#include "stdafx.h" #include "overlays.h" #include "../GSRender.h" #include "Emu/Cell/SPUThread.h" #include "Emu/Cell/RawSPUThread.h" #include "Emu/Cell/PPUThread.h" #include "Utilities/sysinfo.h" namespace rsx { namespace overlays { inline color4f convert_color_code(std::string hex_color, f32 opacity = 1.0f) { if (hex_color.length() > 0 && hex_color[0] == '#') { hex_color.erase(0, 1); } unsigned long hexval; const int len = hex_color.length(); try { if (len != 6 && len != 8) { fmt::throw_exception("wrong length: %d", len); } hexval = std::stoul(hex_color, nullptr, 16); } catch (const std::exception& e) { LOG_ERROR(RSX, "Overlays: tried to convert incompatible color code: '%s' exception: '%s'", hex_color, e.what()); return color4f(0.0f, 0.0f, 0.0f, 0.0f); } const int r = (len == 8 ? (hexval >> 24) : (hexval >> 16)) & 0xff; const int g = (len == 8 ? (hexval >> 16) : (hexval >> 8)) & 0xff; const int b = (len == 8 ? (hexval >> 8) : (hexval >> 0)) & 0xff; const int a = len == 8 ? ((hexval >> 0) & 0xff) : 255; return color4f(r / 255.f, g / 255.f, b / 255.f, a / 255.f * opacity); } void perf_metrics_overlay::reset_transform(label& elm) const { const u32 text_padding = m_font_size / 2; // left, top, right, bottom const areau padding { text_padding, text_padding - 4, text_padding, text_padding }; const positionu margin { m_margin_x, m_margin_y }; positionu pos; const auto overlay_width = m_body.w + margin.x; const auto overlay_height = m_body.h + margin.y; switch (m_quadrant) { case screen_quadrant::top_left: pos.x = margin.x; pos.y = margin.y; break; case screen_quadrant::top_right: pos.x = virtual_width - overlay_width; pos.y = margin.y; break; case screen_quadrant::bottom_left: pos.x = margin.x; pos.y = virtual_height - overlay_height; break; case screen_quadrant::bottom_right: pos.x = virtual_width - overlay_width; pos.y = virtual_height - overlay_height; break; } if (g_cfg.video.perf_overlay.center_x) { pos.x = (virtual_width - m_body.w) / 2; } if (g_cfg.video.perf_overlay.center_y) { pos.y = (virtual_height - m_body.h) / 2; } elm.set_pos(pos.x, pos.y); elm.set_padding(padding.x1, padding.x2, padding.y1, padding.y2); } void perf_metrics_overlay::reset_transforms() { reset_transform(m_body); reset_transform(m_titles); } void perf_metrics_overlay::reset_body() { m_body.set_font(m_font.c_str(), m_font_size); m_body.fore_color = convert_color_code(g_cfg.video.perf_overlay.color_body, m_opacity); m_body.back_color = convert_color_code(g_cfg.video.perf_overlay.background_body, m_opacity); reset_transform(m_body); } void perf_metrics_overlay::reset_titles() { m_titles.set_font(m_font.c_str(), m_font_size); m_titles.fore_color = convert_color_code(g_cfg.video.perf_overlay.color_title, m_opacity); m_titles.back_color = convert_color_code(g_cfg.video.perf_overlay.background_title, m_opacity); reset_transform(m_titles); switch (m_detail) { case detail_level::minimal: case detail_level::low: m_titles.text = ""; break; case detail_level::medium: m_titles.text = fmt::format("\n\n%s", title1_medium); break; case detail_level::high: m_titles.text = fmt::format("\n\n%s\n\n\n\n\n\n%s", title1_high, title2); break; } m_titles.auto_resize(); m_titles.refresh(); } void perf_metrics_overlay::reset_text() { reset_body(); reset_titles(); } void perf_metrics_overlay::init() { reset_text(); force_next_update(); update(); m_update_timer.Start(); m_is_initialised = true; } void perf_metrics_overlay::set_detail_level(detail_level level) { m_detail = level; if (m_is_initialised) { reset_titles(); } } void perf_metrics_overlay::set_position(screen_quadrant quadrant) { m_quadrant = quadrant; if (m_is_initialised) { reset_transforms(); } } // In ms void perf_metrics_overlay::set_update_interval(u32 update_interval) { m_update_interval = update_interval; } void perf_metrics_overlay::set_font(std::string font) { m_font = font; if (m_is_initialised) { reset_text(); } } void perf_metrics_overlay::set_font_size(u32 font_size) { m_font_size = font_size; if (m_is_initialised) { reset_text(); } } void perf_metrics_overlay::set_margins(u32 margin_x, u32 margin_y) { m_margin_x = margin_x; m_margin_y = margin_y; if (m_is_initialised) { reset_transforms(); } } void perf_metrics_overlay::set_opacity(f32 opacity) { m_opacity = opacity; if (m_is_initialised) { reset_text(); } } void perf_metrics_overlay::force_next_update() { m_force_update = true; } void perf_metrics_overlay::update() { const auto elapsed = m_update_timer.GetElapsedTimeInMilliSec(); if (!m_force_update) { ++m_frames; } if (elapsed >= m_update_interval || m_force_update) { f32 fps{0}; f32 frametime{0}; u64 ppu_cycles{0}; u64 spu_cycles{0}; u64 rsx_cycles{0}; u64 total_cycles{0}; u32 ppus{0}; u32 spus{0}; f32 cpu_usage{-1.f}; u32 total_threads{0}; f32 ppu_usage{0}; f32 spu_usage{0}; f32 rsx_usage{0}; u32 rsx_load{0}; std::shared_ptr rsx_thread; std::string perf_text; // 1. Fetch/calculate metrics we'll need switch (m_detail) { case detail_level::high: { frametime = m_force_update ? 0 : std::max(0.0, elapsed / m_frames); rsx_thread = fxm::get(); rsx_load = rsx_thread->get_load(); total_threads = CPUStats::get_thread_count(); // fallthrough } case detail_level::medium: { ppus = idm::select>([&ppu_cycles](u32, named_thread& ppu) { ppu_cycles += thread_ctrl::get_cycles(ppu); }); spus = idm::select>([&spu_cycles](u32, named_thread& spu) { spu_cycles += thread_ctrl::get_cycles(spu); }); if (!rsx_thread) rsx_thread = fxm::get(); rsx_cycles += rsx_thread->get_cycles(); total_cycles = ppu_cycles + spu_cycles + rsx_cycles; cpu_usage = m_cpu_stats.get_usage(); ppu_usage = std::clamp(cpu_usage * ppu_cycles / total_cycles, 0.f, 100.f); spu_usage = std::clamp(cpu_usage * spu_cycles / total_cycles, 0.f, 100.f); rsx_usage = std::clamp(cpu_usage * rsx_cycles / total_cycles, 0.f, 100.f); // fallthrough } case detail_level::low: { if (cpu_usage == -1.f) cpu_usage = m_cpu_stats.get_usage(); // fallthrough } case detail_level::minimal: { fps = m_force_update ? 0 : std::max(0.0, static_cast(m_frames) / (elapsed / 1000)); } } // 2. Format output string switch (m_detail) { case detail_level::minimal: { perf_text += fmt::format("FPS : %05.2f", fps); break; } case detail_level::low: { perf_text += fmt::format("FPS : %05.2f\n" "CPU : %04.1f %%", fps, cpu_usage); break; } case detail_level::medium: { perf_text += fmt::format("FPS : %05.2f\n\n" "%s\n" " PPU : %04.1f %%\n" " SPU : %04.1f %%\n" " RSX : %04.1f %%\n" " Total : %04.1f %%", fps, std::string(title1_medium.size(), ' '), ppu_usage, spu_usage, rsx_usage, cpu_usage, std::string(title2.size(), ' ')); break; } case detail_level::high: { perf_text += fmt::format("FPS : %05.2f (%03.1fms)\n\n" "%s\n" " PPU : %04.1f %% (%2u)\n" " SPU : %04.1f %% (%2u)\n" " RSX : %04.1f %% ( 1)\n" " Total : %04.1f %% (%2u)\n\n" "%s\n" " RSX : %02u %%", fps, frametime, std::string(title1_high.size(), ' '), ppu_usage, ppus, spu_usage, spus, rsx_usage, cpu_usage, total_threads, std::string(title2.size(), ' '), rsx_load); break; } } m_body.text = perf_text; if (m_body.auto_resize()) { reset_transforms(); } m_body.refresh(); if (!m_force_update) { m_frames = 0; m_update_timer.Start(); } else { // Only force once m_force_update = false; } } } } // namespace overlays } // namespace rsx