Nerfed/Nerfed.Runtime/ProfilerVisualizer.cs

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C#
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using ImGuiNET;
using System.Numerics;
namespace Nerfed.Runtime;
public static class ProfilerVisualizer
{
private const float barHeight = 20f;
private const float barPadding = 2f;
// Render the flame graph across multiple threads
public static void RenderFlameGraph(Profiler.Frame frame)
{
if (frame == null) return;
if (frame.RootNodes == null) return;
// Calculate the total timeline duration (max end time across all nodes)
double totalDuration = frame.EndTime - frame.StartTime;
double startTime = frame.StartTime;
// Precompute the maximum depth for each thread's call stack
Dictionary<int, int> threadMaxDepths = new Dictionary<int, int>();
foreach (IGrouping<int, Profiler.ScopeNode> threadGroup in frame.RootNodes.GroupBy(node => node.ManagedThreadId))
{
int maxDepth = 0;
foreach (Profiler.ScopeNode rootNode in threadGroup)
{
maxDepth = Math.Max(maxDepth, GetMaxDepth(rootNode, 0));
}
threadMaxDepths[threadGroup.Key] = maxDepth;
}
// Start a child window to support scrolling
ImGui.BeginChild("FlameGraph", new Vector2(0, 64), ImGuiChildFlags.Border | ImGuiChildFlags.ResizeY, ImGuiWindowFlags.HorizontalScrollbar | ImGuiWindowFlags.AlwaysVerticalScrollbar);
ImDrawListPtr drawList = ImGui.GetWindowDrawList();
Vector2 windowPos = ImGui.GetCursorScreenPos();
// Sort nodes by ThreadID, ensuring main thread (Thread ID 1) is on top
IOrderedEnumerable<IGrouping<int, Profiler.ScopeNode>> threadGroups = frame.RootNodes.GroupBy(node => node.ManagedThreadId).OrderBy(g => g.Key);
// Initial Y position for drawing
float baseY = windowPos.Y;
bool alternate = false;
float contentWidth = ImGui.GetContentRegionAvail().X;
// Draw each thread's flame graph row by row
foreach (IGrouping<int, Profiler.ScopeNode> threadGroup in threadGroups)
{
int threadId = threadGroup.Key;
// Compute the base Y position for this thread
float threadBaseY = baseY;
// Calculate the maximum height for this thread's flame graph
float threadHeight = (threadMaxDepths[threadId] + 1) * (barHeight + barPadding);
// Draw the alternating background for each thread row
uint backgroundColor = ImGui.ColorConvertFloat4ToU32(alternate ? new Vector4(0.2f, 0.2f, 0.2f, 1f) : new Vector4(0.1f, 0.1f, 0.1f, 1f));
drawList.AddRectFilled(new Vector2(windowPos.X, threadBaseY), new Vector2(windowPos.X + contentWidth, threadBaseY + threadHeight), backgroundColor);
alternate = !alternate;
// Draw each root node in the group (one per thread)
foreach (Profiler.ScopeNode rootNode in threadGroup)
{
RenderNode(drawList, rootNode, startTime, totalDuration, windowPos.X, threadBaseY, 0, contentWidth, false);
}
// Move to the next thread's row (max depth * height per level)
baseY += (threadMaxDepths[threadId] + 1) * (barHeight + barPadding);
}
// Ensure that ImGui knows the size of the content.
ImGui.Dummy(new Vector2(contentWidth, baseY));
ImGui.EndChild();
}
private static void RenderNode(ImDrawListPtr drawList, Profiler.ScopeNode node, double startTime, double totalDuration, float startX, float baseY, int depth, float contentWidth, bool alternate)
{
if (node == null) return;
double nodeStartTime = node.StartTime - startTime;
double nodeEndTime = node.EndTime - startTime;
double nodeDuration = nodeEndTime - nodeStartTime;
// Calculate the position and width of the bar based on time
float xPos = (float)(startX + (nodeStartTime / totalDuration) * contentWidth);
float width = (float)((nodeDuration / totalDuration) * contentWidth);
// Calculate the Y position based on depth
float yPos = baseY + (depth * (barHeight + barPadding)) + (barPadding * 0.5f);
// Define the rectangle bounds for the node
Vector2 min = new Vector2(xPos, yPos);
Vector2 max = new Vector2(xPos + width, yPos + barHeight);
// Define color.
Vector4 barColor = alternate ? new Vector4(0.4f, 0.6f, 0.9f, 1f) : new Vector4(0.4f, 0.5f, 0.8f, 1f);
Vector4 textColor = new Vector4(1f, 1f, 1f, 1f);
if (depth != 0)
{
// Draw the bar for the node (colored based on thread depth)
drawList.AddRectFilled(min, max, ImGui.ColorConvertFloat4ToU32(barColor));
// Draw the label if it fits inside the bar
string label = $"{node.Label} ({node.ElapsedMilliseconds():0.000} ms)";
if (width > ImGui.CalcTextSize(label).X)
{
drawList.AddText(new Vector2(xPos + barPadding, yPos + barPadding), ImGui.ColorConvertFloat4ToU32(textColor), label);
}
// Add tooltip on hover
if (ImGui.IsMouseHoveringRect(min, max))
{
// Show tooltip when hovering over the node
ImGui.BeginTooltip();
ImGui.Text($"{node.Label}");
ImGui.Text($"{node.ElapsedMilliseconds():0.000} ms");
ImGui.Text($"{node.ManagedThreadId}");
ImGui.EndTooltip();
}
}
else
{
// Aka root node.
string label = $"{node.Label}";
drawList.AddText(new Vector2(startX + barPadding, yPos + barPadding), ImGui.ColorConvertFloat4ToU32(textColor), label);
}
// Draw each child node under this node
foreach (Profiler.ScopeNode child in node.Children)
{
alternate = !alternate;
RenderNode(drawList, child, startTime, totalDuration, startX, baseY, depth + 1, contentWidth, alternate);
}
}
// Recursive function to calculate the maximum depth of the node tree
private static int GetMaxDepth(Profiler.ScopeNode node, int currentDepth)
{
if (node.Children == null || node.Children.Count == 0)
{
return currentDepth;
}
int maxDepth = currentDepth;
foreach (Profiler.ScopeNode child in node.Children)
{
maxDepth = Math.Max(maxDepth, GetMaxDepth(child, currentDepth + 1));
}
return maxDepth;
}
}