Change logic at runtime - c++

The new Unreal Engine 4 is able to change the game logic at runtime. For example you can jump into the game, change some game logic and once it is recompiled it will be updated in the game itself.
I was wondering how they did it?
My first idea was that they separate their game logic to a .dll and then they are just reloading/injecting it at runtime. But I also know that .dlls are windows specific. I think the equivalent in linux is called .elf.
What alternatives are there?
I also know that there is a c++ interpreter available but I think the newer version uses a jit compiler now. Would this help me in any way?
I hope you can clear things up for me.

Unreal Engine does this by using Hot Reload which basically (re)compiles the source code that has been changed and reloads it back into game. The game will be in a paused state while compilation is taking place.
This presentation goes into more detail about the technique.

Related

why does a DX12 app with SDI/MDI make strange flickering when using the DXGI_FORMAT_R16G16B16A16_FLOAT for the back buffer

I have been programming on DirectX12 since last year, and I've experienced DX10 and 11. There is something bizarre I found in my application DX12 and i am not able to find why or a solution. I cannot show my original code, but it's ok, because it happens in any simply DX12 sample.
We can use directly the Triangle Sample (provided by DirectX12 officials) for example. I integrate it without modifying anything basic in a MFC SDI application, and until now everything works fine. But after I change the Swap Chain format to DXGI_FORMAT_R16G16B16A16_FLOAT, the application produces flickers when other windows or apps are staying/moving on the top of it but without entirely covering it. You can find here the video I made (sorry for the quality) to show the flickering, and also here the visual c++ 2015 mfc sample.
I tried something like changing erasebackground method, but still can't find a solution... Is this a programming level problem? but in which level, MFC, DirectX12, or DXGI? Or is this a os or hardware level problem??
I have already give the whole project vc++, so i suppose I can jump the step of giving the "Minimal, Complete, and Verifiable example". I dont show the code, because I dont know which part of code may be the cause of the problem, and also I am not sure if it is coding problem. And I would like to mention that the problem arises only when I replace the DXGI_FORMAT_R8G8B8A8_UNORM by DXGI_FORMAT_R16G16B16A16_FLOAT. And by the way, the flickering does not happen with DirectX11 if i do the same "integration to MFC" thing.
PS. There is no error or warning when debugging in VC2015.
PS. the same thing happens when I integrate the sample (by making it dll) into an C# Winforms apps.

VST2.x GUI How does it work?

Although I know how to create a VST plugin today, I still don't understand the GUI part of it.
I've been playing around with Steinbergs samples and what I can see is that they are using some default sliders in the exapmles, but am I supposed to use these when designing my own and apply some graphics to them? Or should I create my own completly? How should I think around the GUI approach to make the GUI code also work for both PC and MAC later on?
I've been searching my rearbehind off but can't find anything about these questions anywhere. Please give my a lead or guide me to the light so I can grow my hair back.
How should I think around the GUI approach to make the GUI code also
work for both PC and MAC later on?
If that is your ultimate goal, then I strongly suggest you check out the JUCE library. The plugin wrappers are very good and it is completely cross-platform.

Mute all but my application

I made little sound generator in C# 4.0 using DirectSound.
I would like to mute all other sounds. I want only my application to be able to emit sounds.
How to do it?
I know how to pInvoke so you can give me unmanaged code.
Properly designed programs either stop playing back sound when their main window becomes deactivated. Or use IDirectSound::SetCooperativeLevel() so they play nice with other programs that want to be heard.
You are asking how to make a improperly designed program behave nicely. With a bit of a hint that you don't contemplate being nice yourself. Teaching that uncooperative program a lesson is simple, run its uninstaller. Avoid being the victim of that same advice.

What's the best language for real-time graphics programming on Android?

Some googling has led me to believe that C++ is the best language for real-time 2D graphics programming, but since the Android is Java-based, is that still the best option? Or us the fact that I have to use NDK going to slow it down or something? My program also has a lot of scientific computing and I know C++ is best/fastest for that...
I've never done anything with the Android before so I'm really helpless right now. If I'm just going about it the wrong way, please give me other suggestions... Some other vocab I came across is OpenGL (which I have experience with, but that's more for 3D, right?) and Canvas (don't quite get this)? If I could get access to GPU-like capabilities that would be great.
Android applications are written Java, yes - however the Android NDK allows you to write performance-critical sections of your program in C or C++. From the Android NDK website,
The Android NDK is a companion tool to
the Android SDK that lets you build
performance-critical portions of your
apps in native code. It provides
headers and libraries that allow you
to build activities, handle user
input, use hardware sensors, access
application resources, and more, when
programming in C or C++.
That said, using the NDK appropriately will most likely not slow your program down.
OpenGL works for 3D and 2D graphics - if you're only interested in 2D you will want to look at using an Orthographic Projection - see glOrtho for more information. The Android Canvas, on the other hand, is the Java method for drawing raster graphics to the screen. It will let you render 2D graphics, but at a slower rate (and with frequent interruptions from the Android Garbage Collector).
Keep in mind that if you want to use C++, as of writing, there is no STL implementation available. There are, however unofficial ports that provide most of the functionality. STLPort is one that I have tried with some success. The biggest reason to move code to C/C++ is because of interruptions from the Android Java Garbage Collector - if you're not overly careful with your code, it will interrupt your program frequently to clean up objects you've left lying around. In practice this can limit game or simulation framerates drastically.
All that said, I would strongly recommend you look into one of the few open source android game engines that are cropping up. The best one I've tried is libGDX. It takes care of all the messy NDK details and lets you code your game / simulation purely in Java. It automatically runs the performance-heavy parts of the game engine in native code to get the fastest possible performance with the ease of coding in Java. Best of all, you can write your application code once and have it automatically run on Windows, Linux, OSX and Android - which makes testing your applications much, much easier than using the Android Emulator.
If you really want to look into the NDK yourself, or need to have really fine control on what OpenGL is doing, I would recommend you download the Android SDK and NDK, get eclipse set up, and then start with the NDK samples. There is an OpenGL demo there that shows you how to get everything set up. Another good starting point would be the SpinningCube google project.
EDIT: I'm not really sure if what you mean by 'GPU-like capabilities', but With libGDX, you can compile vertex and fragment shaders under OpenGL ES 2.0 - you could use this to run embarrassingly parallel code using the device's GPU.
You're making the assumption that the Android system will be too slow to do what you want, without any data to back that up. Write some tests in Java, and test out the performance first. You don't want to make assumptions about performance without any basis.
Premature optimization is the root of
all evil. - Knuth
How to do it: C-programmers guide to Java and JNI in Android
Good question, I put myself like 1½ years ago, found it very annoying. I feel a lot for you!
And because of this I like to give a hands on answer.
But look it is easy if you follow this guideline step by step (you will have much less struggle). I did it.
Learning this, you can in no time learn easily write Java Netbeans GUI with JNI apps (for any other OS) also, you are in the Java GUI JNI development world?
The basis is “knowing C/C++ very well, not knowing Java or Android programming at all, coming from for instance the Win32 SDK culture and making the first Android app”.
Android GUI is Java – you have to yield
Thing is that the GUI of Android is Java. Java like your app and the app is more or less in practice a piece of the GUI/OS environment completely integrated calling Java GUI SDK code all the time. The debugger even goes into the Java GUI SDK source code (feels like going off road, real odd for a Win32 SDK programmer).
In short, no way writing any Android apps, but in Java.
But it is pretty easy in anyway, you got the JNI
There are three very good shortcuts:
The Android sample library (is very rich), especially the Hello JNI sample is really important
The fact Java is in syntax very much alike C/C++ (but very different in its soul, read below, you need to understand)
You got the JNI C-code opportunity in doing the heavy work (and you major share of the code)
You have to write a small Java Android GUI user interface for your app (by thieving form samples) and the major part JNI, where you write your C/C++-code doing all the work.
Start with the Hello JNI sample program
Install Java and Android Studio and that it is all you need in tools (available in Win10, OSX or Ubuntu, they are the same).
Start Android Studio and its generic picture is a menu, select the lowest, Import an Android code sample.
The main sample program for a traditional C/C++ programmer is Hello JNI. Select it and say next to everything.
The Android Studio editor will open with the sample code (chews somewhat first see status line low).
Up to the right you (might need to push the Android tab to) see the content of your project Hello JNI, app. It consists of:
Manifests (app declaration, today of minor importance because most is now in Gradle script declarations (below))
Java tab for the Java files
Cpp-tab for your C-code files
Resources (texts, menus and icons)
Gradle compiling scripts
C-make-files
The Android studio might ask you for installation plugin upgrades, say yes to everything until it is done (see status line below).
Then run the Hello JNI sample code, to make certain your installation is OK
Pushing the green arrow in a cogwheel (mid top).
You get a dialogue box. Here you can try the sample on:
A physical Android device (via a cable from your PC, might need a Samsung win driver from their support)
A HAXM Android unit emulator (is reel good)
But you need to switch off the Hyper-V feature (used for XP emulation) in Win10 to make it run. Android studio might do it automatically for you asking, else control panel/Programs and functions/Windows functions.
Select Create new Virtual device. You might need to do some installation plugin upgrades more, say yes to everything.
When the Hello JNI app is working in the device, you have an OK installation.
C-code, check hello-jni.c
Look in the cpp-folder Up right) and you will find a C-file with a function.
Here and in any other C-file you can fill it with regular C-code.
Everything but the ANSI C locale features are supported (must get locale data from Java and transport them to the C-environment).
You need to edit the CMakeLists.txt file to add any additional C/C++-files (it is the makefile, look up to the right under the Gradle scripts).
Memory heaps, Java with JNI and C are different
You must be aware that everting in the data jstrings delivered by the JNI interface is located in the Java memory heap. This is also the case after the data has been in delivered C-format by JNI.
You will have fuzz if you don’t copy string data (and arrays) from the Java heap to the C-heap. Make a basic function like this to copy the data and release the JNI data:
char *GetStringfromJniString(JNIEnv *env, jstring jniString)
{
const char *TempString = (*env)->GetStringUTFChars(env, jniString, 0);
char *String = calloc(strlen(TempString) + 1, sizeof(char));
strcpy(String, TempString);
(*env)->ReleaseStringUTFChars(env, jniString, TempString);
return String;
}
When you send data to Java jstrings you need to contain it to the JNI transport by using the
return (*env)->NewStringUTF(env, pCstring);
Long funny names of the JNI-functions
The function name is Java_com_example_hellojni_HelloJni stringFromJNI(…).
There “Java” is always there
com_example_hellojni means it communicate with your app in the Java com.example.hellojni Java package (read about it in the tutorial)
The HelloJni is the name of the Java file the JNI function is declared
And stringFromJNI(…) is the actual function name (functions in Java are called Methods).
If naming is OK the declaration of the C JNI-functions in the Java file is black text, if not red text. (Give it a chance, it stores and checks the code continuously in the Java environment, might take a few seconds to verify it is right (becoming black).
You must declare the C JNI-functions in java
In the Java file here HelloJni.java the JNI-functions must declared as Java Methods (functions in Java).
public native String stringFromJNI(…);
Where return values and function/method switches are the same as in C.
After that you can use the JNI-functions as Java methods as they are declared in the Java declaration. Note that char * is String in java.
Constants must be declared on both sides
#define CONSTANT_A = 24
Is in Java
static final int CONSTANT_A = 24;
And you can use them in Java and in C as usually.
if(!variable) does not work in Java
You need to do
if(variable==0)
Test other samples
The sample library is full of fully nice functioning Java samples. Try them one by one until you find a user interface of your like. It is actually nice to test samples.
There are a lot of sample in Github but a lot of them need fixes of Gradle scripts or comes from Eclipse (the past Android dev environment) and is harder to try (often need fixes). Other Github sample are just fragments and a lot of work making them working. Of course nothing for a Java Android star but we are not there yet. But Github a very good even larger source of samples.
Copy the Java stuff into your Hello-JNI
Found anything nice, copy it!
Theft always pays as JS Bach used to do!
It is quite easy to just copy stuff from one sample to another. When copying in the Android studio, Android studio adds automatically the includes (asking first) and just accept. Sometimes it does it asking you to enter Alt-Enter, do it.
Editing several projects at the same time
The File/Open recent - Own windows-command, make you having two projects up at the same time, easier to copy stuff in between.
Making your own application
After some testing you create your own app.
Go to the generic Android studio picture (file/close project), select Start a new Android Studio project. Put your Package tree data (think that over, read about it in the tutorial) and create it. Then copy the stuff you tested to your own app.
Learn Java, the Android developer tutorial is real good
Now you have made your environment working and spotted some good user interfaces, learn Java!
The Android Studio tutorial is real good. Try it, and soon after a few lessons you will be able to play with Java code and very soon you are a Java programmer.
Getting stuck, google and you find most answers in Stackoverflow, just search.
You are never the first with a problem and Stackoverflow is real good. Read all the answers and think, you find what fits you best.
The Java environment and Android OS is very different from Windows
You need a feeling for the culture and environment. Like a Swede coming to Norway, the same food taste slightly different, even if it looks the same.
The major difference is that in Java nothing crash as good as in pure C in a C environment. Finding bugs can be hell because of non-consistent crashing. The program continue to run and crash later, but you find the bugs.
There are Java log files for debugging, but it takes quite an effort to penetrate it. Like learning the assembly code in a Windows debugger.
A good idea is to really debug the C-code in a pure C-environment first and handle the Java stuff in Android Studio.
I can amend C-code in Android Studio but writing a large chunk of C-code is really looking for troubles debugging it. Like asking a Norwegian make a Swedish dinner, impossible to get it right, looks the same but taste different. Nothing is wrong but different culture.
The soft crashing style of Java includes even security soft crash features like the try/catchy/finally stuff. (You have to google and read about it yourself. It is unbelievable for a hard core C-programmer, but it is real.)
There are no h-files and #if-compiler switches in Java
Instead of h-files and common declarations of functions/variables as in C in java you have to refer to them with a filename followed by a dot and the method name, using them from another file.
If declared private variables and methods can only be accessed from the same file, with public can be used with file reference. Static is something very different in Java.
There are no compiler #if-switches so you need to use regular variables/constants (for constants put final before in the declaration).
There are no pointers in Java, but there are strings
There are no pointers in Java but a String (and array) variable is in fact a char pointer
But you can’t handle pointers as in C with * and &, but in JNI you certainly can. The memory management is completely different, nothing is fixed in Java.
You don’t need to free data, Java wipes it all for you
Java cleans unused data automatically.
You don’t free data just delete (=0;) the string-“pointers” or just leave the method (Java function) and it cleans it.
So if you have a string pointer and just replace it with something else the old stuff is automatically wiped.
The Java environment lives its own life, but the Android studio debugger includes a monitor of the data used.
Size limitations of Java apps and JNI code
Good to know is that there are some restrictions in how large a Java app can be (but as usual nothing is written in stone in Java) but the JNI heap can be as large as the HW can take.
But you are not alone in a phone, an incoming call might come and you don’t want to mess that up? If you clean well it is a larger chance your app is intact returning to it and not killed.
Android apps don’t die by exit
If you exit an app, the app is still running even though the GUI is gone (like in Macintosh). Thing is that you have to be aware of that, read about it if you make serious apps.
Android kills apps
But on the other hand you can never trust that an app is not wiped by the OS and you have to rebuild. If the OS need memory it just starts to kill apps. But the JNI part usually survive and you can store data there for a recovery.
There is only one JNI instance (WinSDK term) but there might be many Java instances
And them all connect to the same JNI at the same time. Only one app instance can be active (shown) but the others might make background tasks. In JNI you need to keep track of them.
Normally there is only one Android instance of every app. But if you start the app by a work files from for instance like an email client, you in fact have another instance of the app (with its own memory and everything (but the JNI that is in only one common instance)).
Starting an appended file there will be two or more Android instances. Each related to each email instance, by the intents procedures (learn about intents in Android tutorial).
A smart thing is keeping track of the instances by number them when the app is created if savedInstanceState == null.
Copy data to the emulated unit
You might need to upload some data to test your app. In a regular phone you just attach the USB-cable and enter the Phone storage from Windows explorer. With the emulated units you must use the adb-terminal script functionality (can be used in bat-files in Windows and a copy bat file looks like this:
PATH=%PATH%;C:\Users\You\AppData\Local\Android\sdk\platform-tools
adb push C:\Users\You\Documents\v.txt /storage/emulated/0/Android/data/com.yours.app/files/v.txt
Very limited privileges to read and write files
Thing is however that you are only allowed to open your own files stored by your app in the emulated SD card. Else nothing comes reading them.
Use standard ANSI C file functions rather than Java
Best in a C-heavy app is to use standard C- file functions, as a C-programmer you are used to them and their behavior.
The C-file functions works fine and is easier to get binary code or transparent text files with ctrl-characters etc (Is not allowed in Java Strings but in java bit arrays). Take some effort learning Java file handling if you try that.
JNI performance is no issue
The C-code is much faster than the Java code so a lot of developers not from the C-culture must make JNI-functions and pure C-code to perform in heavy apps, needing performance. In short JNI performance is no issue.
However I have the impression that the Android GUI is faster than the WinSDK GUI in many cases. Working with ListViews and sometimes very long lists, Android is far better optimised. It looks like WinSDK is loading every line of the list, but Android only the lines visual, and in long lists it makes a huge difference.
I am impressed by performance in Android even with tiny ARM processors. Apps do perform very well. Intel Android units are real good in performance. I wouldn't hesitate trying to make a heavy duty app in Android, as long as I use JNI. Does not come short compared to Windows.
But notice, that running HAXM in an Intel PC the Intel emulated units runs much faster than the ARM than in real HW-units, because it runs intel code straight and not over an emulator layer as with ARM emulated units.
I am amazed that the Android x86 is not marketed heavier as a competitor to Windows on netbooks, for the common man, doing some documents, some calculations, email and Google? I believe the Crome OS is too alien for most people and most people have Android phones, feeling home. As a SW vendor I would like to see Android netbooks marketed much more and I would put more effort in SW development. Same thing with the Android TV without menus is closing the market for just the old Smart-TV approach. Something I can't understand having a boxed Win10 on the back of my TV since years, using a lot of programs there. The lack of Android graphics driver for the Raspberry-pie is also hard to understand, one with a regular Android would be smashing attached to the TV. In Sweden where I live, people under 40 don't watch aired TV, they stream, public service play, YouTube and Cable TV operators packages over internet. Having regular Android in the TV would generate usage of a lot of other apps. I see a market opportunity for SW vendors is closed. This when MS is making suicide with leased SW (normal people don't pay) mixing the culture of large accounts with the common man, a huge marketing window is opened. And the Android app performance is real good and nothing to worry about. It is not performance but marketing policies that limits the app market.
Quick you become a Java and Android master
You will be surprised how easy Java is for a C-programmer, doing it the right way (like following this guideline).
It might be slightly harder for a C++-programmer because the Classes in java and C++ culture looks to vary, might be easier to learn Java classes from scratch? But if you see C++-code in Win32 and OSX environment they look usually from different planets, so they might use to it.
The major disadvantage is that you wouldn’t get a diploma for your CV as doing a programmers course?

Is there a simple way for opening one (or many) opengl window in mac OS X with C++?

Yes, I hate Objective-c, plus my project will be portable, so I'd like to code as much of it in C++ as possible, ideally 100%.
So I have a regular C++ project made with Xcode, and want to open some OpenGL windows.
edit: Damn, Glut takes over the app's control with glutMainLoop() and I'll like to have more control over the loop.
Will try freeglut, although I can't find OSX binaries, and I always have such bad luck trying to compile someone else's code.
Update:
I tried yet again to link to SDL 1.3 and this time I could get it to work! yoo-hoo!
I always wanted to work with SDL, but using more than one window was mandatory, and that's a feature of version 1.3 which is under development and I never could get it working.
As it is portable to a zillion OSes, and handles 2D graphics as well as OpenGL I'm going with it. Thanks to all!
If you don't want to use objective-c you're going to have to use either the deprecated carbon libraries, X11, or another library like GLUT to create the window. If portability is a concern either go the GLUT route, or you'll need to write your own window management code for each platform you want to support.
If you don't go the GLUT route you will need to write window management code fore each operating system so I strongly suggest you bite the bullet and write the window management in objective-c++. The only thing you really need to know is that a pointer is always a pointer no matter which language it is in, so just store objective-c ids as void* and cast them back to ids, it actually works out pretty easy.
i guess NeHe tutorials could help;
GLUT works fine for your stated purpose, although you will probably wish for a nice C++ wrapper for it. I ended up hacking my own, and although GLUT isn't friendly to wrapping, it was doable.
EDIT: Since you have a problem with glutMainLoop(), you may be trying to do more than GLUT was designed to do -- it is mainly intended for hacks, one-off projects and opengl demos. And freeglut doesn't compile OOB on the mac, at least that was my experience.
For a portable, fuller featured app, Qt may be the way to go for you. Otherwise, design your C++ for portability and use a thin GUI layer on each platform. If getting something running on each platform is most important, go for the former. If the best user experience on each platform is most important, go for the latter. You may find that "thin" is not the most descriptive term for what is involved.
I found this demo to be useful for getting a simple Cocoa/OpenGL window working, even though the code has a number of ridiculous bugs: http://developer.apple.com/library/mac/#samplecode/CocoaGL/Introduction/Intro.html
This question has been asked over 3 years ago, yet remain quite fresh. I just recently went through similar exercise for planning school curriculum, and trying to figure out what's the best portable library to work with on Mac/Windows/Linux/mobile with OpenGL projects. Perhaps my notes will help someone make a decision. I only mention the main options that I've considered.
Higher level APIs, for window management plus additional goodies, like sprites, fonts, sounds, event handling, etc:
SFML and github repo: nice&tidy, C++, object oriented library that integrates with OpenGL natively. Portability for managing windows and OpenGL 3.3 contexts out of the box on MacOS, Win and Linux. Mobile support provided in the 2.2 branch (github).
SDL2: all major platforms, including mobile, supported. The OpenGL context needs to be manually managed somewhat, so use of GLEW for example comes really handy (see below). A bit lower level than SFML.
Lower level APIs, mostly for window and OpenGL context management:
GLWF: This is pretty much a GLUT replacement for modern OpenGL. Rather low level, but portable across: Win, OSX, Lin. In active development.
GLEW: I only mention it for completness. It doesn't manage windows, but helps managing OpenGL contexts and you might use it together with GLWF or SDL for example.
Others:
Freeglut: Open source continuation of GLUT. Suitable for small demo projects. I have not used it myself, but seen good docs and demo code. In active development.
GLUT: old one, discontinued. Legacy demos and code around the net.