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I am using 63 registers/thread ,so (32768 is maximum) i can use about 520 threads.I am using now 512 threads in this example.

(The parallelism is in the function "computeEvec" inside global computeEHfields function function.) The problems are:

1) The mem check error below.

2) When i use numPointsRp>2000 it show me "out of memory" ,but (if i am not doing wrong) i compute the global memory and it's ok.

-------------------------------UPDATED---------------------------

i run the program with cuda-memcheck and it gives me (only when numPointsRs>numPointsRp):

========= Invalid global read of size 4

========= at 0x00000428 in computeEHfields

========= by thread (2,0,0) in block (0,0,0)

========= Address 0x4001076e0 is out of bounds

========= ========= Invalid global read of size 4

========= at 0x00000428 in computeEHfields

========= by thread (1,0,0) in block (0,0,0)

========= Address 0x4001076e0 is out of bounds

========= ========= Invalid global read of size 4

========= at 0x00000428 in computeEHfields

========= by thread (0,0,0) in block (0,0,0)

========= Address 0x4001076e0 is out of bounds

ERROR SUMMARY: 160 errors

-----------EDIT----------------------------

Also , some times (if i use only threads and not blocks (i haven't test it for blocks) ) if for example i have numPointsRs=1000 and numPointsRp=100 and then change the numPointsRp=200 and then again change the numPointsRp=100 i am not taking the first results!

import pycuda.gpuarray as gpuarray
import pycuda.autoinit
from pycuda.compiler import SourceModule
import numpy as np
import cmath
import pycuda.driver as drv


Rs=np.zeros((numPointsRs,3)).astype(np.float32)
for k in range (numPointsRs): 
    Rs[k]=[0,k,0]

Rp=np.zeros((numPointsRp,3)).astype(np.float32)
for k in range (numPointsRp): 
    Rp[k]=[1+k,0,0]


#---- Initialization and passing(allocate memory and transfer data) to GPU -------------------------
Rs_gpu=gpuarray.to_gpu(Rs)
Rp_gpu=gpuarray.to_gpu(Rp)


J_gpu=gpuarray.to_gpu(np.ones((numPointsRs,3)).astype(np.complex64))
M_gpu=gpuarray.to_gpu(np.ones((numPointsRs,3)).astype(np.complex64))

Evec_gpu=gpuarray.to_gpu(np.zeros((numPointsRp,3)).astype(np.complex64))
Hvec_gpu=gpuarray.to_gpu(np.zeros((numPointsRp,3)).astype(np.complex64))
All_gpu=gpuarray.to_gpu(np.ones(numPointsRp).astype(np.complex64))


mod =SourceModule("""
#include <pycuda-complex.hpp>
#include <cmath>
#include <vector>
#define RowRsSize %(numrs)d
#define RowRpSize %(numrp)d


typedef  pycuda::complex<float> cmplx;
extern "C"{


    __device__ void computeEvec(float Rs_mat[][3], int numPointsRs,   
         cmplx J[][3],
         cmplx M[][3],
         float *Rp,
         cmplx kp, 
         cmplx eta,
         cmplx *Evec,
         cmplx *Hvec, cmplx *All)

{

    while (c<numPointsRs){
        ...         
                c++;

                }     
        }


__global__  void computeEHfields(float *Rs_mat_, int numPointsRs,   
        float *Rp_mat_, int numPointsRp,    
    cmplx *J_,
    cmplx *M_,
    cmplx  kp, 
    cmplx  eta,
    cmplx E[][3],
    cmplx H[][3], cmplx *All )
    {
        float Rs_mat[RowRsSize][3];
        float Rp_mat[RowRpSize][3];

        cmplx J[RowRsSize][3];
        cmplx M[RowRsSize][3];


    int k=threadIdx.x+blockIdx.x*blockDim.x;

      while (k<numPointsRp)  
     {

        computeEvec( Rs_mat, numPointsRs,  J, M, Rp_mat[k], kp, eta, E[k], H[k], All );
        k+=blockDim.x*gridDim.x;


    }

}
}

"""% { "numrs":numPointsRs, "numrp":numPointsRp},no_extern_c=1)


func = mod.get_function("computeEHfields")


func(Rs_gpu,np.int32(numPointsRs),Rp_gpu,np.int32(numPointsRp),J_gpu, M_gpu, np.complex64(kp), np.complex64(eta),Evec_gpu,Hvec_gpu, All_gpu, block=(128,1,1),grid=(200,1))

print(" \n")


#----- get data back from GPU-----
Rs=Rs_gpu.get()
Rp=Rp_gpu.get()
J=J_gpu.get()
M=M_gpu.get()
Evec=Evec_gpu.get()
Hvec=Hvec_gpu.get()
All=All_gpu.get()

--------------------GPU MODEL------------------------------------------------

Device 0: "GeForce GTX 560"
  CUDA Driver Version / Runtime Version          4.20 / 4.10
  CUDA Capability Major/Minor version number:    2.1
  Total amount of global memory:                 1024 MBytes (1073283072 bytes)
  ( 0) Multiprocessors x (48) CUDA Cores/MP:     0 CUDA Cores   //CUDA Cores    336 => 7 MP and 48 Cores/MP
share|improve this question
    
Are you copying all the points to the GPU memory at once? What is the size of a point? –  Tudor Aug 28 '12 at 12:58
    
The size is int.I am calling inside global function another (device) function and there i do the parallelism. –  George Aug 28 '12 at 13:35
1  
Your question doesn't give enough details, your block/grid sizes are valid so there must be something in your kernel or host code causing the error (you don't even say where the error comes from). –  Tom Aug 28 '12 at 14:07
2  
But you are doing retaliatory upvoting, which in many cases just bumps bad questions up to the top of the list. This might help the ego of the poster, but it makes the task (my task) of supporting a developer community more difficult. –  harrism Aug 29 '12 at 4:50
2  
@George: I don't want to see hundreds of lines of code. I want to see a concise case that reproduces the problem. If you can't do that, you haven't thought about this enough. And that last error means you have an invalid block dimension in your function call. –  talonmies Aug 29 '12 at 11:23

2 Answers 2

up vote 1 down vote accepted

When i use numPointsRp>2000 it show me "out of memory"

Now we have some real code to work with, let's compile it and see what happens. Using RowRsSize=2000 and RowRpSize=200 and compiling with the CUDA 4.2 toolchain, I get:

nvcc -arch=sm_21 -Xcompiler="-D RowRsSize=2000 -D RowRpSize=200" -Xptxas="-v" -c -I./ kivekset.cu 
ptxas info    : Compiling entry function '_Z15computeEHfieldsPfiS_iPN6pycuda7complexIfEES3_S2_S2_PA3_S2_S5_S3_' for 'sm_21'
ptxas info    : Function properties for _Z15computeEHfieldsPfiS_iPN6pycuda7complexIfEES3_S2_S2_PA3_S2_S5_S3_
    122432 bytes stack frame, 0 bytes spill stores, 0 bytes spill loads
ptxas info    : Used 57 registers, 84 bytes cmem[0], 168 bytes cmem[2], 76 bytes cmem[16]

The key numbers are 57 registers and 122432 bytes stack frame per thread. The occupancy calculator suggests that a block of 512 threads will have a maximum of 1 block per SM, and your GPU has 7 SM. This gives a total of 122432 * 512 * 7 = 438796288 bytes of stack frame (local memory) to run your kernel, before you have allocated a single of byte of memory for input and output using pyCUDA. On a GPU with 1Gb of memory, it isn't hard to imagine running out of memory. Your kernel has a enormous local memory footprint. Start thinking about ways to reduce it.


As I indicated in comments, it is absolutely unclear why every thread needs a complete copy of the input data in this kernel code. It results in a gigantic local memory footprint and there seems to be absolutely no reason why the code should be written in this way. You could, I suspect, modify the kernel to something like this:

typedef  pycuda::complex<float> cmplx;
typedef float fp3[3];
typedef cmplx cp3[3];

__global__  
void computeEHfields2(
        float *Rs_mat_, int numPointsRs,
        float *Rp_mat_, int numPointsRp,
        cmplx *J_,
        cmplx *M_,
        cmplx  kp, 
        cmplx  eta,
        cmplx E[][3],
        cmplx H[][3], 
        cmplx *All )
{

    fp3 * Rs_mat = (fp3 *)Rs_mat_;
    cp3 * J = (cp3 *)J_;
    cp3 * M = (cp3 *)M_;

    int k=threadIdx.x+blockIdx.x*blockDim.x;
    while (k<numPointsRp)  
    {
        fp3 * Rp_mat = (fp3 *)(Rp_mat_+k);
        computeEvec2( Rs_mat, numPointsRs, J, M, *Rp_mat, kp, eta, E[k], H[k], All );
        k+=blockDim.x*gridDim.x;
    }
}

and the main __device__ function it calls to something like this:

__device__ void computeEvec2(
        fp3 Rs_mat[], int numPointsRs,   
        cp3 J[],
        cp3 M[],
        fp3   Rp,
        cmplx kp, 
        cmplx eta,
        cmplx *Evec,
        cmplx *Hvec, 
        cmplx *All)
{
 ....
}

and eliminate every byte of thread local memory without changing the functionality of the computational code at all.

share|improve this answer
    
:So, it's a bad designed code,right?I need to alter it in order to use shared memory?Can you give me some tips (in my code) for that?from your experience i mean,without taking your time.Also,i get 63 registers ,why that difference? –  George Sep 2 '12 at 12:46
    
:And last , you said the 438796288 are allocated before even the program runs.So,when i run it , the memory that is needed (the matrices i have as input) is adding to the 438796288 bytes? –  George Sep 2 '12 at 12:49
    
On the memory question, yes that is how it works. But this code is a complete train wreck. Why does every thread load a local memory copy of the complete input data for? That is insanity, especially when most of the contents of Rp_mat loaded by any given thread are never used. Why have local memory copies at all? Why not just read from the arrays directly? So much of this code make so little sense that it is impossible for me to even begin to suggest how to "fix" it. –  talonmies Sep 2 '12 at 15:51
    
:The problem is that i didn't begin the designing of this code to be used with cuda ,but with c++ ,that's why it is doesn't use good parallelism practices.So,i must design it again.Thank you very much for your help.(Can you give me an example of what you mean"Why not just read from the arrays directly") –  George Sep 2 '12 at 15:57
1  
@George: I really don't care about your bounty. It is probably because you edited your question so much that it was converted to a community wiki question, and so my answer was also make into a wiki entry, which are not eligible for reputation. By have a look at my edit, and then I suggest going away and thinking about this some more. It seems you are vastly overcomplicating things for reasons that are not obvious. –  talonmies Sep 2 '12 at 16:45

Using R=1000 and then

block=R/2,1,1 and grid=1,1 everything ok

If i try R=10000 and

block=R/20,1,1 and grid=20,1 ,then it show me "out of memory"

I'm not familiar with pycuda and didn't read into your code too deeply. However you have more blocks and more threads, so it will

  • local memory (probably the kernel's stack, it's allocated per thread),

  • shared memory (allocated per block), or

  • global memory that gets allocated based on grid or gridDim.

You can reduce the stack size calling

cudeDeviceSetLimit(cudaLimitStackSize, N));

(the code is for the C runtime API, but the pycuda equivalent shouldn't be too hard to find).

share|improve this answer
    
:hello and thanks for the help.I can see (from information from ptxas) that until about 82000 bytes stack frame the program runs ok.But for more,it doesn't.Also,reducing the stack size gives me the same results. –  George Sep 1 '12 at 10:38
    
:I can't understand also this: I do the parallelism for numPointsRp,but if i increase numPointsRs to 10000 for example it show me "cuLaunchKernel failed: invalid value". –  George Sep 1 '12 at 13:55
    
A 1x1x1 grid makes no sense - you try to run all threads on just a single SM. Why do you have to copy the input redundantly to local memory? The code won't scale this way, so don't waste your time trying to make it run with hammer and crowbar. Instead try to really understand the device you are targeting, its types of memory, the C/C++ ABI and its limits and rewrite your program accordingly (see the CUDA Documentation or maybe my answer in [this post][stackoverflow.com/questions/12172279/… can help to get you started). –  Dude Sep 2 '12 at 0:30
    
:Thanks for your help and suggestions.I upvoted –  George Sep 2 '12 at 16:01

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