ladybird/Applications/SystemMonitor/ProcessModel.cpp

#include "ProcessModel.h"
#include "GraphWidget.h"
#include <AK/JsonArray.h>
#include <AK/JsonObject.h>
#include <AK/JsonValue.h>
#include <AK/SharedBuffer.h>
#include <LibCore/CProcessStatisticsReader.h>
#include <fcntl.h>
#include <stdio.h>

static ProcessModel* s_the;

ProcessModel& ProcessModel::the()
{
    ASSERT(s_the);
    return *s_the;
}

ProcessModel::ProcessModel()
{
    ASSERT(!s_the);
    s_the = this;
    m_generic_process_icon = GraphicsBitmap::load_from_file("/res/icons/gear16.png");
    m_high_priority_icon = GraphicsBitmap::load_from_file("/res/icons/highpriority16.png");
    m_low_priority_icon = GraphicsBitmap::load_from_file("/res/icons/lowpriority16.png");
    m_normal_priority_icon = GraphicsBitmap::load_from_file("/res/icons/normalpriority16.png");
}

ProcessModel::~ProcessModel()
{
}

int ProcessModel::row_count(const GModelIndex&) const
{
    return m_pids.size();
}

int ProcessModel::column_count(const GModelIndex&) const
{
    return Column::__Count;
}

String ProcessModel::column_name(int column) const
{
    switch (column) {
    case Column::Icon:
        return "";
    case Column::PID:
        return "PID";
    case Column::TID:
        return "TID";
    case Column::State:
        return "State";
    case Column::User:
        return "User";
    case Column::Priority:
        return "Pr";
    case Column::EffectivePriority:
        return "EPr";
    case Column::Virtual:
        return "Virtual";
    case Column::Physical:
        return "Physical";
    case Column::DirtyPrivate:
        return "DirtyP";
    case Column::CleanInode:
        return "CleanI";
    case Column::PurgeableVolatile:
        return "Purg:V";
    case Column::PurgeableNonvolatile:
        return "Purg:N";
    case Column::CPU:
        return "CPU";
    case Column::Name:
        return "Name";
    case Column::Syscalls:
        return "Syscalls";
    case Column::InodeFaults:
        return "F:Inode";
    case Column::ZeroFaults:
        return "F:Zero";
    case Column::CowFaults:
        return "F:CoW";
    case Column::IPv4SocketReadBytes:
        return "IPv4 In";
    case Column::IPv4SocketWriteBytes:
        return "IPv4 Out";
    case Column::UnixSocketReadBytes:
        return "Unix In";
    case Column::UnixSocketWriteBytes:
        return "Unix Out";
    case Column::FileReadBytes:
        return "File In";
    case Column::FileWriteBytes:
        return "File Out";
    case Column::Pledge:
        return "Pledge";
    default:
        ASSERT_NOT_REACHED();
    }
}

GModel::ColumnMetadata ProcessModel::column_metadata(int column) const
{
    switch (column) {
    case Column::Icon:
        return { 16, TextAlignment::CenterLeft };
    case Column::PID:
        return { 32, TextAlignment::CenterRight };
    case Column::TID:
        return { 32, TextAlignment::CenterRight };
    case Column::State:
        return { 75, TextAlignment::CenterLeft };
    case Column::Priority:
        return { 16, TextAlignment::CenterRight };
    case Column::EffectivePriority:
        return { 16, TextAlignment::CenterRight };
    case Column::User:
        return { 50, TextAlignment::CenterLeft };
    case Column::Virtual:
        return { 65, TextAlignment::CenterRight };
    case Column::Physical:
        return { 65, TextAlignment::CenterRight };
    case Column::DirtyPrivate:
        return { 65, TextAlignment::CenterRight };
    case Column::CleanInode:
        return { 65, TextAlignment::CenterRight };
    case Column::PurgeableVolatile:
        return { 65, TextAlignment::CenterRight };
    case Column::PurgeableNonvolatile:
        return { 65, TextAlignment::CenterRight };
    case Column::CPU:
        return { 32, TextAlignment::CenterRight };
    case Column::Name:
        return { 140, TextAlignment::CenterLeft };
    case Column::Syscalls:
        return { 60, TextAlignment::CenterRight };
    case Column::InodeFaults:
        return { 60, TextAlignment::CenterRight };
    case Column::ZeroFaults:
        return { 60, TextAlignment::CenterRight };
    case Column::CowFaults:
        return { 60, TextAlignment::CenterRight };
    case Column::FileReadBytes:
        return { 60, TextAlignment::CenterRight };
    case Column::FileWriteBytes:
        return { 60, TextAlignment::CenterRight };
    case Column::UnixSocketReadBytes:
        return { 60, TextAlignment::CenterRight };
    case Column::UnixSocketWriteBytes:
        return { 60, TextAlignment::CenterRight };
    case Column::IPv4SocketReadBytes:
        return { 60, TextAlignment::CenterRight };
    case Column::IPv4SocketWriteBytes:
        return { 60, TextAlignment::CenterRight };
    case Column::Pledge:
        return { 60, TextAlignment::CenterLeft };
    default:
        ASSERT_NOT_REACHED();
    }
}

static String pretty_byte_size(size_t size)
{
    return String::format("%uK", size / 1024);
}

GVariant ProcessModel::data(const GModelIndex& index, Role role) const
{
    ASSERT(is_valid(index));

    auto it = m_threads.find(m_pids[index.row()]);
    auto& thread = *(*it).value;

    if (role == Role::Sort) {
        switch (index.column()) {
        case Column::Icon:
            return 0;
        case Column::PID:
            return thread.current_state.pid;
        case Column::TID:
            return thread.current_state.tid;
        case Column::State:
            return thread.current_state.state;
        case Column::User:
            return thread.current_state.user;
        case Column::Priority:
            return thread.current_state.priority;
        case Column::EffectivePriority:
            return thread.current_state.effective_priority;
        case Column::Virtual:
            return (int)thread.current_state.amount_virtual;
        case Column::Physical:
            return (int)thread.current_state.amount_resident;
        case Column::DirtyPrivate:
            return (int)thread.current_state.amount_dirty_private;
        case Column::CleanInode:
            return (int)thread.current_state.amount_clean_inode;
        case Column::PurgeableVolatile:
            return (int)thread.current_state.amount_purgeable_volatile;
        case Column::PurgeableNonvolatile:
            return (int)thread.current_state.amount_purgeable_nonvolatile;
        case Column::CPU:
            return thread.current_state.cpu_percent;
        case Column::Name:
            return thread.current_state.name;
        case Column::Syscalls:
            return thread.current_state.syscall_count;
        case Column::InodeFaults:
            return thread.current_state.inode_faults;
        case Column::ZeroFaults:
            return thread.current_state.zero_faults;
        case Column::CowFaults:
            return thread.current_state.cow_faults;
        case Column::IPv4SocketReadBytes:
            return thread.current_state.ipv4_socket_read_bytes;
        case Column::IPv4SocketWriteBytes:
            return thread.current_state.ipv4_socket_write_bytes;
        case Column::UnixSocketReadBytes:
            return thread.current_state.unix_socket_read_bytes;
        case Column::UnixSocketWriteBytes:
            return thread.current_state.unix_socket_write_bytes;
        case Column::FileReadBytes:
            return thread.current_state.file_read_bytes;
        case Column::FileWriteBytes:
            return thread.current_state.file_write_bytes;
        case Column::Pledge:
            return thread.current_state.pledge;
        }
        ASSERT_NOT_REACHED();
        return {};
    }

    if (role == Role::Display) {
        switch (index.column()) {
        case Column::Icon:
            if (thread.current_state.icon_id != -1) {
                auto icon_buffer = SharedBuffer::create_from_shared_buffer_id(thread.current_state.icon_id);
                if (icon_buffer) {
                    auto icon_bitmap = GraphicsBitmap::create_with_shared_buffer(GraphicsBitmap::Format::RGBA32, *icon_buffer, { 16, 16 });
                    if (icon_bitmap)
                        return *icon_bitmap;
                }
            }
            return *m_generic_process_icon;
        case Column::PID:
            return thread.current_state.pid;
        case Column::TID:
            return thread.current_state.tid;
        case Column::State:
            return thread.current_state.state;
        case Column::User:
            return thread.current_state.user;
        case Column::Priority:
            return thread.current_state.priority;
        case Column::EffectivePriority:
            return thread.current_state.effective_priority;
        case Column::Virtual:
            return pretty_byte_size(thread.current_state.amount_virtual);
        case Column::Physical:
            return pretty_byte_size(thread.current_state.amount_resident);
        case Column::DirtyPrivate:
            return pretty_byte_size(thread.current_state.amount_dirty_private);
        case Column::CleanInode:
            return pretty_byte_size(thread.current_state.amount_clean_inode);
        case Column::PurgeableVolatile:
            return pretty_byte_size(thread.current_state.amount_purgeable_volatile);
        case Column::PurgeableNonvolatile:
            return pretty_byte_size(thread.current_state.amount_purgeable_nonvolatile);
        case Column::CPU:
            return thread.current_state.cpu_percent;
        case Column::Name:
            return thread.current_state.name;
        case Column::Syscalls:
            return thread.current_state.syscall_count;
        case Column::InodeFaults:
            return thread.current_state.inode_faults;
        case Column::ZeroFaults:
            return thread.current_state.zero_faults;
        case Column::CowFaults:
            return thread.current_state.cow_faults;
        case Column::IPv4SocketReadBytes:
            return thread.current_state.ipv4_socket_read_bytes;
        case Column::IPv4SocketWriteBytes:
            return thread.current_state.ipv4_socket_write_bytes;
        case Column::UnixSocketReadBytes:
            return thread.current_state.unix_socket_read_bytes;
        case Column::UnixSocketWriteBytes:
            return thread.current_state.unix_socket_write_bytes;
        case Column::FileReadBytes:
            return thread.current_state.file_read_bytes;
        case Column::FileWriteBytes:
            return thread.current_state.file_write_bytes;
        case Column::Pledge:
            return thread.current_state.pledge;
        }
    }

    return {};
}

void ProcessModel::update()
{
    auto all_processes = CProcessStatisticsReader::get_all();

    unsigned last_sum_times_scheduled = 0;
    for (auto& it : m_threads)
        last_sum_times_scheduled += it.value->current_state.times_scheduled;

    HashTable<PidAndTid> live_pids;
    unsigned sum_times_scheduled = 0;
    for (auto& it : all_processes) {
        for (auto& thread : it.value.threads) {
            ThreadState state;
            state.pid = it.value.pid;
            state.user = it.value.username;
            state.pledge = it.value.pledge;
            state.syscall_count = thread.syscall_count;
            state.inode_faults = thread.inode_faults;
            state.zero_faults = thread.zero_faults;
            state.cow_faults = thread.cow_faults;
            state.unix_socket_read_bytes = thread.unix_socket_read_bytes;
            state.unix_socket_write_bytes = thread.unix_socket_write_bytes;
            state.ipv4_socket_read_bytes = thread.ipv4_socket_read_bytes;
            state.ipv4_socket_write_bytes = thread.ipv4_socket_write_bytes;
            state.file_read_bytes = thread.file_read_bytes;
            state.file_write_bytes = thread.file_write_bytes;
            state.amount_virtual = it.value.amount_virtual;
            state.amount_resident = it.value.amount_resident;
            state.amount_dirty_private = it.value.amount_dirty_private;
            state.amount_clean_inode = it.value.amount_clean_inode;
            state.amount_purgeable_volatile = it.value.amount_purgeable_volatile;
            state.amount_purgeable_nonvolatile = it.value.amount_purgeable_nonvolatile;
            state.icon_id = it.value.icon_id;

            state.name = thread.name;

            state.tid = thread.tid;
            state.times_scheduled = thread.times_scheduled;
            state.priority = thread.priority;
            state.effective_priority = thread.effective_priority;
            state.state = thread.state;
            sum_times_scheduled += thread.times_scheduled;
            {
                auto pit = m_threads.find({ it.value.pid, thread.tid });
                if (pit == m_threads.end())
                    m_threads.set({ it.value.pid, thread.tid }, make<Thread>());
            }
            auto pit = m_threads.find({ it.value.pid, thread.tid });
            ASSERT(pit != m_threads.end());
            (*pit).value->previous_state = (*pit).value->current_state;
            (*pit).value->current_state = state;

            live_pids.set({ it.value.pid, thread.tid });
        }
    }

    m_pids.clear();
    float total_cpu_percent = 0;
    Vector<PidAndTid, 16> pids_to_remove;
    for (auto& it : m_threads) {
        if (!live_pids.contains(it.key)) {
            pids_to_remove.append(it.key);
            continue;
        }
        auto& process = *it.value;
        u32 times_scheduled_diff = process.current_state.times_scheduled - process.previous_state.times_scheduled;
        process.current_state.cpu_percent = ((float)times_scheduled_diff * 100) / (float)(sum_times_scheduled - last_sum_times_scheduled);
        if (it.key.pid != 0) {
            total_cpu_percent += process.current_state.cpu_percent;
            m_pids.append(it.key);
        }
    }
    for (auto pid : pids_to_remove)
        m_threads.remove(pid);

    if (on_new_cpu_data_point)
        on_new_cpu_data_point(total_cpu_percent);

    did_update();
}