I don't understand the first function in the second code snippet in here. Why must there be a general foo_part accepting T when we are talking about specialization?
Shouldn't that go in the main foo function? I don't understand the purpose of template<typename T> inline void foo_part(const T& x).
The point is that you want to do something special for certain specializations of foo. If you simply specialize foo you have to rewrite all the functions, but maybe only 1 function needs to be changed and you are tired of copy-pasting the same code for all the foos. Therefore you put the specialization into a function and only specialize that function and then call that from foo.
I see. That's where the` template<typename T> inline void foo_part(const T& x)` confusion kicks in. What's the purpose of that one if I already have the general code in the main foo.
Ah, it's needed for the sake of the foo_part specialization overloads, right?
You can't overload a function if there is no function name to begin with. I think I get it.
Right. The point is to split foo into parts that need specializations and parts that don't so that when you specialize you don't have to copy+paste the non-specialized parts.
I'm not sure what the difference between "match" and "match exactly" is there. Clearly double and T * don't match at all. I could imagine that int and const T & "match", but don't "match exactly", but that seems to not be what they mean.
Also the "abcdef" is not that trivial either because there is a const char [7] -> const char * conversion going on that doesn't count as a conversion as far as overload resolution is concerned. At least I think that's how it works.
Classic GDI gives you a DC whose backing store is the video card itself. If you write a pixel to that DC, it goes straight to the video card and shows up on the screen. (DWM changes this model, but you should generally work with the classic model.) — Raymond Chen18 hours ago
@nwp FYI ^
So I guess it's like GDI is writing to a pixel buffer, but it doesn't use double buffering so there's no "frame rate" other than when the card decides to send the pixels over the wire. Seems like I'm still missing something, though.
@jrh It does, but you have to be careful what you use as your render target, as if you're using a DC render target then it just does a memcpy on the CPU into the DC memory
instead of doing a swapchain
which for most desktop applications is probably fine actually
I'd be interested to read more about what exactly a DC is, and what it was supposed to abstract
I've got about 8 winapi and MFC books but none of them really talk about how it works compared to something like Direct2D, or even the old DOS framebuffer
yeah, I've been through those articles. I just think it's a bit weird that the API gives you low level routines like drawing rectangles and lines, but it isn't really set up in a way that makes it easy to, for example, draw a background image, some rectangles on top of it, then push the frame out only after that without doing a lot of masking after drawing the background
I might play around with some old graphics drawing stuff in DOS to remind myself of how much work it really was to do double buffering back then, IIRC it was just an interrupt (after writing to the off-screen buffer)
actually I kinda tried that; I wanted to try to see the scan lines so I recorded the screen with a (somewhat) high speed camera, didn't really work though
I'd have to get a bit fancier with it, I think... I don't have my super fast cameras anymore
@jrh They probably were, it's just that it wasn't common in 2d applications where normally you'd write to a buffer (DC/Surface/Whatever) indicate that the paint had finished and let the underlying API do the swap
Remember GDI and Cairo are 2D drawing APIs
The need to have fast frame updates generally wouldn't have been a thing for 2D apps, and when they needed it they would have implemented for their specific sections of the screen requiring it
@jrh The old new thing has a ton of microsoft-internal information about the rational of various decisions. There is some GDI stuff too. Just in case you haven't seen it yet.
I kind of have a lot of nostalgia for DOS, plus professionally I'll probably never get away from Winforms (due to third party APIs, among other things), so I'll never really get away from GDI
and even if I did want to get away from GDI as my main graphics API, "the only way out is through", because I have to make sure whatever I replace it with doesn't break the stuff that has to use GDI.
So in the meantime I'll just have a good time learning how and why this whole thing got rolling and got built on, (Windows 1.0, VB6, Winforms), and then semi-replaced a couple times (DirectDraw, Direct2D, WPF, etc.); should be a good story
that's what I've heard, I've had limited luck embedding stuff like SDL surfaces but that was quite a long time ago and I've learned a lot since then; I'll give it another shot at some point.
I have this file:
ply
format ascii 1.0
element vertex 3
property float32 x
property float32 y
property float32 z
element faces 1
property list uint8 int32 vertex_indices
end_header
0.075 1.44 1.42483
0.075 1.45483 1.41
0.0601702 1.44 1.41
3 0 1 2
But when I run meshlab I can only see three poi...
@nwp I got it ->> "Class members cannot be captured explicitly by a capture without initializer (as mentioned above, only variables are permitted in the capture list)"
I suppose I can ask C questions here, just a really short one:
int soma(int a, int b) { return a+b; }
int main() {
int (*ptr)(int, int);
ptr = soma;
printf("%d\n", (*ptr)(3,4));
printf("%d\n", ptr(3,4));
return 0;
}
Because functions decay to function pointers and also there is a rule that calling a function pointer without dereferencing it first implicitly dereferences it.
printf("%d\n", (*************************ptr)(3,4)); should also compile.
The values specified in global_work_size cannot exceed the range given by the sizeof(size_t) for the device on which the kernel execution will be enqueued. The sizeof(size_t) for a device can be determined using CL_DEVICE_ADDRESS_BITS in the table of OpenCL Device Queries for clGetDeviceInfo
Points to an array of work_dim unsigned values that describe the number of global work-items in work_dim dimensions that will execute the kernel function
The total number of global work-items is computed as global_work_size[0] ... global_work_size[work_dim - 1].
The values specified in global_work_size cannot exceed the range given by the sizeof(size_t) for the device on which the kernel execution will be enqueued. The sizeof(size_t) for a device can be determined using CL_DEVICE_ADDRESS_BITS in the table of OpenCL Device Queries for clGetDeviceInfo. If, for example, CL_DEVICE_ADDRESS_BITS = 32,
i.e. the device uses a 32-bit address space, size_t is a 32-bit unsigned integer and global_work_size values must be in the range 1 .. 2^32 - 1. Values outside this range return a CL_OUT_OF_RESOURCES error.
my understanding is that since I have 64 = CL_DEVICE_ADDRESS_BITS then I can allocate up to 2^64 - 1
CL_DEVICE_GLOBAL_MEM_SIZE:
Global memory amount of the device. You typically don't care, unless you use high amount of data. Anyway the OpenCL spec will complain with OUT_OF_RESOURCES error if you use more than allowed. (bytes)
CL_DEVICE_LOCAL_MEM_SIZE:
Amount of local memory for each workg...
@user8469759 no because that could vastly exceed your memory
In general you can choose global_work_size as big as you want, while local_work_size is constraint by the underlying device/hardware, so all query results will tell you the possible dimensions for local_work_size instead of the global_work_size. the only constraint for the global_work_size is tha...
@VioAriton Every general purpose programming language has some sort of ARGV parameters. These are the parameters passed when the program is called from a terminal. If I write myprogram some arguments, the arguments the program receives through ARGV are ["myprogram", "some", "arguments"].
As it turns out, there are are large amount of programs that are intended to be invoked from a terminal. They don't have a graphical interface.
It sets the calling convention. Usually you don't want to mess with that.
Microsoft's documentation is a bit ... special. It is meant to also be understood by, say, delphi developers, so they spell out some things you normally don't need to specify in C++.