEval_Vector
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_PyFunction_Vectorcall
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PyObject_Vectorcall
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call_function
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_PyEval_EvalFrameDefault ------> Evaluation frame of bar()
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[Jit compiled code 2]
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_PyEval_EvalFrame
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_PyEval_Vector
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_PyFunction_Vectorcall
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PyObject_Vectorcall
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call_function
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_PyEval_EvalFrameDefault -------> Evaluation frame of baz()
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[Jit compiled code 1]
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_PyEval_EvalFrame
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_PyEval_Vector
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_PyFunction_Vectorcall
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PyObject_Vectorcall
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call_function
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...
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Py_RunMain
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When we generate every unique copy of the trampoline (what here we called "[Jit
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compiled code N]") we write the relationship between the compiled code and the
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Python function that is associated with it. Every profiler requires this
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information in a different format. For example, the Linux "perf" profiler
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requires a file in "/tmp/perf-PID.map" (name and location not configurable)
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with the following format:
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<compiled code address> <compiled code size> <name of the compiled code>
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If this file is available when "perf" generates reports, it will automatically
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associate every trampoline with the Python function that it is associated with
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allowing it to generate reports that include Python information. These reports
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then can also be filtered in a way that *only* Python information appears.
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Notice that for this to work, there must be a unique copied of the trampoline
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per Python code object even if the code in the trampoline is the same. To
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achieve this we have a assembly template in Objects/asm_trampiline.S that is
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compiled into the Python executable/shared library. This template generates a
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symbol that maps the start of the assembly code and another that marks the end
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of the assembly code for the trampoline. Then, every time we need a unique
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trampoline for a Python code object, we copy the assembly code into a mmaped
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area that has executable permissions and we return the start of that area as
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our trampoline function.
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Asking for a mmap-ed memory area for trampoline is very wasteful so we
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allocate big arenas of memory in a single mmap call, we populate the entire
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arena with copies of the trampoline (this allows us to now have to invalidate
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the icache for the instructions in the page) and then we return the next
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available chunk every time someone asks for a new trampoline. We keep a linked
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list of arenas in case the current memory arena is exhausted and another one is
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needed.
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For the best results, Python should be compiled with
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CFLAGS="-fno-omit-frame-pointer -mno-omit-leaf-frame-pointer" as this allows
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profilers to unwind using only the frame pointer and not on DWARF debug
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information (note that as trampilines are dynamically generated there won't be
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any DWARF information available for them).
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*/
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#include "Python.h"
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#include "pycore_ceval.h" // _PyPerf_Callbacks
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#include "pycore_frame.h"
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#include "pycore_interp.h"
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#ifdef PY_HAVE_PERF_TRAMPOLINE
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#include <fcntl.h>
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#include <stdio.h>
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#include <stdlib.h>
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#include <sys/mman.h> // mmap()
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#include <sys/types.h>
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#include <unistd.h> // sysconf()
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#if defined(__arm__) || defined(__arm64__) || defined(__aarch64__)
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#define PY_HAVE_INVALIDATE_ICACHE
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#if defined(__clang__) || defined(__GNUC__)
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extern void __clear_cache(void *, void*);
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#endif
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static void invalidate_icache(char* begin, char*end) {
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#if defined(__clang__) || defined(__GNUC__)
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return __clear_cache(begin, end);
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#else
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return;
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#endif
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}
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#endif
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/* The function pointer is passed as last argument. The other three arguments
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* are passed in the same order as the function requires. This results in
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* shorter, more efficient ASM code for trampoline.
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*/
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typedef PyObject *(*py_evaluator)(PyThreadState *, _PyInterpreterFrame *,
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int throwflag);
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typedef PyObject *(*py_trampoline)(PyThreadState *, _PyInterpreterFrame *, int,
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py_evaluator);
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extern void *_Py_trampoline_func_start; // Start of the template of the
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// assembly trampoline
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extern void *
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_Py_trampoline_func_end; // End of the template of the assembly trampoline
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struct code_arena_st {
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char *start_addr; // Start of the memory arena
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char *current_addr; // Address of the current trampoline within the arena
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size_t size; // Size of the memory arena
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size_t size_left; // Remaining size of the memory arena
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size_t code_size; // Size of the code of every trampoline in the arena
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struct code_arena_st
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*prev; // Pointer to the arena or NULL if this is the first arena.
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};
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typedef struct code_arena_st code_arena_t;
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typedef struct trampoline_api_st trampoline_api_t;
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#define perf_status _PyRuntime.ceval.perf.status
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#define extra_code_index _PyRuntime.ceval.perf.extra_code_index
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#define perf_code_arena _PyRuntime.ceval.perf.code_arena
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#define trampoline_api _PyRuntime.ceval.perf.trampoline_api
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#define perf_map_file _PyRuntime.ceval.perf.map_file
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#define persist_after_fork _PyRuntime.ceval.perf.persist_after_fork
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static void
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perf_map_write_entry(void *state, const void *code_addr,
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unsigned int code_size, PyCodeObject *co)
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{
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const char *entry = "";
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if (co->co_qualname != NULL) {
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entry = PyUnicode_AsUTF8(co->co_qualname);
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}
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const char *filename = "";
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if (co->co_filename != NULL) {
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filename = PyUnicode_AsUTF8(co->co_filename);
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}
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size_t perf_map_entry_size = snprintf(NULL, 0, "py::%s:%s", entry, filename) + 1;
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char* perf_map_entry = (char*) PyMem_RawMalloc(perf_map_entry_size);
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if (perf_map_entry == NULL) {
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return;
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}
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snprintf(perf_map_entry, perf_map_entry_size, "py::%s:%s", entry, filename);
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PyUnstable_WritePerfMapEntry(code_addr, code_size, perf_map_entry);
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PyMem_RawFree(perf_map_entry);
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}
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static void*
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perf_map_init_state(void)
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{
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PyUnstable_PerfMapState_Init();
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return NULL;
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}
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static int
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perf_map_free_state(void *state)
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{
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PyUnstable_PerfMapState_Fini();
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return 0;
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}
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_PyPerf_Callbacks _Py_perfmap_callbacks = {
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&perf_map_init_state,
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&perf_map_write_entry,
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&perf_map_free_state,
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};
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static int
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new_code_arena(void)
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{
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// non-trivial programs typically need 64 to 256 kiB.
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size_t mem_size = 4096 * 16;
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assert(mem_size % sysconf(_SC_PAGESIZE) == 0);
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char *memory =
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mmap(NULL, // address
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mem_size, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANONYMOUS,
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-1, // fd (not used here)
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0); // offset (not used here)
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if (memory == MAP_FAILED) {
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PyErr_SetFromErrno(PyExc_OSError);
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PyErr_FormatUnraisable("Failed to create new mmap for perf trampoline");
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perf_status = PERF_STATUS_FAILED;
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return -1;
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}
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void *start = &_Py_trampoline_func_start;
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void *end = &_Py_trampoline_func_end;
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size_t code_size = end - start;
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// TODO: Check the effect of alignment of the code chunks. Initial investigation
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// showed that this has no effect on performance in x86-64 or aarch64 and the current
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// version has the advantage that the unwinder in GDB can unwind across JIT-ed code.
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//
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// We should check the values in the future and see if there is a
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// measurable performance improvement by rounding trampolines up to 32-bit
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// or 64-bit alignment.
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size_t n_copies = mem_size / code_size;
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for (size_t i = 0; i < n_copies; i++) {
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memcpy(memory + i * code_size, start, code_size * sizeof(char));
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}
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// Some systems may prevent us from creating executable code on the fly.
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int res = mprotect(memory, mem_size, PROT_READ | PROT_EXEC);
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if (res == -1) {
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PyErr_SetFromErrno(PyExc_OSError);
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munmap(memory, mem_size);
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PyErr_FormatUnraisable("Failed to set mmap for perf trampoline to "
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"PROT_READ | PROT_EXEC");
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return -1;
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}
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#ifdef PY_HAVE_INVALIDATE_ICACHE
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// Before the JIT can run a block of code that has been emitted it must invalidate
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// the instruction cache on some platforms like arm and aarch64.
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invalidate_icache(memory, memory + mem_size);
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#endif
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code_arena_t *new_arena = PyMem_RawCalloc(1, sizeof(code_arena_t));
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if (new_arena == NULL) {
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PyErr_NoMemory();
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munmap(memory, mem_size);
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PyErr_FormatUnraisable("Failed to allocate new code arena struct for perf trampoline");
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return -1;
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}
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new_arena->start_addr = memory;
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new_arena->current_addr = memory;
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new_arena->size = mem_size;
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new_arena->size_left = mem_size;
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new_arena->code_size = code_size;
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new_arena->prev = perf_code_arena;
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perf_code_arena = new_arena;
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return 0;
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}
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static void
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free_code_arenas(void)
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{
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code_arena_t *cur = perf_code_arena;
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code_arena_t *prev;
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perf_code_arena = NULL; // invalid static pointer
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while (cur) {
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munmap(cur->start_addr, cur->size);
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prev = cur->prev;
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PyMem_RawFree(cur);
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cur = prev;
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}
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}
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static inline py_trampoline
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code_arena_new_code(code_arena_t *code_arena)
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{
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py_trampoline trampoline = (py_trampoline)code_arena->current_addr;
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code_arena->size_left -= code_arena->code_size;
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code_arena->current_addr += code_arena->code_size;
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return trampoline;
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}
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static inline py_trampoline
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compile_trampoline(void)
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{
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if ((perf_code_arena == NULL) ||
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(perf_code_arena->size_left <= perf_code_arena->code_size)) {
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if (new_code_arena() < 0) {
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return NULL;
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}
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}
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assert(perf_code_arena->size_left <= perf_code_arena->size);
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return code_arena_new_code(perf_code_arena);
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}
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static PyObject *
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py_trampoline_evaluator(PyThreadState *ts, _PyInterpreterFrame *frame,
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int throw)
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{
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if (perf_status == PERF_STATUS_FAILED ||
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perf_status == PERF_STATUS_NO_INIT) {
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goto default_eval;
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}
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PyCodeObject *co = _PyFrame_GetCode(frame);
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py_trampoline f = NULL;
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assert(extra_code_index != -1);
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int ret = _PyCode_GetExtra((PyObject *)co, extra_code_index, (void **)&f);
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if (ret != 0 || f == NULL) {
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// This is the first time we see this code object so we need
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// to compile a trampoline for it.
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py_trampoline new_trampoline = compile_trampoline();
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if (new_trampoline == NULL) {
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goto default_eval;
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}
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trampoline_api.write_state(trampoline_api.state, new_trampoline,
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perf_code_arena->code_size, co);
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_PyCode_SetExtra((PyObject *)co, extra_code_index,
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(void *)new_trampoline);
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f = new_trampoline;
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}
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assert(f != NULL);
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return f(ts, frame, throw, _PyEval_EvalFrameDefault);
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default_eval:
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// Something failed, fall back to the default evaluator.
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return _PyEval_EvalFrameDefault(ts, frame, throw);
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}
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#endif // PY_HAVE_PERF_TRAMPOLINE
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int PyUnstable_PerfTrampoline_CompileCode(PyCodeObject *co)
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{
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#ifdef PY_HAVE_PERF_TRAMPOLINE
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py_trampoline f = NULL;
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assert(extra_code_index != -1);
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int ret = _PyCode_GetExtra((PyObject *)co, extra_code_index, (void **)&f);
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if (ret != 0 || f == NULL) {
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py_trampoline new_trampoline = compile_trampoline();
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if (new_trampoline == NULL) {
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return 0;
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}
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trampoline_api.write_state(trampoline_api.state, new_trampoline,
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perf_code_arena->code_size, co);
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return _PyCode_SetExtra((PyObject *)co, extra_code_index,
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(void *)new_trampoline);
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}
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#endif // PY_HAVE_PERF_TRAMPOLINE
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return 0;
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}
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int
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_PyIsPerfTrampolineActive(void)
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{
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#ifdef PY_HAVE_PERF_TRAMPOLINE
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PyThreadState *tstate = _PyThreadState_GET();
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return tstate->interp->eval_frame == py_trampoline_evaluator;
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#endif
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return 0;
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}
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void
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_PyPerfTrampoline_GetCallbacks(_PyPerf_Callbacks *callbacks)
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{
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if (callbacks == NULL) {
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return;
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}
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#ifdef PY_HAVE_PERF_TRAMPOLINE
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callbacks->init_state = trampoline_api.init_state;
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callbacks->write_state = trampoline_api.write_state;
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callbacks->free_state = trampoline_api.free_state;
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#endif
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return;
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}
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int
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_PyPerfTrampoline_SetCallbacks(_PyPerf_Callbacks *callbacks)
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{
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if (callbacks == NULL) {
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return -1;
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}
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#ifdef PY_HAVE_PERF_TRAMPOLINE
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if (trampoline_api.state) {
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_PyPerfTrampoline_Fini();
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}
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trampoline_api.init_state = callbacks->init_state;
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trampoline_api.write_state = callbacks->write_state;
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trampoline_api.free_state = callbacks->free_state;
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trampoline_api.state = NULL;
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#endif
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return 0;
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}
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int
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_PyPerfTrampoline_Init(int activate)
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{
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#ifdef PY_HAVE_PERF_TRAMPOLINE
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PyThreadState *tstate = _PyThreadState_GET();
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if (tstate->interp->eval_frame &&
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tstate->interp->eval_frame != py_trampoline_evaluator) {
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PyErr_SetString(PyExc_RuntimeError,
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"Trampoline cannot be initialized as a custom eval "
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"frame is already present");
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return -1;
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}
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if (!activate) {
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tstate->interp->eval_frame = NULL;
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perf_status = PERF_STATUS_NO_INIT;
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}
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else {
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tstate->interp->eval_frame = py_trampoline_evaluator;
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if (new_code_arena() < 0) {
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return -1;
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}
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extra_code_index = _PyEval_RequestCodeExtraIndex(NULL);
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if (extra_code_index == -1) {
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return -1;
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}
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if (trampoline_api.state == NULL && trampoline_api.init_state != NULL) {
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trampoline_api.state = trampoline_api.init_state();
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}
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perf_status = PERF_STATUS_OK;
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}
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#endif
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return 0;
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}
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int
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_PyPerfTrampoline_Fini(void)
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{
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#ifdef PY_HAVE_PERF_TRAMPOLINE
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if (perf_status != PERF_STATUS_OK) {
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return 0;
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}
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PyThreadState *tstate = _PyThreadState_GET();
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if (tstate->interp->eval_frame == py_trampoline_evaluator) {
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tstate->interp->eval_frame = NULL;
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}
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if (perf_status == PERF_STATUS_OK) {
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trampoline_api.free_state(trampoline_api.state);
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}
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extra_code_index = -1;
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perf_status = PERF_STATUS_NO_INIT;
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#endif
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return 0;
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}
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void _PyPerfTrampoline_FreeArenas(void) {
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#ifdef PY_HAVE_PERF_TRAMPOLINE
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free_code_arenas();
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#endif
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return;
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}
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int
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PyUnstable_PerfTrampoline_SetPersistAfterFork(int enable){
|
|
#ifdef PY_HAVE_PERF_TRAMPOLINE
|
|
persist_after_fork = enable;
|
|
return persist_after_fork;
|
|
#endif
|
|
return 0;
|
|
}
|
|
|
|
PyStatus
|
|
_PyPerfTrampoline_AfterFork_Child(void)
|
|
{
|
|
#ifdef PY_HAVE_PERF_TRAMPOLINE
|
|
if (persist_after_fork) {
|
|
_PyPerfTrampoline_Fini();
|
|
char filename[256];
|
|
pid_t parent_pid = getppid();
|
|
snprintf(filename, sizeof(filename), "/tmp/perf-%d.map", parent_pid);
|
|
if (PyUnstable_CopyPerfMapFile(filename) != 0) {
|
|
return PyStatus_Error("Failed to copy perf map file.");
|
|
}
|
|
} else {
|
|
// Restart trampoline in file in child.
|
|
int was_active = _PyIsPerfTrampolineActive();
|
|
_PyPerfTrampoline_Fini();
|
|
if (was_active) {
|
|
_PyPerfTrampoline_Init(1);
|
|
}
|
|
}
|
|
#endif
|
|
return PyStatus_Ok();
|
|
}
|