ladybird/Kernel/Profiling.cpp

#include <AK/Demangle.h>
#include <AK/StringBuilder.h>
#include <Kernel/FileSystem/Custody.h>
#include <Kernel/KBuffer.h>
#include <Kernel/Process.h>
#include <Kernel/Profiling.h>
#include <LibELF/ELFLoader.h>

namespace Profiling {

static KBufferImpl* s_profiling_buffer;
static size_t s_slot_count;
static size_t s_next_slot_index;
static Process* s_process;

void start(Process& process)
{
    s_process = &process;

    if (!s_profiling_buffer) {
        s_profiling_buffer = RefPtr<KBufferImpl>(KBuffer::create_with_size(8 * MB).impl()).leak_ref();
        s_slot_count = s_profiling_buffer->size() / sizeof(Sample);
    }

    s_next_slot_index = 0;
}

static Sample& sample_slot(size_t index)
{
    return ((Sample*)s_profiling_buffer->data())[index];
}

Sample& next_sample_slot()
{
    auto& slot = sample_slot(s_next_slot_index++);
    if (s_next_slot_index >= s_slot_count)
        s_next_slot_index = 0;
    return slot;
}

static void symbolicate(Sample& stack)
{
    auto& process = *s_process;
    ProcessPagingScope paging_scope(process);
    struct RecognizedSymbol {
        u32 address;
        const KSym* ksym;
    };
    Vector<RecognizedSymbol, max_stack_frame_count> recognized_symbols;
    for (size_t i = 1; i < max_stack_frame_count; ++i) {
        if (stack.frames[i] == 0)
            break;
        recognized_symbols.append({ stack.frames[i], ksymbolicate(stack.frames[i]) });
    }

    size_t i = 1;
    for (auto& symbol : recognized_symbols) {
        if (!symbol.address)
            break;
        auto& symbol_string_slot = stack.symbolicated_frames[i];
        auto& offset_slot = stack.offsets[i];
        ++i;
        if (!symbol.ksym) {
            if (!Scheduler::is_active() && process.elf_loader() && process.elf_loader()->has_symbols())
                symbol_string_slot = process.elf_loader()->symbolicate(symbol.address, &offset_slot);
            else
                symbol_string_slot = String::empty();
            continue;
        }
        u32 offset = symbol.address - symbol.ksym->address;
        if (symbol.ksym->address == ksym_highest_address && offset > 4096) {
            symbol_string_slot = String::empty();
            offset_slot = 0;
        } else {
            symbol_string_slot = demangle(symbol.ksym->name);
            offset_slot = offset;
        }
    }
}

void stop()
{
    for (size_t i = 0; i < s_next_slot_index; ++i) {
        auto& stack = sample_slot(i);
        symbolicate(stack);
    }

    s_process = nullptr;
}

void for_each_sample(Function<void(Sample&)> callback)
{
    for (size_t i = 0; i < s_next_slot_index; ++i) {
        auto& sample = sample_slot(i);
        callback(sample);
    }
}

}
Kernel: Implement a simple process time profiler The kernel now supports basic profiling of all the threads in a process by calling profiling_enable(pid_t). You finish the profiling by calling profiling_disable(pid_t). This all works by recording thread stacks when the timer interrupt fires and the current thread is in a process being profiled. Note that symbolication is deferred until profiling_disable() to avoid adding more noise than necessary to the profile. A simple "/bin/profile" command is included here that can be used to start/stop profiling like so: $ profile 10 on ... wait ... $ profile 10 off After a profile has been recorded, it can be fetched in /proc/profile There are various limits (or "bugs") on this mechanism at the moment: - Only one process can be profiled at a time. - We allocate 8MB for the samples, if you use more space, things will not work, and probably break a bit. - Things will probably fall apart if the profiled process dies during profiling, or while extracing /proc/profile 2019-12-11 22:36:56 +03:00			`#include <AK/Demangle.h>`
			`#include <AK/StringBuilder.h>`
			`#include <Kernel/FileSystem/Custody.h>`
			`#include <Kernel/KBuffer.h>`
			`#include <Kernel/Process.h>`
			`#include <Kernel/Profiling.h>`
			`#include <LibELF/ELFLoader.h>`

			`namespace Profiling {`

			`static KBufferImpl* s_profiling_buffer;`
			`static size_t s_slot_count;`
			`static size_t s_next_slot_index;`
			`static Process* s_process;`

			`void start(Process& process)`
			`{`
			`s_process = &process;`

			`if (!s_profiling_buffer) {`
			`s_profiling_buffer = RefPtr<KBufferImpl>(KBuffer::create_with_size(8 * MB).impl()).leak_ref();`
			`s_slot_count = s_profiling_buffer->size() / sizeof(Sample);`
			`}`

			`s_next_slot_index = 0;`
			`}`

			`static Sample& sample_slot(size_t index)`
			`{`
			`return ((Sample*)s_profiling_buffer->data())[index];`
			`}`

			`Sample& next_sample_slot()`
			`{`
			`auto& slot = sample_slot(s_next_slot_index++);`
			`if (s_next_slot_index >= s_slot_count)`
			`s_next_slot_index = 0;`
			`return slot;`
			`}`

			`static void symbolicate(Sample& stack)`
			`{`
			`auto& process = *s_process;`
			`ProcessPagingScope paging_scope(process);`
			`struct RecognizedSymbol {`
			`u32 address;`
			`const KSym* ksym;`
			`};`
			`Vector<RecognizedSymbol, max_stack_frame_count> recognized_symbols;`
			`for (size_t i = 1; i < max_stack_frame_count; ++i) {`
			`if (stack.frames[i] == 0)`
			`break;`
			`recognized_symbols.append({ stack.frames[i], ksymbolicate(stack.frames[i]) });`
			`}`

			`size_t i = 1;`
			`for (auto& symbol : recognized_symbols) {`
			`if (!symbol.address)`
			`break;`
Kernel: Separate out the symbol offsets in profile output Instead of saying "main +39" and "main +57" etc, we now have a separate field in /proc/profile for the offset-into-the-symbol. 2019-12-12 23:59:47 +03:00			`auto& symbol_string_slot = stack.symbolicated_frames[i];`
			`auto& offset_slot = stack.offsets[i];`
			`++i;`
Kernel: Implement a simple process time profiler The kernel now supports basic profiling of all the threads in a process by calling profiling_enable(pid_t). You finish the profiling by calling profiling_disable(pid_t). This all works by recording thread stacks when the timer interrupt fires and the current thread is in a process being profiled. Note that symbolication is deferred until profiling_disable() to avoid adding more noise than necessary to the profile. A simple "/bin/profile" command is included here that can be used to start/stop profiling like so: $ profile 10 on ... wait ... $ profile 10 off After a profile has been recorded, it can be fetched in /proc/profile There are various limits (or "bugs") on this mechanism at the moment: - Only one process can be profiled at a time. - We allocate 8MB for the samples, if you use more space, things will not work, and probably break a bit. - Things will probably fall apart if the profiled process dies during profiling, or while extracing /proc/profile 2019-12-11 22:36:56 +03:00			`if (!symbol.ksym) {`
			`if (!Scheduler::is_active() && process.elf_loader() && process.elf_loader()->has_symbols())`
Kernel: Separate out the symbol offsets in profile output Instead of saying "main +39" and "main +57" etc, we now have a separate field in /proc/profile for the offset-into-the-symbol. 2019-12-12 23:59:47 +03:00			`symbol_string_slot = process.elf_loader()->symbolicate(symbol.address, &offset_slot);`
Kernel: Implement a simple process time profiler The kernel now supports basic profiling of all the threads in a process by calling profiling_enable(pid_t). You finish the profiling by calling profiling_disable(pid_t). This all works by recording thread stacks when the timer interrupt fires and the current thread is in a process being profiled. Note that symbolication is deferred until profiling_disable() to avoid adding more noise than necessary to the profile. A simple "/bin/profile" command is included here that can be used to start/stop profiling like so: $ profile 10 on ... wait ... $ profile 10 off After a profile has been recorded, it can be fetched in /proc/profile There are various limits (or "bugs") on this mechanism at the moment: - Only one process can be profiled at a time. - We allocate 8MB for the samples, if you use more space, things will not work, and probably break a bit. - Things will probably fall apart if the profiled process dies during profiling, or while extracing /proc/profile 2019-12-11 22:36:56 +03:00			`else`
			`symbol_string_slot = String::empty();`
			`continue;`
			`}`
Kernel: Separate out the symbol offsets in profile output Instead of saying "main +39" and "main +57" etc, we now have a separate field in /proc/profile for the offset-into-the-symbol. 2019-12-12 23:59:47 +03:00			`u32 offset = symbol.address - symbol.ksym->address;`
			`if (symbol.ksym->address == ksym_highest_address && offset > 4096) {`
Kernel: Implement a simple process time profiler The kernel now supports basic profiling of all the threads in a process by calling profiling_enable(pid_t). You finish the profiling by calling profiling_disable(pid_t). This all works by recording thread stacks when the timer interrupt fires and the current thread is in a process being profiled. Note that symbolication is deferred until profiling_disable() to avoid adding more noise than necessary to the profile. A simple "/bin/profile" command is included here that can be used to start/stop profiling like so: $ profile 10 on ... wait ... $ profile 10 off After a profile has been recorded, it can be fetched in /proc/profile There are various limits (or "bugs") on this mechanism at the moment: - Only one process can be profiled at a time. - We allocate 8MB for the samples, if you use more space, things will not work, and probably break a bit. - Things will probably fall apart if the profiled process dies during profiling, or while extracing /proc/profile 2019-12-11 22:36:56 +03:00			`symbol_string_slot = String::empty();`
Kernel: Separate out the symbol offsets in profile output Instead of saying "main +39" and "main +57" etc, we now have a separate field in /proc/profile for the offset-into-the-symbol. 2019-12-12 23:59:47 +03:00			`offset_slot = 0;`
			`} else {`
			`symbol_string_slot = demangle(symbol.ksym->name);`
			`offset_slot = offset;`
			`}`
Kernel: Implement a simple process time profiler The kernel now supports basic profiling of all the threads in a process by calling profiling_enable(pid_t). You finish the profiling by calling profiling_disable(pid_t). This all works by recording thread stacks when the timer interrupt fires and the current thread is in a process being profiled. Note that symbolication is deferred until profiling_disable() to avoid adding more noise than necessary to the profile. A simple "/bin/profile" command is included here that can be used to start/stop profiling like so: $ profile 10 on ... wait ... $ profile 10 off After a profile has been recorded, it can be fetched in /proc/profile There are various limits (or "bugs") on this mechanism at the moment: - Only one process can be profiled at a time. - We allocate 8MB for the samples, if you use more space, things will not work, and probably break a bit. - Things will probably fall apart if the profiled process dies during profiling, or while extracing /proc/profile 2019-12-11 22:36:56 +03:00			`}`
			`}`

			`void stop()`
			`{`
			`for (size_t i = 0; i < s_next_slot_index; ++i) {`
			`auto& stack = sample_slot(i);`
			`symbolicate(stack);`
			`}`

			`s_process = nullptr;`
			`}`

			`void for_each_sample(Function<void(Sample&)> callback)`
			`{`
			`for (size_t i = 0; i < s_next_slot_index; ++i) {`
			`auto& sample = sample_slot(i);`
			`callback(sample);`
			`}`
			`}`

			`}`