34

I run through millions of records and sometimes I have to debug using Console.WriteLine to see what is going on.

However, Console.WriteLine is very slow, considerably slower than writing to a file.

BUT it is very convenient - does anyone know of a way to speed it up?

11
  • 1
    System io is inheritantly slow
    – Woot4Moo
    Mar 11, 2011 at 11:16
  • 11
    i don't think there is any way to speed it up more then to write less to it...
    – Peter
    Mar 11, 2011 at 11:16
  • 2
    I agree with Petoj. Whenever I output e.g. real-time data, I put a counter / timer in to only output 1% or so. Mar 11, 2011 at 11:18
  • I write to it the minimum amount, but for some test - it is still a huge amount. I don't understand why should be slower than writing to file...
    – ManInMoon
    Mar 11, 2011 at 11:19
  • 6
    why not output to a log file instead then? and maybe only output to the console when it's an error?
    – jb.
    Mar 11, 2011 at 11:21

8 Answers 8

15

If it is just for debugging purposes you should use Debug.WriteLine instead. This will most likely be a bit faster than using Console.WriteLine.

Example

Debug.WriteLine("There was an error processing the data.");
6
  • 1
    Where does that write to? i.e. how do I see it?
    – ManInMoon
    Mar 11, 2011 at 11:23
  • @MainInMoon, your Output Window. Mar 11, 2011 at 11:24
  • 2
    Why would screen redrawing of that take less long than Console.WriteLIne?
    – ManInMoon
    Mar 11, 2011 at 11:32
  • 7
    Filip is right that Debug.WriteLine is faster. But it's not just "a bit faster"... it's A LOT faster.
    – HappyNomad
    Apr 21, 2011 at 0:14
  • This is not faster than Console.WriteLine for me
    – Ahmad
    Aug 11, 2015 at 22:20
13

You can use the OutputDebugString API function to send a string to the debugger. It doesn't wait for anything to redraw and this is probably the fastest thing you can get without digging into the low-level stuff too much. The text you give to this function will go into Visual Studio Output window.

[DllImport("kernel32.dll")]
static extern void OutputDebugString(string lpOutputString);

Then you just call OutputDebugString("Hello world!");

9
  • And even though the Ouput screen needs to redraw - you belive this is faster than Console.WriteLine which writes to the same place?
    – ManInMoon
    Mar 11, 2011 at 11:52
  • 1
    The Pretender - just tested this - BUT it hasn't written to Output window - could it be somewhere else?
    – ManInMoon
    Mar 11, 2011 at 11:59
  • As far as I understand, your problem is that Console.WriteLine takes too much time to execute and blocks your program flow until it's finished. OutputDebugString will return immediately, whether the Output window has redrawn itself or not. If you are concerned with time between the function call and the time when you actually see the message, that's another story. Mar 11, 2011 at 12:01
  • But where does OutputDebugString output to?
    – ManInMoon
    Mar 11, 2011 at 12:05
  • 1
    You can also use DebugView (technet.microsoft.com/en-us/sysinternals/bb896647) то view these messages. I've just tested it with a sample .NET 4 console app and it works like a charm. Mar 11, 2011 at 12:45
10

Do something like this:

public static class QueuedConsole
{
    private static StringBuilder _sb = new StringBuilder();
    private static int _lineCount;

    public void WriteLine(string message)
    {
        _sb.AppendLine(message);
        ++_lineCount;
        if (_lineCount >= 10)
           WriteAll();
    }

    public void WriteAll()
    {
        Console.WriteLine(_sb.ToString());
        _lineCount = 0;
        _sb.Clear();
    }
}

QueuedConsole.WriteLine("This message will not be written directly, but with nine other entries to increase performance.");

//after your operations, end with write all to get the last lines.
QueuedConsole.WriteAll();

Here is another example: Does Console.WriteLine block?

6
  • Thanks for that. I have a fast writer that uses a file. I am just wondering why such a useful facility is slow - and forces us to come up with creative solutions...
    – ManInMoon
    Mar 11, 2011 at 11:33
  • Check the other answer that I added as a link.
    – jgauffin
    Mar 11, 2011 at 11:35
  • 2
    Might be better to create a class then the destructor can print the remaining buffer if the prog. crashes.
    – user159335
    Mar 11, 2011 at 11:36
  • Are you sure that the console is still intact if an application crashes?
    – jgauffin
    Mar 11, 2011 at 11:37
  • I was thinking of exceptions that may be caught at a higher level rather than anything catastrophic.
    – user159335
    Mar 11, 2011 at 11:39
10

I recently did a benchmark battery for this on .NET 4.8. The tests included many of the proposals mentioned on this page, including Async and blocking variants of both BCL and custom code, and then most of those both with and without dedicated threading, and finally scaled across power-of-2 buffer sizes.

The fastest method, now used in my own projects, buffers 64K of wide (Unicode) characters at a time from .NET directly to the Win32 function WriteConsoleW without copying or even hard-pinning. Remainders larger than 64K, after filling and flushing one buffer, are also sent directly, and in-situ as well. The approach deliberately bypasses the Stream/TextWriter paradigm so it can (obviously enough) provide .NET text that is already Unicode to a (native) Unicode API without all the superfluous memory copying/shuffling and byte[] array allocations required for first "decoding" to a byte stream.

If there is interest (perhaps because the buffering logic is slightly intricate), I can provide the source for the above; it's only about 80 lines. However, my tests determined that there's a simpler way to get nearly the same performance, and since it doesn't require any Win32 calls, I'll show this latter technique instead.

The following is way faster than Console.Write:

public static class FastConsole
{
    static readonly BufferedStream str;

    static FastConsole()
    {
        Console.OutputEncoding = Encoding.Unicode;  // crucial

        // avoid special "ShadowBuffer" for hard-coded size 0x14000 in 'BufferedStream' 
        str = new BufferedStream(Console.OpenStandardOutput(), 0x15000);
    }

    public static void WriteLine(String s) => Write(s + "\r\n");

    public static void Write(String s)
    {
        // avoid endless 'GetByteCount' dithering in 'Encoding.Unicode.GetBytes(s)'
        var rgb = new byte[s.Length << 1];
        Encoding.Unicode.GetBytes(s, 0, s.Length, rgb, 0);

        lock (str)   // (optional, can omit if appropriate)
            str.Write(rgb, 0, rgb.Length);
    }

    public static void Flush() { lock (str) str.Flush(); }
};

Note that this is a buffered writer, so you must call Flush() when you have no more text to write.

I should also mention that, as shown, technically this code assumes 16-bit Unicode (UCS-2, as opposed to UTF-16) and thus won't properly handle 4-byte escape surrogates for characters beyond the Basic Multilingual Plane. The point hardly seems important given the more extreme limitations on console text display in general, but could perhaps still matter for piping/redirection.

Usage:

FastConsole.WriteLine("hello world.");
// etc...
FastConsole.Flush();

On my machine, this gets about 77,000 lines/second (mixed-length) versus only 5,200 lines/sec under identical conditions for normal Console.WriteLine. That's a factor of almost 15x speedup.

These are controlled comparison results only; note that absolute measurements of console output performance are highly variable, depending on the console window settings and runtime conditions, including size, layout, fonts, DWM clipping, etc.

1
  • 1
    I tried calling FastConsole.Flush after each FastConsole.WriteLine, and the performance became almost identical with the native Console.WriteLine. I guess this was expected. The performance boost comes basically from omitting flushing the stream after each write. Sep 7, 2019 at 21:30
6

Why Console is slow:

  • Console output is actually an IO stream that's managed by your operating system. Most IO classes (like FileStream) have async methods but the Console class was never updated so it always blocks the thread when writing.

  • Console.WriteLine is backed by SyncTextWriter which uses a global lock to prevent multiple threads from writing partial lines. This is a major bottleneck that forces all threads to wait for each other to finish the write.

  • If the console window is visible on screen then there can be significant slowdown because the window needs to be redrawn before the console output is considered flushed.

Solutions:

Wrap the Console stream with a StreamWriter and then use async methods:

var sw = new StreamWriter(Console.OpenStandardOutput());
await sw.WriteLineAsync("...");

You can also set a larger buffer if you need to use sync methods. The call will occasionally block when the buffer gets full and is flushed to the stream.

// set a buffer size
var sw = new StreamWriter(Console.OpenStandardOutput(), Encoding.UTF8, 8192);
// this write call will block when buffer is full
sw.Write("...")

If you want the fastest writes though, you'll need to make your own buffer class that writes to memory and flushes to the console asynchronously in the background using a single thread without locking. The new Channel<T> class in .NET Core 2.1 makes this simple and fast. Plenty of other questions showing that code but comment if you need tips.

2
  • Am I right thinking that it's anyway gonna block a thread, right? Isn't this same as wrap a sync operation into something like Task.Run ? I see that OpenStandardOutput returns a Stream which provides an async API so that seems like I'm wrong and this is indeed asynchronous. Mar 29, 2022 at 20:42
  • @E.Shcherbo No. The first option uses standard async methods for writing to a stream, and stdout is just a stream. All you have to do is initialize your own StreamWriter instead of using the static Console class. This still uses a global lock if you're writing the entire line so there will be contention, which is what I talk about near the end. Mar 30, 2022 at 22:57
4

A little old thread and maybe not exactly what the OP is looking for, but I ran into the same question recently, when processing audio data in real time.

I compared Console.WriteLine to Debug.WriteLine with this code and used DebugView as a dos box alternative. It's only an executable (nothing to install) and can be customized in very neat ways (filters & colors!). It has no problems with tens of thousands of lines and manages the memory quite well (I could not find any kind of leak, even after days of logging).

After doing some testing in different environments (e.g.: virtual machine, IDE, background processes running, etc) I made the following observations:

  • Debug is almost always faster
  • For small bursts of lines (<1000), it's about 10 times faster
  • For larger chunks it seems to converge to about 3x
  • If the Debug output goes to the IDE, Console is faster :-)
  • If DebugView is not running, Debug gets even faster
  • For really large amounts of consecutive outputs (>10000), Debug gets slower and Console stays constant. I presume this is due to the memory, Debug has to allocate and Console does not.
  • Obviously, it makes a difference if DebugView is actually "in-view" or not, as the many gui updates have a significant impact on the overall performance of the system, while Console simply hangs, if visible or not. But it's hard to put numbers on that one...

I did not try multiple threads writing to the Console, as I think this should generally avoided. I never had (performance) problems when writing to Debug from multiple threads.

If you compile with Release settings, usually all Debug statements are omitted and Trace should produce the same behaviour as Debug.

I used VS2017 & .Net 4.6.1

Sorry for so much code, but I had to tweak it quite a lot to actually measure what I wanted to. If you can spot any problems with the code (biases, etc.), please comment. I would love to get more precise data for real life systems.

using System;
using System.Collections.Generic;
using System.Diagnostics;
using System.Linq;
using System.Threading;

namespace Console_vs_Debug {
 class Program {
  class Trial {
   public string name;
   public Action console;
   public Action debug;
   public List < float > consoleMeasuredTimes = new List < float > ();
   public List < float > debugMeasuredTimes = new List < float > ();
  }

  static Stopwatch sw = new Stopwatch();
  private static int repeatLoop = 1000;
  private static int iterations = 2;
  private static int dummy = 0;

  static void Main(string[] args) {
   if (args.Length == 2) {
    repeatLoop = int.Parse(args[0]);
    iterations = int.Parse(args[1]);
   }

   // do some dummy work
   for (int i = 0; i < 100; i++) {
    Console.WriteLine("-");
    Debug.WriteLine("-");
   }

   for (int i = 0; i < iterations; i++) {
    foreach(Trial trial in trials) {
     Thread.Sleep(50);
     sw.Restart();
     for (int r = 0; r < repeatLoop; r++)
      trial.console();
     sw.Stop();
     trial.consoleMeasuredTimes.Add(sw.ElapsedMilliseconds);
     Thread.Sleep(1);
     sw.Restart();
     for (int r = 0; r < repeatLoop; r++)
      trial.debug();
     sw.Stop();
     trial.debugMeasuredTimes.Add(sw.ElapsedMilliseconds);

    }
   }
   Console.WriteLine("---\r\n");
   foreach(Trial trial in trials) {
    var consoleAverage = trial.consoleMeasuredTimes.Average();
    var debugAverage = trial.debugMeasuredTimes.Average();
    Console.WriteLine(trial.name);
    Console.WriteLine($ "    console: {consoleAverage,11:F4}");
    Console.WriteLine($ "      debug: {debugAverage,11:F4}");
    Console.WriteLine($ "{consoleAverage / debugAverage,32:F2} (console/debug)");
    Console.WriteLine();
   }

   Console.WriteLine("all measurements are in milliseconds");
   Console.WriteLine("anykey");
   Console.ReadKey();
  }

  private static List < Trial > trials = new List < Trial > {
   new Trial {
    name = "constant",
     console = delegate {
      Console.WriteLine("A static and constant string");
     },
     debug = delegate {
      Debug.WriteLine("A static and constant string");
     }
   },
   new Trial {
    name = "dynamic",
     console = delegate {
      Console.WriteLine("A dynamically built string (number " + dummy++ + ")");
     },
     debug = delegate {
      Debug.WriteLine("A dynamically built string (number " + dummy++ + ")");
     }
   },
   new Trial {
    name = "interpolated",
     console = delegate {
      Console.WriteLine($ "An interpolated string (number {dummy++,6})");
     },
     debug = delegate {
      Debug.WriteLine($ "An interpolated string (number {dummy++,6})");
     }
   }
  };
 }
}
1

Just a little trick I use sometimes: If you remove focus from the Console window by opening another window over it, and leave it until it completes, it won't redraw the window until you refocus, speeding it up significantly. Just make sure you have the buffer set up high enough that you can scroll back through all of the output.

2
  • 1
    I haven;t found that that helps... even if I close Output winodw - the speed is the same
    – ManInMoon
    Mar 11, 2011 at 11:35
  • 1
    I don't think this makes a difference, either.
    – HappyNomad
    Apr 21, 2011 at 0:15
1

Try using the System.Diagnostics Debug class? You can accomplish the same things as using Console.WriteLine.

You can view the available class methods here.

1
  • If you meant Debug.WriteLine, it isn't. It seems to be a common misconception. That just wouldn't work unless a PC have an IDE.
    – Hi-Angel
    Sep 4, 2015 at 11:19

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