providing a different user interface: • VS Code is a full IDE with built-in support for profile visualization • ProfileView.jl is a stand-alone visualizer based on GTK • ProfileVega.jl uses VegaLight and but can also generate interactive HTML files. An entirely independent approach to profile visualization is PProf.jl, which uses the external pprof tool. Here, though, we'll use the text-based display 434 In this simple example, we use PProf to visualize the alloc profile. You could use another visualization tool instead. We collect the profile (specifying a sample rate), then we visualize it. using

providing a different user interface: • VS Code is a full IDE with built-in support for profile visualization • ProfileView.jl is a stand-alone visualizer based on GTK • ProfileVega.jl uses VegaLight and but can also generate interactive HTML files. An entirely independent approach to profile visualization is PProf.jl, which uses the external pprof tool. Here, though, we'll use the text-based display 434 In this simple example, we use PProf to visualize the alloc profile. You could use another visualization tool instead. We collect the profile (specifying a sample rate), then we visualize it. using

providing a different user interface: • VS Code is a full IDE with built-in support for profile visualization • ProfileView.jl is a stand-alone visualizer based on GTK • ProfileVega.jl uses VegaLight and but can also generate interactive HTML files. An entirely independent approach to profile visualization is PProf.jl, which uses the external pprof tool. Here, though, we'll use the text-based display 434 In this simple example, we use PProf to visualize the alloc profile. You could use another visualization tool instead. We collect the profile (specifying a sample rate), then we visualize it. using

providing a different user interface: • VS Code is a full IDE with built-in support for profile visualization • ProfileView.jl is a stand-alone visualizer based on GTK • ProfileVega.jl uses VegaLight and but can also generate interactive HTML files. An entirely independent approach to profile visualization is PProf.jl, which uses the external pprof tool. Here, though, we'll use the text-based display 444 In this simple example, we use PProf to visualize the alloc profile. You could use another visualization tool instead. We collect the profile (specifying a sample rate), then we visualize it. using

providing a different user interface: • VS Code is a full IDE with built-in support for profile visualization • ProfileView.jl is a stand-alone visualizer based on GTK • ProfileVega.jl uses VegaLight and but can also generate interactive HTML files. An entirely independent approach to profile visualization is PProf.jl, which uses the external pprof tool. Here, though, we'll use the text-based display 445 In this simple example, we use PProf to visualize the alloc profile. You could use another visualization tool instead. We collect the profile (specifying a sample rate), then we visualize it. using

providing a different user interface: • VS Code is a full IDE with built-in support for profile visualization • ProfileView.jl is a stand-alone visualizer based on GTK • ProfileVega.jl uses VegaLight and but can also generate interactive HTML files. An entirely independent approach to profile visualization is PProf.jl, which uses the external pprof tool. Here, though, we'll use the text-based display 444 In this simple example, we use PProf to visualize the alloc profile. You could use another visualization tool instead. We collect the profile (specifying a sample rate), then we visualize it. using

providing a different user interface: • VS Code is a full IDE with built-in support for profile visualization • ProfileView.jl is a stand-alone visualizer based on GTK • ProfileVega.jl uses VegaLight and but can also generate interactive HTML files. An entirely independent approach to profile visualization is PProf.jl, which uses the external pprof tool. Here, though, we'll use the text-based display 444 In this simple example, we use PProf to visualize the alloc profile. You could use another visualization tool instead. We collect the profile (specifying a sample rate), then we visualize it. using

providing a different user interface: • VS Code is a full IDE with built-in support for profile visualization • ProfileView.jl is a stand-alone visualizer based on GTK • ProfileVega.jl uses VegaLight and but can also generate interactive HTML files. An entirely independent approach to profile visualization is PProf.jl, which uses the external pprof tool. Here, though, we'll use the text-based display 444 In this simple example, we use PProf to visualize the alloc profile. You could use another visualization tool instead. We collect the profile (specifying a sample rate), then we visualize it. using

providing a different user interface: • VS Code is a full IDE with built-in support for profile visualization • ProfileView.jl is a stand-alone visualizer based on GTK • ProfileVega.jl uses VegaLight and but can also generate interactive HTML files. An entirely independent approach to profile visualization is PProf.jl, which uses the external pprof tool. Here, though, we'll use the text-based display 433 In this simple example, we use PProf to visualize the alloc profile. You could use another visualization tool instead. We collect the profile (specifying a sample rate), then we visualize it. using

providing a different user interface: • VS Code is a full IDE with built-in support for profile visualization • ProfileView.jl is a stand-alone visualizer based on GTK • ProfileVega.jl uses VegaLight and but can also generate interactive HTML files. An entirely independent approach to profile visualization is PProf.jl, which uses the external pprof tool. Here, though, we'll use the text-based display 433 In this simple example, we use PProf to visualize the alloc profile. You could use another visualization tool instead. We collect the profile (specifying a sample rate), then we visualize it. using