/* * Copyright (C) 1998 Spizella Software * All rights reserved. * * Programmer: Robb Matzke * Thursday, January 15, 1998 * * Purpose: Provides I/O facilities for multi-dimensional arrays of bytes * stored with various layout policies. If the caller is * interested in arrays of elements >1 byte then add an extra * dimension. For example, a 10x20 array of int would * translate to a 10x20x4 array of bytes at this level. */ #include #include #include #include #include #include #include #include #include /* MPIO driver functions are needed for some special checks */ #include /* Interface initialization */ #define PABLO_MASK H5Farray_mask #define INTERFACE_INIT NULL static intn interface_initialize_g = 0; /*------------------------------------------------------------------------- * Function: H5F_arr_create * * Purpose: Creates an array of bytes. * * Return: Non-negative on success/Negative on failure * * Programmer: Robb Matzke * Friday, January 16, 1998 * * Modifications: * *------------------------------------------------------------------------- */ herr_t H5F_arr_create (H5F_t *f, struct H5O_layout_t *layout/*in,out*/) { intn i; hsize_t nbytes; FUNC_ENTER (H5F_arr_create, FAIL); /* check args */ assert (f); assert (layout); layout->addr = HADDR_UNDEF; /*just in case we fail*/ switch (layout->type) { case H5D_CONTIGUOUS: /* Reserve space in the file for the entire array */ for (i=0, nbytes=1; indims; i++) nbytes *= layout->dim[i]; assert (nbytes>0); if (HADDR_UNDEF==(layout->addr=H5MF_alloc(f, H5FD_MEM_DRAW, nbytes))) { HRETURN_ERROR (H5E_IO, H5E_NOSPACE, FAIL, "unable to reserve file space"); } break; case H5D_CHUNKED: /* Create the root of the B-tree that describes chunked storage */ if (H5F_istore_create (f, layout/*out*/)<0) { HRETURN_ERROR (H5E_IO, H5E_CANTINIT, FAIL, "unable to initialize chunked storage"); } break; default: assert ("not implemented yet" && 0); HRETURN_ERROR (H5E_IO, H5E_UNSUPPORTED, FAIL, "unsupported storage layout"); } FUNC_LEAVE (SUCCEED); } /*------------------------------------------------------------------------- * Function: H5F_arr_read * * Purpose: Reads a hyperslab of a file byte array into a hyperslab of * a byte array in memory. The data is read from file F and the * array's size and storage information is in LAYOUT. External * files are described according to the external file list, EFL. * The hyperslab offset is FILE_OFFSET[] in the file and * MEM_OFFSET[] in memory (offsets are relative to the origin of * the array) and the size of the hyperslab is HSLAB_SIZE[]. The * total size of the file array is implied in the LAYOUT * argument and the total size of the memory array is * MEM_SIZE[]. The dimensionality of these vectors is implied by * the LAYOUT argument. * * Return: Non-negative on success/Negative on failure * * Programmer: Robb Matzke * Friday, January 16, 1998 * * Modifications: * Albert Cheng, 1998-06-02 * Added xfer_mode argument * * Robb Matzke, 1998-09-28 * Added the `xfer' argument and removed the `xfer_mode' * argument since it's a field of `xfer'. * * Robb Matzke, 1999-08-02 * Data transfer properties are passed by ID since that's how * the virtual file layer wants them. *------------------------------------------------------------------------- */ herr_t H5F_arr_read(H5F_t *f, hid_t dxpl_id, const struct H5O_layout_t *layout, const struct H5O_pline_t *pline, const H5O_fill_t *fill, const struct H5O_efl_t *efl, const hsize_t _hslab_size[], const hsize_t mem_size[], const hssize_t mem_offset[], const hssize_t file_offset[], void *_buf/*out*/) { uint8_t *buf = (uint8_t*)_buf; /*cast for arithmetic */ hssize_t file_stride[H5O_LAYOUT_NDIMS]; /*strides through file */ hssize_t mem_stride[H5O_LAYOUT_NDIMS]; /*strides through memory*/ hsize_t hslab_size[H5O_LAYOUT_NDIMS]; /*hyperslab size */ hsize_t idx[H5O_LAYOUT_NDIMS]; /*multi-dim counter */ size_t mem_start; /*byte offset to start */ hsize_t file_start; /*byte offset to start */ hsize_t elmt_size = 1; /*bytes per element */ size_t nelmts, z; /*number of elements */ intn ndims; /*stride dimensionality */ haddr_t addr; /*address in file */ intn i, j; /*counters */ hbool_t carray; /*carry for subtraction */ #ifdef H5_HAVE_PARALLEL H5FD_mpio_xfer_t xfer_mode=H5FD_MPIO_INDEPENDENT; #endif FUNC_ENTER(H5F_arr_read, FAIL); /* Check args */ assert(f); assert(layout); assert(_hslab_size); assert(file_offset); assert(mem_offset); assert(mem_size); assert(buf); /* Make a local copy of size so we can modify it */ H5V_vector_cpy(layout->ndims, hslab_size, _hslab_size); #ifdef H5_HAVE_PARALLEL { /* Get the transfer mode */ H5F_xfer_t *dxpl; H5FD_mpio_dxpl_t *dx; if (H5P_DEFAULT!=dxpl_id && (dxpl=H5I_object(dxpl_id)) && H5FD_MPIO==dxpl->driver_id && (dx=dxpl->driver_info) && H5FD_MPIO_INDEPENDENT!=dx->xfer_mode) { xfer_mode = dx->xfer_mode; } } #endif #ifdef H5_HAVE_PARALLEL /* Collective MPIO access is unsupported for non-contiguous datasets */ if (H5D_CONTIGUOUS!=layout->type && H5FD_MPIO_COLLECTIVE==xfer_mode) { HRETURN_ERROR (H5E_DATASET, H5E_READERROR, FAIL, "collective access on non-contiguous datasets not " "supported yet"); } #endif #ifdef QAK { extern int qak_debug; if(qak_debug) { printf("%s: layout->ndims=%d\n",FUNC,(int)layout->ndims); for(i=0; indims; i++) printf("%s: %d: hslab_size=%d, mem_size=%d, mem_offset=%d, file_offset=%d\n",FUNC,i,(int)_hslab_size[i],(int)mem_size[i],(int)mem_offset[i],(int)file_offset[i]); printf("%s: *buf=%d, *(buf+1)=%d\n", FUNC,(int)*(const uint16_t *)buf,(int)*((const uint16 *)buf+1)); } } #endif /* QAK */ switch (layout->type) { case H5D_CONTIGUOUS: ndims = layout->ndims; /* * Offsets must not be negative for this type of storage. */ for (i=0; infilters>0) { HRETURN_ERROR(H5E_IO, H5E_READERROR, FAIL, "filters are not allowed for contiguous data"); } /* * Calculate the strides needed to walk through the array on disk * and memory. Optimize the strides to result in the fewest number of * I/O requests. */ mem_start = H5V_hyper_stride(ndims, hslab_size, mem_size, mem_offset, mem_stride/*out*/); file_start = H5V_hyper_stride(ndims, hslab_size, layout->dim, file_offset, file_stride/*out*/); H5V_stride_optimize2(&ndims, &elmt_size, hslab_size, mem_stride, file_stride); /* * Initialize loop variables. The loop is a multi-dimensional loop * that counts from SIZE down to zero and IDX is the counter. Each * element of IDX is treated as a digit with IDX[0] being the least * significant digit. */ H5V_vector_cpy(ndims, idx, hslab_size); nelmts = H5V_vector_reduce_product(ndims, hslab_size); if (efl && efl->nused>0) { addr = 0; } else { addr = layout->addr; } addr += file_start; buf += mem_start; /* * Now begin to walk through the array, copying data from disk to * memory. */ #ifdef H5_HAVE_PARALLEL if (H5FD_MPIO_COLLECTIVE==xfer_mode){ /* * Currently supports same number of collective access. Need to * be changed LATER to combine all reads into one collective MPIO * call. */ unsigned long max, min, temp; temp = nelmts; assert(temp==nelmts); /* verify no overflow */ MPI_Allreduce(&temp, &max, 1, MPI_UNSIGNED_LONG, MPI_MAX, H5FD_mpio_communicator(f->shared->lf)); MPI_Allreduce(&temp, &min, 1, MPI_UNSIGNED_LONG, MPI_MIN, H5FD_mpio_communicator(f->shared->lf)); #ifdef AKC printf("nelmts=%lu, min=%lu, max=%lu\n", temp, min, max); #endif if (max != min) HRETURN_ERROR(H5E_DATASET, H5E_READERROR, FAIL, "collective access with unequal number of " "blocks not supported yet"); } #endif for (z=0; znused>0) { if (H5O_efl_read(f, efl, addr, elmt_size, buf)<0) { HRETURN_ERROR(H5E_IO, H5E_READERROR, FAIL, "external data read failed"); } } else if (H5F_block_read(f, addr, elmt_size, dxpl_id, buf)<0) { HRETURN_ERROR(H5E_IO, H5E_READERROR, FAIL, "block read failed"); } /* Decrement indices and advance pointers */ for (j=ndims-1, carray=TRUE; j>=0 && carray; --j) { addr += file_stride[j]; buf += mem_stride[j]; if (--idx[j]) carray = FALSE; else idx[j] = hslab_size[j]; } } break; case H5D_CHUNKED: /* * This method is unable to access external raw data files or to copy * into a proper hyperslab. */ if (efl && efl->nused>0) { HRETURN_ERROR(H5E_IO, H5E_UNSUPPORTED, FAIL, "chunking and external files are mutually " "exclusive"); } for (i=0; indims; i++) { if (0!=mem_offset[i] || hslab_size[i]!=mem_size[i]) { HRETURN_ERROR(H5E_IO, H5E_UNSUPPORTED, FAIL, "unable to copy into a proper hyperslab"); } } if (H5F_istore_read(f, dxpl_id, layout, pline, fill, file_offset, hslab_size, buf)<0) { HRETURN_ERROR(H5E_IO, H5E_READERROR, FAIL, "chunked read failed"); } break; default: assert("not implemented yet" && 0); HRETURN_ERROR(H5E_IO, H5E_UNSUPPORTED, FAIL, "unsupported storage layout"); } FUNC_LEAVE(SUCCEED); } /*------------------------------------------------------------------------- * Function: H5F_arr_write * * Purpose: Copies a hyperslab of a memory array to a hyperslab of a * file array. The data is written to file F and the file * array's size and storage information is implied by LAYOUT. * The data is stored in external files according to the * external file list, EFL. The hyperslab offset is * FILE_OFFSET[] in the file and MEM_OFFSET[] in memory (offsets * are relative to the origin of the array) and the size of the * hyperslab is HSLAB_SIZE[]. The total size of the file array * is implied by the LAYOUT argument and the total size of the * memory array is MEM_SIZE[]. The dimensionality of these * vectors is implied by the LAYOUT argument. * * Return: Non-negative on success/Negative on failure * * Programmer: Robb Matzke * Friday, January 16, 1998 * * Modifications: * Albert Cheng, 1998-06-02 * Added xfer_mode argument * * Robb Matzke, 1998-09-28 * Added `xfer' argument, removed `xfer_mode' argument since it * is a member of H5F_xfer_t. * * Robb Matzke, 1999-08-02 * Data transfer properties are passed by ID since that's how * the virtual file layer wants them. *------------------------------------------------------------------------- */ herr_t H5F_arr_write(H5F_t *f, hid_t dxpl_id, const struct H5O_layout_t *layout, const struct H5O_pline_t *pline, const struct H5O_fill_t *fill, const struct H5O_efl_t *efl, const hsize_t _hslab_size[], const hsize_t mem_size[], const hssize_t mem_offset[], const hssize_t file_offset[], const void *_buf) { const uint8_t *buf = (const uint8_t *)_buf; /*cast for arithmetic */ hssize_t file_stride[H5O_LAYOUT_NDIMS]; /*strides through file */ hssize_t mem_stride[H5O_LAYOUT_NDIMS]; /*strides through memory*/ hsize_t hslab_size[H5O_LAYOUT_NDIMS]; /*hyperslab size */ hsize_t idx[H5O_LAYOUT_NDIMS]; /*multi-dim counter */ hsize_t mem_start; /*byte offset to start */ hsize_t file_start; /*byte offset to start */ hsize_t elmt_size = 1; /*bytes per element */ size_t nelmts, z; /*number of elements */ intn ndims; /*dimensionality */ haddr_t addr; /*address in file */ intn i, j; /*counters */ hbool_t carray; /*carry for subtraction */ #ifdef H5_HAVE_PARALLEL H5FD_mpio_xfer_t xfer_mode=H5FD_MPIO_INDEPENDENT; #endif FUNC_ENTER(H5F_arr_write, FAIL); /* Check args */ assert(f); assert(layout); assert(_hslab_size); assert(file_offset); assert(mem_offset); assert(mem_size); assert(buf); /* Make a local copy of _size so we can modify it */ H5V_vector_cpy(layout->ndims, hslab_size, _hslab_size); #ifdef H5_HAVE_PARALLEL { /* Get the transfer mode */ H5F_xfer_t *dxpl; H5FD_mpio_dxpl_t *dx; if (H5P_DEFAULT!=dxpl_id && (dxpl=H5I_object(dxpl_id)) && H5FD_MPIO==dxpl->driver_id && (dx=dxpl->driver_info) && H5FD_MPIO_INDEPENDENT!=dx->xfer_mode) { xfer_mode = dx->xfer_mode; } } #endif #ifdef H5_HAVE_PARALLEL if (H5D_CONTIGUOUS!=layout->type && H5FD_MPIO_COLLECTIVE==xfer_mode) { HRETURN_ERROR (H5E_DATASET, H5E_WRITEERROR, FAIL, "collective access on non-contiguous datasets not " "supported yet"); } #endif #ifdef QAK { extern int qak_debug; printf("%s: layout->ndims=%d\n",FUNC,(int)layout->ndims); for(i=0; indims; i++) printf("%s: %d: hslab_size=%d, mem_size=%d, mem_offset=%d, " "file_offset=%d\n", FUNC, i, (int)_hslab_size[i], (int)mem_size[i],(int)mem_offset[i],(int)file_offset[i]); if(qak_debug) { printf("%s: *buf=%d, *(buf+1)=%d\n", FUNC, (int)*(const uint16_t *)buf, (int)*((const uint16_t *)buf+1)); } } #endif /* QAK */ switch (layout->type) { case H5D_CONTIGUOUS: ndims = layout->ndims; /* * Offsets must not be negative for this type of storage. */ for (i=0; infilters>0) { HRETURN_ERROR(H5E_IO, H5E_WRITEERROR, FAIL, "filters are not allowed for contiguous data"); } /* * Calculate the strides needed to walk through the array on disk. * Optimize the strides to result in the fewest number of I/O * requests. */ mem_start = H5V_hyper_stride(ndims, hslab_size, mem_size, mem_offset, mem_stride/*out*/); file_start = H5V_hyper_stride(ndims, hslab_size, layout->dim, file_offset, file_stride/*out*/); H5V_stride_optimize2(&ndims, &elmt_size, hslab_size, mem_stride, file_stride); /* * Initialize loop variables. The loop is a multi-dimensional loop * that counts from SIZE down to zero and IDX is the counter. Each * element of IDX is treated as a digit with IDX[0] being the least * significant digit. */ H5V_vector_cpy(ndims, idx, hslab_size); nelmts = H5V_vector_reduce_product(ndims, hslab_size); if (efl && efl->nused>0) { addr = 0; } else { addr = layout->addr; } addr += file_start; buf += mem_start; /* * Now begin to walk through the array, copying data from memory to * disk. */ #ifdef H5_HAVE_PARALLEL if (H5FD_MPIO_COLLECTIVE==xfer_mode){ /* * Currently supports same number of collective access. Need to * be changed LATER to combine all writes into one collective * MPIO call. */ unsigned long max, min, temp; temp = nelmts; assert(temp==nelmts); /* verify no overflow */ MPI_Allreduce(&temp, &max, 1, MPI_UNSIGNED_LONG, MPI_MAX, H5FD_mpio_communicator(f->shared->lf)); MPI_Allreduce(&temp, &min, 1, MPI_UNSIGNED_LONG, MPI_MIN, H5FD_mpio_communicator(f->shared->lf)); #ifdef AKC printf("nelmts=%lu, min=%lu, max=%lu\n", temp, min, max); #endif if (max != min) { HRETURN_ERROR(H5E_DATASET, H5E_WRITEERROR, FAIL, "collective access with unequal number of " "blocks not supported yet"); } } #endif for (z=0; znused>0) { if (H5O_efl_write(f, efl, addr, elmt_size, buf)<0) { HRETURN_ERROR(H5E_IO, H5E_READERROR, FAIL, "external data write failed"); } } else if (H5F_block_write(f, addr, elmt_size, dxpl_id, buf)<0) { HRETURN_ERROR(H5E_IO, H5E_WRITEERROR, FAIL, "block write failed"); } /* Decrement indices and advance pointers */ for (j=ndims-1, carray=TRUE; j>=0 && carray; --j) { addr += file_stride[j]; buf += mem_stride[j]; if (--idx[j]) carray = FALSE; else idx[j] = hslab_size[j]; } } break; case H5D_CHUNKED: /* * This method is unable to access external raw data files or to copy * from a proper hyperslab. */ if (efl && efl->nused>0) { HRETURN_ERROR(H5E_IO, H5E_UNSUPPORTED, FAIL, "chunking and external files are mutually " "exclusive"); } for (i=0; indims; i++) { if (0!=mem_offset[i] || hslab_size[i]!=mem_size[i]) { HRETURN_ERROR(H5E_IO, H5E_UNSUPPORTED, FAIL, "unable to copy from a proper hyperslab"); } } if (H5F_istore_write(f, dxpl_id, layout, pline, fill, file_offset, hslab_size, buf)<0) { HRETURN_ERROR(H5E_IO, H5E_WRITEERROR, FAIL, "chunked write failed"); } break; default: assert("not implemented yet" && 0); HRETURN_ERROR(H5E_IO, H5E_UNSUPPORTED, FAIL, "unsupported storage layout"); } FUNC_LEAVE (SUCCEED); }