/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * Copyright by The HDF Group. * * All rights reserved. * * * * This file is part of HDF5. The full HDF5 copyright notice, including * * terms governing use, modification, and redistribution, is contained in * * the COPYING file, which can be found at the root of the source code * * distribution tree, or in https://www.hdfgroup.org/licenses. * * If you do not have access to either file, you may request a copy from * * help@hdfgroup.org. * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */ /* * Module Info: Datatype conversions for the H5T interface. */ /****************/ /* Module Setup */ /****************/ #include "H5Tmodule.h" /* This source code file is part of the H5T module */ /***********/ /* Headers */ /***********/ #include "H5private.h" /* Generic Functions */ #include "H5CXprivate.h" /* API Contexts */ #include "H5Dprivate.h" /* Datasets */ #include "H5Eprivate.h" /* Error handling */ #include "H5FLprivate.h" /* Free Lists */ #include "H5Iprivate.h" /* IDs */ #include "H5MMprivate.h" /* Memory management */ #include "H5Tpkg.h" /* Datatypes */ /****************/ /* Local Macros */ /****************/ /* * These macros are for the bodies of functions that convert buffers of one * atomic type to another using hardware. * * They all start with `H5T_CONV_' and end with two letters that represent the * source and destination types, respectively. The letters `s' and `S' refer to * signed integers while the letters `u' and `U' refer to unsigned integers, and * the letters `f' and `F' refer to floating-point values. * * The letter which is capitalized indicates that the corresponding type * (source or destination) is at least as large as the other type. * * Certain conversions may experience overflow conditions which arise when the * source value has a magnitude that cannot be represented by the destination * type. * * Suffix Description * ------ ----------- * sS: Signed integers to signed integers where the destination is * at least as wide as the source. This case cannot generate * overflows. * * sU: Signed integers to unsigned integers where the destination is * at least as wide as the source. This case experiences * overflows when the source value is negative. * * uS: Unsigned integers to signed integers where the destination is * at least as wide as the source. This case can experience * overflows when the source and destination are the same size. * * uU: Unsigned integers to unsigned integers where the destination * is at least as wide as the source. Overflows are not * possible in this case. * * Ss: Signed integers to signed integers where the source is at * least as large as the destination. Overflows can occur when * the destination is narrower than the source. * * Su: Signed integers to unsigned integers where the source is at * least as large as the destination. Overflows occur when the * source value is negative and can also occur if the * destination is narrower than the source. * * Us: Unsigned integers to signed integers where the source is at * least as large as the destination. Overflows can occur for * all sizes. * * Uu: Unsigned integers to unsigned integers where the source is at * least as large as the destination. Overflows can occur if the * destination is narrower than the source. * * su: Conversion from signed integers to unsigned integers where * the source and destination are the same size. Overflow occurs * when the source value is negative. * * us: Conversion from unsigned integers to signed integers where * the source and destination are the same size. Overflow * occurs when the source magnitude is too large for the * destination. * * fF: Floating-point values to floating-point values where the * destination is at least as wide as the source. This case * cannot generate overflows. * * Ff: Floating-point values to floating-point values the source is at * least as large as the destination. Overflows can occur when * the destination is narrower than the source. * * xF: Integers to float-point(float or double) values where the destination * is at least as wide as the source. This case cannot generate * overflows. * * Fx: Float-point(float or double) values to integer where the source is * at least as wide as the destination. Overflow can occur * when the source magnitude is too large for the destination. * * fX: Floating-point values to integers where the destination is at least * as wide as the source. This case cannot generate overflows. * * Xf: Integers to floating-point values where the source is at least as * wide as the destination. Overflows can occur when the destination is * narrower than the source. * * * The macros take a subset of these arguments in the order listed here: * * CDATA: A pointer to the H5T_cdata_t structure that was passed to the * conversion function. * * STYPE: The hid_t value for the source datatype. * * DTYPE: The hid_t value for the destination datatype. * * BUF: A pointer to the conversion buffer. * * NELMTS: The number of values to be converted. * * ST: The C name for source datatype (e.g., int) * * DT: The C name for the destination datatype (e.g., signed char) * * D_MIN: The minimum possible destination value. For unsigned * destination types this should be zero. For signed * destination types it's a negative value with a magnitude that * is usually one greater than D_MAX. Source values which are * smaller than D_MIN generate overflows. * * D_MAX: The maximum possible destination value. Source values which * are larger than D_MAX generate overflows. * * The macros are implemented with a generic programming technique, similar * to templates in C++. The macro which defines the "core" part of the * conversion (which actually moves the data from the source to the destination) * is invoked inside the H5T_CONV "template" macro by "gluing" it together, * which allows the core conversion macro to be invoked as necessary. * * "Core" macros come in two flavors: one which calls the exception handling * routine and one which doesn't (the "_NOEX" variant). The presence of the * exception handling routine is detected before the loop over the values and * the appropriate core routine loop is executed. * * The generic "core" macros are: (others are specific to particular conversion) * * Suffix Description * ------ ----------- * xX: Generic Conversion where the destination is at least as * wide as the source. This case cannot generate overflows. * * Xx: Generic signed conversion where the source is at least as large * as the destination. Overflows can occur when the destination is * narrower than the source. * * Ux: Generic conversion for the `Us', `Uu' & `us' cases * Overflow occurs when the source magnitude is too large for the * destination. * */ #define H5T_CONV_xX_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_xX_NOEX_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ *(D) = (DT)(*(S)); \ } /* Added a condition branch(else if (*(S) == (DT)(D_MAX))) which seems redundant. * It handles a special situation when the source is "float" and assigned the value * of "INT_MAX". A compiler may do roundup making this value "INT_MAX+1". However, * when do comparison "if (*(S) > (DT)(D_MAX))", the compiler may consider them * equal. In this case, do not return exception but make sure the maximum is assigned * to the destination. SLU - 2005/06/29 */ #define H5T_CONV_Xx_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ if (*(S) > (ST)(D_MAX)) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, S, D, \ conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = (DT)(D_MAX); \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else if (*(S) < (ST)(D_MIN)) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_RANGE_LOW, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, S, D, \ conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = (DT)(D_MIN); \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_Xx_NOEX_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ if (*(S) > (ST)(D_MAX)) { \ *(D) = (DT)(D_MAX); \ } \ else if (*(S) < (ST)(D_MIN)) { \ *(D) = (DT)(D_MIN); \ } \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_Ux_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ if (*(S) > (ST)(D_MAX)) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, S, D, \ conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = (DT)(D_MAX); \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_Ux_NOEX_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ if (*(S) > (ST)(D_MAX)) { \ *(D) = (DT)(D_MAX); \ } \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_sS(STYPE, DTYPE, ST, DT, D_MIN, D_MAX) \ do { \ HDcompile_assert(sizeof(ST) <= sizeof(DT)); \ H5T_CONV(H5T_CONV_xX, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, N) \ } while (0) #define H5T_CONV_sU_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ if (*(S) < 0) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_RANGE_LOW, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, S, D, \ conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = 0; \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_sU_NOEX_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ if (*(S) < 0) \ *(D) = 0; \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_sU(STYPE, DTYPE, ST, DT, D_MIN, D_MAX) \ do { \ HDcompile_assert(sizeof(ST) <= sizeof(DT)); \ H5T_CONV(H5T_CONV_sU, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, N) \ } while (0) /* Define to 1 if overflow is possible during conversion, 0 otherwise * Because destination is at least as wide as the source, this should only * occur between types of equal size */ #define H5T_CONV_uS_UCHAR_SHORT 0 #define H5T_CONV_uS_UCHAR_INT 0 #define H5T_CONV_uS_UCHAR_LONG 0 #define H5T_CONV_uS_UCHAR_LLONG 0 #if H5_SIZEOF_SHORT == H5_SIZEOF_INT #define H5T_CONV_uS_USHORT_INT 1 #else #define H5T_CONV_uS_USHORT_INT 0 #endif #define H5T_CONV_uS_USHORT_LONG 0 #define H5T_CONV_uS_USHORT_LLONG 0 #if H5_SIZEOF_INT == H5_SIZEOF_LONG #define H5T_CONV_uS_UINT_LONG 1 #else #define H5T_CONV_uS_UINT_LONG 0 #endif #define H5T_CONV_uS_UINT_LLONG 0 #if H5_SIZEOF_LONG == H5_SIZEOF_LONG_LONG #define H5T_CONV_uS_ULONG_LLONG 1 #else #define H5T_CONV_uS_ULONG_LLONG 0 #endif /* Note. If an argument is stringified or concatenated, the prescan does not * occur. To expand the macro, then stringify or concatenate its expansion, * one macro must call another macro that does the stringification or * concatenation. */ #define H5T_CONV_uS_EVAL_TYPES(STYPE, DTYPE) H5_GLUE4(H5T_CONV_uS_, STYPE, _, DTYPE) /* Called if overflow is possible */ #define H5T_CONV_uS_CORE_1(S, D, ST, DT, D_MIN, D_MAX) \ if (*(S) > (DT)(D_MAX)) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, S, D, \ conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler */ \ *(D) = (DT)(D_MAX); \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if (except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else \ *(D) = (DT)(*(S)); /* Called if no overflow is possible */ #define H5T_CONV_uS_CORE_0(S, D, ST, DT, D_MIN, D_MAX) *(D) = (DT)(*(S)); #define H5T_CONV_uS_CORE_I(over, S, D, ST, DT, D_MIN, D_MAX) \ H5_GLUE(H5T_CONV_uS_CORE_, over)(S, D, ST, DT, D_MIN, D_MAX) #define H5T_CONV_uS_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ H5T_CONV_uS_CORE_I(H5T_CONV_uS_EVAL_TYPES(STYPE, DTYPE), S, D, ST, DT, D_MIN, D_MAX) \ } /* Called if overflow is possible */ #define H5T_CONV_uS_NOEX_CORE_1(S, D, ST, DT, D_MIN, D_MAX) \ if (*(S) > (DT)(D_MAX)) \ *(D) = (D_MAX); \ else \ *(D) = (DT)(*(S)); /* Called if no overflow is possible */ #define H5T_CONV_uS_NOEX_CORE_0(S, D, ST, DT, D_MIN, D_MAX) *(D) = (DT)(*(S)); #define H5T_CONV_uS_NOEX_CORE_I(over, S, D, ST, DT, D_MIN, D_MAX) \ H5_GLUE(H5T_CONV_uS_NOEX_CORE_, over)(S, D, ST, DT, D_MIN, D_MAX) #define H5T_CONV_uS_NOEX_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ H5T_CONV_uS_NOEX_CORE_I(H5T_CONV_uS_EVAL_TYPES(STYPE, DTYPE), S, D, ST, DT, D_MIN, D_MAX) \ } #define H5T_CONV_uS(STYPE, DTYPE, ST, DT, D_MIN, D_MAX) \ do { \ HDcompile_assert(sizeof(ST) <= sizeof(DT)); \ H5T_CONV(H5T_CONV_uS, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, N) \ } while (0) #define H5T_CONV_uU(STYPE, DTYPE, ST, DT, D_MIN, D_MAX) \ do { \ HDcompile_assert(sizeof(ST) <= sizeof(DT)); \ H5T_CONV(H5T_CONV_xX, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, N) \ } while (0) #define H5T_CONV_Ss(STYPE, DTYPE, ST, DT, D_MIN, D_MAX) \ do { \ HDcompile_assert(sizeof(ST) >= sizeof(DT)); \ H5T_CONV(H5T_CONV_Xx, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, N) \ } while (0) #define H5T_CONV_Su_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ if (*(S) < 0) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_RANGE_LOW, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, S, D, \ conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = 0; \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else if (sizeof(ST) > sizeof(DT) && *(S) > (ST)(D_MAX)) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, S, D, \ conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = (DT)(D_MAX); \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_Su_NOEX_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ if (*(S) < 0) \ *(D) = 0; \ else if (sizeof(ST) > sizeof(DT) && *(S) > (ST)(D_MAX)) \ *(D) = (DT)(D_MAX); \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_Su(STYPE, DTYPE, ST, DT, D_MIN, D_MAX) \ do { \ HDcompile_assert(sizeof(ST) >= sizeof(DT)); \ H5T_CONV(H5T_CONV_Su, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, N) \ } while (0) #define H5T_CONV_Us(STYPE, DTYPE, ST, DT, D_MIN, D_MAX) \ do { \ HDcompile_assert(sizeof(ST) >= sizeof(DT)); \ H5T_CONV(H5T_CONV_Ux, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, N) \ } while (0) #define H5T_CONV_Uu(STYPE, DTYPE, ST, DT, D_MIN, D_MAX) \ do { \ HDcompile_assert(sizeof(ST) >= sizeof(DT)); \ H5T_CONV(H5T_CONV_Ux, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, N) \ } while (0) #define H5T_CONV_su_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ /* Assumes memory format of unsigned & signed integers is same */ \ if (*(S) < 0) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_RANGE_LOW, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, S, D, \ conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = 0; \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_su_NOEX_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ /* Assumes memory format of unsigned & signed integers is same */ \ if (*(S) < 0) \ *(D) = 0; \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_su(STYPE, DTYPE, ST, DT, D_MIN, D_MAX) \ do { \ HDcompile_assert(sizeof(ST) == sizeof(DT)); \ H5T_CONV(H5T_CONV_su, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, N) \ } while (0) #define H5T_CONV_us_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ /* Assumes memory format of unsigned & signed integers is same */ \ if (*(S) > (ST)(D_MAX)) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, S, D, \ conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = (DT)(D_MAX); \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_us_NOEX_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ /* Assumes memory format of unsigned & signed integers is same */ \ if (*(S) > (ST)(D_MAX)) \ *(D) = (DT)(D_MAX); \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_us(STYPE, DTYPE, ST, DT, D_MIN, D_MAX) \ do { \ HDcompile_assert(sizeof(ST) == sizeof(DT)); \ H5T_CONV(H5T_CONV_us, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, N) \ } while (0) #define H5T_CONV_fF(STYPE, DTYPE, ST, DT, D_MIN, D_MAX) \ do { \ HDcompile_assert(sizeof(ST) <= sizeof(DT)); \ H5T_CONV(H5T_CONV_xX, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, N) \ } while (0) /* Same as H5T_CONV_Xx_CORE, except that instead of using D_MAX and D_MIN * when an overflow occurs, use the 'float' infinity values. */ #define H5T_CONV_Ff_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ if (*(S) > (ST)(D_MAX)) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, S, D, \ conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = H5_GLUE3(H5T_NATIVE_, DTYPE, _POS_INF_g); \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else if (*(S) < (ST)(D_MIN)) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_RANGE_LOW, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, S, D, \ conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = H5_GLUE3(H5T_NATIVE_, DTYPE, _NEG_INF_g); \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_Ff_NOEX_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ if (*(S) > (ST)(D_MAX)) \ *(D) = H5_GLUE3(H5T_NATIVE_, DTYPE, _POS_INF_g); \ else if (*(S) < (ST)(D_MIN)) \ *(D) = H5_GLUE3(H5T_NATIVE_, DTYPE, _NEG_INF_g); \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_Ff(STYPE, DTYPE, ST, DT, D_MIN, D_MAX) \ do { \ HDcompile_assert(sizeof(ST) >= sizeof(DT)); \ H5T_CONV(H5T_CONV_Ff, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, N) \ } while (0) #define H5T_HI_LO_BIT_SET(TYP, V, LO, HI) \ { \ unsigned count; \ unsigned char p; \ unsigned u; \ \ count = 0; \ for (u = 0; u < sizeof(TYP); u++) { \ count = (((unsigned)sizeof(TYP) - 1) - u) * 8; \ p = (unsigned char)((V) >> count); \ if (p > 0) { \ if (p & 0x80) \ count += 7; \ else if (p & 0x40) \ count += 6; \ else if (p & 0x20) \ count += 5; \ else if (p & 0x10) \ count += 4; \ else if (p & 0x08) \ count += 3; \ else if (p & 0x04) \ count += 2; \ else if (p & 0x02) \ count += 1; \ break; \ } /* end if */ \ } /* end for */ \ \ HI = count; \ \ count = 0; \ for (u = 0; u < sizeof(TYP); u++) { \ p = (unsigned char)((V) >> (u * 8)); \ if (p > 0) { \ count = u * 8; \ \ if (p & 0x01) \ ; \ else if (p & 0x02) \ count += 1; \ else if (p & 0x04) \ count += 2; \ else if (p & 0x08) \ count += 3; \ else if (p & 0x10) \ count += 4; \ else if (p & 0x20) \ count += 5; \ else if (p & 0x40) \ count += 6; \ else if (p & 0x80) \ count += 7; \ break; \ } /* end if */ \ } /* end for */ \ \ LO = count; \ } #define H5T_CONV_xF_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ if (sprec > dprec) { \ unsigned low_bit_pos, high_bit_pos; \ \ /* Detect high & low bits set in source */ \ H5T_HI_LO_BIT_SET(ST, *(S), low_bit_pos, high_bit_pos) \ \ /* Check for more bits of precision in src than available in dst */ \ if ((high_bit_pos - low_bit_pos) >= dprec) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_PRECISION, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, \ S, D, conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = (DT)(*(S)); \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else \ *(D) = (DT)(*(S)); \ } \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_xF_NOEX_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_xF(STYPE, DTYPE, ST, DT, D_MIN, D_MAX) \ do { \ H5T_CONV(H5T_CONV_xF, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, Y) \ } while (0) /* Quincey added the condition branch (else if (*(S) != (ST)((DT)(*(S))))). * It handles a special situation when the source is "float" and assigned the value * of "INT_MAX". Compilers do roundup making this value "INT_MAX+1". This branch * is to check that situation and return exception for some compilers, mainly GCC. * The branch if (*(S) > (DT)(D_MAX) || (sprec < dprec && *(S) == * (ST)(D_MAX))) is for some compilers like Sun, HP, IBM, and SGI where under * the same situation the "int" doesn't overflow. SLU - 2005/9/12 */ #define H5T_CONV_Fx_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ if (*(S) > (ST)(D_MAX) || (sprec < dprec && *(S) == (ST)(D_MAX))) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, S, D, \ conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = (DT)(D_MAX); \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else if (*(S) < (ST)(D_MIN)) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_RANGE_LOW, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, S, D, \ conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = (DT)(D_MIN); \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else if (*(S) != (ST)((DT)(*(S)))) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_TRUNCATE, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, S, D, \ conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = (DT)(*(S)); \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_Fx_NOEX_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ if (*(S) > (ST)(D_MAX)) \ *(D) = (DT)(D_MAX); \ else if (*(S) < (ST)(D_MIN)) \ *(D) = (DT)(D_MIN); \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_Fx(STYPE, DTYPE, ST, DT, D_MIN, D_MAX) \ do { \ H5T_CONV(H5T_CONV_Fx, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, Y) \ } while (0) #define H5T_CONV_fX(STYPE, DTYPE, ST, DT, D_MIN, D_MAX) \ do { \ HDcompile_assert(sizeof(ST) <= sizeof(DT)); \ H5T_CONV(H5T_CONV_xX, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, N) \ } while (0) #define H5T_CONV_Xf_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ if (*(S) > (ST)(D_MAX) || (sprec < dprec && *(S) == (ST)(D_MAX))) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, S, D, \ conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = H5_GLUE3(H5T_NATIVE_, DTYPE, _POS_INF_g); \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else if (*(S) < (ST)(D_MIN)) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_RANGE_LOW, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, S, D, \ conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = H5_GLUE3(H5T_NATIVE_, DTYPE, _NEG_INF_g); \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else if (sprec > dprec) { \ unsigned low_bit_pos, high_bit_pos; \ \ /* Detect high & low bits set in source */ \ H5T_HI_LO_BIT_SET(ST, *(S), low_bit_pos, high_bit_pos) \ \ /* Check for more bits of precision in src than available in dst */ \ if ((high_bit_pos - low_bit_pos) >= dprec) { \ H5T_conv_ret_t except_ret = (conv_ctx->u.conv.cb_struct.func)( \ H5T_CONV_EXCEPT_PRECISION, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, \ S, D, conv_ctx->u.conv.cb_struct.user_data); \ if (except_ret == H5T_CONV_UNHANDLED) \ /* Let compiler convert if case is ignored by user handler*/ \ *(D) = (DT)(*(S)); \ else if (except_ret == H5T_CONV_ABORT) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); \ /* if(except_ret==H5T_CONV_HANDLED): Fall through, user handled it */ \ } \ else \ *(D) = (DT)(*(S)); \ } \ else \ *(D) = (DT)(*(S)); \ } #define H5T_CONV_Xf_NOEX_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ if (*(S) > (ST)(D_MAX)) \ *(D) = H5_GLUE3(H5T_NATIVE_, DTYPE, _POS_INF_g); \ else { \ intmax_t s_cast = (intmax_t)(*(S)); \ intmax_t d_cast = (intmax_t)(D_MAX); \ \ /* Check if source value would underflow destination. Do NOT do this \ * by comparing against D_MIN casted to type ST here, as this will \ * generally be undefined behavior (casting negative float value <= 1.0 \ * to integer) for all floating point types and some compilers optimize \ * this in a way that causes unexpected behavior. Instead, grab the \ * absolute value of the source value first, then compare it to D_MAX. \ */ \ if (s_cast != INTMAX_MIN) \ s_cast = imaxabs(s_cast); \ else { \ /* Handle two's complement integer representations where abs(INTMAX_MIN) \ * can't be represented. Other representations will fall here as well, \ * but this should be fine. \ */ \ s_cast = INTMAX_MAX; \ d_cast -= 1; \ } \ \ if (s_cast > d_cast) \ *(D) = H5_GLUE3(H5T_NATIVE_, DTYPE, _NEG_INF_g); \ else \ *(D) = (DT)(*(S)); \ } \ } #define H5T_CONV_Xf(STYPE, DTYPE, ST, DT, D_MIN, D_MAX) \ do { \ HDcompile_assert(sizeof(ST) >= sizeof(DT)); \ H5T_CONV(H5T_CONV_Xf, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, Y) \ } while (0) /* Since all "no exception" cores do the same thing (assign the value in the * source location to the destination location, using casting), use one "core" * to do them all. */ #ifndef H5_WANT_DCONV_EXCEPTION #define H5T_CONV_NO_EXCEPT_CORE(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ { \ *(D) = (DT)(*(S)); \ } #endif /* H5_WANT_DCONV_EXCEPTION */ /* The main part of every integer hardware conversion macro */ #define H5T_CONV(GUTS, STYPE, DTYPE, ST, DT, D_MIN, D_MAX, PREC) \ { \ herr_t ret_value = SUCCEED; /* Return value */ \ \ FUNC_ENTER_PACKAGE \ \ { \ size_t elmtno; /*element number */ \ H5T_CONV_DECL_PREC(PREC) /*declare precision variables, or not */ \ void *src_buf; /*'raw' source buffer */ \ void *dst_buf; /*'raw' destination buffer */ \ ST *src, *s; /*source buffer */ \ DT *dst, *d; /*destination buffer */ \ ST src_aligned; /*source aligned type */ \ DT dst_aligned; /*destination aligned type */ \ bool s_mv, d_mv; /*move data to align it? */ \ ssize_t s_stride, d_stride; /*src and dst strides */ \ size_t safe; /*how many elements are safe to process in each pass */ \ \ switch (cdata->command) { \ case H5T_CONV_INIT: \ /* Sanity check and initialize statistics */ \ cdata->need_bkg = H5T_BKG_NO; \ if (NULL == st || NULL == dt) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTINIT, FAIL, "invalid datatype"); \ if (st->shared->size != sizeof(ST) || dt->shared->size != sizeof(DT)) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTINIT, FAIL, "disagreement about datatype size"); \ CI_ALLOC_PRIV \ break; \ \ case H5T_CONV_FREE: \ /* Print and free statistics */ \ CI_PRINT_STATS(STYPE, DTYPE); \ CI_FREE_PRIV \ break; \ \ case H5T_CONV_CONV: \ if (NULL == st || NULL == dt) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTINIT, FAIL, "invalid datatype"); \ if (NULL == conv_ctx) \ HGOTO_ERROR(H5E_DATATYPE, H5E_CANTINIT, FAIL, \ "invalid datatype conversion context pointer"); \ \ /* Initialize source & destination strides */ \ if (buf_stride) { \ assert(buf_stride >= sizeof(ST)); \ assert(buf_stride >= sizeof(DT)); \ s_stride = d_stride = (ssize_t)buf_stride; \ } \ else { \ s_stride = sizeof(ST); \ d_stride = sizeof(DT); \ } \ \ /* Is alignment required for source or dest? */ \ s_mv = H5T_NATIVE_##STYPE##_ALIGN_g > 1 && \ ((size_t)buf % H5T_NATIVE_##STYPE##_ALIGN_g || \ /* Cray */ ((size_t)((ST *)buf) != (size_t)buf) || \ (size_t)s_stride % H5T_NATIVE_##STYPE##_ALIGN_g); \ d_mv = H5T_NATIVE_##DTYPE##_ALIGN_g > 1 && \ ((size_t)buf % H5T_NATIVE_##DTYPE##_ALIGN_g || \ /* Cray */ ((size_t)((DT *)buf) != (size_t)buf) || \ (size_t)d_stride % H5T_NATIVE_##DTYPE##_ALIGN_g); \ CI_INC_SRC(s_mv) \ CI_INC_DST(d_mv) \ \ H5T_CONV_SET_PREC(PREC) /*init precision variables, or not */ \ \ /* The outer loop of the type conversion macro, controlling which */ \ /* direction the buffer is walked */ \ while (nelmts > 0) { \ /* Check if we need to go backwards through the buffer */ \ if (d_stride > s_stride) { \ /* Compute the number of "safe" destination elements at */ \ /* the end of the buffer (Those which don't overlap with */ \ /* any source elements at the beginning of the buffer) */ \ safe = nelmts - (((nelmts * (size_t)s_stride) + (size_t)(d_stride - 1)) / \ (size_t)d_stride); \ \ /* If we're down to the last few elements, just wrap up */ \ /* with a "real" reverse copy */ \ if (safe < 2) { \ src = (ST *)(src_buf = (void *)((uint8_t *)buf + \ (nelmts - 1) * (size_t)s_stride)); \ dst = (DT *)(dst_buf = (void *)((uint8_t *)buf + \ (nelmts - 1) * (size_t)d_stride)); \ s_stride = -s_stride; \ d_stride = -d_stride; \ \ safe = nelmts; \ } /* end if */ \ else { \ src = (ST *)(src_buf = (void *)((uint8_t *)buf + \ (nelmts - safe) * (size_t)s_stride)); \ dst = (DT *)(dst_buf = (void *)((uint8_t *)buf + \ (nelmts - safe) * (size_t)d_stride)); \ } /* end else */ \ } /* end if */ \ else { \ /* Single forward pass over all data */ \ src = (ST *)(src_buf = buf); \ dst = (DT *)(dst_buf = buf); \ safe = nelmts; \ } /* end else */ \ \ /* Perform loop over elements to convert */ \ if (s_mv && d_mv) { \ /* Alignment is required for both source and dest */ \ s = &src_aligned; \ H5T_CONV_LOOP_OUTER(PRE_SALIGN, PRE_DALIGN, POST_SALIGN, POST_DALIGN, GUTS, \ STYPE, DTYPE, s, d, ST, DT, D_MIN, D_MAX) \ } \ else if (s_mv) { \ /* Alignment is required only for source */ \ s = &src_aligned; \ H5T_CONV_LOOP_OUTER(PRE_SALIGN, PRE_DNOALIGN, POST_SALIGN, POST_DNOALIGN, GUTS, \ STYPE, DTYPE, s, dst, ST, DT, D_MIN, D_MAX) \ } \ else if (d_mv) { \ /* Alignment is required only for destination */ \ H5T_CONV_LOOP_OUTER(PRE_SNOALIGN, PRE_DALIGN, POST_SNOALIGN, POST_DALIGN, GUTS, \ STYPE, DTYPE, src, d, ST, DT, D_MIN, D_MAX) \ } \ else { \ /* Alignment is not required for both source and destination */ \ H5T_CONV_LOOP_OUTER(PRE_SNOALIGN, PRE_DNOALIGN, POST_SNOALIGN, POST_DNOALIGN, \ GUTS, STYPE, DTYPE, src, dst, ST, DT, D_MIN, D_MAX) \ } \ \ /* Decrement number of elements left to convert */ \ nelmts -= safe; \ } /* end while */ \ break; \ \ default: \ HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); \ } \ } \ \ done: \ FUNC_LEAVE_NOAPI(ret_value) \ } /* Declare the source & destination precision variables */ #define H5T_CONV_DECL_PREC(PREC) H5_GLUE(H5T_CONV_DECL_PREC_, PREC) #define H5T_CONV_DECL_PREC_Y \ size_t sprec; /*source precision */ \ size_t dprec; /*destination precision */ \ H5T_class_t tclass; /*datatype's class */ #define H5T_CONV_DECL_PREC_N /*no precision variables */ /* Initialize the source & destination precision variables */ #define H5T_CONV_SET_PREC(PREC) H5_GLUE(H5T_CONV_SET_PREC_, PREC) #define H5T_CONV_SET_PREC_Y \ /* Get source & destination precisions into a variable */ \ tclass = st->shared->type; \ assert(tclass == H5T_INTEGER || tclass == H5T_FLOAT); \ if (tclass == H5T_INTEGER) \ sprec = st->shared->u.atomic.prec; \ else \ sprec = 1 + st->shared->u.atomic.u.f.msize; \ tclass = dt->shared->type; \ assert(tclass == H5T_INTEGER || tclass == H5T_FLOAT); \ if (tclass == H5T_INTEGER) \ dprec = dt->shared->u.atomic.prec; \ else \ dprec = 1 + dt->shared->u.atomic.u.f.msize; #define H5T_CONV_SET_PREC_N /*don't init precision variables */ /* Macro defining action on source data which needs to be aligned (before main action) */ #define H5T_CONV_LOOP_PRE_SALIGN(ST) \ { \ /* The uint8_t * cast is required to avoid tripping over undefined behavior. \ * \ * The typed pointer arrives via a void pointer, which may have any alignment. \ * We then cast it to a pointer to a type that is assumed to be aligned, which \ * is undefined behavior (section 6.3.2.3 paragraph 7 of the C99 standard). \ * In the past this hasn't caused many problems, but in some cases (e.g. \ * converting long doubles on macOS), an optimizing compiler might do the \ * wrong thing (in the macOS case, the conversion uses SSE, which has stricter \ * requirements about alignment). \ */ \ H5MM_memcpy(&src_aligned, (const uint8_t *)src, sizeof(ST)); \ } /* Macro defining action on source data which doesn't need to be aligned (before main action) */ #define H5T_CONV_LOOP_PRE_SNOALIGN(ST) \ { \ } /* Macro defining action on destination data which needs to be aligned (before main action) */ #define H5T_CONV_LOOP_PRE_DALIGN(DT) \ { \ d = &dst_aligned; \ } /* Macro defining action on destination data which doesn't need to be aligned (before main action) */ #define H5T_CONV_LOOP_PRE_DNOALIGN(DT) \ { \ } /* Macro defining action on source data which needs to be aligned (after main action) */ #define H5T_CONV_LOOP_POST_SALIGN(ST) \ { \ } /* Macro defining action on source data which doesn't need to be aligned (after main action) */ #define H5T_CONV_LOOP_POST_SNOALIGN(ST) \ { \ } /* Macro defining action on destination data which needs to be aligned (after main action) */ #define H5T_CONV_LOOP_POST_DALIGN(DT) \ { \ /* The uint8_t * cast is required to avoid tripping over undefined behavior. \ * \ * The typed pointer arrives via a void pointer, which may have any alignment. \ * We then cast it to a pointer to a type that is assumed to be aligned, which \ * is undefined behavior (section 6.3.2.3 paragraph 7 of the C99 standard). \ * In the past this hasn't caused many problems, but in some cases (e.g. \ * converting long doubles on macOS), an optimizing compiler might do the \ * wrong thing (in the macOS case, the conversion uses SSE, which has stricter \ * requirements about alignment). \ */ \ H5MM_memcpy((uint8_t *)dst, &dst_aligned, sizeof(DT)); \ } /* Macro defining action on destination data which doesn't need to be aligned (after main action) */ #define H5T_CONV_LOOP_POST_DNOALIGN(DT) \ { \ } /* The outer wrapper for the type conversion loop, to check for an exception handling routine */ #define H5T_CONV_LOOP_OUTER(PRE_SALIGN_GUTS, PRE_DALIGN_GUTS, POST_SALIGN_GUTS, POST_DALIGN_GUTS, GUTS, \ STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ if (conv_ctx->u.conv.cb_struct.func) { \ H5T_CONV_LOOP(PRE_SALIGN_GUTS, PRE_DALIGN_GUTS, POST_SALIGN_GUTS, POST_DALIGN_GUTS, GUTS, STYPE, \ DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ } \ else { \ H5T_CONV_LOOP(PRE_SALIGN_GUTS, PRE_DALIGN_GUTS, POST_SALIGN_GUTS, POST_DALIGN_GUTS, \ H5_GLUE(GUTS, _NOEX), STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ } /* The inner loop of the type conversion macro, actually converting the elements */ #define H5T_CONV_LOOP(PRE_SALIGN_GUTS, PRE_DALIGN_GUTS, POST_SALIGN_GUTS, POST_DALIGN_GUTS, GUTS, STYPE, \ DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ for (elmtno = 0; elmtno < safe; elmtno++) { \ /* Handle source pre-alignment */ \ H5_GLUE(H5T_CONV_LOOP_, PRE_SALIGN_GUTS) \ (ST) \ \ /* Handle destination pre-alignment */ \ H5_GLUE(H5T_CONV_LOOP_, PRE_DALIGN_GUTS)(DT) \ \ /* ... user-defined stuff here -- the conversion ... */ \ H5T_CONV_LOOP_GUTS(GUTS, STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ \ /* Handle source post-alignment */ \ H5_GLUE(H5T_CONV_LOOP_, POST_SALIGN_GUTS)(ST) \ \ /* Handle destination post-alignment */ \ H5_GLUE(H5T_CONV_LOOP_, POST_DALIGN_GUTS)(DT) \ \ /* Advance pointers */ \ src_buf = (void *)((uint8_t *)src_buf + s_stride); \ src = (ST *)src_buf; \ dst_buf = (void *)((uint8_t *)dst_buf + d_stride); \ dst = (DT *)dst_buf; \ } /* Macro to call the actual "guts" of the type conversion, or call the "no exception" guts */ #ifdef H5_WANT_DCONV_EXCEPTION #define H5T_CONV_LOOP_GUTS(GUTS, STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ /* ... user-defined stuff here -- the conversion ... */ \ H5_GLUE(GUTS, _CORE)(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) #else /* H5_WANT_DCONV_EXCEPTION */ #define H5T_CONV_LOOP_GUTS(GUTS, STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) \ H5_GLUE(H5T_CONV_NO_EXCEPT, _CORE)(STYPE, DTYPE, S, D, ST, DT, D_MIN, D_MAX) #endif /* H5_WANT_DCONV_EXCEPTION */ #ifdef H5T_DEBUG /* Print alignment statistics */ #define CI_PRINT_STATS(STYPE, DTYPE) \ do { \ if (H5DEBUG(T) && ((H5T_conv_hw_t *)cdata->priv)->s_aligned) { \ fprintf(H5DEBUG(T), " %zu src elements aligned on %zu-byte boundaries\n", \ ((H5T_conv_hw_t *)cdata->priv)->s_aligned, H5T_NATIVE_##STYPE##_ALIGN_g); \ } \ if (H5DEBUG(T) && ((H5T_conv_hw_t *)cdata->priv)->d_aligned) { \ fprintf(H5DEBUG(T), " %zu dst elements aligned on %zu-byte boundaries\n", \ ((H5T_conv_hw_t *)cdata->priv)->d_aligned, H5T_NATIVE_##DTYPE##_ALIGN_g); \ } \ } while (0) /* Allocate private alignment structure for atomic types */ #define CI_ALLOC_PRIV \ if (NULL == (cdata->priv = H5MM_calloc(sizeof(H5T_conv_hw_t)))) { \ HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed"); \ } /* Free private alignment structure for atomic types */ #define CI_FREE_PRIV \ if (cdata->priv != NULL) \ cdata->priv = H5MM_xfree(cdata->priv); /* Increment source alignment counter */ #define CI_INC_SRC(s) \ if (s) \ ((H5T_conv_hw_t *)cdata->priv)->s_aligned += nelmts; /* Increment destination alignment counter */ #define CI_INC_DST(d) \ if (d) \ ((H5T_conv_hw_t *)cdata->priv)->d_aligned += nelmts; #else /* H5T_DEBUG */ #define CI_PRINT_STATS(STYPE, DTYPE) /*void*/ #define CI_ALLOC_PRIV cdata->priv = NULL; #define CI_FREE_PRIV /* void */ #define CI_INC_SRC(s) /* void */ #define CI_INC_DST(d) /* void */ #endif /* H5T_DEBUG */ /* Swap two elements (I & J) of an array using a temporary variable */ #define H5_SWAP_BYTES(ARRAY, I, J) \ do { \ uint8_t _tmp; \ _tmp = ARRAY[I]; \ ARRAY[I] = ARRAY[J]; \ ARRAY[J] = _tmp; \ } while (0) /* Minimum size of variable-length conversion buffer */ #define H5T_VLEN_MIN_CONF_BUF_SIZE 4096 /******************/ /* Local Typedefs */ /******************/ /* Conversion data for H5T__conv_struct() */ typedef struct H5T_conv_struct_t { int *src2dst; /*mapping from src to dst member num */ H5T_t **src_memb; /*source member datatypes */ H5T_t **dst_memb; /*destination member datatypes */ hid_t *src_memb_id; /*source member type ID's */ hid_t *dst_memb_id; /*destination member type ID's */ H5T_path_t **memb_path; /*conversion path for each member */ H5T_subset_info_t subset_info; /*info related to compound subsets */ unsigned src_nmembs; /*needed by free function */ bool need_ids; /*whether we need IDs for the datatypes */ } H5T_conv_struct_t; /* Conversion data for H5T__conv_enum() */ typedef struct H5T_enum_struct_t { int base; /*lowest `in' value */ unsigned length; /*num elements in arrays */ int *src2dst; /*map from src to dst index */ } H5T_enum_struct_t; /* Conversion data for the hardware conversion functions */ typedef struct H5T_conv_hw_t { size_t s_aligned; /*number source elements aligned */ size_t d_aligned; /*number destination elements aligned*/ } H5T_conv_hw_t; /********************/ /* Package Typedefs */ /********************/ /********************/ /* Local Prototypes */ /********************/ static herr_t H5T__reverse_order(uint8_t *rev, uint8_t *s, size_t size, H5T_order_t order); /*********************/ /* Public Variables */ /*********************/ /*********************/ /* Package Variables */ /*********************/ /*****************************/ /* Library Private Variables */ /*****************************/ /*******************/ /* Local Variables */ /*******************/ /* Declare a free list to manage pieces of vlen data */ H5FL_BLK_DEFINE_STATIC(vlen_seq); /* Declare a free list to manage pieces of array data */ H5FL_BLK_DEFINE_STATIC(array_seq); /* Declare a free list to manage pieces of reference data */ H5FL_BLK_DEFINE_STATIC(ref_seq); /*------------------------------------------------------------------------- * Function: H5T__conv_noop * * Purpose: The no-op conversion. The library knows about this * conversion without it being registered. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_noop(H5T_t H5_ATTR_UNUSED *src, H5T_t H5_ATTR_UNUSED *dst, H5T_cdata_t *cdata, const H5T_conv_ctx_t H5_ATTR_UNUSED *conv_ctx, size_t H5_ATTR_UNUSED nelmts, size_t H5_ATTR_UNUSED buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void H5_ATTR_UNUSED *buf, void H5_ATTR_UNUSED *background) { herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE switch (cdata->command) { case H5T_CONV_INIT: cdata->need_bkg = H5T_BKG_NO; break; case H5T_CONV_CONV: /* Nothing to convert */ break; case H5T_CONV_FREE: break; default: HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); } /* end switch */ done: FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_noop() */ /*------------------------------------------------------------------------- * Function: H5T__conv_order_opt * * Purpose: Convert one type to another when byte order is the only * difference. This is the optimized version of H5T__conv_order() * for a handful of different sizes. * * Note: This is a soft conversion function. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_order_opt(H5T_t *src, H5T_t *dst, H5T_cdata_t *cdata, const H5T_conv_ctx_t H5_ATTR_UNUSED *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *_buf, void H5_ATTR_UNUSED *background) { uint8_t *buf = (uint8_t *)_buf; size_t i; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE switch (cdata->command) { case H5T_CONV_INIT: /* Capability query */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); if (src->shared->size != dst->shared->size || 0 != src->shared->u.atomic.offset || 0 != dst->shared->u.atomic.offset) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "conversion not supported"); if ((src->shared->type == H5T_REFERENCE && dst->shared->type != H5T_REFERENCE) || (dst->shared->type == H5T_REFERENCE && src->shared->type != H5T_REFERENCE)) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "conversion not supported"); if (src->shared->type != H5T_REFERENCE && !((H5T_ORDER_BE == src->shared->u.atomic.order && H5T_ORDER_LE == dst->shared->u.atomic.order) || (H5T_ORDER_LE == src->shared->u.atomic.order && H5T_ORDER_BE == dst->shared->u.atomic.order))) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "conversion not supported"); if (src->shared->size != 1 && src->shared->size != 2 && src->shared->size != 4 && src->shared->size != 8 && src->shared->size != 16) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "conversion not supported"); switch (src->shared->type) { case H5T_INTEGER: case H5T_BITFIELD: case H5T_REFERENCE: /* nothing to check */ break; case H5T_FLOAT: if (src->shared->u.atomic.u.f.sign != dst->shared->u.atomic.u.f.sign || src->shared->u.atomic.u.f.epos != dst->shared->u.atomic.u.f.epos || src->shared->u.atomic.u.f.esize != dst->shared->u.atomic.u.f.esize || src->shared->u.atomic.u.f.ebias != dst->shared->u.atomic.u.f.ebias || src->shared->u.atomic.u.f.mpos != dst->shared->u.atomic.u.f.mpos || src->shared->u.atomic.u.f.msize != dst->shared->u.atomic.u.f.msize || src->shared->u.atomic.u.f.norm != dst->shared->u.atomic.u.f.norm || src->shared->u.atomic.u.f.pad != dst->shared->u.atomic.u.f.pad) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "conversion not supported"); break; case H5T_NO_CLASS: case H5T_TIME: case H5T_STRING: case H5T_OPAQUE: case H5T_COMPOUND: case H5T_ENUM: case H5T_VLEN: case H5T_ARRAY: case H5T_NCLASSES: default: HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "conversion not supported"); } cdata->need_bkg = H5T_BKG_NO; break; case H5T_CONV_CONV: /* The conversion */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); /* Check for "no op" reference conversion */ if (src->shared->type == H5T_REFERENCE) { /* Sanity check */ if (dst->shared->type != H5T_REFERENCE) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a H5T_REFERENCE datatype"); /* Check if we are on a little-endian machine (the order that * the addresses in the file must be) and just get out now, there * is no need to convert the object reference. Yes, this is * icky and non-portable, but I can't think of a better way to * support allowing the objno in the H5O_info_t struct and the * hobj_ref_t type to be compared directly without introducing a * "native" hobj_ref_t datatype and I think that would break a * lot of existing programs. -QAK */ if (H5T_native_order_g == H5T_ORDER_LE) break; } /* end if */ buf_stride = buf_stride ? buf_stride : src->shared->size; switch (src->shared->size) { case 1: /*no-op*/ break; case 2: for (/*void*/; nelmts >= 20; nelmts -= 20) { H5_SWAP_BYTES(buf, 0, 1); /* 0 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 1 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 2 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 3 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 4 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 5 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 6 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 7 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 8 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 9 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 10 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 11 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 12 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 13 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 14 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 15 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 16 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 17 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 18 */ buf += buf_stride; H5_SWAP_BYTES(buf, 0, 1); /* 19 */ buf += buf_stride; } /* end for */ for (i = 0; i < nelmts; i++, buf += buf_stride) H5_SWAP_BYTES(buf, 0, 1); break; case 4: for (/*void*/; nelmts >= 20; nelmts -= 20) { H5_SWAP_BYTES(buf, 0, 3); /* 0 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 1 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 2 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 3 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 4 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 5 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 6 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 7 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 8 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 9 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 10 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 11 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 12 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 13 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 14 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 15 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 16 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 17 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 18 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 3); /* 19 */ H5_SWAP_BYTES(buf, 1, 2); buf += buf_stride; } /* end for */ for (i = 0; i < nelmts; i++, buf += buf_stride) { H5_SWAP_BYTES(buf, 0, 3); H5_SWAP_BYTES(buf, 1, 2); } /* end for */ break; case 8: for (/*void*/; nelmts >= 10; nelmts -= 10) { H5_SWAP_BYTES(buf, 0, 7); /* 0 */ H5_SWAP_BYTES(buf, 1, 6); H5_SWAP_BYTES(buf, 2, 5); H5_SWAP_BYTES(buf, 3, 4); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 7); /* 1 */ H5_SWAP_BYTES(buf, 1, 6); H5_SWAP_BYTES(buf, 2, 5); H5_SWAP_BYTES(buf, 3, 4); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 7); /* 2 */ H5_SWAP_BYTES(buf, 1, 6); H5_SWAP_BYTES(buf, 2, 5); H5_SWAP_BYTES(buf, 3, 4); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 7); /* 3 */ H5_SWAP_BYTES(buf, 1, 6); H5_SWAP_BYTES(buf, 2, 5); H5_SWAP_BYTES(buf, 3, 4); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 7); /* 4 */ H5_SWAP_BYTES(buf, 1, 6); H5_SWAP_BYTES(buf, 2, 5); H5_SWAP_BYTES(buf, 3, 4); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 7); /* 5 */ H5_SWAP_BYTES(buf, 1, 6); H5_SWAP_BYTES(buf, 2, 5); H5_SWAP_BYTES(buf, 3, 4); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 7); /* 6 */ H5_SWAP_BYTES(buf, 1, 6); H5_SWAP_BYTES(buf, 2, 5); H5_SWAP_BYTES(buf, 3, 4); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 7); /* 7 */ H5_SWAP_BYTES(buf, 1, 6); H5_SWAP_BYTES(buf, 2, 5); H5_SWAP_BYTES(buf, 3, 4); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 7); /* 8 */ H5_SWAP_BYTES(buf, 1, 6); H5_SWAP_BYTES(buf, 2, 5); H5_SWAP_BYTES(buf, 3, 4); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 7); /* 9 */ H5_SWAP_BYTES(buf, 1, 6); H5_SWAP_BYTES(buf, 2, 5); H5_SWAP_BYTES(buf, 3, 4); buf += buf_stride; } /* end for */ for (i = 0; i < nelmts; i++, buf += buf_stride) { H5_SWAP_BYTES(buf, 0, 7); H5_SWAP_BYTES(buf, 1, 6); H5_SWAP_BYTES(buf, 2, 5); H5_SWAP_BYTES(buf, 3, 4); } /* end for */ break; case 16: for (/*void*/; nelmts >= 10; nelmts -= 10) { H5_SWAP_BYTES(buf, 0, 15); /* 0 */ H5_SWAP_BYTES(buf, 1, 14); H5_SWAP_BYTES(buf, 2, 13); H5_SWAP_BYTES(buf, 3, 12); H5_SWAP_BYTES(buf, 4, 11); H5_SWAP_BYTES(buf, 5, 10); H5_SWAP_BYTES(buf, 6, 9); H5_SWAP_BYTES(buf, 7, 8); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 15); /* 1 */ H5_SWAP_BYTES(buf, 1, 14); H5_SWAP_BYTES(buf, 2, 13); H5_SWAP_BYTES(buf, 3, 12); H5_SWAP_BYTES(buf, 4, 11); H5_SWAP_BYTES(buf, 5, 10); H5_SWAP_BYTES(buf, 6, 9); H5_SWAP_BYTES(buf, 7, 8); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 15); /* 2 */ H5_SWAP_BYTES(buf, 1, 14); H5_SWAP_BYTES(buf, 2, 13); H5_SWAP_BYTES(buf, 3, 12); H5_SWAP_BYTES(buf, 4, 11); H5_SWAP_BYTES(buf, 5, 10); H5_SWAP_BYTES(buf, 6, 9); H5_SWAP_BYTES(buf, 7, 8); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 15); /* 3 */ H5_SWAP_BYTES(buf, 1, 14); H5_SWAP_BYTES(buf, 2, 13); H5_SWAP_BYTES(buf, 3, 12); H5_SWAP_BYTES(buf, 4, 11); H5_SWAP_BYTES(buf, 5, 10); H5_SWAP_BYTES(buf, 6, 9); H5_SWAP_BYTES(buf, 7, 8); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 15); /* 4 */ H5_SWAP_BYTES(buf, 1, 14); H5_SWAP_BYTES(buf, 2, 13); H5_SWAP_BYTES(buf, 3, 12); H5_SWAP_BYTES(buf, 4, 11); H5_SWAP_BYTES(buf, 5, 10); H5_SWAP_BYTES(buf, 6, 9); H5_SWAP_BYTES(buf, 7, 8); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 15); /* 5 */ H5_SWAP_BYTES(buf, 1, 14); H5_SWAP_BYTES(buf, 2, 13); H5_SWAP_BYTES(buf, 3, 12); H5_SWAP_BYTES(buf, 4, 11); H5_SWAP_BYTES(buf, 5, 10); H5_SWAP_BYTES(buf, 6, 9); H5_SWAP_BYTES(buf, 7, 8); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 15); /* 6 */ H5_SWAP_BYTES(buf, 1, 14); H5_SWAP_BYTES(buf, 2, 13); H5_SWAP_BYTES(buf, 3, 12); H5_SWAP_BYTES(buf, 4, 11); H5_SWAP_BYTES(buf, 5, 10); H5_SWAP_BYTES(buf, 6, 9); H5_SWAP_BYTES(buf, 7, 8); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 15); /* 7 */ H5_SWAP_BYTES(buf, 1, 14); H5_SWAP_BYTES(buf, 2, 13); H5_SWAP_BYTES(buf, 3, 12); H5_SWAP_BYTES(buf, 4, 11); H5_SWAP_BYTES(buf, 5, 10); H5_SWAP_BYTES(buf, 6, 9); H5_SWAP_BYTES(buf, 7, 8); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 15); /* 8 */ H5_SWAP_BYTES(buf, 1, 14); H5_SWAP_BYTES(buf, 2, 13); H5_SWAP_BYTES(buf, 3, 12); H5_SWAP_BYTES(buf, 4, 11); H5_SWAP_BYTES(buf, 5, 10); H5_SWAP_BYTES(buf, 6, 9); H5_SWAP_BYTES(buf, 7, 8); buf += buf_stride; H5_SWAP_BYTES(buf, 0, 15); /* 9 */ H5_SWAP_BYTES(buf, 1, 14); H5_SWAP_BYTES(buf, 2, 13); H5_SWAP_BYTES(buf, 3, 12); H5_SWAP_BYTES(buf, 4, 11); H5_SWAP_BYTES(buf, 5, 10); H5_SWAP_BYTES(buf, 6, 9); H5_SWAP_BYTES(buf, 7, 8); buf += buf_stride; } /* end for */ for (i = 0; i < nelmts; i++, buf += buf_stride) { H5_SWAP_BYTES(buf, 0, 15); H5_SWAP_BYTES(buf, 1, 14); H5_SWAP_BYTES(buf, 2, 13); H5_SWAP_BYTES(buf, 3, 12); H5_SWAP_BYTES(buf, 4, 11); H5_SWAP_BYTES(buf, 5, 10); H5_SWAP_BYTES(buf, 6, 9); H5_SWAP_BYTES(buf, 7, 8); } /* end for */ break; default: HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "invalid conversion size"); } /* end switch */ break; case H5T_CONV_FREE: /* Free private data */ break; default: HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); } /* end switch */ done: FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_order_opt() */ /*------------------------------------------------------------------------- * Function: H5T__conv_order * * Purpose: Convert one type to another when byte order is the only * difference. * * Note: This is a soft conversion function. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_order(H5T_t *src, H5T_t *dst, H5T_cdata_t *cdata, const H5T_conv_ctx_t H5_ATTR_UNUSED *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *_buf, void H5_ATTR_UNUSED *background) { uint8_t *buf = (uint8_t *)_buf; size_t i; size_t j, md; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE switch (cdata->command) { case H5T_CONV_INIT: /* Capability query */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); if (src->shared->size != dst->shared->size || 0 != src->shared->u.atomic.offset || 0 != dst->shared->u.atomic.offset || !((H5T_ORDER_BE == src->shared->u.atomic.order && H5T_ORDER_LE == dst->shared->u.atomic.order) || (H5T_ORDER_LE == src->shared->u.atomic.order && H5T_ORDER_BE == dst->shared->u.atomic.order))) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "conversion not supported"); switch (src->shared->type) { case H5T_INTEGER: case H5T_BITFIELD: /* nothing to check */ break; case H5T_FLOAT: if (src->shared->u.atomic.u.f.sign != dst->shared->u.atomic.u.f.sign || src->shared->u.atomic.u.f.epos != dst->shared->u.atomic.u.f.epos || src->shared->u.atomic.u.f.esize != dst->shared->u.atomic.u.f.esize || src->shared->u.atomic.u.f.ebias != dst->shared->u.atomic.u.f.ebias || src->shared->u.atomic.u.f.mpos != dst->shared->u.atomic.u.f.mpos || src->shared->u.atomic.u.f.msize != dst->shared->u.atomic.u.f.msize || src->shared->u.atomic.u.f.norm != dst->shared->u.atomic.u.f.norm || src->shared->u.atomic.u.f.pad != dst->shared->u.atomic.u.f.pad) { HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "conversion not supported"); } /* end if */ break; case H5T_NO_CLASS: case H5T_TIME: case H5T_STRING: case H5T_OPAQUE: case H5T_COMPOUND: case H5T_REFERENCE: case H5T_ENUM: case H5T_VLEN: case H5T_ARRAY: case H5T_NCLASSES: default: HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "conversion not supported"); } /* end switch */ cdata->need_bkg = H5T_BKG_NO; break; case H5T_CONV_CONV: /* The conversion */ if (NULL == src) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); buf_stride = buf_stride ? buf_stride : src->shared->size; md = src->shared->size / 2; for (i = 0; i < nelmts; i++, buf += buf_stride) for (j = 0; j < md; j++) H5_SWAP_BYTES(buf, j, src->shared->size - (j + 1)); break; case H5T_CONV_FREE: /* Free private data */ break; default: HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); } /* end switch */ done: FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_order() */ /*------------------------------------------------------------------------- * Function: H5T__conv_b_b * * Purpose: Convert from one bitfield to any other bitfield. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_b_b(H5T_t *src, H5T_t *dst, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *_buf, void H5_ATTR_UNUSED *background) { uint8_t *buf = (uint8_t *)_buf; ssize_t direction; /*direction of traversal */ size_t elmtno; /*element number */ size_t olap; /*num overlapping elements */ size_t half_size; /*1/2 of total size for swapping*/ uint8_t *s, *sp, *d, *dp; /*source and dest traversal ptrs*/ uint8_t dbuf[256] = {0}; /*temp destination buffer */ size_t msb_pad_offset; /*offset for dest MSB padding */ size_t i; uint8_t *src_rev = NULL; /*order-reversed source buffer */ H5T_conv_ret_t except_ret; /*return of callback function */ bool reverse; /*if reverse the order of destination */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE switch (cdata->command) { case H5T_CONV_INIT: /* Capability query */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); if (H5T_ORDER_LE != src->shared->u.atomic.order && H5T_ORDER_BE != src->shared->u.atomic.order) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unsupported byte order"); if (H5T_ORDER_LE != dst->shared->u.atomic.order && H5T_ORDER_BE != dst->shared->u.atomic.order) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unsupported byte order"); cdata->need_bkg = H5T_BKG_NO; break; case H5T_CONV_FREE: break; case H5T_CONV_CONV: if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); if (NULL == conv_ctx) HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "invalid datatype conversion context pointer"); /* * Do we process the values from beginning to end or vice versa? Also, * how many of the elements have the source and destination areas * overlapping? */ if (src->shared->size == dst->shared->size || buf_stride) { sp = dp = (uint8_t *)buf; direction = 1; olap = nelmts; } else if (src->shared->size >= dst->shared->size) { double olap_d = ceil((double)(dst->shared->size) / (double)(src->shared->size - dst->shared->size)); olap = (size_t)olap_d; sp = dp = (uint8_t *)buf; direction = 1; } else { double olap_d = ceil((double)(src->shared->size) / (double)(dst->shared->size - src->shared->size)); olap = (size_t)olap_d; sp = (uint8_t *)buf + (nelmts - 1) * src->shared->size; dp = (uint8_t *)buf + (nelmts - 1) * dst->shared->size; direction = -1; } /* Allocate space for order-reversed source buffer */ src_rev = (uint8_t *)H5MM_calloc(src->shared->size); /* The conversion loop */ H5_CHECK_OVERFLOW(buf_stride, size_t, ssize_t); H5_CHECK_OVERFLOW(src->shared->size, size_t, ssize_t); H5_CHECK_OVERFLOW(dst->shared->size, size_t, ssize_t); for (elmtno = 0; elmtno < nelmts; elmtno++) { /* * If the source and destination buffers overlap then use a * temporary buffer for the destination. */ if (direction > 0) { s = sp; d = elmtno < olap ? dbuf : dp; } /* end if */ else { s = sp; d = (elmtno + olap) >= nelmts ? dbuf : dp; } /* end else */ #ifndef NDEBUG /* I don't quite trust the overlap calculations yet --rpm */ if (d == dbuf) assert((dp >= sp && dp < sp + src->shared->size) || (sp >= dp && sp < dp + dst->shared->size)); else assert((dp < sp && dp + dst->shared->size <= sp) || (sp < dp && sp + src->shared->size <= dp)); #endif /* * Put the data in little endian order so our loops aren't so * complicated. We'll do all the conversion stuff assuming * little endian and then we'll fix the order at the end. */ if (H5T_ORDER_BE == src->shared->u.atomic.order) { half_size = src->shared->size / 2; for (i = 0; i < half_size; i++) { uint8_t tmp = s[src->shared->size - (i + 1)]; s[src->shared->size - (i + 1)] = s[i]; s[i] = tmp; } /* end for */ } /* end if */ /* Initiate these variables */ except_ret = H5T_CONV_UNHANDLED; reverse = true; /* * Copy the significant part of the value. If the source is larger * than the destination then invoke the overflow function or copy * as many bits as possible. Zero extra bits in the destination. */ if (src->shared->u.atomic.prec > dst->shared->u.atomic.prec) { /*overflow*/ if (conv_ctx->u.conv.cb_struct.func) { /*If user's exception handler is present, use it*/ H5T__reverse_order(src_rev, s, src->shared->size, src->shared->u.atomic.order); /*reverse order first*/ except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } /* end if */ if (except_ret == H5T_CONV_UNHANDLED) { H5T__bit_copy(d, dst->shared->u.atomic.offset, s, src->shared->u.atomic.offset, dst->shared->u.atomic.prec); } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); else if (except_ret == H5T_CONV_HANDLED) /*Don't reverse because user handles it*/ reverse = false; } else { H5T__bit_copy(d, dst->shared->u.atomic.offset, s, src->shared->u.atomic.offset, src->shared->u.atomic.prec); H5T__bit_set(d, dst->shared->u.atomic.offset + src->shared->u.atomic.prec, dst->shared->u.atomic.prec - src->shared->u.atomic.prec, false); } /* * Fill the destination padding areas. */ switch (dst->shared->u.atomic.lsb_pad) { case H5T_PAD_ZERO: H5T__bit_set(d, (size_t)0, dst->shared->u.atomic.offset, false); break; case H5T_PAD_ONE: H5T__bit_set(d, (size_t)0, dst->shared->u.atomic.offset, true); break; case H5T_PAD_ERROR: case H5T_PAD_BACKGROUND: case H5T_NPAD: default: HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unsupported LSB padding"); } /* end switch */ msb_pad_offset = dst->shared->u.atomic.offset + dst->shared->u.atomic.prec; switch (dst->shared->u.atomic.msb_pad) { case H5T_PAD_ZERO: H5T__bit_set(d, msb_pad_offset, 8 * dst->shared->size - msb_pad_offset, false); break; case H5T_PAD_ONE: H5T__bit_set(d, msb_pad_offset, 8 * dst->shared->size - msb_pad_offset, true); break; case H5T_PAD_ERROR: case H5T_PAD_BACKGROUND: case H5T_NPAD: default: HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unsupported MSB padding"); } /* end switch */ /* * Put the destination in the correct byte order. See note at * beginning of loop. */ if (H5T_ORDER_BE == dst->shared->u.atomic.order && reverse) { half_size = dst->shared->size / 2; for (i = 0; i < half_size; i++) { uint8_t tmp = d[dst->shared->size - (i + 1)]; d[dst->shared->size - (i + 1)] = d[i]; d[i] = tmp; } /* end for */ } /* end if */ /* * If we had used a temporary buffer for the destination then we * should copy the value to the true destination buffer. */ if (d == dbuf) H5MM_memcpy(dp, d, dst->shared->size); if (buf_stride) { sp += direction * (ssize_t)buf_stride; /* Note that cast is checked with H5_CHECK_OVERFLOW, above */ dp += direction * (ssize_t)buf_stride; /* Note that cast is checked with H5_CHECK_OVERFLOW, above */ } /* end if */ else { sp += direction * (ssize_t) src->shared->size; /* Note that cast is checked with H5_CHECK_OVERFLOW, above */ dp += direction * (ssize_t) dst->shared->size; /* Note that cast is checked with H5_CHECK_OVERFLOW, above */ } /* end else */ } /* end for */ break; default: HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); } /* end switch */ done: if (src_rev) H5MM_free(src_rev); FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_b_b() */ /*------------------------------------------------------------------------- * Function: H5T__conv_struct_free * * Purpose: Free the private data structure used by the compound * conversion functions. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ static herr_t H5T__conv_struct_free(H5T_conv_struct_t *priv) { int *src2dst = priv->src2dst; H5T_t **src_memb = priv->src_memb; H5T_t **dst_memb = priv->dst_memb; hid_t *src_memb_id = priv->src_memb_id; hid_t *dst_memb_id = priv->dst_memb_id; herr_t ret_value = SUCCEED; FUNC_ENTER_PACKAGE_NOERR for (unsigned i = 0; i < priv->src_nmembs; i++) if (src2dst[i] >= 0) { if (priv->need_ids) { if (H5I_dec_ref(src_memb_id[i]) < 0) ret_value = FAIL; /* set return value, but keep going */ if (H5I_dec_ref(dst_memb_id[src2dst[i]]) < 0) ret_value = FAIL; /* set return value, but keep going */ } else { if (H5T_close(src_memb[i]) < 0) ret_value = FAIL; /* set return value, but keep going */ if (H5T_close(dst_memb[src2dst[i]]) < 0) ret_value = FAIL; /* set return value, but keep going */ } } /* end if */ H5MM_xfree(src2dst); H5MM_xfree(src_memb); H5MM_xfree(dst_memb); H5MM_xfree(src_memb_id); H5MM_xfree(dst_memb_id); H5MM_xfree(priv->memb_path); H5MM_xfree(priv); FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_struct_free() */ /*------------------------------------------------------------------------- * Function: H5T__conv_struct_init * * Purpose: Initialize the `priv' field of `cdata' with conversion * information that is relatively constant. If `priv' is * already initialized then the member conversion functions * are recalculated. * * Priv fields are indexed by source member number or * destination member number depending on whether the field * contains information about the source datatype or the * destination datatype (fields that contains the same * information for both source and destination are indexed by * source member number). The src2dst[] priv array maps source * member numbers to destination member numbers, but if the * source member doesn't have a corresponding destination member * then the src2dst[i]=-1. * * Special optimization case when the source and destination * members are a subset of each other, and the order is the same, * and no conversion is needed. For example: * struct source { struct destination { * TYPE1 A; --> TYPE1 A; * TYPE2 B; --> TYPE2 B; * TYPE3 C; --> TYPE3 C; * }; TYPE4 D; * TYPE5 E; * }; * or * struct destination { struct source { * TYPE1 A; <-- TYPE1 A; * TYPE2 B; <-- TYPE2 B; * TYPE3 C; <-- TYPE3 C; * }; TYPE4 D; * TYPE5 E; * }; * The optimization is simply moving data to the appropriate * places in the buffer. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ static herr_t H5T__conv_struct_init(H5T_t *src, H5T_t *dst, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx) { H5T_conv_struct_t *priv = (H5T_conv_struct_t *)(cdata->priv); int *src2dst = NULL; unsigned src_nmembs, dst_nmembs; unsigned i, j; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE src_nmembs = src->shared->u.compnd.nmembs; dst_nmembs = dst->shared->u.compnd.nmembs; if (!priv) { /* * Allocate private data structure and arrays. */ if (NULL == (priv = (H5T_conv_struct_t *)(cdata->priv = H5MM_calloc(sizeof(H5T_conv_struct_t))))) HGOTO_ERROR(H5E_RESOURCE, H5E_CANTALLOC, FAIL, "couldn't allocate private conversion data"); if (NULL == (priv->src2dst = (int *)H5MM_malloc(src_nmembs * sizeof(int)))) HGOTO_ERROR(H5E_RESOURCE, H5E_CANTALLOC, FAIL, "couldn't allocate source to destination member mapping array"); if (NULL == (priv->src_memb = (H5T_t **)H5MM_malloc(src_nmembs * sizeof(H5T_t *)))) HGOTO_ERROR(H5E_RESOURCE, H5E_CANTALLOC, FAIL, "couldn't allocate source compound member datatype array"); if (NULL == (priv->dst_memb = (H5T_t **)H5MM_malloc(dst_nmembs * sizeof(H5T_t *)))) HGOTO_ERROR(H5E_RESOURCE, H5E_CANTALLOC, FAIL, "couldn't allocate destination compound member datatype array"); priv->need_ids = (cdata->command == H5T_CONV_INIT && conv_ctx->u.init.cb_struct.func) || (cdata->command == H5T_CONV_CONV && conv_ctx->u.conv.cb_struct.func); /* Only create IDs for compound member datatypes if we need to */ if (priv->need_ids) { if (NULL == (priv->src_memb_id = (hid_t *)H5MM_malloc(src_nmembs * sizeof(hid_t)))) HGOTO_ERROR(H5E_RESOURCE, H5E_CANTALLOC, FAIL, "couldn't allocate source compound member datatype ID array"); if (NULL == (priv->dst_memb_id = (hid_t *)H5MM_malloc(dst_nmembs * sizeof(hid_t)))) HGOTO_ERROR(H5E_RESOURCE, H5E_CANTALLOC, FAIL, "couldn't allocate destination compound member datatype ID array"); } src2dst = priv->src2dst; priv->src_nmembs = src_nmembs; /* The flag of special optimization to indicate if source members and destination * members are a subset of each other. Initialize it to false */ priv->subset_info.subset = H5T_SUBSET_FALSE; priv->subset_info.copy_size = 0; /* * Ensure that members are sorted. */ H5T__sort_value(src, NULL); H5T__sort_value(dst, NULL); /* * Build a mapping from source member number to destination member * number. If some source member is not a destination member then that * mapping element will be negative. Also create atoms for each * source and destination member datatype if necessary. */ for (i = 0; i < src_nmembs; i++) { src2dst[i] = -1; for (j = 0; j < dst_nmembs; j++) { if (!strcmp(src->shared->u.compnd.memb[i].name, dst->shared->u.compnd.memb[j].name)) { H5_CHECKED_ASSIGN(src2dst[i], int, j, unsigned); break; } /* end if */ } /* end for */ if (src2dst[i] >= 0) { H5T_t *type; hid_t tid; if (NULL == (type = H5T_copy(src->shared->u.compnd.memb[i].type, H5T_COPY_ALL))) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCOPY, FAIL, "can't copy source compound member datatype"); priv->src_memb[i] = type; if (priv->need_ids) { if ((tid = H5I_register(H5I_DATATYPE, type, false)) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTREGISTER, FAIL, "can't register ID for source compound member datatype"); priv->src_memb_id[i] = tid; } if (NULL == (type = H5T_copy(dst->shared->u.compnd.memb[src2dst[i]].type, H5T_COPY_ALL))) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCOPY, FAIL, "can't copy destination compound member datatype"); priv->dst_memb[src2dst[i]] = type; if (priv->need_ids) { if ((tid = H5I_register(H5I_DATATYPE, type, false)) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTREGISTER, FAIL, "can't register ID for source compound member datatype"); priv->dst_memb_id[src2dst[i]] = tid; } } /* end if */ } /* end for */ } /* end if */ else { /* Restore sorted conditions for the datatypes */ /* (Required for the src2dst array to be valid) */ H5T__sort_value(src, NULL); H5T__sort_value(dst, NULL); } /* end else */ /* * (Re)build the cache of member conversion functions and pointers to * their cdata entries. */ src2dst = priv->src2dst; H5MM_xfree(priv->memb_path); if (NULL == (priv->memb_path = (H5T_path_t **)H5MM_malloc(src->shared->u.compnd.nmembs * sizeof(H5T_path_t *)))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed"); for (i = 0; i < src_nmembs; i++) { if (src2dst[i] >= 0) { H5T_path_t *tpath = H5T_path_find(src->shared->u.compnd.memb[i].type, dst->shared->u.compnd.memb[src2dst[i]].type); if (NULL == (priv->memb_path[i] = tpath)) { H5T__conv_struct_free(priv); cdata->priv = NULL; HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unable to convert member datatype"); } /* end if */ } /* end if */ } /* end for */ /* The compound conversion functions need a background buffer */ cdata->need_bkg = H5T_BKG_YES; if (src_nmembs < dst_nmembs) { priv->subset_info.subset = H5T_SUBSET_SRC; for (i = 0; i < src_nmembs; i++) { /* If any of source members doesn't have counterpart in the same * order or there's conversion between members, don't do the * optimization. */ if (src2dst[i] != (int)i || (src->shared->u.compnd.memb[i].offset != dst->shared->u.compnd.memb[i].offset) || (priv->memb_path[i])->is_noop == false) { priv->subset_info.subset = H5T_SUBSET_FALSE; break; } /* end if */ } /* end for */ /* Compute the size of the data to be copied for each element. It * may be smaller than either src or dst if there is extra space at * the end of src. */ if (priv->subset_info.subset == H5T_SUBSET_SRC) priv->subset_info.copy_size = src->shared->u.compnd.memb[src_nmembs - 1].offset + src->shared->u.compnd.memb[src_nmembs - 1].size; } else if (dst_nmembs < src_nmembs) { priv->subset_info.subset = H5T_SUBSET_DST; for (i = 0; i < dst_nmembs; i++) { /* If any of source members doesn't have counterpart in the same order or * there's conversion between members, don't do the optimization. */ if (src2dst[i] != (int)i || (src->shared->u.compnd.memb[i].offset != dst->shared->u.compnd.memb[i].offset) || (priv->memb_path[i])->is_noop == false) { priv->subset_info.subset = H5T_SUBSET_FALSE; break; } } /* end for */ /* Compute the size of the data to be copied for each element. It * may be smaller than either src or dst if there is extra space at * the end of dst. */ if (priv->subset_info.subset == H5T_SUBSET_DST) priv->subset_info.copy_size = dst->shared->u.compnd.memb[dst_nmembs - 1].offset + dst->shared->u.compnd.memb[dst_nmembs - 1].size; } else /* If the numbers of source and dest members are equal and no conversion is needed, * the case should have been handled as noop earlier in H5Dio.c. */ { } cdata->recalc = false; done: FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_struct_init() */ /*------------------------------------------------------------------------- * Function: H5T__conv_struct_subset * * Purpose: A quick way to return a field in a struct private in this * file. The flag SMEMBS_SUBSET indicates whether the source * members are a subset of destination or the destination * members are a subset of the source, and the order is the * same, and no conversion is needed. For example: * struct source { struct destination { * TYPE1 A; --> TYPE1 A; * TYPE2 B; --> TYPE2 B; * TYPE3 C; --> TYPE3 C; * }; TYPE4 D; * TYPE5 E; * }; * * Return: A pointer to the subset info struct in p. Points directly * into the structure. * *------------------------------------------------------------------------- */ H5T_subset_info_t * H5T__conv_struct_subset(const H5T_cdata_t *cdata) { H5T_conv_struct_t *priv = NULL; FUNC_ENTER_PACKAGE_NOERR assert(cdata); assert(cdata->priv); priv = (H5T_conv_struct_t *)(cdata->priv); FUNC_LEAVE_NOAPI((H5T_subset_info_t *)&priv->subset_info) } /* end H5T__conv_struct_subset() */ /*------------------------------------------------------------------------- * Function: H5T__conv_struct * * Purpose: Converts between compound datatypes. This is a soft * conversion function. The algorithm is basically: * * For each element do * For I=1..NELMTS do * If sizeof destination type <= sizeof source type then * Convert member to destination type; * Move member as far left as possible; * * For I=NELMTS..1 do * If not destination type then * Convert member to destination type; * Move member to correct position in BKG * * Copy BKG to BUF * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_struct(H5T_t *src, H5T_t *dst, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t bkg_stride, void *_buf, void *_bkg) { uint8_t *buf = (uint8_t *)_buf; /*cast for pointer arithmetic */ uint8_t *bkg = (uint8_t *)_bkg; /*background pointer arithmetic */ uint8_t *xbuf = buf, *xbkg = bkg; /*temp pointers into buf and bkg*/ int *src2dst = NULL; /*maps src member to dst member */ H5T_cmemb_t *src_memb = NULL; /*source struct member descript.*/ H5T_cmemb_t *dst_memb = NULL; /*destination struct memb desc. */ size_t offset; /*byte offset wrt struct */ ssize_t src_delta; /*source stride */ ssize_t bkg_delta; /*background stride */ size_t elmtno; unsigned u; /*counters */ H5T_conv_struct_t *priv = (H5T_conv_struct_t *)(cdata->priv); H5T_conv_ctx_t tmp_conv_ctx = {0}; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE switch (cdata->command) { case H5T_CONV_INIT: /* * First, determine if this conversion function applies to the * conversion path SRC-->DST. If not, return failure; * otherwise initialize the `priv' field of `cdata' with information * that remains (almost) constant for this conversion path. */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a datatype"); if (H5T_COMPOUND != src->shared->type) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a H5T_COMPOUND datatype"); if (H5T_COMPOUND != dst->shared->type) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a H5T_COMPOUND datatype"); if (H5T__conv_struct_init(src, dst, cdata, conv_ctx) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTINIT, FAIL, "unable to initialize conversion data"); break; case H5T_CONV_FREE: { /* * Free the private conversion data. */ herr_t status = H5T__conv_struct_free(priv); cdata->priv = NULL; if (status < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTFREE, FAIL, "unable to free private conversion data"); break; } case H5T_CONV_CONV: /* * Conversion. */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a datatype"); if (NULL == conv_ctx) HGOTO_ERROR(H5E_DATATYPE, H5E_BADVALUE, FAIL, "invalid datatype conversion context pointer"); assert(priv); assert(bkg && cdata->need_bkg); /* Initialize temporary conversion context */ tmp_conv_ctx = *conv_ctx; if (cdata->recalc && H5T__conv_struct_init(src, dst, cdata, conv_ctx) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTINIT, FAIL, "unable to initialize conversion data"); /* * Insure that members are sorted. */ H5T__sort_value(src, NULL); H5T__sort_value(dst, NULL); src2dst = priv->src2dst; /* * Direction of conversion and striding through background. */ if (buf_stride) { H5_CHECKED_ASSIGN(src_delta, ssize_t, buf_stride, size_t); if (!bkg_stride) { H5_CHECKED_ASSIGN(bkg_delta, ssize_t, dst->shared->size, size_t); } /* end if */ else H5_CHECKED_ASSIGN(bkg_delta, ssize_t, bkg_stride, size_t); } /* end if */ else if (dst->shared->size <= src->shared->size) { H5_CHECKED_ASSIGN(src_delta, ssize_t, src->shared->size, size_t); H5_CHECKED_ASSIGN(bkg_delta, ssize_t, dst->shared->size, size_t); } /* end else-if */ else { H5_CHECK_OVERFLOW(src->shared->size, size_t, ssize_t); src_delta = -(ssize_t)src->shared->size; H5_CHECK_OVERFLOW(dst->shared->size, size_t, ssize_t); bkg_delta = -(ssize_t)dst->shared->size; xbuf += (nelmts - 1) * src->shared->size; xbkg += (nelmts - 1) * dst->shared->size; } /* end else */ /* Conversion loop... */ for (elmtno = 0; elmtno < nelmts; elmtno++) { /* * For each source member which will be present in the * destination, convert the member to the destination type unless * it is larger than the source type. Then move the member to the * left-most unoccupied position in the buffer. This makes the * data point as small as possible with all the free space on the * right side. */ for (u = 0, offset = 0; u < src->shared->u.compnd.nmembs; u++) { if (src2dst[u] < 0) continue; /*subsetting*/ src_memb = src->shared->u.compnd.memb + u; dst_memb = dst->shared->u.compnd.memb + src2dst[u]; if (dst_memb->size <= src_memb->size) { if (priv->need_ids) { /* Update IDs in conversion context */ tmp_conv_ctx.u.conv.src_type_id = priv->src_memb_id[u]; tmp_conv_ctx.u.conv.dst_type_id = priv->dst_memb_id[src2dst[u]]; } if (H5T_convert_with_ctx(priv->memb_path[u], priv->src_memb[u], priv->dst_memb[src2dst[u]], &tmp_conv_ctx, (size_t)1, (size_t)0, (size_t)0, /*no striding (packed array)*/ xbuf + src_memb->offset, xbkg + dst_memb->offset) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "unable to convert compound datatype member"); memmove(xbuf + offset, xbuf + src_memb->offset, dst_memb->size); offset += dst_memb->size; } /* end if */ else { memmove(xbuf + offset, xbuf + src_memb->offset, src_memb->size); offset += src_memb->size; } /* end else */ } /* end for */ /* * For each source member which will be present in the * destination, convert the member to the destination type if it * is larger than the source type (that is, has not been converted * yet). Then copy the member to the destination offset in the * background buffer. */ H5_CHECK_OVERFLOW(src->shared->u.compnd.nmembs, size_t, int); for (int i = (int)src->shared->u.compnd.nmembs - 1; i >= 0; --i) { if (src2dst[i] < 0) continue; /*subsetting*/ src_memb = src->shared->u.compnd.memb + i; dst_memb = dst->shared->u.compnd.memb + src2dst[i]; if (dst_memb->size > src_memb->size) { if (priv->need_ids) { /* Update IDs in conversion context */ tmp_conv_ctx.u.conv.src_type_id = priv->src_memb_id[i]; tmp_conv_ctx.u.conv.dst_type_id = priv->dst_memb_id[src2dst[i]]; } offset -= src_memb->size; if (H5T_convert_with_ctx(priv->memb_path[i], priv->src_memb[i], priv->dst_memb[src2dst[i]], &tmp_conv_ctx, (size_t)1, (size_t)0, (size_t)0, /*no striding (packed array)*/ xbuf + offset, xbkg + dst_memb->offset) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "unable to convert compound datatype member"); } /* end if */ else offset -= dst_memb->size; memmove(xbkg + dst_memb->offset, xbuf + offset, dst_memb->size); } /* end for */ assert(0 == offset); /* * Update pointers */ xbuf += src_delta; xbkg += bkg_delta; } /* end for */ /* If the bkg_delta was set to -(dst->shared->size), make it positive now */ if (buf_stride == 0 && dst->shared->size > src->shared->size) H5_CHECKED_ASSIGN(bkg_delta, ssize_t, dst->shared->size, size_t); /* * Copy the background buffer back into the in-place conversion * buffer. */ for (xbuf = buf, xbkg = bkg, elmtno = 0; elmtno < nelmts; elmtno++) { memmove(xbuf, xbkg, dst->shared->size); xbuf += buf_stride ? buf_stride : dst->shared->size; xbkg += bkg_delta; } /* end for */ break; default: /* Some other command we don't know about yet.*/ HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); } /* end switch */ done: FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_struct() */ /*------------------------------------------------------------------------- * Function: H5T__conv_struct_opt * * Purpose: Converts between compound datatypes in a manner more * efficient than the general-purpose H5T__conv_struct() * function. This function isn't applicable if the destination * is larger than the source type. This is a soft conversion * function. The algorithm is basically: * * For each member of the struct * If sizeof destination type <= sizeof source type then * Convert member to destination type for all elements * Move memb to BKG buffer for all elements * Else * Move member as far left as possible for all elements * * For each member of the struct (in reverse order) * If not destination type then * Convert member to destination type for all elements * Move member to correct position in BKG for all elements * * Copy BKG to BUF for all elements * * Special case when the source and destination members * are a subset of each other, and the order is the same, and no * conversion is needed. For example: * struct source { struct destination { * TYPE1 A; --> TYPE1 A; * TYPE2 B; --> TYPE2 B; * TYPE3 C; --> TYPE3 C; * }; TYPE4 D; * TYPE5 E; * }; * The optimization is simply moving data to the appropriate * places in the buffer. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_struct_opt(H5T_t *src, H5T_t *dst, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t bkg_stride, void *_buf, void *_bkg) { uint8_t *buf = (uint8_t *)_buf; /*cast for pointer arithmetic */ uint8_t *bkg = (uint8_t *)_bkg; /*background pointer arithmetic */ uint8_t *xbuf = NULL; /*temporary pointer into `buf' */ uint8_t *xbkg = NULL; /*temporary pointer into `bkg' */ int *src2dst = NULL; /*maps src member to dst member */ H5T_cmemb_t *src_memb = NULL; /*source struct member descript.*/ H5T_cmemb_t *dst_memb = NULL; /*destination struct memb desc. */ size_t offset; /*byte offset wrt struct */ size_t elmtno; /*element counter */ size_t copy_size; /*size of element for copying */ H5T_conv_struct_t *priv = NULL; /*private data */ H5T_conv_ctx_t tmp_conv_ctx = {0}; /*temporary conversion context */ bool no_stride = false; /*flag to indicate no stride */ unsigned u; /*counters */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE switch (cdata->command) { case H5T_CONV_INIT: /* * First, determine if this conversion function applies to the * conversion path SRC-->DST. If not, return failure; * otherwise initialize the `priv' field of `cdata' with information * that remains (almost) constant for this conversion path. */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); if (H5T_COMPOUND != src->shared->type) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a H5T_COMPOUND datatype"); if (H5T_COMPOUND != dst->shared->type) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a H5T_COMPOUND datatype"); /* Initialize data which is relatively constant */ if (H5T__conv_struct_init(src, dst, cdata, conv_ctx) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTINIT, FAIL, "unable to initialize conversion data"); priv = (H5T_conv_struct_t *)(cdata->priv); src2dst = priv->src2dst; /* * If the destination type is not larger than the source type then * this conversion function is guaranteed to work (provided all * members can be converted also). Otherwise the determination is * quite a bit more complicated. Essentially we have to make sure * that there is always room in the source buffer to do the * conversion of a member in place. This is basically the same pair * of loops as in the actual conversion except it checks that there * is room for each conversion instead of actually doing anything. */ if (dst->shared->size > src->shared->size) { for (u = 0, offset = 0; u < src->shared->u.compnd.nmembs; u++) { if (src2dst[u] < 0) continue; src_memb = src->shared->u.compnd.memb + u; dst_memb = dst->shared->u.compnd.memb + src2dst[u]; if (dst_memb->size > src_memb->size) offset += src_memb->size; } /* end for */ H5_CHECK_OVERFLOW(src->shared->u.compnd.nmembs, size_t, int); for (int i = (int)src->shared->u.compnd.nmembs - 1; i >= 0; --i) { if (src2dst[i] < 0) continue; src_memb = src->shared->u.compnd.memb + i; dst_memb = dst->shared->u.compnd.memb + src2dst[i]; if (dst_memb->size > src_memb->size) { offset -= src_memb->size; if (dst_memb->size > src->shared->size - offset) { H5T__conv_struct_free(priv); cdata->priv = NULL; HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "conversion is unsupported by this function"); } /* end if */ } /* end if */ } /* end for */ } /* end if */ break; case H5T_CONV_FREE: { /* * Free the private conversion data. */ herr_t status = H5T__conv_struct_free((H5T_conv_struct_t *)(cdata->priv)); cdata->priv = NULL; if (status < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTFREE, FAIL, "unable to free private conversion data"); break; } case H5T_CONV_CONV: /* * Conversion. */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); if (NULL == conv_ctx) HGOTO_ERROR(H5E_DATATYPE, H5E_BADVALUE, FAIL, "invalid datatype conversion context pointer"); /* Initialize temporary conversion context */ tmp_conv_ctx = *conv_ctx; /* Update cached data if necessary */ if (cdata->recalc && H5T__conv_struct_init(src, dst, cdata, conv_ctx) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTINIT, FAIL, "unable to initialize conversion data"); priv = (H5T_conv_struct_t *)(cdata->priv); assert(priv); src2dst = priv->src2dst; assert(bkg && cdata->need_bkg); /* * Insure that members are sorted. */ H5T__sort_value(src, NULL); H5T__sort_value(dst, NULL); /* * Calculate strides. If BUF_STRIDE is non-zero then convert one * data element at every BUF_STRIDE bytes through the main buffer * (BUF), leaving the result of each conversion at the same * location; otherwise assume the source and destination data are * packed tightly based on src->shared->size and dst->shared->size. Also, if * BUF_STRIDE and BKG_STRIDE are both non-zero then place * background data into the BKG buffer at multiples of BKG_STRIDE; * otherwise assume BKG buffer is the packed destination datatype. */ if (!buf_stride || !bkg_stride) bkg_stride = dst->shared->size; if (!buf_stride) { no_stride = true; buf_stride = src->shared->size; } /* end if */ if (priv->subset_info.subset == H5T_SUBSET_SRC || priv->subset_info.subset == H5T_SUBSET_DST) { /* If the optimization flag is set to indicate source members are a subset and * in the top of the destination, simply copy the source members to background buffer. */ xbuf = buf; xbkg = bkg; copy_size = priv->subset_info.copy_size; for (elmtno = 0; elmtno < nelmts; elmtno++) { memmove(xbkg, xbuf, copy_size); /* Update pointers */ xbuf += buf_stride; xbkg += bkg_stride; } /* end for */ } /* end if */ else { /* * For each member where the destination is not larger than the * source, stride through all the elements converting only that member * in each element and then copying the element to its final * destination in the bkg buffer. Otherwise move the element as far * left as possible in the buffer. */ for (u = 0, offset = 0; u < src->shared->u.compnd.nmembs; u++) { if (src2dst[u] < 0) continue; /*subsetting*/ src_memb = src->shared->u.compnd.memb + u; dst_memb = dst->shared->u.compnd.memb + src2dst[u]; if (dst_memb->size <= src_memb->size) { if (priv->need_ids) { /* Update IDs in conversion context */ tmp_conv_ctx.u.conv.src_type_id = priv->src_memb_id[u]; tmp_conv_ctx.u.conv.dst_type_id = priv->dst_memb_id[src2dst[u]]; } xbuf = buf + src_memb->offset; xbkg = bkg + dst_memb->offset; if (H5T_convert_with_ctx(priv->memb_path[u], priv->src_memb[u], priv->dst_memb[src2dst[u]], &tmp_conv_ctx, nelmts, buf_stride, bkg_stride, xbuf, xbkg) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "unable to convert compound datatype member"); for (elmtno = 0; elmtno < nelmts; elmtno++) { memmove(xbkg, xbuf, dst_memb->size); xbuf += buf_stride; xbkg += bkg_stride; } /* end for */ } /* end if */ else { for (xbuf = buf, elmtno = 0; elmtno < nelmts; elmtno++) { memmove(xbuf + offset, xbuf + src_memb->offset, src_memb->size); xbuf += buf_stride; } /* end for */ offset += src_memb->size; } /* end else */ } /* end else */ /* * Work from right to left, converting those members that weren't * converted in the previous loop (those members where the destination * is larger than the source) and them to their final position in the * bkg buffer. */ H5_CHECK_OVERFLOW(src->shared->u.compnd.nmembs, size_t, int); for (int i = (int)src->shared->u.compnd.nmembs - 1; i >= 0; --i) { if (src2dst[i] < 0) continue; src_memb = src->shared->u.compnd.memb + i; dst_memb = dst->shared->u.compnd.memb + src2dst[i]; if (dst_memb->size > src_memb->size) { if (priv->need_ids) { /* Update IDs in conversion context */ tmp_conv_ctx.u.conv.src_type_id = priv->src_memb_id[i]; tmp_conv_ctx.u.conv.dst_type_id = priv->dst_memb_id[src2dst[i]]; } offset -= src_memb->size; xbuf = buf + offset; xbkg = bkg + dst_memb->offset; if (H5T_convert_with_ctx(priv->memb_path[i], priv->src_memb[i], priv->dst_memb[src2dst[i]], &tmp_conv_ctx, nelmts, buf_stride, bkg_stride, xbuf, xbkg) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "unable to convert compound datatype member"); for (elmtno = 0; elmtno < nelmts; elmtno++) { memmove(xbkg, xbuf, dst_memb->size); xbuf += buf_stride; xbkg += bkg_stride; } /* end for */ } /* end if */ } /* end for */ } /* end else */ if (no_stride) buf_stride = dst->shared->size; /* Move background buffer into result buffer */ for (xbuf = buf, xbkg = bkg, elmtno = 0; elmtno < nelmts; elmtno++) { memmove(xbuf, xbkg, dst->shared->size); xbuf += buf_stride; xbkg += bkg_stride; } /* end for */ break; default: /* Some other command we don't know about yet.*/ HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); } /* end switch */ done: FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_struct_opt() */ /*------------------------------------------------------------------------- * Function: H5T__conv_enum_init * * Purpose: Initialize information for H5T__conv_enum(). * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ static herr_t H5T__conv_enum_init(H5T_t *src, H5T_t *dst, H5T_cdata_t *cdata) { H5T_enum_struct_t *priv = NULL; /*private conversion data */ int n; /*src value cast as native int */ int domain[2] = {0, 0}; /*min and max source values */ int *map = NULL; /*map from src value to dst idx */ unsigned length; /*nelmts in map array */ unsigned i, j; /*counters */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE cdata->need_bkg = H5T_BKG_NO; if (NULL == (priv = (H5T_enum_struct_t *)(cdata->priv = H5MM_calloc(sizeof(*priv))))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed"); if (0 == src->shared->u.enumer.nmembs) HGOTO_DONE(SUCCEED); /* * Check that the source symbol names are a subset of the destination * symbol names and build a map from source member index to destination * member index. */ H5T__sort_name(src, NULL); H5T__sort_name(dst, NULL); if (NULL == (priv->src2dst = (int *)H5MM_malloc(src->shared->u.enumer.nmembs * sizeof(int)))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed"); for (i = 0, j = 0; i < src->shared->u.enumer.nmembs && j < dst->shared->u.enumer.nmembs; i++, j++) { while (j < dst->shared->u.enumer.nmembs && strcmp(src->shared->u.enumer.name[i], dst->shared->u.enumer.name[j]) != 0) j++; if (j >= dst->shared->u.enumer.nmembs) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "source type is not a subset of destination type"); priv->src2dst[i] = (int)j; } /* end for */ /* * The conversion function will use an O(log N) lookup method for each * value converted. However, if all of the following constraints are met * then we can build a perfect hash table and use an O(1) lookup method. * * A: The source datatype size matches one of our native datatype * sizes. * * B: After casting the source value bit pattern to a native type * the size of the range of values is less than 20% larger than * the number of values. * * If this special case is met then we use the source bit pattern cast as * a native integer type as an index into the `val2dst'. The values of * that array are the index numbers in the destination type or negative * if the entry is unused. * * (This optimized algorithm doesn't work when the byte orders are different. * The code such as "n = *((int*)(src->shared->u.enumer.value+i*src->shared->size));" * can change the value significantly. i.g. if the source value is big-endian 0x0000000f, * executing the casting on little-endian machine will get a big number 0x0f000000. * Then it can't meet the condition * "if(src->shared->u.enumer.nmembs<2 || (double)length/src->shared->u.enumer.nmembs<1.2)" * Because this is the optimized code, we won't fix it. It should still work in some * situations. SLU - 2011/5/24) */ if (1 == src->shared->size || sizeof(short) == src->shared->size || sizeof(int) == src->shared->size) { for (i = 0; i < src->shared->u.enumer.nmembs; i++) { if (1 == src->shared->size) n = *((signed char *)((uint8_t *)src->shared->u.enumer.value + i)); else if (sizeof(short) == src->shared->size) n = *((short *)((void *)((uint8_t *)src->shared->u.enumer.value + (i * src->shared->size)))); else n = *((int *)((void *)((uint8_t *)src->shared->u.enumer.value + (i * src->shared->size)))); if (0 == i) { domain[0] = domain[1] = n; } else { domain[0] = MIN(domain[0], n); domain[1] = MAX(domain[1], n); } } /* end for */ assert(domain[1] >= domain[0]); length = (unsigned)(domain[1] - domain[0]) + 1; if (src->shared->u.enumer.nmembs < 2 || (double)length / src->shared->u.enumer.nmembs < (double)(1.2F)) { priv->base = domain[0]; priv->length = length; if (NULL == (map = (int *)H5MM_malloc(length * sizeof(int)))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed"); for (i = 0; i < length; i++) map[i] = -1; /*entry unused*/ for (i = 0; i < src->shared->u.enumer.nmembs; i++) { if (1 == src->shared->size) n = *((signed char *)((uint8_t *)src->shared->u.enumer.value + i)); else if (sizeof(short) == src->shared->size) n = *(( short *)((void *)((uint8_t *)src->shared->u.enumer.value + (i * src->shared->size)))); else n = *( (int *)((void *)((uint8_t *)src->shared->u.enumer.value + (i * src->shared->size)))); n -= priv->base; assert(n >= 0 && (unsigned)n < priv->length); assert(map[n] < 0); map[n] = priv->src2dst[i]; } /* end for */ /* * Replace original src2dst array with our new one. The original * was indexed by source member number while the new one is * indexed by source values. */ H5MM_xfree(priv->src2dst); priv->src2dst = map; HGOTO_DONE(SUCCEED); } } /* Sort source type by value and adjust src2dst[] appropriately */ H5T__sort_value(src, priv->src2dst); done: if (ret_value < 0 && priv) { H5MM_xfree(priv->src2dst); H5MM_xfree(priv); cdata->priv = NULL; } FUNC_LEAVE_NOAPI(ret_value) } /*------------------------------------------------------------------------- * Function: H5T__conv_enum * * Purpose: Converts one type of enumerated data to another. * * Return: Success: Non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_enum(H5T_t *src, H5T_t *dst, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *_buf, void H5_ATTR_UNUSED *bkg) { uint8_t *buf = (uint8_t *)_buf; /*cast for pointer arithmetic */ uint8_t *s = NULL, *d = NULL; /*src and dst BUF pointers */ ssize_t src_delta, dst_delta; /*conversion strides */ int n; /*src value cast as native int */ H5T_enum_struct_t *priv = (H5T_enum_struct_t *)(cdata->priv); H5T_conv_ret_t except_ret; /*return of callback function */ size_t i; /*counters */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE switch (cdata->command) { case H5T_CONV_INIT: /* * Determine if this conversion function applies to the conversion * path SRC->DST. If not return failure; otherwise initialize * the `priv' field of `cdata' with information about the underlying * integer conversion. */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a datatype"); if (H5T_ENUM != src->shared->type) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a H5T_ENUM datatype"); if (H5T_ENUM != dst->shared->type) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a H5T_ENUM datatype"); if (H5T__conv_enum_init(src, dst, cdata) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTINIT, FAIL, "unable to initialize private data"); break; case H5T_CONV_FREE: #ifdef H5T_DEBUG if (H5DEBUG(T)) { fprintf(H5DEBUG(T), " Using %s mapping function%s\n", priv->length ? "O(1)" : "O(log N)", priv->length ? "" : ", where N is the number of enum members"); } #endif if (priv) { H5MM_xfree(priv->src2dst); H5MM_xfree(priv); } cdata->priv = NULL; break; case H5T_CONV_CONV: if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); if (NULL == conv_ctx) HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "invalid datatype conversion context pointer"); if (H5T_ENUM != src->shared->type) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a H5T_ENUM datatype"); if (H5T_ENUM != dst->shared->type) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a H5T_ENUM datatype"); /* priv->src2dst map was computed for certain sort keys. Make sure those same * sort keys are used here during conversion. See H5T__conv_enum_init(). But * we actually don't care about the source type's order when doing the O(1) * conversion algorithm, which is turned on by non-zero priv->length */ H5T__sort_name(dst, NULL); if (!priv->length) H5T__sort_value(src, NULL); /* * Direction of conversion. */ if (buf_stride) { H5_CHECK_OVERFLOW(buf_stride, size_t, ssize_t); src_delta = dst_delta = (ssize_t)buf_stride; s = d = buf; } else if (dst->shared->size <= src->shared->size) { H5_CHECKED_ASSIGN(src_delta, ssize_t, src->shared->size, size_t); H5_CHECKED_ASSIGN(dst_delta, ssize_t, dst->shared->size, size_t); s = d = buf; } else { H5_CHECK_OVERFLOW(src->shared->size, size_t, ssize_t); H5_CHECK_OVERFLOW(dst->shared->size, size_t, ssize_t); src_delta = -(ssize_t)src->shared->size; dst_delta = -(ssize_t)dst->shared->size; s = buf + (nelmts - 1) * src->shared->size; d = buf + (nelmts - 1) * dst->shared->size; } for (i = 0; i < nelmts; i++, s += src_delta, d += dst_delta) { if (priv->length) { /* Use O(1) lookup */ /* (The casting won't work when the byte orders are different. i.g. if the source value * is big-endian 0x0000000f, the direct casting "n = *((int*)s);" will make it a big * number 0x0f000000 on little-endian machine. But we won't fix it because it's an * optimization code. Please also see the comment in the H5T__conv_enum_init() function. * SLU - 2011/5/24) */ if (1 == src->shared->size) n = *((signed char *)s); else if (sizeof(short) == src->shared->size) n = *((short *)((void *)s)); else n = *((int *)((void *)s)); n -= priv->base; if (n < 0 || (unsigned)n >= priv->length || priv->src2dst[n] < 0) { /*overflow*/ except_ret = H5T_CONV_UNHANDLED; /*If user's exception handler is present, use it*/ if (conv_ctx->u.conv.cb_struct.func) except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, s, d, conv_ctx->u.conv.cb_struct.user_data); if (except_ret == H5T_CONV_UNHANDLED) memset(d, 0xff, dst->shared->size); else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); } else H5MM_memcpy(d, (uint8_t *)dst->shared->u.enumer.value + ((unsigned)priv->src2dst[n] * dst->shared->size), dst->shared->size); } /* end if */ else { /* Use O(log N) lookup */ unsigned lt = 0; unsigned rt = src->shared->u.enumer.nmembs; unsigned md = 0; int cmp; while (lt < rt) { md = (lt + rt) / 2; cmp = memcmp(s, (uint8_t *)src->shared->u.enumer.value + (md * src->shared->size), src->shared->size); if (cmp < 0) rt = md; else if (cmp > 0) lt = md + 1; else break; } /* end while */ if (lt >= rt) { except_ret = H5T_CONV_UNHANDLED; /*If user's exception handler is present, use it*/ if (conv_ctx->u.conv.cb_struct.func) except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, s, d, conv_ctx->u.conv.cb_struct.user_data); if (except_ret == H5T_CONV_UNHANDLED) memset(d, 0xff, dst->shared->size); else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); } /* end if */ else { assert(priv->src2dst[md] >= 0); H5MM_memcpy(d, (uint8_t *)dst->shared->u.enumer.value + ((unsigned)priv->src2dst[md] * dst->shared->size), dst->shared->size); } /* end else */ } /* end else */ } break; default: /* Some other command we don't know about yet.*/ HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); } /* end switch */ done: FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_enum() */ /*------------------------------------------------------------------------- * Function: H5T__conv_enum_numeric * * Purpose: Converts enumerated data to a numeric type (integer or * floating-point number). This function is registered into * the conversion table twice in H5T_init_interface in H5T.c. * Once for enum-integer conversion. Once for enum-float conversion. * * Return: Success: Non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_enum_numeric(H5T_t *src, H5T_t *dst, H5T_cdata_t *cdata, const H5T_conv_ctx_t H5_ATTR_UNUSED *conv_ctx, size_t nelmts, size_t H5_ATTR_UNUSED buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *_buf, void H5_ATTR_UNUSED *bkg) { H5T_t *src_parent; /*parent type for src */ H5T_t *tmp_type = NULL; /*temporary datatype for parent type */ H5T_path_t *tpath; /* Conversion information */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE switch (cdata->command) { case H5T_CONV_INIT: /* * Determine if this conversion function applies to the conversion * path SRC->DST. If not, return failure. */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a datatype"); if (H5T_ENUM != src->shared->type) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "source type is not a H5T_ENUM datatype"); if (H5T_INTEGER != dst->shared->type && H5T_FLOAT != dst->shared->type) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "destination is not an integer type"); cdata->need_bkg = H5T_BKG_NO; break; case H5T_CONV_FREE: break; case H5T_CONV_CONV: if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); src_parent = src->shared->parent; if (NULL == (tpath = H5T_path_find(src_parent, dst))) { HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unable to convert between src and dest datatype"); } else if (!H5T_path_noop(tpath)) { if (NULL == (tmp_type = H5T_copy(src_parent, H5T_COPY_ALL))) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCOPY, FAIL, "can't copy parent datatype"); /* Convert the data */ if (H5T_convert(tpath, tmp_type, dst, nelmts, buf_stride, bkg_stride, _buf, bkg) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTINIT, FAIL, "datatype conversion failed"); } break; default: /* Some other command we don't know about yet.*/ HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); } /* end switch */ done: /* Release the temporary datatype used */ if (tmp_type && (H5T_close(tmp_type) < 0)) HDONE_ERROR(H5E_DATATYPE, H5E_CANTCLOSEOBJ, FAIL, "can't close temporary datatype"); FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_enum_numeric() */ /*------------------------------------------------------------------------- * Function: H5T__conv_vlen_nested_free * * Purpose: Recursively locates and frees any nested VLEN components of * complex data types (including COMPOUND). * * Return: Non-negative on success/Negative on failure. * *------------------------------------------------------------------------- */ static herr_t H5T__conv_vlen_nested_free(uint8_t *buf, H5T_t *dt) { herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE switch (dt->shared->type) { case H5T_VLEN: /* Pointer buf refers to VLEN data; free it (always reset tmp) */ if ((*(dt->shared->u.vlen.cls->del))(dt->shared->u.vlen.file, buf) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTFREE, FAIL, "can't free nested vlen"); break; case H5T_COMPOUND: /* Pointer buf refers to COMPOUND data; recurse for each member. */ for (unsigned i = 0; i < dt->shared->u.compnd.nmembs; ++i) if (H5T__conv_vlen_nested_free(buf + dt->shared->u.compnd.memb[i].offset, dt->shared->u.compnd.memb[i].type) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTFREE, FAIL, "can't free compound member"); break; case H5T_ARRAY: /* Pointer buf refers to ARRAY data; recurse for each element. */ for (unsigned i = 0; i < dt->shared->u.array.nelem; ++i) if (H5T__conv_vlen_nested_free(buf + i * dt->shared->parent->shared->size, dt->shared->parent) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTFREE, FAIL, "can't free array data"); break; case H5T_INTEGER: case H5T_FLOAT: case H5T_TIME: case H5T_STRING: case H5T_BITFIELD: case H5T_OPAQUE: case H5T_REFERENCE: case H5T_ENUM: /* These types cannot contain vl data */ break; case H5T_NO_CLASS: case H5T_NCLASSES: default: HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "invalid datatype class"); } done: FUNC_LEAVE_NOAPI(ret_value) } /* H5T__conv_vlen_nested_free() */ /*------------------------------------------------------------------------- * Function: H5T__conv_vlen * * Purpose: Converts between VL datatypes in memory and on disk. * This is a soft conversion function. The algorithm is * basically: * * For every VL struct in the main buffer: * 1. Allocate space for temporary dst VL data (reuse buffer * if possible) * 2. Copy VL data from src buffer into dst buffer * 3. Convert VL data into dst representation * 4. Allocate buffer in dst heap * 5. Free heap objects storing old data * 6. Write dst VL data into dst heap * 7. Store (heap ID or pointer) and length in main dst buffer * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_vlen(H5T_t *src, H5T_t *dst, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t bkg_stride, void *buf, void *bkg) { H5T_vlen_alloc_info_t vl_alloc_info; /* VL allocation info */ H5T_conv_ctx_t tmp_conv_ctx = {0}; /* Temporary conversion context */ H5T_path_t *tpath = NULL; /* Type conversion path */ bool noop_conv = false; /* Flag to indicate a noop conversion */ bool write_to_file = false; /* Flag to indicate writing to file */ htri_t parent_is_vlen; /* Flag to indicate parent is vlen datatype */ size_t bg_seq_len = 0; /* The number of elements in the background sequence */ H5T_t *tsrc_cpy = NULL; /*temporary copy of source base datatype */ H5T_t *tdst_cpy = NULL; /*temporary copy of destination base datatype */ hid_t tsrc_id = H5I_INVALID_HID; /*temporary type atom */ hid_t tdst_id = H5I_INVALID_HID; /*temporary type atom */ uint8_t *s = NULL; /*source buffer */ uint8_t *d = NULL; /*destination buffer */ uint8_t *b = NULL; /*background buffer */ ssize_t s_stride, d_stride; /*src and dst strides */ ssize_t b_stride; /*bkg stride */ size_t safe; /*how many elements are safe to process in each pass */ size_t src_base_size; /*source base size*/ size_t dst_base_size; /*destination base size*/ void *conv_buf = NULL; /*temporary conversion buffer */ size_t conv_buf_size = 0; /*size of conversion buffer in bytes */ void *tmp_buf = NULL; /*temporary background buffer */ size_t tmp_buf_size = 0; /*size of temporary bkg buffer */ bool nested = false; /*flag of nested VL case */ bool need_ids = false; /*whether we need IDs for the datatypes */ size_t elmtno; /*element number counter */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE switch (cdata->command) { case H5T_CONV_INIT: /* * First, determine if this conversion function applies to the * conversion path SRC_ID-->DST_ID. If not, return failure; * otherwise initialize the `priv' field of `cdata' with * information that remains (almost) constant for this * conversion path. */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a datatype"); if (H5T_VLEN != src->shared->type) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a H5T_VLEN datatype"); if (H5T_VLEN != dst->shared->type) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a H5T_VLEN datatype"); if (H5T_VLEN_STRING == src->shared->u.vlen.type && H5T_VLEN_STRING == dst->shared->u.vlen.type) { if ((H5T_CSET_ASCII == src->shared->u.vlen.cset && H5T_CSET_UTF8 == dst->shared->u.vlen.cset) || (H5T_CSET_ASCII == dst->shared->u.vlen.cset && H5T_CSET_UTF8 == src->shared->u.vlen.cset)) HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "The library doesn't convert between strings of ASCII and UTF"); } /* end if */ /* Variable-length types don't need a background buffer */ cdata->need_bkg = H5T_BKG_NO; break; case H5T_CONV_FREE: /* QAK - Nothing to do currently */ break; case H5T_CONV_CONV: /* * Conversion. */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); if (NULL == conv_ctx) HGOTO_ERROR(H5E_DATATYPE, H5E_BADVALUE, FAIL, "invalid datatype conversion context pointer"); /* Initialize temporary conversion context */ tmp_conv_ctx = *conv_ctx; need_ids = (conv_ctx->u.conv.cb_struct.func != NULL); /* Initialize source & destination strides */ if (buf_stride) { assert(buf_stride >= src->shared->size); assert(buf_stride >= dst->shared->size); H5_CHECK_OVERFLOW(buf_stride, size_t, ssize_t); s_stride = d_stride = (ssize_t)buf_stride; } /* end if */ else { H5_CHECK_OVERFLOW(src->shared->size, size_t, ssize_t); H5_CHECK_OVERFLOW(dst->shared->size, size_t, ssize_t); s_stride = (ssize_t)src->shared->size; d_stride = (ssize_t)dst->shared->size; } /* end else */ if (bkg) { if (bkg_stride) b_stride = (ssize_t)bkg_stride; else b_stride = d_stride; } /* end if */ else b_stride = 0; /* Get the size of the base types in src & dst */ src_base_size = H5T_get_size(src->shared->parent); dst_base_size = H5T_get_size(dst->shared->parent); /* Set up conversion path for base elements */ if (NULL == (tpath = H5T_path_find(src->shared->parent, dst->shared->parent))) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unable to convert between src and dest datatypes"); else if (!H5T_path_noop(tpath)) { if (NULL == (tsrc_cpy = H5T_copy(src->shared->parent, H5T_COPY_ALL))) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCOPY, FAIL, "unable to copy src base type for conversion"); /* References need to know about the src file */ if (tsrc_cpy->shared->type == H5T_REFERENCE) if (H5T_set_loc(tsrc_cpy, src->shared->u.vlen.file, src->shared->u.vlen.loc) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTSET, FAIL, "can't set datatype location"); if (NULL == (tdst_cpy = H5T_copy(dst->shared->parent, H5T_COPY_ALL))) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCOPY, FAIL, "unable to copy dst base type for conversion"); /* References need to know about the dst file */ if (tdst_cpy->shared->type == H5T_REFERENCE) if (H5T_set_loc(tdst_cpy, dst->shared->u.vlen.file, dst->shared->u.vlen.loc) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTSET, FAIL, "can't set datatype location"); if (need_ids) { if ((tsrc_id = H5I_register(H5I_DATATYPE, tsrc_cpy, false)) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTREGISTER, FAIL, "unable to register ID for source base datatype"); if ((tdst_id = H5I_register(H5I_DATATYPE, tdst_cpy, false)) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTREGISTER, FAIL, "unable to register ID for destination base datatype"); } /* Update IDs in conversion context */ tmp_conv_ctx.u.conv.src_type_id = tsrc_id; tmp_conv_ctx.u.conv.dst_type_id = tdst_id; } /* end else-if */ else noop_conv = true; /* Check if we need a temporary buffer for this conversion */ if ((parent_is_vlen = H5T_detect_class(dst->shared->parent, H5T_VLEN, false)) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_SYSTEM, FAIL, "internal error when detecting variable-length class"); if (tpath->cdata.need_bkg || parent_is_vlen) { /* Set up initial background buffer */ tmp_buf_size = MAX(src_base_size, dst_base_size); if (NULL == (tmp_buf = H5FL_BLK_CALLOC(vlen_seq, tmp_buf_size))) HGOTO_ERROR(H5E_RESOURCE, H5E_CANTALLOC, FAIL, "memory allocation failed for type conversion"); } /* end if */ /* Get the allocation info */ if (H5CX_get_vlen_alloc_info(&vl_alloc_info) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTGET, FAIL, "unable to retrieve VL allocation info"); /* Set flags to indicate we are writing to or reading from the file */ if (dst->shared->u.vlen.file != NULL) write_to_file = true; /* Set the flag for nested VL case */ if (write_to_file && parent_is_vlen && bkg != NULL) nested = true; /* The outer loop of the type conversion macro, controlling which */ /* direction the buffer is walked */ while (nelmts > 0) { /* Check if we need to go backwards through the buffer */ if (d_stride > s_stride) { /* Sanity check */ assert(s_stride > 0); assert(d_stride > 0); assert(b_stride >= 0); /* Compute the number of "safe" destination elements at */ /* the end of the buffer (Those which don't overlap with */ /* any source elements at the beginning of the buffer) */ safe = nelmts - (((nelmts * (size_t)s_stride) + ((size_t)d_stride - 1)) / (size_t)d_stride); /* If we're down to the last few elements, just wrap up */ /* with a "real" reverse copy */ if (safe < 2) { s = (uint8_t *)buf + (nelmts - 1) * (size_t)s_stride; d = (uint8_t *)buf + (nelmts - 1) * (size_t)d_stride; if (bkg) b = (uint8_t *)bkg + (nelmts - 1) * (size_t)b_stride; s_stride = -s_stride; d_stride = -d_stride; b_stride = -b_stride; safe = nelmts; } /* end if */ else { s = (uint8_t *)buf + (nelmts - safe) * (size_t)s_stride; d = (uint8_t *)buf + (nelmts - safe) * (size_t)d_stride; if (bkg) b = (uint8_t *)bkg + (nelmts - safe) * (size_t)b_stride; } /* end else */ } /* end if */ else { /* Single forward pass over all data */ s = d = (uint8_t *)buf; b = (uint8_t *)bkg; safe = nelmts; } /* end else */ for (elmtno = 0; elmtno < safe; elmtno++) { bool is_nil; /* Whether sequence is "nil" */ /* Check for "nil" source sequence */ if ((*(src->shared->u.vlen.cls->isnull))(src->shared->u.vlen.file, s, &is_nil) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTGET, FAIL, "can't check if VL data is 'nil'"); else if (is_nil) { /* Write "nil" sequence to destination location */ if ((*(dst->shared->u.vlen.cls->setnull))(dst->shared->u.vlen.file, d, b) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_WRITEERROR, FAIL, "can't set VL data to 'nil'"); } /* end else-if */ else { size_t seq_len; /* The number of elements in the current sequence */ /* Get length of element sequences */ if ((*(src->shared->u.vlen.cls->getlen))(src->shared->u.vlen.file, s, &seq_len) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTGET, FAIL, "bad sequence length"); /* If we are reading from memory and there is no conversion, just get the pointer to * sequence */ if (write_to_file && noop_conv) { /* Get direct pointer to sequence */ if (NULL == (conv_buf = (*(src->shared->u.vlen.cls->getptr))(s))) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "invalid source pointer"); } /* end if */ else { size_t src_size, dst_size; /*source & destination total size in bytes*/ src_size = seq_len * src_base_size; dst_size = seq_len * dst_base_size; /* Check if conversion buffer is large enough, resize if * necessary. If the SEQ_LEN is 0, allocate a minimal size buffer. */ if (!seq_len && !conv_buf) { conv_buf_size = H5T_VLEN_MIN_CONF_BUF_SIZE; if (NULL == (conv_buf = H5FL_BLK_CALLOC(vlen_seq, conv_buf_size))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for type conversion"); } /* end if */ else if (conv_buf_size < MAX(src_size, dst_size)) { /* Only allocate conversion buffer in H5T_VLEN_MIN_CONF_BUF_SIZE increments */ conv_buf_size = ((MAX(src_size, dst_size) / H5T_VLEN_MIN_CONF_BUF_SIZE) + 1) * H5T_VLEN_MIN_CONF_BUF_SIZE; if (NULL == (conv_buf = H5FL_BLK_REALLOC(vlen_seq, conv_buf, conv_buf_size))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for type conversion"); memset(conv_buf, 0, conv_buf_size); } /* end else-if */ /* Read in VL sequence */ if ((*(src->shared->u.vlen.cls->read))(src->shared->u.vlen.file, s, conv_buf, src_size) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_READERROR, FAIL, "can't read VL data"); } /* end else */ if (!noop_conv) { /* Check if temporary buffer is large enough, resize if necessary */ /* (Chain off the conversion buffer size) */ if (tmp_buf && tmp_buf_size < conv_buf_size) { /* Set up initial background buffer */ tmp_buf_size = conv_buf_size; if (NULL == (tmp_buf = H5FL_BLK_REALLOC(vlen_seq, tmp_buf, tmp_buf_size))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for type conversion"); memset(tmp_buf, 0, tmp_buf_size); } /* end if */ /* If we are writing and there is a nested VL type, read * the sequence into the background buffer */ if (nested) { /* Sanity check */ assert(write_to_file); /* Get length of background element sequence */ if ((*(dst->shared->u.vlen.cls->getlen))(dst->shared->u.vlen.file, b, &bg_seq_len) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTGET, FAIL, "bad sequence length"); /* Read sequence if length > 0 */ if (bg_seq_len > 0) { if (tmp_buf_size < (bg_seq_len * MAX(src_base_size, dst_base_size))) { tmp_buf_size = (bg_seq_len * MAX(src_base_size, dst_base_size)); if (NULL == (tmp_buf = H5FL_BLK_REALLOC(vlen_seq, tmp_buf, tmp_buf_size))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for type conversion"); memset(tmp_buf, 0, tmp_buf_size); } /* end if */ /* Read in background VL sequence */ if ((*(dst->shared->u.vlen.cls->read))(dst->shared->u.vlen.file, b, tmp_buf, bg_seq_len * dst_base_size) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_READERROR, FAIL, "can't read VL data"); } /* end if */ /* If the sequence gets shorter, pad out the original sequence with zeros */ if (bg_seq_len < seq_len) memset((uint8_t *)tmp_buf + dst_base_size * bg_seq_len, 0, (seq_len - bg_seq_len) * dst_base_size); } /* end if */ /* Convert VL sequence */ if (H5T_convert_with_ctx(tpath, tsrc_cpy, tdst_cpy, &tmp_conv_ctx, seq_len, (size_t)0, (size_t)0, conv_buf, tmp_buf) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "datatype conversion failed"); } /* end if */ /* Write sequence to destination location */ if ((*(dst->shared->u.vlen.cls->write))(dst->shared->u.vlen.file, &vl_alloc_info, d, conv_buf, b, seq_len, dst_base_size) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_WRITEERROR, FAIL, "can't write VL data"); if (!noop_conv) { /* For nested VL case, free leftover heap objects from the deeper level if the * length of new data elements is shorter than the old data elements.*/ if (nested && seq_len < bg_seq_len) { uint8_t *tmp; size_t u; /* Sanity check */ assert(write_to_file); tmp = (uint8_t *)tmp_buf + seq_len * dst_base_size; for (u = seq_len; u < bg_seq_len; u++, tmp += dst_base_size) { /* Recursively free destination data */ if (H5T__conv_vlen_nested_free(tmp, dst->shared->parent) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTREMOVE, FAIL, "unable to remove heap object"); } /* end for */ } /* end if */ } /* end if */ } /* end else */ /* Advance pointers */ s += s_stride; d += d_stride; if (b) b += b_stride; } /* end for */ /* Decrement number of elements left to convert */ nelmts -= safe; } /* end while */ break; default: /* Some other command we don't know about yet.*/ HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); } /* end switch */ done: if (tsrc_id >= 0) { if (H5I_dec_ref(tsrc_id) < 0) HDONE_ERROR(H5E_DATATYPE, H5E_CANTDEC, FAIL, "can't decrement reference on temporary ID"); } else if (tsrc_cpy) { if (H5T_close(tsrc_cpy) < 0) HDONE_ERROR(H5E_DATATYPE, H5E_CANTCLOSEOBJ, FAIL, "can't close temporary datatype"); } if (tdst_id >= 0) { if (H5I_dec_ref(tdst_id) < 0) HDONE_ERROR(H5E_DATATYPE, H5E_CANTDEC, FAIL, "can't decrement reference on temporary ID"); } else if (tdst_cpy) { if (H5T_close(tdst_cpy) < 0) HDONE_ERROR(H5E_DATATYPE, H5E_CANTCLOSEOBJ, FAIL, "can't close temporary datatype"); } /* If the conversion buffer doesn't need to be freed, reset its pointer */ if (write_to_file && noop_conv) conv_buf = NULL; /* Release the conversion buffer (always allocated, except on errors) */ if (conv_buf) conv_buf = H5FL_BLK_FREE(vlen_seq, conv_buf); /* Release the background buffer, if we have one */ if (tmp_buf) tmp_buf = H5FL_BLK_FREE(vlen_seq, tmp_buf); FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_vlen() */ /*------------------------------------------------------------------------- * Function: H5T__conv_array * * Purpose: Converts between array datatypes in memory and on disk. * This is a soft conversion function. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_array(H5T_t *src, H5T_t *dst, H5T_cdata_t *cdata, const H5T_conv_ctx_t H5_ATTR_UNUSED *conv_ctx, size_t nelmts, size_t buf_stride, size_t bkg_stride, void *_buf, void H5_ATTR_UNUSED *_bkg) { H5T_conv_ctx_t tmp_conv_ctx = {0}; /* Temporary conversion context */ H5T_path_t *tpath; /* Type conversion path */ H5T_t *tsrc_cpy = NULL; /*temporary copy of source base datatype */ H5T_t *tdst_cpy = NULL; /*temporary copy of destination base datatype */ hid_t tsrc_id = H5I_INVALID_HID; /*temporary type atom */ hid_t tdst_id = H5I_INVALID_HID; /*temporary type atom */ uint8_t *sp, *dp; /*source and dest traversal ptrs */ ssize_t src_delta, dst_delta; /*source & destination stride */ int direction; /*direction of traversal */ bool need_ids = false; /*whether we need IDs for the datatypes */ void *bkg_buf = NULL; /*temporary background buffer */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE switch (cdata->command) { case H5T_CONV_INIT: /* * First, determine if this conversion function applies to the * conversion path SRC-->DST. If not, return failure; * otherwise initialize the `priv' field of `cdata' with * information that remains (almost) constant for this * conversion path. */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); assert(H5T_ARRAY == src->shared->type); assert(H5T_ARRAY == dst->shared->type); /* Check the number and sizes of the dimensions */ if (src->shared->u.array.ndims != dst->shared->u.array.ndims) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "array datatypes do not have the same number of dimensions"); for (unsigned u = 0; u < src->shared->u.array.ndims; u++) if (src->shared->u.array.dim[u] != dst->shared->u.array.dim[u]) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "array datatypes do not have the same sizes of dimensions"); /* Array datatypes don't need a background buffer */ cdata->need_bkg = H5T_BKG_NO; break; case H5T_CONV_FREE: /* QAK - Nothing to do currently */ break; case H5T_CONV_CONV: /* * Conversion. */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); if (NULL == conv_ctx) HGOTO_ERROR(H5E_DATATYPE, H5E_BADVALUE, FAIL, "invalid datatype conversion context pointer"); /* Initialize temporary conversion context */ tmp_conv_ctx = *conv_ctx; need_ids = (conv_ctx->u.conv.cb_struct.func != NULL); /* * Do we process the values from beginning to end or vice * versa? Also, how many of the elements have the source and * destination areas overlapping? */ if (src->shared->size >= dst->shared->size || buf_stride > 0) { sp = dp = (uint8_t *)_buf; direction = 1; } else { sp = (uint8_t *)_buf + (nelmts - 1) * (buf_stride ? buf_stride : src->shared->size); dp = (uint8_t *)_buf + (nelmts - 1) * (buf_stride ? buf_stride : dst->shared->size); direction = -1; } /* * Direction & size of buffer traversal. */ H5_CHECK_OVERFLOW(buf_stride, size_t, ssize_t); H5_CHECK_OVERFLOW(src->shared->size, size_t, ssize_t); H5_CHECK_OVERFLOW(dst->shared->size, size_t, ssize_t); src_delta = (ssize_t)direction * (ssize_t)(buf_stride ? buf_stride : src->shared->size); dst_delta = (ssize_t)direction * (ssize_t)(buf_stride ? buf_stride : dst->shared->size); /* Set up conversion path for base elements */ if (NULL == (tpath = H5T_path_find(src->shared->parent, dst->shared->parent))) { HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unable to convert between src and dest datatypes"); } else if (!H5T_path_noop(tpath)) { if (NULL == (tsrc_cpy = H5T_copy(src->shared->parent, H5T_COPY_ALL))) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCOPY, FAIL, "unable to copy src base type for conversion"); if (NULL == (tdst_cpy = H5T_copy(dst->shared->parent, H5T_COPY_ALL))) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCOPY, FAIL, "unable to copy dst base type for conversion"); if (need_ids) { if ((tsrc_id = H5I_register(H5I_DATATYPE, tsrc_cpy, false)) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTREGISTER, FAIL, "unable to register ID for source base datatype"); if ((tdst_id = H5I_register(H5I_DATATYPE, tdst_cpy, false)) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTREGISTER, FAIL, "unable to register ID for destination base datatype"); } /* Update IDs in conversion context */ tmp_conv_ctx.u.conv.src_type_id = tsrc_id; tmp_conv_ctx.u.conv.dst_type_id = tdst_id; } /* Check if we need a background buffer for this conversion */ if (tpath->cdata.need_bkg) { size_t bkg_buf_size; /*size of background buffer in bytes */ /* Allocate background buffer */ bkg_buf_size = src->shared->u.array.nelem * MAX(src->shared->size, dst->shared->size); if (NULL == (bkg_buf = H5FL_BLK_CALLOC(array_seq, bkg_buf_size))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for type conversion"); } /* end if */ /* Perform the actual conversion */ for (size_t elmtno = 0; elmtno < nelmts; elmtno++) { /* Copy the source array into the correct location for the destination */ memmove(dp, sp, src->shared->size); /* Convert array */ if (H5T_convert_with_ctx(tpath, tsrc_cpy, tdst_cpy, &tmp_conv_ctx, src->shared->u.array.nelem, (size_t)0, bkg_stride, dp, bkg_buf) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "datatype conversion failed"); /* Advance the source & destination pointers */ sp += src_delta; dp += dst_delta; } /* end for */ break; default: /* Some other command we don't know about yet.*/ HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); } /* end switch */ done: if (tsrc_id >= 0) { if (H5I_dec_ref(tsrc_id) < 0) HDONE_ERROR(H5E_DATATYPE, H5E_CANTDEC, FAIL, "can't decrement reference on temporary ID"); } else if (tsrc_cpy) { if (H5T_close(tsrc_cpy) < 0) HDONE_ERROR(H5E_DATATYPE, H5E_CANTCLOSEOBJ, FAIL, "can't close temporary datatype"); } if (tdst_id >= 0) { if (H5I_dec_ref(tdst_id) < 0) HDONE_ERROR(H5E_DATATYPE, H5E_CANTDEC, FAIL, "can't decrement reference on temporary ID"); } else if (tdst_cpy) { if (H5T_close(tdst_cpy) < 0) HDONE_ERROR(H5E_DATATYPE, H5E_CANTCLOSEOBJ, FAIL, "can't close temporary datatype"); } /* Release the background buffer, if we have one */ if (bkg_buf) bkg_buf = H5FL_BLK_FREE(array_seq, bkg_buf); FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_array() */ /*------------------------------------------------------------------------- * Function: H5T__conv_ref * * Purpose: Converts between reference datatypes in memory and on disk. * This is a soft conversion function. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ref(H5T_t *src, H5T_t *dst, H5T_cdata_t *cdata, const H5T_conv_ctx_t H5_ATTR_UNUSED *conv_ctx, size_t nelmts, size_t buf_stride, size_t bkg_stride, void *buf, void *bkg) { uint8_t *s = NULL; /* source buffer */ uint8_t *d = NULL; /* destination buffer */ uint8_t *b = NULL; /* background buffer */ ssize_t s_stride, d_stride; /* src and dst strides */ ssize_t b_stride; /* bkg stride */ size_t safe; /* how many elements are safe to process in each pass */ void *conv_buf = NULL; /* temporary conversion buffer */ size_t conv_buf_size = 0; /* size of conversion buffer in bytes */ size_t elmtno; /* element number counter */ herr_t ret_value = SUCCEED; /* return value */ FUNC_ENTER_PACKAGE switch (cdata->command) { case H5T_CONV_INIT: /* * First, determine if this conversion function applies to the * conversion path SRC-->DST. If not, return failure; * otherwise initialize the `priv' field of `cdata' with * information that remains (almost) constant for this * conversion path. */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a datatype"); if (H5T_REFERENCE != src->shared->type) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a H5T_REFERENCE datatype"); if (H5T_REFERENCE != dst->shared->type) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not a H5T_REFERENCE datatype"); /* Only allow for source reference that is not an opaque type, destination must be opaque */ if (!dst->shared->u.atomic.u.r.opaque) HGOTO_ERROR(H5E_DATATYPE, H5E_BADTYPE, FAIL, "not an H5T_STD_REF datatype"); /* Reference types don't need a background buffer */ cdata->need_bkg = H5T_BKG_NO; break; case H5T_CONV_FREE: break; case H5T_CONV_CONV: { /* * Conversion. */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); assert(src->shared->u.atomic.u.r.cls); /* Initialize source & destination strides */ if (buf_stride) { assert(buf_stride >= src->shared->size); assert(buf_stride >= dst->shared->size); H5_CHECK_OVERFLOW(buf_stride, size_t, ssize_t); s_stride = d_stride = (ssize_t)buf_stride; } /* end if */ else { H5_CHECK_OVERFLOW(src->shared->size, size_t, ssize_t); H5_CHECK_OVERFLOW(dst->shared->size, size_t, ssize_t); s_stride = (ssize_t)src->shared->size; d_stride = (ssize_t)dst->shared->size; } /* end else */ if (bkg) { if (bkg_stride) b_stride = (ssize_t)bkg_stride; else b_stride = d_stride; } /* end if */ else b_stride = 0; /* The outer loop of the type conversion macro, controlling which */ /* direction the buffer is walked */ while (nelmts > 0) { /* Check if we need to go backwards through the buffer */ if (d_stride > s_stride) { /* Sanity check */ assert(s_stride > 0); assert(d_stride > 0); assert(b_stride >= 0); /* Compute the number of "safe" destination elements at */ /* the end of the buffer (Those which don't overlap with */ /* any source elements at the beginning of the buffer) */ safe = nelmts - (((nelmts * (size_t)s_stride) + ((size_t)d_stride - 1)) / (size_t)d_stride); /* If we're down to the last few elements, just wrap up */ /* with a "real" reverse copy */ if (safe < 2) { s = (uint8_t *)buf + (nelmts - 1) * (size_t)s_stride; d = (uint8_t *)buf + (nelmts - 1) * (size_t)d_stride; if (bkg) b = (uint8_t *)bkg + (nelmts - 1) * (size_t)b_stride; s_stride = -s_stride; d_stride = -d_stride; b_stride = -b_stride; safe = nelmts; } /* end if */ else { s = (uint8_t *)buf + (nelmts - safe) * (size_t)s_stride; d = (uint8_t *)buf + (nelmts - safe) * (size_t)d_stride; if (bkg) b = (uint8_t *)bkg + (nelmts - safe) * (size_t)b_stride; } /* end else */ } /* end if */ else { /* Single forward pass over all data */ s = d = (uint8_t *)buf; b = (uint8_t *)bkg; safe = nelmts; } /* end else */ for (elmtno = 0; elmtno < safe; elmtno++) { size_t buf_size; bool dst_copy = false; bool is_nil; /* Whether reference is "nil" */ /* Check for "nil" source reference */ if ((*(src->shared->u.atomic.u.r.cls->isnull))(src->shared->u.atomic.u.r.file, s, &is_nil) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTGET, FAIL, "can't check if reference data is 'nil'"); if (is_nil) { /* Write "nil" reference to destination location */ if ((*(dst->shared->u.atomic.u.r.cls->setnull))(dst->shared->u.atomic.u.r.file, d, b) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_WRITEERROR, FAIL, "can't set reference data to 'nil'"); } /* end else-if */ else { /* Get size of references */ if (0 == (buf_size = src->shared->u.atomic.u.r.cls->getsize( src->shared->u.atomic.u.r.file, s, src->shared->size, dst->shared->u.atomic.u.r.file, &dst_copy))) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "unable to obtain size of reference"); /* Check if conversion buffer is large enough, resize if necessary. */ if (conv_buf_size < buf_size) { conv_buf_size = buf_size; if (NULL == (conv_buf = H5FL_BLK_REALLOC(ref_seq, conv_buf, conv_buf_size))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for type conversion"); memset(conv_buf, 0, conv_buf_size); } /* end if */ if (dst_copy && (src->shared->u.atomic.u.r.loc == H5T_LOC_DISK)) H5MM_memcpy(conv_buf, s, buf_size); else { /* Read reference */ if (src->shared->u.atomic.u.r.cls->read( src->shared->u.atomic.u.r.file, s, src->shared->size, dst->shared->u.atomic.u.r.file, conv_buf, buf_size) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_READERROR, FAIL, "can't read reference data"); } /* end else */ if (dst_copy && (dst->shared->u.atomic.u.r.loc == H5T_LOC_DISK)) H5MM_memcpy(d, conv_buf, buf_size); else { /* Write reference to destination location */ if (dst->shared->u.atomic.u.r.cls->write( src->shared->u.atomic.u.r.file, conv_buf, buf_size, src->shared->u.atomic.u.r.rtype, dst->shared->u.atomic.u.r.file, d, dst->shared->size, b) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_WRITEERROR, FAIL, "can't write reference data"); } /* end else */ } /* end else */ /* Advance pointers */ s += s_stride; d += d_stride; if (b) b += b_stride; } /* end for */ /* Decrement number of elements left to convert */ nelmts -= safe; } /* end while */ } /* end case */ break; default: /* Some other command we don't know about yet.*/ HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); } /* end switch */ done: /* Release the conversion buffer (always allocated, except on errors) */ if (conv_buf) conv_buf = H5FL_BLK_FREE(ref_seq, conv_buf); FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_ref() */ /*------------------------------------------------------------------------- * Function: H5T__conv_i_i * * Purpose: Convert one integer type to another. This is the catch-all * function for integer conversions and is probably not * particularly fast. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_i_i(H5T_t *src, H5T_t *dst, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { ssize_t src_delta, dst_delta; /*source & destination stride */ int direction; /*direction of traversal */ size_t elmtno; /*element number */ size_t half_size; /*half the type size */ size_t olap; /*num overlapping elements */ uint8_t *s, *sp, *d, *dp; /*source and dest traversal ptrs*/ uint8_t *src_rev = NULL; /*order-reversed source buffer */ uint8_t dbuf[64] = {0}; /*temp destination buffer */ size_t first; ssize_t sfirst; /*a signed version of `first' */ size_t i; /*Local index variables */ H5T_conv_ret_t except_ret; /*return of callback function */ bool reverse; /*if reverse the order of destination */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE switch (cdata->command) { case H5T_CONV_INIT: if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); if (H5T_ORDER_LE != src->shared->u.atomic.order && H5T_ORDER_BE != src->shared->u.atomic.order) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unsupported byte order"); if (H5T_ORDER_LE != dst->shared->u.atomic.order && H5T_ORDER_BE != dst->shared->u.atomic.order) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unsupported byte order"); if (dst->shared->size > sizeof dbuf) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "destination size is too large"); cdata->need_bkg = H5T_BKG_NO; break; case H5T_CONV_FREE: break; case H5T_CONV_CONV: if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); if (NULL == conv_ctx) HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "invalid datatype conversion context pointer"); /* * Do we process the values from beginning to end or vice versa? Also, * how many of the elements have the source and destination areas * overlapping? */ if (src->shared->size == dst->shared->size || buf_stride) { sp = dp = (uint8_t *)buf; direction = 1; olap = nelmts; } else if (src->shared->size >= dst->shared->size) { double olap_d = ceil((double)(dst->shared->size) / (double)(src->shared->size - dst->shared->size)); olap = (size_t)olap_d; sp = dp = (uint8_t *)buf; direction = 1; } else { double olap_d = ceil((double)(src->shared->size) / (double)(dst->shared->size - src->shared->size)); olap = (size_t)olap_d; sp = (uint8_t *)buf + (nelmts - 1) * src->shared->size; dp = (uint8_t *)buf + (nelmts - 1) * dst->shared->size; direction = -1; } /* * Direction & size of buffer traversal. */ H5_CHECK_OVERFLOW(buf_stride, size_t, ssize_t); H5_CHECK_OVERFLOW(src->shared->size, size_t, ssize_t); H5_CHECK_OVERFLOW(dst->shared->size, size_t, ssize_t); src_delta = (ssize_t)direction * (ssize_t)(buf_stride ? buf_stride : src->shared->size); dst_delta = (ssize_t)direction * (ssize_t)(buf_stride ? buf_stride : dst->shared->size); /* Allocate space for order-reversed source buffer */ src_rev = (uint8_t *)H5MM_calloc(src->shared->size); /* The conversion loop */ for (elmtno = 0; elmtno < nelmts; elmtno++) { /* * If the source and destination buffers overlap then use a * temporary buffer for the destination. */ if (direction > 0) { s = sp; d = elmtno < olap ? dbuf : dp; } else { s = sp; d = elmtno + olap >= nelmts ? dbuf : dp; } #ifndef NDEBUG /* I don't quite trust the overlap calculations yet --rpm */ if (d == dbuf) { assert((dp >= sp && dp < sp + src->shared->size) || (sp >= dp && sp < dp + dst->shared->size)); } else { assert((dp < sp && dp + dst->shared->size <= sp) || (sp < dp && sp + src->shared->size <= dp)); } #endif /* * Put the data in little endian order so our loops aren't so * complicated. We'll do all the conversion stuff assuming * little endian and then we'll fix the order at the end. */ if (H5T_ORDER_BE == src->shared->u.atomic.order) { half_size = src->shared->size / 2; for (i = 0; i < half_size; i++) { uint8_t tmp = s[src->shared->size - (i + 1)]; s[src->shared->size - (i + 1)] = s[i]; s[i] = tmp; } } /* * What is the bit number for the msb bit of S which is set? The * bit number is relative to the significant part of the number. */ sfirst = H5T__bit_find(s, src->shared->u.atomic.offset, src->shared->u.atomic.prec, H5T_BIT_MSB, true); first = (size_t)sfirst; /* Set these variables to default */ except_ret = H5T_CONV_UNHANDLED; reverse = true; if (sfirst < 0) { /* * The source has no bits set and must therefore be zero. * Set the destination to zero. */ H5T__bit_set(d, dst->shared->u.atomic.offset, dst->shared->u.atomic.prec, false); } else if (H5T_SGN_NONE == src->shared->u.atomic.u.i.sign && H5T_SGN_NONE == dst->shared->u.atomic.u.i.sign) { /* * Source and destination are both unsigned, but if the * source has more precision bits than the destination then * it's possible to overflow. When overflow occurs the * destination will be set to the maximum possible value. */ if (src->shared->u.atomic.prec <= dst->shared->u.atomic.prec) { H5T__bit_copy(d, dst->shared->u.atomic.offset, s, src->shared->u.atomic.offset, src->shared->u.atomic.prec); H5T__bit_set(d, dst->shared->u.atomic.offset + src->shared->u.atomic.prec, dst->shared->u.atomic.prec - src->shared->u.atomic.prec, false); } else if (first >= dst->shared->u.atomic.prec) { /*overflow*/ if (conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ H5T__reverse_order(src_rev, s, src->shared->size, src->shared->u.atomic.order); /*reverse order first*/ except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { H5T__bit_set(d, dst->shared->u.atomic.offset, dst->shared->u.atomic.prec, true); } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); else if (except_ret == H5T_CONV_HANDLED) /*Don't reverse because user handles it already*/ reverse = false; } else { H5T__bit_copy(d, dst->shared->u.atomic.offset, s, src->shared->u.atomic.offset, dst->shared->u.atomic.prec); } } else if (H5T_SGN_2 == src->shared->u.atomic.u.i.sign && H5T_SGN_NONE == dst->shared->u.atomic.u.i.sign) { /* * If the source is signed and the destination isn't then we * can have overflow if the source contains more bits than * the destination (destination is set to the maximum * possible value) or overflow if the source is negative * (destination is set to zero). */ if (first + 1 == src->shared->u.atomic.prec) { /*overflow - source is negative*/ if (conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ H5T__reverse_order(src_rev, s, src->shared->size, src->shared->u.atomic.order); /*reverse order first*/ except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_RANGE_LOW, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { H5T__bit_set(d, dst->shared->u.atomic.offset, dst->shared->u.atomic.prec, false); } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); else if (except_ret == H5T_CONV_HANDLED) /*Don't reverse because user handles it already*/ reverse = false; } else if (src->shared->u.atomic.prec < dst->shared->u.atomic.prec) { H5T__bit_copy(d, dst->shared->u.atomic.offset, s, src->shared->u.atomic.offset, src->shared->u.atomic.prec - 1); H5T__bit_set(d, dst->shared->u.atomic.offset + src->shared->u.atomic.prec - 1, (dst->shared->u.atomic.prec - src->shared->u.atomic.prec) + 1, false); } else if (first >= dst->shared->u.atomic.prec) { /*overflow - source is positive*/ if (conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ H5T__reverse_order(src_rev, s, src->shared->size, src->shared->u.atomic.order); /*reverse order first*/ except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) H5T__bit_set(d, dst->shared->u.atomic.offset, dst->shared->u.atomic.prec, true); else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); else if (except_ret == H5T_CONV_HANDLED) /*Don't reverse because user handles it already*/ reverse = false; } else { H5T__bit_copy(d, dst->shared->u.atomic.offset, s, src->shared->u.atomic.offset, dst->shared->u.atomic.prec); } } else if (H5T_SGN_NONE == src->shared->u.atomic.u.i.sign && H5T_SGN_2 == dst->shared->u.atomic.u.i.sign) { /* * If the source is not signed but the destination is then * overflow can occur in which case the destination is set to * the largest possible value (all bits set except the msb). */ if (first + 1 >= dst->shared->u.atomic.prec) { /*overflow*/ if (conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ H5T__reverse_order(src_rev, s, src->shared->size, src->shared->u.atomic.order); /*reverse order first*/ except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { H5T__bit_set(d, dst->shared->u.atomic.offset, dst->shared->u.atomic.prec - 1, true); H5T__bit_set(d, (dst->shared->u.atomic.offset + dst->shared->u.atomic.prec - 1), (size_t)1, false); } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); else if (except_ret == H5T_CONV_HANDLED) /*Don't reverse because user handles it already*/ reverse = false; } else if (src->shared->u.atomic.prec < dst->shared->u.atomic.prec) { H5T__bit_copy(d, dst->shared->u.atomic.offset, s, src->shared->u.atomic.offset, src->shared->u.atomic.prec); H5T__bit_set(d, dst->shared->u.atomic.offset + src->shared->u.atomic.prec, dst->shared->u.atomic.prec - src->shared->u.atomic.prec, false); } else { H5T__bit_copy(d, dst->shared->u.atomic.offset, s, src->shared->u.atomic.offset, dst->shared->u.atomic.prec); } } else if (first + 1 == src->shared->u.atomic.prec) { /* * Both the source and the destination are signed and the * source value is negative. We could experience overflow * if the destination isn't wide enough in which case the * destination is set to a negative number with the largest * possible magnitude. */ ssize_t sfz = H5T__bit_find(s, src->shared->u.atomic.offset, src->shared->u.atomic.prec - 1, H5T_BIT_MSB, false); size_t fz = (size_t)sfz; if (sfz >= 0 && fz + 1 >= dst->shared->u.atomic.prec) { /*overflow*/ if (conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ H5T__reverse_order(src_rev, s, src->shared->size, src->shared->u.atomic.order); /*reverse order first*/ except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_RANGE_LOW, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { H5T__bit_set(d, dst->shared->u.atomic.offset, dst->shared->u.atomic.prec - 1, false); H5T__bit_set(d, (dst->shared->u.atomic.offset + dst->shared->u.atomic.prec - 1), (size_t)1, true); } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); else if (except_ret == H5T_CONV_HANDLED) /*Don't reverse because user handles it already*/ reverse = false; } else if (src->shared->u.atomic.prec < dst->shared->u.atomic.prec) { H5T__bit_copy(d, dst->shared->u.atomic.offset, s, src->shared->u.atomic.offset, src->shared->u.atomic.prec); H5T__bit_set(d, dst->shared->u.atomic.offset + src->shared->u.atomic.prec, dst->shared->u.atomic.prec - src->shared->u.atomic.prec, true); } else { H5T__bit_copy(d, dst->shared->u.atomic.offset, s, src->shared->u.atomic.offset, dst->shared->u.atomic.prec); } } else { /* * Source and destination are both signed but the source * value is positive. We could have an overflow in which * case the destination is set to the largest possible * positive value. */ if (first + 1 >= dst->shared->u.atomic.prec) { /*overflow*/ if (conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ H5T__reverse_order(src_rev, s, src->shared->size, src->shared->u.atomic.order); /*reverse order first*/ except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { H5T__bit_set(d, dst->shared->u.atomic.offset, dst->shared->u.atomic.prec - 1, true); H5T__bit_set(d, (dst->shared->u.atomic.offset + dst->shared->u.atomic.prec - 1), (size_t)1, false); } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); else if (except_ret == H5T_CONV_HANDLED) /*Don't reverse because user handles it already*/ reverse = false; } else if (src->shared->u.atomic.prec < dst->shared->u.atomic.prec) { H5T__bit_copy(d, dst->shared->u.atomic.offset, s, src->shared->u.atomic.offset, src->shared->u.atomic.prec); H5T__bit_set(d, dst->shared->u.atomic.offset + src->shared->u.atomic.prec, dst->shared->u.atomic.prec - src->shared->u.atomic.prec, false); } else { H5T__bit_copy(d, dst->shared->u.atomic.offset, s, src->shared->u.atomic.offset, dst->shared->u.atomic.prec); } } /* * Set padding areas in destination. */ if (dst->shared->u.atomic.offset > 0) { assert(H5T_PAD_ZERO == dst->shared->u.atomic.lsb_pad || H5T_PAD_ONE == dst->shared->u.atomic.lsb_pad); H5T__bit_set(d, (size_t)0, dst->shared->u.atomic.offset, (bool)(H5T_PAD_ONE == dst->shared->u.atomic.lsb_pad)); } if (dst->shared->u.atomic.offset + dst->shared->u.atomic.prec != 8 * dst->shared->size) { assert(H5T_PAD_ZERO == dst->shared->u.atomic.msb_pad || H5T_PAD_ONE == dst->shared->u.atomic.msb_pad); H5T__bit_set(d, dst->shared->u.atomic.offset + dst->shared->u.atomic.prec, 8 * dst->shared->size - (dst->shared->u.atomic.offset + dst->shared->u.atomic.prec), (bool)(H5T_PAD_ONE == dst->shared->u.atomic.msb_pad)); } /* * Put the destination in the correct byte order. See note at * beginning of loop. */ if (H5T_ORDER_BE == dst->shared->u.atomic.order && reverse) { half_size = dst->shared->size / 2; for (i = 0; i < half_size; i++) { uint8_t tmp = d[dst->shared->size - (i + 1)]; d[dst->shared->size - (i + 1)] = d[i]; d[i] = tmp; } } /* * If we had used a temporary buffer for the destination then we * should copy the value to the true destination buffer. */ if (d == dbuf) H5MM_memcpy(dp, d, dst->shared->size); /* Advance source & destination pointers by delta amounts */ sp += src_delta; dp += dst_delta; } /* end for */ break; default: HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); } /* end switch */ done: if (src_rev) H5MM_free(src_rev); FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_i_i() */ /*------------------------------------------------------------------------- * Function: H5T__conv_f_f * * Purpose: Convert one floating point type to another. This is a catch * all for floating point conversions and is probably not * particularly fast! * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_f_f(H5T_t *src_p, H5T_t *dst_p, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { /* Traversal-related variables */ H5T_atomic_t src; /*atomic source info */ H5T_atomic_t dst; /*atomic destination info */ ssize_t src_delta, dst_delta; /*source & destination stride */ int direction; /*forward or backward traversal */ size_t elmtno; /*element number */ size_t half_size; /*half the type size */ size_t tsize; /*type size for swapping bytes */ size_t olap; /*num overlapping elements */ ssize_t bitno = 0; /*bit number */ uint8_t *s, *sp, *d, *dp; /*source and dest traversal ptrs*/ uint8_t *src_rev = NULL; /*order-reversed source buffer */ uint8_t dbuf[64] = {0}; /*temp destination buffer */ uint8_t tmp1, tmp2; /*temp variables for swapping bytes*/ /* Conversion-related variables */ int64_t expo; /*exponent */ hssize_t expo_max; /*maximum possible dst exponent */ size_t msize = 0; /*useful size of mantissa in src*/ size_t mpos; /*offset to useful mant is src */ uint64_t sign; /*source sign bit value */ size_t mrsh; /*amount to right shift mantissa*/ bool carry = false; /*carry after rounding mantissa */ size_t i; /*miscellaneous counters */ size_t implied; /*destination implied bits */ bool denormalized = false; /*is either source or destination denormalized?*/ H5T_conv_ret_t except_ret; /*return of callback function */ bool reverse; /*if reverse the order of destination */ herr_t ret_value = SUCCEED; /*return value */ FUNC_ENTER_PACKAGE switch (cdata->command) { case H5T_CONV_INIT: if (NULL == src_p || NULL == dst_p) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); src = src_p->shared->u.atomic; dst = dst_p->shared->u.atomic; if (H5T_ORDER_LE != src.order && H5T_ORDER_BE != src.order && H5T_ORDER_VAX != src.order) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unsupported byte order"); if (H5T_ORDER_LE != dst.order && H5T_ORDER_BE != dst.order && H5T_ORDER_VAX != dst.order) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unsupported byte order"); if (dst_p->shared->size > sizeof(dbuf)) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "destination size is too large"); if (8 * sizeof(expo) - 1 < src.u.f.esize || 8 * sizeof(expo) - 1 < dst.u.f.esize) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "exponent field is too large"); cdata->need_bkg = H5T_BKG_NO; break; case H5T_CONV_FREE: break; case H5T_CONV_CONV: if (NULL == src_p || NULL == dst_p) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); if (NULL == conv_ctx) HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "invalid datatype conversion context pointer"); src = src_p->shared->u.atomic; dst = dst_p->shared->u.atomic; expo_max = ((hssize_t)1 << dst.u.f.esize) - 1; /* * Do we process the values from beginning to end or vice versa? Also, * how many of the elements have the source and destination areas * overlapping? */ if (src_p->shared->size == dst_p->shared->size || buf_stride) { sp = dp = (uint8_t *)buf; direction = 1; olap = nelmts; } else if (src_p->shared->size >= dst_p->shared->size) { double olap_d = ceil((double)(dst_p->shared->size) / (double)(src_p->shared->size - dst_p->shared->size)); olap = (size_t)olap_d; sp = dp = (uint8_t *)buf; direction = 1; } else { double olap_d = ceil((double)(src_p->shared->size) / (double)(dst_p->shared->size - src_p->shared->size)); olap = (size_t)olap_d; sp = (uint8_t *)buf + (nelmts - 1) * src_p->shared->size; dp = (uint8_t *)buf + (nelmts - 1) * dst_p->shared->size; direction = -1; } /* * Direction & size of buffer traversal. */ H5_CHECK_OVERFLOW(buf_stride, size_t, ssize_t); H5_CHECK_OVERFLOW(src_p->shared->size, size_t, ssize_t); H5_CHECK_OVERFLOW(dst_p->shared->size, size_t, ssize_t); src_delta = (ssize_t)direction * (ssize_t)(buf_stride ? buf_stride : src_p->shared->size); dst_delta = (ssize_t)direction * (ssize_t)(buf_stride ? buf_stride : dst_p->shared->size); /* Allocate space for order-reversed source buffer */ src_rev = (uint8_t *)H5MM_calloc(src_p->shared->size); /* The conversion loop */ for (elmtno = 0; elmtno < nelmts; elmtno++) { /* Set these variables to default */ except_ret = H5T_CONV_UNHANDLED; reverse = true; /* * If the source and destination buffers overlap then use a * temporary buffer for the destination. */ if (direction > 0) { s = sp; d = elmtno < olap ? dbuf : dp; } else { s = sp; d = elmtno + olap >= nelmts ? dbuf : dp; } #ifndef NDEBUG /* I don't quite trust the overlap calculations yet --rpm */ if (d == dbuf) { assert((dp >= sp && dp < sp + src_p->shared->size) || (sp >= dp && sp < dp + dst_p->shared->size)); } else { assert((dp < sp && dp + dst_p->shared->size <= sp) || (sp < dp && sp + src_p->shared->size <= dp)); } #endif /* * Put the data in little endian order so our loops aren't so * complicated. We'll do all the conversion stuff assuming * little endian and then we'll fix the order at the end. */ if (H5T_ORDER_BE == src.order) { half_size = src_p->shared->size / 2; for (i = 0; i < half_size; i++) { tmp1 = s[src_p->shared->size - (i + 1)]; s[src_p->shared->size - (i + 1)] = s[i]; s[i] = tmp1; } } else if (H5T_ORDER_VAX == src.order) { tsize = src_p->shared->size; assert(0 == tsize % 2); for (i = 0; i < tsize; i += 4) { tmp1 = s[i]; tmp2 = s[i + 1]; s[i] = s[(tsize - 2) - i]; s[i + 1] = s[(tsize - 1) - i]; s[(tsize - 2) - i] = tmp1; s[(tsize - 1) - i] = tmp2; } } /* * Find the sign bit value of the source. */ sign = H5T__bit_get_d(s, src.u.f.sign, (size_t)1); /* * Check for special cases: +0, -0, +Inf, -Inf, NaN */ if (H5T__bit_find(s, src.u.f.mpos, src.u.f.msize, H5T_BIT_LSB, true) < 0) { if (H5T__bit_find(s, src.u.f.epos, src.u.f.esize, H5T_BIT_LSB, true) < 0) { /* +0 or -0 */ H5T__bit_copy(d, dst.u.f.sign, s, src.u.f.sign, (size_t)1); H5T__bit_set(d, dst.u.f.epos, dst.u.f.esize, false); H5T__bit_set(d, dst.u.f.mpos, dst.u.f.msize, false); goto padding; } else if (H5T__bit_find(s, src.u.f.epos, src.u.f.esize, H5T_BIT_LSB, false) < 0) { /* +Inf or -Inf */ if (conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); if (sign) except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_NINF, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); else except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_PINF, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { H5T__bit_copy(d, dst.u.f.sign, s, src.u.f.sign, (size_t)1); H5T__bit_set(d, dst.u.f.epos, dst.u.f.esize, true); H5T__bit_set(d, dst.u.f.mpos, dst.u.f.msize, false); /*If the destination no implied mantissa bit, we'll need to set *the 1st bit of mantissa to 1. The Intel-Linux long double is *this case.*/ if (H5T_NORM_NONE == dst.u.f.norm) H5T__bit_set(d, dst.u.f.mpos + dst.u.f.msize - 1, (size_t)1, true); } else if (except_ret == H5T_CONV_HANDLED) { /*No need to reverse the order of destination because user handles it*/ reverse = false; goto next; } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); goto padding; } } else if (H5T_NORM_NONE == src.u.f.norm && H5T__bit_find(s, src.u.f.mpos, src.u.f.msize - 1, H5T_BIT_LSB, true) < 0 && H5T__bit_find(s, src.u.f.epos, src.u.f.esize, H5T_BIT_LSB, false) < 0) { /*This is a special case for the source of no implied mantissa bit. *If the exponent bits are all 1s and only the 1st bit of mantissa *is set to 1. It's infinity. The Intel-Linux "long double" is this case.*/ /* +Inf or -Inf */ if (conv_ctx->u.conv.cb_struct.func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); if (sign) except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_NINF, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); else except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_PINF, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { H5T__bit_copy(d, dst.u.f.sign, s, src.u.f.sign, (size_t)1); H5T__bit_set(d, dst.u.f.epos, dst.u.f.esize, true); H5T__bit_set(d, dst.u.f.mpos, dst.u.f.msize, false); /*If the destination no implied mantissa bit, we'll need to set *the 1st bit of mantissa to 1. The Intel-Linux long double is *this case.*/ if (H5T_NORM_NONE == dst.u.f.norm) H5T__bit_set(d, dst.u.f.mpos + dst.u.f.msize - 1, (size_t)1, true); } else if (except_ret == H5T_CONV_HANDLED) { /*No need to reverse the order of destination because user handles it*/ reverse = false; goto next; } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); goto padding; /* Temporary solution to handle VAX special values. * Note that even though we don't support VAX anymore, we * still need to handle legacy VAX files so this code must * remain in place. */ } else if (H5T__bit_find(s, src.u.f.epos, src.u.f.esize, H5T_BIT_LSB, false) < 0) { /* NaN */ if (conv_ctx->u.conv.cb_struct.func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_NAN, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { /* There are many NaN values, so we just set all bits of * the significand. */ H5T__bit_copy(d, dst.u.f.sign, s, src.u.f.sign, (size_t)1); H5T__bit_set(d, dst.u.f.epos, dst.u.f.esize, true); H5T__bit_set(d, dst.u.f.mpos, dst.u.f.msize, true); } else if (except_ret == H5T_CONV_HANDLED) { /*No need to reverse the order of destination because user handles it*/ reverse = false; goto next; } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); goto padding; } /* * Get the exponent as an unsigned quantity from the section of * the source bit field where it's located. Don't worry about * the exponent bias yet. */ expo = (int64_t)H5T__bit_get_d(s, src.u.f.epos, src.u.f.esize); if (expo == 0) denormalized = true; /* * Set markers for the source mantissa, excluding the leading `1' * (might be implied). */ implied = 1; mpos = src.u.f.mpos; mrsh = 0; if (0 == expo || H5T_NORM_NONE == src.u.f.norm) { if ((bitno = H5T__bit_find(s, src.u.f.mpos, src.u.f.msize, H5T_BIT_MSB, true)) > 0) { msize = (size_t)bitno; } else if (0 == bitno) { msize = 1; H5T__bit_set(s, src.u.f.mpos, (size_t)1, false); } } else if (H5T_NORM_IMPLIED == src.u.f.norm) { msize = src.u.f.msize; } else { HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "normalization method not implemented yet"); } /* * The sign for the destination is the same as the sign for the * source in all cases. */ H5T__bit_copy(d, dst.u.f.sign, s, src.u.f.sign, (size_t)1); /* * Calculate the true source exponent by adjusting according to * the source exponent bias. */ if (0 == expo || H5T_NORM_NONE == src.u.f.norm) { assert(bitno >= 0); expo -= (int64_t)((src.u.f.ebias - 1) + (src.u.f.msize - (size_t)bitno)); } else if (H5T_NORM_IMPLIED == src.u.f.norm) { expo -= (int64_t)src.u.f.ebias; } else { HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "normalization method not implemented yet"); } /* * If the destination is not normalized then right shift the * mantissa by one. */ if (H5T_NORM_NONE == dst.u.f.norm) mrsh++; /* * Calculate the destination exponent by adding the destination * bias and clipping by the minimum and maximum possible * destination exponent values. */ expo += (int64_t)dst.u.f.ebias; if (expo < -(hssize_t)(dst.u.f.msize)) { /* The exponent is way too small. Result is zero. */ expo = 0; H5T__bit_set(d, dst.u.f.mpos, dst.u.f.msize, false); msize = 0; } else if (expo <= 0) { /* * The exponent is too small to fit in the exponent field, * but by shifting the mantissa to the right we can * accommodate that value. The mantissa of course is no * longer normalized. */ mrsh += (size_t)(1 - expo); expo = 0; denormalized = true; } else if (expo >= expo_max) { /* * The exponent is too large to fit in the available region * or it results in the maximum possible value. Use positive * or negative infinity instead unless the application * specifies something else. Before calling the overflow * handler make sure the source buffer we hand it is in the * original byte order. */ if (conv_ctx->u.conv.cb_struct.func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { expo = expo_max; H5T__bit_set(d, dst.u.f.mpos, dst.u.f.msize, false); msize = 0; } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); else if (except_ret == H5T_CONV_HANDLED) { reverse = false; goto next; } } /* * If the destination mantissa is smaller than the source * mantissa then round the source mantissa. Rounding may cause a * carry in which case the exponent has to be re-evaluated for * overflow. That is, if `carry' is clear then the implied * mantissa bit is `1', else it is `10' binary. */ if (msize > 0 && mrsh <= dst.u.f.msize && mrsh + msize > dst.u.f.msize) { bitno = (ssize_t)(mrsh + msize - dst.u.f.msize); assert(bitno >= 0 && (size_t)bitno <= msize); /* If the 1st bit being cut off is set and source isn't denormalized.*/ if (H5T__bit_get_d(s, (mpos + (size_t)bitno) - 1, (size_t)1) && !denormalized) { /* Don't do rounding if exponent is 111...110 and mantissa is 111...11. * To do rounding and increment exponent in this case will create an infinity value.*/ if ((H5T__bit_find(s, mpos + (size_t)bitno, msize - (size_t)bitno, H5T_BIT_LSB, false) >= 0 || expo < expo_max - 1)) { carry = H5T__bit_inc(s, mpos + (size_t)bitno - 1, 1 + msize - (size_t)bitno); if (carry) implied = 2; } } else if (H5T__bit_get_d(s, (mpos + (size_t)bitno) - 1, (size_t)1) && denormalized) /* For either source or destination, denormalized value doesn't increment carry.*/ H5T__bit_inc(s, mpos + (size_t)bitno - 1, 1 + msize - (size_t)bitno); } else carry = false; /* * Write the mantissa to the destination */ if (mrsh > dst.u.f.msize + 1) { H5T__bit_set(d, dst.u.f.mpos, dst.u.f.msize, false); } else if (mrsh == dst.u.f.msize + 1) { H5T__bit_set(d, dst.u.f.mpos + 1, dst.u.f.msize - 1, false); H5T__bit_set(d, dst.u.f.mpos, (size_t)1, true); } else if (mrsh == dst.u.f.msize) { H5T__bit_set(d, dst.u.f.mpos, dst.u.f.msize, false); H5T__bit_set_d(d, dst.u.f.mpos, MIN(2, dst.u.f.msize), (hsize_t)implied); } else { if (mrsh > 0) { H5T__bit_set(d, dst.u.f.mpos + dst.u.f.msize - mrsh, mrsh, false); H5T__bit_set_d(d, dst.u.f.mpos + dst.u.f.msize - mrsh, (size_t)2, (hsize_t)implied); } if (mrsh + msize >= dst.u.f.msize) { H5T__bit_copy(d, dst.u.f.mpos, s, (mpos + msize + mrsh - dst.u.f.msize), dst.u.f.msize - mrsh); } else { H5T__bit_copy(d, dst.u.f.mpos + dst.u.f.msize - (mrsh + msize), s, mpos, msize); H5T__bit_set(d, dst.u.f.mpos, dst.u.f.msize - (mrsh + msize), false); } } /* Write the exponent */ if (carry) { expo++; if (expo >= expo_max) { /* * The exponent is too large to fit in the available * region or it results in the maximum possible value. * Use positive or negative infinity instead unless the * application specifies something else. Before * calling the overflow handler make sure the source * buffer we hand it is in the original byte order. */ if (conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { expo = expo_max; H5T__bit_set(d, dst.u.f.mpos, dst.u.f.msize, false); } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); else if (except_ret == H5T_CONV_HANDLED) { reverse = false; goto next; } } } /*reset CARRY*/ carry = false; H5_CHECK_OVERFLOW(expo, hssize_t, hsize_t); H5T__bit_set_d(d, dst.u.f.epos, dst.u.f.esize, (hsize_t)expo); padding: /* * Set external padding areas */ if (dst.offset > 0) { assert(H5T_PAD_ZERO == dst.lsb_pad || H5T_PAD_ONE == dst.lsb_pad); H5T__bit_set(d, (size_t)0, dst.offset, (bool)(H5T_PAD_ONE == dst.lsb_pad)); } if (dst.offset + dst.prec != 8 * dst_p->shared->size) { assert(H5T_PAD_ZERO == dst.msb_pad || H5T_PAD_ONE == dst.msb_pad); H5T__bit_set(d, dst.offset + dst.prec, 8 * dst_p->shared->size - (dst.offset + dst.prec), (bool)(H5T_PAD_ONE == dst.msb_pad)); } /* * Put the destination in the correct byte order. See note at * beginning of loop. */ if (H5T_ORDER_BE == dst.order && reverse) { half_size = dst_p->shared->size / 2; for (i = 0; i < half_size; i++) { uint8_t tmp = d[dst_p->shared->size - (i + 1)]; d[dst_p->shared->size - (i + 1)] = d[i]; d[i] = tmp; } } else if (H5T_ORDER_VAX == dst.order && reverse) { tsize = dst_p->shared->size; assert(0 == tsize % 2); for (i = 0; i < tsize; i += 4) { tmp1 = d[i]; tmp2 = d[i + 1]; d[i] = d[(tsize - 2) - i]; d[i + 1] = d[(tsize - 1) - i]; d[(tsize - 2) - i] = tmp1; d[(tsize - 1) - i] = tmp2; } } /* * If we had used a temporary buffer for the destination then we * should copy the value to the true destination buffer. */ next: if (d == dbuf) H5MM_memcpy(dp, d, dst_p->shared->size); /* Advance source & destination pointers by delta amounts */ sp += src_delta; dp += dst_delta; } break; default: HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); } /* end switch */ done: if (src_rev) H5MM_free(src_rev); FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_f_f() */ /*------------------------------------------------------------------------- * Function: H5T__conv_s_s * * Purpose: Convert one fixed-length string type to another. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_s_s(H5T_t *src, H5T_t *dst, H5T_cdata_t *cdata, const H5T_conv_ctx_t H5_ATTR_UNUSED *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { ssize_t src_delta, dst_delta; /*source & destination stride */ int direction; /*direction of traversal */ size_t elmtno; /*element number */ size_t olap; /*num overlapping elements */ size_t nchars = 0; /*number of characters copied */ uint8_t *s, *sp, *d, *dp; /*src and dst traversal pointers*/ uint8_t *dbuf = NULL; /*temp buf for overlap converts. */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE switch (cdata->command) { case H5T_CONV_INIT: if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); if (8 * src->shared->size != src->shared->u.atomic.prec || 8 * dst->shared->size != dst->shared->u.atomic.prec) HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "bad precision"); if (0 != src->shared->u.atomic.offset || 0 != dst->shared->u.atomic.offset) HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "bad offset"); if (H5T_CSET_ASCII != src->shared->u.atomic.u.s.cset && H5T_CSET_UTF8 != src->shared->u.atomic.u.s.cset) HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "bad source character set"); if (H5T_CSET_ASCII != dst->shared->u.atomic.u.s.cset && H5T_CSET_UTF8 != dst->shared->u.atomic.u.s.cset) HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "bad destination character set"); if ((H5T_CSET_ASCII == src->shared->u.atomic.u.s.cset && H5T_CSET_UTF8 == dst->shared->u.atomic.u.s.cset) || (H5T_CSET_ASCII == dst->shared->u.atomic.u.s.cset && H5T_CSET_UTF8 == src->shared->u.atomic.u.s.cset)) HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "The library doesn't convert between strings of ASCII and UTF"); if (src->shared->u.atomic.u.s.pad < 0 || src->shared->u.atomic.u.s.pad >= H5T_NSTR || dst->shared->u.atomic.u.s.pad < 0 || dst->shared->u.atomic.u.s.pad >= H5T_NSTR) HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "bad character padding"); cdata->need_bkg = H5T_BKG_NO; break; case H5T_CONV_FREE: break; case H5T_CONV_CONV: /* Get the datatypes */ if (NULL == src || NULL == dst) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); /* * Do we process the values from beginning to end or vice versa? Also, * how many of the elements have the source and destination areas * overlapping? */ if (src->shared->size == dst->shared->size || buf_stride) { /* * When the source and destination are the same size we can do * all the conversions in place. */ sp = dp = (uint8_t *)buf; direction = 1; olap = 0; } else if (src->shared->size >= dst->shared->size) { double olapd = ceil((double)(dst->shared->size) / (double)(src->shared->size - dst->shared->size)); olap = (size_t)olapd; sp = dp = (uint8_t *)buf; direction = 1; } else { double olapd = ceil((double)(src->shared->size) / (double)(dst->shared->size - src->shared->size)); olap = (size_t)olapd; sp = (uint8_t *)buf + (nelmts - 1) * src->shared->size; dp = (uint8_t *)buf + (nelmts - 1) * dst->shared->size; direction = -1; } /* * Direction & size of buffer traversal. */ H5_CHECK_OVERFLOW(buf_stride, size_t, ssize_t); H5_CHECK_OVERFLOW(src->shared->size, size_t, ssize_t); H5_CHECK_OVERFLOW(dst->shared->size, size_t, ssize_t); src_delta = (ssize_t)direction * (ssize_t)(buf_stride ? buf_stride : src->shared->size); dst_delta = (ssize_t)direction * (ssize_t)(buf_stride ? buf_stride : dst->shared->size); /* Allocate the overlap buffer */ if (NULL == (dbuf = (uint8_t *)H5MM_calloc(dst->shared->size))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for string conversion"); /* The conversion loop. */ for (elmtno = 0; elmtno < nelmts; elmtno++) { /* * If the source and destination buffers overlap then use a * temporary buffer for the destination. */ if (direction > 0) { s = sp; d = elmtno < olap ? dbuf : dp; } else { s = sp; d = elmtno + olap >= nelmts ? dbuf : dp; } #ifndef NDEBUG /* I don't quite trust the overlap calculations yet --rpm */ if (src->shared->size == dst->shared->size || buf_stride) { assert(s == d); } else if (d == dbuf) { assert((dp >= sp && dp < sp + src->shared->size) || (sp >= dp && sp < dp + dst->shared->size)); } else { assert((dp < sp && dp + dst->shared->size <= sp) || (sp < dp && sp + src->shared->size <= dp)); } #endif /* Copy characters from source to destination */ switch (src->shared->u.atomic.u.s.pad) { case H5T_STR_NULLTERM: for (nchars = 0; nchars < dst->shared->size && nchars < src->shared->size && s[nchars]; nchars++) { d[nchars] = s[nchars]; } break; case H5T_STR_NULLPAD: for (nchars = 0; nchars < dst->shared->size && nchars < src->shared->size && s[nchars]; nchars++) { d[nchars] = s[nchars]; } break; case H5T_STR_SPACEPAD: nchars = src->shared->size; while (nchars > 0 && ' ' == s[nchars - 1]) --nchars; nchars = MIN(dst->shared->size, nchars); if (d != s) H5MM_memcpy(d, s, nchars); break; case H5T_STR_RESERVED_3: case H5T_STR_RESERVED_4: case H5T_STR_RESERVED_5: case H5T_STR_RESERVED_6: case H5T_STR_RESERVED_7: case H5T_STR_RESERVED_8: case H5T_STR_RESERVED_9: case H5T_STR_RESERVED_10: case H5T_STR_RESERVED_11: case H5T_STR_RESERVED_12: case H5T_STR_RESERVED_13: case H5T_STR_RESERVED_14: case H5T_STR_RESERVED_15: case H5T_STR_ERROR: default: HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "source string padding method not supported"); } /* end switch */ /* Terminate or pad the destination */ switch (dst->shared->u.atomic.u.s.pad) { case H5T_STR_NULLTERM: while (nchars < dst->shared->size) d[nchars++] = '\0'; d[dst->shared->size - 1] = '\0'; break; case H5T_STR_NULLPAD: while (nchars < dst->shared->size) d[nchars++] = '\0'; break; case H5T_STR_SPACEPAD: while (nchars < dst->shared->size) d[nchars++] = ' '; break; case H5T_STR_RESERVED_3: case H5T_STR_RESERVED_4: case H5T_STR_RESERVED_5: case H5T_STR_RESERVED_6: case H5T_STR_RESERVED_7: case H5T_STR_RESERVED_8: case H5T_STR_RESERVED_9: case H5T_STR_RESERVED_10: case H5T_STR_RESERVED_11: case H5T_STR_RESERVED_12: case H5T_STR_RESERVED_13: case H5T_STR_RESERVED_14: case H5T_STR_RESERVED_15: case H5T_STR_ERROR: default: HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "destination string padding method not supported"); } /* end switch */ /* * If we used a temporary buffer for the destination then we * should copy the value to the true destination buffer. */ if (d == dbuf) H5MM_memcpy(dp, d, dst->shared->size); /* Advance source & destination pointers by delta amounts */ sp += src_delta; dp += dst_delta; } /* end for */ break; default: HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); } /* end switch */ done: H5MM_xfree(dbuf); FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_s_s() */ /*------------------------------------------------------------------------- * Function: H5T__conv_schar_uchar * * Purpose: Converts `signed char' to `unsigned char' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_schar_uchar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_su(SCHAR, UCHAR, signed char, unsigned char, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_uchar_schar * * Purpose: Converts `unsigned char' to `signed char' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uchar_schar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_us(UCHAR, SCHAR, unsigned char, signed char, -, SCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_schar_short * * Purpose: Converts `signed char' to `short' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_schar_short(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sS(SCHAR, SHORT, signed char, short, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_schar_ushort * * Purpose: Converts `signed char' to `unsigned short' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_schar_ushort(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sU(SCHAR, USHORT, signed char, unsigned short, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_uchar_short * * Purpose: Converts `unsigned char' to `short' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uchar_short(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uS(UCHAR, SHORT, unsigned char, short, -, SHRT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_uchar_ushort * * Purpose: Converts `unsigned char' to `unsigned short' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uchar_ushort(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uU(UCHAR, USHORT, unsigned char, unsigned short, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_schar_int * * Purpose: Converts `signed char' to `int' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_schar_int(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sS(SCHAR, INT, signed char, int, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_schar_uint * * Purpose: Converts `signed char' to `unsigned int' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_schar_uint(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sU(SCHAR, UINT, signed char, unsigned, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_uchar_int * * Purpose: Converts `unsigned char' to `int' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uchar_int(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uS(UCHAR, INT, unsigned char, int, -, INT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_uchar_uint * * Purpose: Converts `unsigned char' to `unsigned int' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uchar_uint(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uU(UCHAR, UINT, unsigned char, unsigned, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_schar_long * * Purpose: Converts `signed char' to `long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_schar_long(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sS(SCHAR, LONG, signed char, long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_schar_ulong * * Purpose: Converts `signed char' to `unsigned long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_schar_ulong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sU(SCHAR, ULONG, signed char, unsigned long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_uchar_long * * Purpose: Converts `unsigned char' to `long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uchar_long(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uS(UCHAR, LONG, unsigned char, long, -, LONG_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_uchar_ulong * * Purpose: Converts `unsigned char' to `unsigned long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uchar_ulong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uU(UCHAR, ULONG, unsigned char, unsigned long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_schar_llong * * Purpose: Converts `signed char' to `long long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_schar_llong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sS(SCHAR, LLONG, signed char, long long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_schar_ullong * * Purpose: Converts `signed char' to `unsigned long long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_schar_ullong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sU(SCHAR, ULLONG, signed char, unsigned long long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_uchar_llong * * Purpose: Converts `unsigned char' to `long long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uchar_llong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uS(UCHAR, LLONG, unsigned char, long long, -, LLONG_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_uchar_ullong * * Purpose: Converts `unsigned char' to `unsigned long long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uchar_ullong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uU(UCHAR, ULLONG, unsigned char, unsigned long long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_short_schar * * Purpose: Converts `short' to `signed char' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_short_schar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Ss(SHORT, SCHAR, short, signed char, SCHAR_MIN, SCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_short_uchar * * Purpose: Converts `short' to `unsigned char' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_short_uchar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Su(SHORT, UCHAR, short, unsigned char, -, UCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ushort_schar * * Purpose: Converts `unsigned short' to `signed char' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ushort_schar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Us(USHORT, SCHAR, unsigned short, signed char, -, SCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ushort_uchar * * Purpose: Converts `unsigned short' to `unsigned char' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ushort_uchar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Uu(USHORT, UCHAR, unsigned short, unsigned char, -, UCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_short_ushort * * Purpose: Converts `short' to `unsigned short' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_short_ushort(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_su(SHORT, USHORT, short, unsigned short, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_ushort_short * * Purpose: Converts `unsigned short' to `short' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ushort_short(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_us(USHORT, SHORT, unsigned short, short, -, SHRT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_short_int * * Purpose: Converts `short' to `int' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_short_int(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sS(SHORT, INT, short, int, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_short_uint * * Purpose: Converts `short' to `unsigned int' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_short_uint(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sU(SHORT, UINT, short, unsigned, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_ushort_int * * Purpose: Converts `unsigned short' to `int' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ushort_int(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uS(USHORT, INT, unsigned short, int, -, INT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ushort_uint * * Purpose: Converts `unsigned short' to `unsigned int' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ushort_uint(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uU(USHORT, UINT, unsigned short, unsigned, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_short_long * * Purpose: Converts `short' to `long' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_short_long(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sS(SHORT, LONG, short, long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_short_ulong * * Purpose: Converts `short' to `unsigned long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_short_ulong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sU(SHORT, ULONG, short, unsigned long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_ushort_long * * Purpose: Converts `unsigned short' to `long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ushort_long(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uS(USHORT, LONG, unsigned short, long, -, LONG_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ushort_ulong * * Purpose: Converts `unsigned short' to `unsigned long' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ushort_ulong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uU(USHORT, ULONG, unsigned short, unsigned long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_short_llong * * Purpose: Converts `short' to `long long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_short_llong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sS(SHORT, LLONG, short, long long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_short_ullong * * Purpose: Converts `short' to `unsigned long long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_short_ullong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sU(SHORT, ULLONG, short, unsigned long long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_ushort_llong * * Purpose: Converts `unsigned short' to `long long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ushort_llong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uS(USHORT, LLONG, unsigned short, long long, -, LLONG_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ushort_ullong * * Purpose: Converts `unsigned short' to `unsigned long long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ushort_ullong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uU(USHORT, ULLONG, unsigned short, unsigned long long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_int_schar * * Purpose: Converts `int' to `signed char' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_int_schar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Ss(INT, SCHAR, int, signed char, SCHAR_MIN, SCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_int_uchar * * Purpose: Converts `int' to `unsigned char' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_int_uchar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Su(INT, UCHAR, int, unsigned char, -, UCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_uint_schar * * Purpose: Converts `unsigned int' to `signed char' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uint_schar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Us(UINT, SCHAR, unsigned, signed char, -, SCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_uint_uchar * * Purpose: Converts `unsigned int' to `unsigned char' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uint_uchar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Uu(UINT, UCHAR, unsigned, unsigned char, -, UCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_int_short * * Purpose: Converts `int' to `short' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_int_short(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Ss(INT, SHORT, int, short, SHRT_MIN, SHRT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_int_ushort * * Purpose: Converts `int' to `unsigned short' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_int_ushort(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Su(INT, USHORT, int, unsigned short, -, USHRT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_uint_short * * Purpose: Converts `unsigned int' to `short' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uint_short(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Us(UINT, SHORT, unsigned, short, -, SHRT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_uint_ushort * * Purpose: Converts `unsigned int' to `unsigned short' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uint_ushort(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Uu(UINT, USHORT, unsigned, unsigned short, -, USHRT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_int_uint * * Purpose: Converts `int' to `unsigned int' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_int_uint(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_su(INT, UINT, int, unsigned, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_uint_int * * Purpose: Converts `unsigned int' to `int' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uint_int(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_us(UINT, INT, unsigned, int, -, INT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_int_long * * Purpose: Converts `int' to `long' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_int_long(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sS(INT, LONG, int, long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_int_ulong * * Purpose: Converts `int' to `unsigned long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_int_ulong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sU(INT, LONG, int, unsigned long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_uint_long * * Purpose: Converts `unsigned int' to `long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uint_long(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uS(UINT, LONG, unsigned, long, -, LONG_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_uint_ulong * * Purpose: Converts `unsigned int' to `unsigned long' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uint_ulong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uU(UINT, ULONG, unsigned, unsigned long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_int_llong * * Purpose: Converts `int' to `long long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_int_llong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sS(INT, LLONG, int, long long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_int_ullong * * Purpose: Converts `int' to `unsigned long long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_int_ullong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sU(INT, ULLONG, int, unsigned long long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_uint_llong * * Purpose: Converts `unsigned int' to `long long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uint_llong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uS(UINT, LLONG, unsigned, long long, -, LLONG_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_uint_ullong * * Purpose: Converts `unsigned int' to `unsigned long long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_uint_ullong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uU(UINT, ULLONG, unsigned, unsigned long long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_long_schar * * Purpose: Converts `long' to `signed char' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_long_schar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Ss(LONG, SCHAR, long, signed char, SCHAR_MIN, SCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_long_uchar * * Purpose: Converts `long' to `unsigned char' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_long_uchar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Su(LONG, UCHAR, long, unsigned char, -, UCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ulong_schar * * Purpose: Converts `unsigned long' to `signed char' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ulong_schar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Us(ULONG, SCHAR, unsigned long, signed char, -, SCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ulong_uchar * * Purpose: Converts `unsigned long' to `unsigned char' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ulong_uchar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Uu(ULONG, UCHAR, unsigned long, unsigned char, -, UCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_long_short * * Purpose: Converts `long' to `short' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_long_short(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Ss(LONG, SHORT, long, short, SHRT_MIN, SHRT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_long_ushort * * Purpose: Converts `long' to `unsigned short' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_long_ushort(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Su(LONG, USHORT, long, unsigned short, -, USHRT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ulong_short * * Purpose: Converts `unsigned long' to `short' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ulong_short(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Us(ULONG, SHORT, unsigned long, short, -, SHRT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ulong_ushort * * Purpose: Converts `unsigned long' to `unsigned short' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ulong_ushort(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Uu(ULONG, USHORT, unsigned long, unsigned short, -, USHRT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_long_int * * Purpose: Converts `long' to `int' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_long_int(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Ss(LONG, INT, long, int, INT_MIN, INT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_long_uint * * Purpose: Converts `long' to `unsigned int' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_long_uint(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Su(LONG, UINT, long, unsigned, -, UINT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ulong_int * * Purpose: Converts `unsigned long' to `int' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ulong_int(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Us(ULONG, INT, unsigned long, int, -, INT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ulong_uint * * Purpose: Converts `unsigned long' to `unsigned int' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ulong_uint(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Uu(ULONG, UINT, unsigned long, unsigned, -, UINT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_long_ulong * * Purpose: Converts `long' to `unsigned long' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_long_ulong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_su(LONG, ULONG, long, unsigned long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_ulong_long * * Purpose: Converts `unsigned long' to `long' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ulong_long(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_us(ULONG, LONG, unsigned long, long, -, LONG_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_long_llong * * Purpose: Converts `long' to `long long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_long_llong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sS(LONG, LLONG, long, long long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_long_ullong * * Purpose: Converts `long' to `unsigned long long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_long_ullong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_sU(LONG, ULLONG, long, unsigned long long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_ulong_llong * * Purpose: Converts `unsigned long' to `long long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ulong_llong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uS(ULONG, LLONG, unsigned long, long long, -, LLONG_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ulong_ullong * * Purpose: Converts `unsigned long' to `unsigned long long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ulong_ullong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_uU(ULONG, ULLONG, unsigned long, unsigned long long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_llong_schar * * Purpose: Converts `long long' to `signed char' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_llong_schar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Ss(LLONG, SCHAR, long long, signed char, SCHAR_MIN, SCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_llong_uchar * * Purpose: Converts `long long' to `unsigned char' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_llong_uchar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Su(LLONG, UCHAR, long long, unsigned char, -, UCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ullong_schar * * Purpose: Converts `unsigned long long' to `signed char' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ullong_schar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Us(ULLONG, SCHAR, unsigned long long, signed char, -, SCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ullong_uchar * * Purpose: Converts `unsigned long long' to `unsigned char' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ullong_uchar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Uu(ULLONG, UCHAR, unsigned long long, unsigned char, -, UCHAR_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_llong_short * * Purpose: Converts `long long' to `short' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_llong_short(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Ss(LLONG, SHORT, long long, short, SHRT_MIN, SHRT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_llong_ushort * * Purpose: Converts `long long' to `unsigned short' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_llong_ushort(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Su(LLONG, USHORT, long long, unsigned short, -, USHRT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ullong_short * * Purpose: Converts `unsigned long long' to `short' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ullong_short(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Us(ULLONG, SHORT, unsigned long long, short, -, SHRT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ullong_ushort * * Purpose: Converts `unsigned long long' to `unsigned short' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ullong_ushort(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Uu(ULLONG, USHORT, unsigned long long, unsigned short, -, USHRT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_llong_int * * Purpose: Converts `long long' to `int' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_llong_int(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Ss(LLONG, INT, long long, int, INT_MIN, INT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_llong_uint * * Purpose: Converts `long long' to `unsigned int' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_llong_uint(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Su(LLONG, UINT, long long, unsigned, -, UINT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ullong_int * * Purpose: Converts `unsigned long long' to `int' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ullong_int(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Us(ULLONG, INT, unsigned long long, int, -, INT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ullong_uint * * Purpose: Converts `unsigned long long' to `unsigned int' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ullong_uint(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Uu(ULLONG, UINT, unsigned long long, unsigned, -, UINT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_llong_long * * Purpose: Converts `long long' to `long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_llong_long(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Ss(LLONG, LONG, long long, long, LONG_MIN, LONG_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_llong_ulong * * Purpose: Converts `long long' to `unsigned long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_llong_ulong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Su(LLONG, ULONG, long long, unsigned long, -, ULONG_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ullong_long * * Purpose: Converts `unsigned long long' to `long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ullong_long(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Us(ULLONG, LONG, unsigned long long, long, -, LONG_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ullong_ulong * * Purpose: Converts `unsigned long long' to `unsigned long' * * Return: Success: Non-negative * * Failure: Negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ullong_ulong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Uu(ULLONG, ULONG, unsigned long long, unsigned long, -, ULONG_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_llong_ullong * * Purpose: Converts `long long' to `unsigned long long' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_llong_ullong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_su(LLONG, ULLONG, long long, unsigned long long, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_ullong_llong * * Purpose: Converts `unsigned long long' to `long long' * * Return: Success: non-negative * * Failure: negative * *------------------------------------------------------------------------- */ herr_t H5T__conv_ullong_llong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_us(ULLONG, LLONG, unsigned long long, long long, -, LLONG_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_float_double * * Purpose: Convert native `float' to native `double' using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_float_double(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_fF(FLOAT, DOUBLE, float, double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_float_ldouble * * Purpose: Convert native `float' to native `long double' using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_float_ldouble(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_fF(FLOAT, LDOUBLE, float, long double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_double_float * * Purpose: Convert native `double' to native `float' using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_double_float(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Ff(DOUBLE, FLOAT, double, float, -FLT_MAX, FLT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_double_ldouble * * Purpose: Convert native `double' to native `long double' using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_double_ldouble(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_fF(DOUBLE, LDOUBLE, double, long double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_ldouble_float * * Purpose: Convert native `long double' to native `float' using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ldouble_float(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Ff(LDOUBLE, FLOAT, long double, float, -FLT_MAX, FLT_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_ldouble_double * * Purpose: Convert native `long double' to native `double' using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ldouble_double(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_Ff(LDOUBLE, DOUBLE, long double, double, -DBL_MAX, DBL_MAX); } /*------------------------------------------------------------------------- * Function: H5T__conv_schar_float * * Purpose: Convert native signed char to native float using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_schar_float(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(SCHAR, FLOAT, signed char, float, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_schar_double * * Purpose: Convert native signed char to native double using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_schar_double(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(SCHAR, DOUBLE, signed char, double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_schar_ldouble * * Purpose: Convert native signed char to native long double using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_schar_ldouble(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(SCHAR, LDOUBLE, signed char, long double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_uchar_float * * Purpose: Convert native unsigned char to native float using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_uchar_float(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(UCHAR, FLOAT, unsigned char, float, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_uchar_double * * Purpose: Convert native unsigned char to native double using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_uchar_double(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(UCHAR, DOUBLE, unsigned char, double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_uchar_ldouble * * Purpose: Convert native unsigned char to native long double using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_uchar_ldouble(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(UCHAR, LDOUBLE, unsigned char, long double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_short_float * * Purpose: Convert native short to native float using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_short_float(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(SHORT, FLOAT, short, float, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_short_double * * Purpose: Convert native short to native double using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_short_double(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(SHORT, DOUBLE, short, double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_short_ldouble * * Purpose: Convert native short to native long double using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_short_ldouble(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(SHORT, LDOUBLE, short, long double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_ushort_float * * Purpose: Convert native unsigned short to native float using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ushort_float(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(USHORT, FLOAT, unsigned short, float, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_ushort_double * * Purpose: Convert native unsigned short to native double using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ushort_double(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(USHORT, DOUBLE, unsigned short, double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_ushort_ldouble * * Purpose: Convert native unsigned short to native long double using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ushort_ldouble(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(USHORT, LDOUBLE, unsigned short, long double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_int_float * * Purpose: Convert native integer to native float using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_int_float(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(INT, FLOAT, int, float, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_int_double * * Purpose: Convert native integer to native double using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_int_double(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(INT, DOUBLE, int, double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_int_ldouble * * Purpose: Convert native integer to native long double using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_int_ldouble(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(INT, LDOUBLE, int, long double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_uint_float * * Purpose: Convert native unsigned integer to native float using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_uint_float(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(UINT, FLOAT, unsigned int, float, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_uint_double * * Purpose: Convert native unsigned integer to native double using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_uint_double(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(UINT, DOUBLE, unsigned int, double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_uint_ldouble * * Purpose: Convert native unsigned integer to native long double using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_uint_ldouble(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(UINT, LDOUBLE, unsigned int, long double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_long_float * * Purpose: Convert native long to native float using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_long_float(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(LONG, FLOAT, long, float, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_long_double * * Purpose: Convert native long to native double using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_long_double(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(LONG, DOUBLE, long, double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_long_ldouble * * Purpose: Convert native long to native long double using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_long_ldouble(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(LONG, LDOUBLE, long, long double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_ulong_float * * Purpose: Convert native unsigned long to native float using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ulong_float(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(ULONG, FLOAT, unsigned long, float, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_ulong_double * * Purpose: Convert native unsigned long to native double using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ulong_double(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(ULONG, DOUBLE, unsigned long, double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_ulong_ldouble * * Purpose: Convert native unsigned long to native long double using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ulong_ldouble(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(ULONG, LDOUBLE, unsigned long, long double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_llong_float * * Purpose: Convert native long long to native float using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_llong_float(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(LLONG, FLOAT, long long, float, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_llong_double * * Purpose: Convert native long long to native double using hardware. * This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_llong_double(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(LLONG, DOUBLE, long long, double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_llong_ldouble * * Purpose: Convert native long long to native long double using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ #ifdef H5T_CONV_INTERNAL_LLONG_LDOUBLE herr_t H5T__conv_llong_ldouble(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(LLONG, LDOUBLE, long long, long double, -, -); } #endif /* H5T_CONV_INTERNAL_LLONG_LDOUBLE */ /*------------------------------------------------------------------------- * Function: H5T__conv_ullong_float * * Purpose: Convert native unsigned long long to native float using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ullong_float(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(ULLONG, FLOAT, unsigned long long, float, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_ullong_double * * Purpose: Convert native unsigned long long to native double using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ullong_double(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(ULLONG, DOUBLE, unsigned long long, double, -, -); } /*------------------------------------------------------------------------- * Function: H5T__conv_ullong_ldouble * * Purpose: Convert native unsigned long long to native long double using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ #ifdef H5T_CONV_INTERNAL_ULLONG_LDOUBLE herr_t H5T__conv_ullong_ldouble(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(ULLONG, LDOUBLE, unsigned long long, long double, -, -); } #endif /*H5T_CONV_INTERNAL_ULLONG_LDOUBLE*/ /*------------------------------------------------------------------------- * Function: H5T__conv_float_schar * * Purpose: Convert native float to native signed char using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_float_schar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(FLOAT, SCHAR, float, signed char, SCHAR_MIN, SCHAR_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_float_uchar * * Purpose: Convert native float to native unsigned char using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_float_uchar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(FLOAT, UCHAR, float, unsigned char, 0, UCHAR_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_double_schar * * Purpose: Convert native double to native signed char using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_double_schar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(DOUBLE, SCHAR, double, signed char, SCHAR_MIN, SCHAR_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_double_uchar * * Purpose: Convert native double to native unsigned char using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_double_uchar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(DOUBLE, UCHAR, double, unsigned char, 0, UCHAR_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_ldouble_schar * * Purpose: Convert native long double to native signed char using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ldouble_schar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(LDOUBLE, SCHAR, long double, signed char, SCHAR_MIN, SCHAR_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_ldouble_uchar * * Purpose: Convert native long double to native unsigned char using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ldouble_uchar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(LDOUBLE, UCHAR, long double, unsigned char, 0, UCHAR_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_float_short * * Purpose: Convert native float to native short using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_float_short(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(FLOAT, SHORT, float, short, SHRT_MIN, SHRT_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_float_ushort * * Purpose: Convert native float to native unsigned short using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_float_ushort(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(FLOAT, USHORT, float, unsigned short, 0, USHRT_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_double_short * * Purpose: Convert native double to native short using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_double_short(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(DOUBLE, SHORT, double, short, SHRT_MIN, SHRT_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_double_ushort * * Purpose: Convert native double to native unsigned short using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_double_ushort(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(DOUBLE, USHORT, double, unsigned short, 0, USHRT_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_ldouble_short * * Purpose: Convert native long double to native short using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ldouble_short(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(LDOUBLE, SHORT, long double, short, SHRT_MIN, SHRT_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_ldouble_ushort * * Purpose: Convert native long double to native unsigned short using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ldouble_ushort(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(LDOUBLE, USHORT, long double, unsigned short, 0, USHRT_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_float_int * * Purpose: Convert native float to native int using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_float_int(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(FLOAT, INT, float, int, INT_MIN, INT_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_float_uint * * Purpose: Convert native float to native unsigned int using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_float_uint(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(FLOAT, UINT, float, unsigned int, 0, UINT_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_double_int * * Purpose: Convert native double to native int using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_double_int(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(DOUBLE, INT, double, int, INT_MIN, INT_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_double_uint * * Purpose: Convert native double to native unsigned int using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_double_uint(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(DOUBLE, UINT, double, unsigned int, 0, UINT_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_ldouble_int * * Purpose: Convert native long double to native int using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ldouble_int(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(LDOUBLE, INT, long double, int, INT_MIN, INT_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_ldouble_uint * * Purpose: Convert native long double to native unsigned int using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ldouble_uint(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(LDOUBLE, UINT, long double, unsigned int, 0, UINT_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_float_long * * Purpose: Convert native float to native long using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_float_long(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(FLOAT, LONG, float, long, LONG_MIN, LONG_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_float_ulong * * Purpose: Convert native float to native unsigned long using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_float_ulong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(FLOAT, ULONG, float, unsigned long, 0, ULONG_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_double_long * * Purpose: Convert native double to native long using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_double_long(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(DOUBLE, LONG, double, long, LONG_MIN, LONG_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_double_ulong * * Purpose: Convert native double to native unsigned long using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_double_ulong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(DOUBLE, ULONG, double, unsigned long, 0, ULONG_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_ldouble_long * * Purpose: Convert native long double to native long using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ldouble_long(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(LDOUBLE, LONG, long double, long, LONG_MIN, LONG_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_ldouble_ulong * * Purpose: Convert native long double to native unsigned long using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_ldouble_ulong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(LDOUBLE, ULONG, long double, unsigned long, 0, ULONG_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_float_llong * * Purpose: Convert native float to native long long using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_float_llong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(FLOAT, LLONG, float, long long, LLONG_MIN, LLONG_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_float_ullong * * Purpose: Convert native float to native unsigned long long using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_float_ullong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(FLOAT, ULLONG, float, unsigned long long, 0, ULLONG_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_double_llong * * Purpose: Convert native double to native long long using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_double_llong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(DOUBLE, LLONG, double, long long, LLONG_MIN, LLONG_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_double_ullong * * Purpose: Convert native double to native unsigned long long using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_double_ullong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(DOUBLE, ULLONG, double, unsigned long long, 0, ULLONG_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } /*------------------------------------------------------------------------- * Function: H5T__conv_ldouble_llong * * Purpose: Convert native long double to native long long using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ #ifdef H5T_CONV_INTERNAL_LDOUBLE_LLONG herr_t H5T__conv_ldouble_llong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(LDOUBLE, LLONG, long double, long long, LLONG_MIN, LLONG_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } #endif /*H5T_CONV_INTERNAL_LDOUBLE_LLONG*/ /*------------------------------------------------------------------------- * Function: H5T__conv_ldouble_ullong * * Purpose: Convert native long double to native unsigned long long using * hardware. This is a fast special case. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ #ifdef H5T_CONV_INTERNAL_LDOUBLE_ULLONG herr_t H5T__conv_ldouble_ullong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(LDOUBLE, ULLONG, long double, unsigned long long, 0, ULLONG_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } #endif /*H5T_CONV_INTERNAL_LDOUBLE_ULLONG*/ /* Conversions for _Float16 type */ #ifdef H5_HAVE__FLOAT16 herr_t H5T__conv_schar__Float16(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(SCHAR, FLOAT16, signed char, H5__Float16, -, -); } herr_t H5T__conv_uchar__Float16(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(UCHAR, FLOAT16, unsigned char, H5__Float16, -, -); } herr_t H5T__conv_short__Float16(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_xF(SHORT, FLOAT16, short, H5__Float16, -, -); } herr_t H5T__conv_ushort__Float16(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { /* Suppress warning about non-standard floating-point literal suffix */ H5_GCC_CLANG_DIAG_OFF("pedantic") H5T_CONV_Xf(USHORT, FLOAT16, unsigned short, H5__Float16, -FLT16_MAX, FLT16_MAX); H5_GCC_CLANG_DIAG_ON("pedantic") } herr_t H5T__conv_int__Float16(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { /* Suppress warning about non-standard floating-point literal suffix */ H5_GCC_CLANG_DIAG_OFF("pedantic") H5T_CONV_Xf(INT, FLOAT16, int, H5__Float16, -FLT16_MAX, FLT16_MAX); H5_GCC_CLANG_DIAG_ON("pedantic") } herr_t H5T__conv_uint__Float16(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { /* Suppress warning about non-standard floating-point literal suffix */ H5_GCC_CLANG_DIAG_OFF("pedantic") H5T_CONV_Xf(UINT, FLOAT16, unsigned int, H5__Float16, -FLT16_MAX, FLT16_MAX); H5_GCC_CLANG_DIAG_ON("pedantic") } herr_t H5T__conv_long__Float16(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { /* Suppress warning about non-standard floating-point literal suffix */ H5_GCC_CLANG_DIAG_OFF("pedantic") H5T_CONV_Xf(LONG, FLOAT16, long, H5__Float16, -FLT16_MAX, FLT16_MAX); H5_GCC_CLANG_DIAG_ON("pedantic") } herr_t H5T__conv_ulong__Float16(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { /* Suppress warning about non-standard floating-point literal suffix */ H5_GCC_CLANG_DIAG_OFF("pedantic") H5T_CONV_Xf(ULONG, FLOAT16, unsigned long, H5__Float16, -FLT16_MAX, FLT16_MAX); H5_GCC_CLANG_DIAG_ON("pedantic") } herr_t H5T__conv_llong__Float16(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { /* Suppress warning about non-standard floating-point literal suffix */ H5_GCC_CLANG_DIAG_OFF("pedantic") H5T_CONV_Xf(LLONG, FLOAT16, long long, H5__Float16, -FLT16_MAX, FLT16_MAX); H5_GCC_CLANG_DIAG_ON("pedantic") } herr_t H5T__conv_ullong__Float16(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { /* Suppress warning about non-standard floating-point literal suffix */ H5_GCC_CLANG_DIAG_OFF("pedantic") H5T_CONV_Xf(ULLONG, FLOAT16, unsigned long long, H5__Float16, -FLT16_MAX, FLT16_MAX); H5_GCC_CLANG_DIAG_ON("pedantic") } herr_t H5T__conv_float__Float16(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { /* Suppress warning about non-standard floating-point literal suffix */ H5_GCC_CLANG_DIAG_OFF("pedantic") H5T_CONV_Ff(FLOAT, FLOAT16, float, H5__Float16, -FLT16_MAX, FLT16_MAX); H5_GCC_CLANG_DIAG_ON("pedantic") } herr_t H5T__conv_double__Float16(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { /* Suppress warning about non-standard floating-point literal suffix */ H5_GCC_CLANG_DIAG_OFF("pedantic") H5T_CONV_Ff(DOUBLE, FLOAT16, double, H5__Float16, -FLT16_MAX, FLT16_MAX); H5_GCC_CLANG_DIAG_ON("pedantic") } #ifdef H5T_CONV_INTERNAL_LDOUBLE_FLOAT16 herr_t H5T__conv_ldouble__Float16(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { /* Suppress warning about non-standard floating-point literal suffix */ H5_GCC_CLANG_DIAG_OFF("pedantic") H5T_CONV_Ff(LDOUBLE, FLOAT16, long double, H5__Float16, -FLT16_MAX, FLT16_MAX); H5_GCC_CLANG_DIAG_ON("pedantic") } #endif herr_t H5T__conv__Float16_schar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(FLOAT16, SCHAR, H5__Float16, signed char, SCHAR_MIN, SCHAR_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } herr_t H5T__conv__Float16_uchar(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(FLOAT16, UCHAR, H5__Float16, unsigned char, 0, UCHAR_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } herr_t H5T__conv__Float16_short(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5_GCC_CLANG_DIAG_OFF("float-equal") H5T_CONV_Fx(FLOAT16, SHORT, H5__Float16, short, SHRT_MIN, SHRT_MAX); H5_GCC_CLANG_DIAG_ON("float-equal") } herr_t H5T__conv__Float16_ushort(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_fX(FLOAT16, USHORT, H5__Float16, unsigned short, 0, USHRT_MAX); } herr_t H5T__conv__Float16_int(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_fX(FLOAT16, INT, H5__Float16, int, INT_MIN, INT_MAX); } herr_t H5T__conv__Float16_uint(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_fX(FLOAT16, UINT, H5__Float16, unsigned int, 0, UINT_MAX); } herr_t H5T__conv__Float16_long(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_fX(FLOAT16, LONG, H5__Float16, long, LONG_MIN, LONG_MAX); } herr_t H5T__conv__Float16_ulong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_fX(FLOAT16, ULONG, H5__Float16, unsigned long, 0, ULONG_MAX); } herr_t H5T__conv__Float16_llong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_fX(FLOAT16, LLONG, H5__Float16, long long, LLONG_MIN, LLONG_MAX); } herr_t H5T__conv__Float16_ullong(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_fX(FLOAT16, ULLONG, H5__Float16, unsigned long long, 0, ULLONG_MAX); } herr_t H5T__conv__Float16_float(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_fF(FLOAT16, FLOAT, H5__Float16, float, -, -); } herr_t H5T__conv__Float16_double(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_fF(FLOAT16, DOUBLE, H5__Float16, double, -, -); } herr_t H5T__conv__Float16_ldouble(H5T_t *st, H5T_t *dt, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { H5T_CONV_fF(FLOAT16, LDOUBLE, H5__Float16, long double, -, -); } #endif /*------------------------------------------------------------------------- * Function: H5T__conv_f_i * * Purpose: Convert one floating-point type to an integer. This is * the catch-all function for float-integer conversions and * is probably not particularly fast. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_f_i(H5T_t *src_p, H5T_t *dst_p, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { /* Traversal-related variables */ H5T_atomic_t src; /*atomic source info */ H5T_atomic_t dst; /*atomic destination info */ int direction; /*forward or backward traversal */ size_t elmtno; /*element number */ size_t half_size; /*half the type size */ size_t tsize; /*type size for swapping bytes */ size_t olap; /*num overlapping elements */ uint8_t *s, *sp, *d, *dp; /*source and dest traversal ptrs*/ uint8_t *src_rev = NULL; /*order-reversed source buffer */ uint8_t dbuf[64] = {0}; /*temp destination buffer */ uint8_t tmp1, tmp2; /*temp variables for swapping bytes*/ /* Conversion-related variables */ hssize_t expo; /*source exponent */ hssize_t sign; /*source sign bit value */ uint8_t *int_buf = NULL; /*buffer for temporary value */ size_t buf_size; /*buffer size for temporary value */ size_t i; /*miscellaneous counters */ ssize_t msb_pos_s; /*first bit(MSB) in an integer */ ssize_t new_msb_pos; /*MSB position after shifting mantissa by exponent */ hssize_t shift_val; /*shift value when shifting mantissa by exponent */ bool truncated; /*if fraction value is dropped */ bool reverse; /*if reverse order of destination at the end */ H5T_conv_ret_t except_ret; /*return of callback function */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE switch (cdata->command) { case H5T_CONV_INIT: if (NULL == src_p || NULL == dst_p) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); src = src_p->shared->u.atomic; dst = dst_p->shared->u.atomic; if (H5T_ORDER_LE != src.order && H5T_ORDER_BE != src.order && H5T_ORDER_VAX != src.order) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unsupported byte order"); if (dst_p->shared->size > sizeof(dbuf)) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "destination size is too large"); if (8 * sizeof(expo) - 1 < src.u.f.esize) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "exponent field is too large"); cdata->need_bkg = H5T_BKG_NO; break; case H5T_CONV_FREE: break; case H5T_CONV_CONV: if (NULL == src_p || NULL == dst_p) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); if (NULL == conv_ctx) HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "invalid datatype conversion context pointer"); src = src_p->shared->u.atomic; dst = dst_p->shared->u.atomic; /* * Do we process the values from beginning to end or vice versa? Also, * how many of the elements have the source and destination areas * overlapping? */ if (src_p->shared->size == dst_p->shared->size || buf_stride) { sp = dp = (uint8_t *)buf; direction = 1; olap = nelmts; } else if (src_p->shared->size >= dst_p->shared->size) { double olap_d = ceil((double)(dst_p->shared->size) / (double)(src_p->shared->size - dst_p->shared->size)); olap = (size_t)olap_d; sp = dp = (uint8_t *)buf; direction = 1; } else { double olap_d = ceil((double)(src_p->shared->size) / (double)(dst_p->shared->size - src_p->shared->size)); olap = (size_t)olap_d; sp = (uint8_t *)buf + (nelmts - 1) * src_p->shared->size; dp = (uint8_t *)buf + (nelmts - 1) * dst_p->shared->size; direction = -1; } /* Allocate enough space for the buffer holding temporary * converted value */ if (dst.prec / 8 > src_p->shared->size) buf_size = (dst.prec + 7) / 8; else buf_size = src_p->shared->size; int_buf = (uint8_t *)H5MM_calloc(buf_size); /* Allocate space for order-reversed source buffer */ src_rev = (uint8_t *)H5MM_calloc(src_p->shared->size); /* The conversion loop */ for (elmtno = 0; elmtno < nelmts; elmtno++) { /* Set these variables to default */ except_ret = H5T_CONV_UNHANDLED; truncated = false; reverse = true; /* * If the source and destination buffers overlap then use a * temporary buffer for the destination. */ if (direction > 0) { s = sp; d = elmtno < olap ? dbuf : dp; } else { s = sp; d = elmtno + olap >= nelmts ? dbuf : dp; } #ifndef NDEBUG /* I don't quite trust the overlap calculations yet --rpm */ if (d == dbuf) { assert((dp >= sp && dp < sp + src_p->shared->size) || (sp >= dp && sp < dp + dst_p->shared->size)); } else { assert((dp < sp && dp + dst_p->shared->size <= sp) || (sp < dp && sp + src_p->shared->size <= dp)); } #endif /* * Put the data in little endian order so our loops aren't so * complicated. We'll do all the conversion stuff assuming * little endian and then we'll fix the order at the end. */ if (H5T_ORDER_BE == src.order) { half_size = src_p->shared->size / 2; for (i = 0; i < half_size; i++) { tmp1 = s[src_p->shared->size - (i + 1)]; s[src_p->shared->size - (i + 1)] = s[i]; s[i] = tmp1; } } else if (H5T_ORDER_VAX == src.order) { tsize = src_p->shared->size; assert(0 == tsize % 2); for (i = 0; i < tsize; i += 4) { tmp1 = s[i]; tmp2 = s[i + 1]; s[i] = s[(tsize - 2) - i]; s[i + 1] = s[(tsize - 1) - i]; s[(tsize - 2) - i] = tmp1; s[(tsize - 1) - i] = tmp2; } } /*zero-set all destination bits*/ H5T__bit_set(d, dst.offset, dst.prec, false); /* * Find the sign bit value of the source. */ sign = (hssize_t)H5T__bit_get_d(s, src.u.f.sign, (size_t)1); /* * Check for special cases: +0, -0, +Inf, -Inf, NaN */ if (H5T__bit_find(s, src.u.f.mpos, src.u.f.msize, H5T_BIT_LSB, true) < 0) { if (H5T__bit_find(s, src.u.f.epos, src.u.f.esize, H5T_BIT_LSB, true) < 0) { /* +0 or -0 */ /* Set all bits to zero */ goto padding; } else if (H5T__bit_find(s, src.u.f.epos, src.u.f.esize, H5T_BIT_LSB, false) < 0) { /* +Infinity or -Infinity */ if (sign) { /* -Infinity */ if (conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_NINF, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { if (H5T_SGN_2 == dst.u.i.sign) H5T__bit_set(d, dst.prec - 1, (size_t)1, true); } else if (except_ret == H5T_CONV_HANDLED) { /*No need to reverse the order of destination because user handles it*/ reverse = false; goto next; } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); } else { /* +Infinity */ if (conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_PINF, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { if (H5T_SGN_NONE == dst.u.i.sign) H5T__bit_set(d, dst.offset, dst.prec, true); else if (H5T_SGN_2 == dst.u.i.sign) H5T__bit_set(d, dst.offset, dst.prec - 1, true); } else if (except_ret == H5T_CONV_HANDLED) { /*No need to reverse the order of destination because user handles it*/ reverse = false; goto next; } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); } goto padding; } } else if (H5T_NORM_NONE == src.u.f.norm && H5T__bit_find(s, src.u.f.mpos, src.u.f.msize - 1, H5T_BIT_LSB, true) < 0 && H5T__bit_find(s, src.u.f.epos, src.u.f.esize, H5T_BIT_LSB, false) < 0) { /*This is a special case for the source of no implied mantissa bit. *If the exponent bits are all 1s and only the 1st bit of mantissa *is set to 1. It's infinity. The Intel-Linux "long double" is this case.*/ /* +Infinity or -Infinity */ if (sign) { /* -Infinity */ if (conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_NINF, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { if (H5T_SGN_2 == dst.u.i.sign) H5T__bit_set(d, dst.prec - 1, (size_t)1, true); } else if (except_ret == H5T_CONV_HANDLED) { /*No need to reverse the order of destination because user handles it*/ reverse = false; goto next; } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); } else { /* +Infinity */ if (conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_PINF, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { if (H5T_SGN_NONE == dst.u.i.sign) H5T__bit_set(d, dst.offset, dst.prec, true); else if (H5T_SGN_2 == dst.u.i.sign) H5T__bit_set(d, dst.offset, dst.prec - 1, true); } else if (except_ret == H5T_CONV_HANDLED) { /*No need to reverse the order of destination because user handles it*/ reverse = false; goto next; } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); } goto padding; } else if (H5T__bit_find(s, src.u.f.epos, src.u.f.esize, H5T_BIT_LSB, false) < 0) { /* NaN */ if (conv_ctx->u.conv.cb_struct.func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_NAN, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { /*Just set all bits to zero.*/ goto padding; } else if (except_ret == H5T_CONV_HANDLED) { /*No need to reverse the order of destination because user handles it*/ reverse = false; goto next; } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); goto padding; } /* * Get the exponent as an unsigned quantity from the section of * the source bit field where it's located. Not expecting * exponent to be greater than the maximal value of hssize_t. */ expo = (hssize_t)H5T__bit_get_d(s, src.u.f.epos, src.u.f.esize); /* * Calculate the true source exponent by adjusting according to * the source exponent bias. */ if (0 == expo || H5T_NORM_NONE == src.u.f.norm) { expo -= (hssize_t)(src.u.f.ebias - 1); } else if (H5T_NORM_IMPLIED == src.u.f.norm) { expo -= (hssize_t)src.u.f.ebias; } else { HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "normalization method not implemented yet"); } /* * Get the mantissa as bit vector from the section of * the source bit field where it's located. * Keep the little-endian order in the buffer. * A sequence 0x01020304 will be like in the buffer, * 04 03 02 01 * | | | | * V V V V * buf[0] buf[1] buf[2] buf[3] */ H5T__bit_copy(int_buf, (size_t)0, s, src.u.f.mpos, src.u.f.msize); /* * Restore the implicit bit for mantissa if it's implied. * Equivalent to mantissa |= (hsize_t)1<u.conv.cb_struct.func) truncated = true; if (H5T_SGN_NONE == dst.u.i.sign) { /*destination is unsigned*/ /* * Destination is unsigned. Library's default way: If the source value * is greater than the maximal destination value then it overflows, the * destination will be set to the maximum possible value. When the * source is negative, underflow happens. Set the destination to be * zero(do nothing). If user's exception handler is set, call it and * let user handle it. */ if (sign) { /*source is negative*/ if (conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_RANGE_LOW, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); else if (except_ret == H5T_CONV_HANDLED) { /*No need to reverse the order of destination because user handles it*/ reverse = false; goto next; } } } else { /*source is positive*/ if (new_msb_pos >= (ssize_t)dst.prec) { /*overflow*/ if (conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) H5T__bit_set(d, dst.offset, dst.prec, true); else if (except_ret == H5T_CONV_HANDLED) { /*No need to reverse the order of destination because user handles it*/ reverse = false; goto next; } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); } else { if (truncated && conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_TRUNCATE, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { /*copy source value into it if case is ignored by user handler*/ if (new_msb_pos >= 0) H5T__bit_copy(d, dst.offset, int_buf, (size_t)0, (size_t)new_msb_pos + 1); } else if (except_ret == H5T_CONV_HANDLED) { /*No need to reverse the order of destination because user handles it*/ reverse = false; goto next; } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); } } } else if (H5T_SGN_2 == dst.u.i.sign) { /*Destination is signed*/ if (sign) { /*source is negative*/ if ((new_msb_pos >= 0) && ((size_t)new_msb_pos < dst.prec - 1)) { if (truncated && conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_TRUNCATE, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { /*If this case ignored by user handler*/ /*Convert to integer representation. Equivalent to ~(value - 1).*/ H5T__bit_dec(int_buf, (size_t)0, dst.prec); H5T__bit_neg(int_buf, (size_t)0, dst.prec); /*copy source value into destination*/ H5T__bit_copy(d, dst.offset, int_buf, (size_t)0, dst.prec - 1); H5T__bit_set(d, (dst.offset + dst.prec - 1), (size_t)1, true); } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); else if (except_ret == H5T_CONV_HANDLED) { /*No need to reverse the order of destination because user handles it*/ reverse = false; goto next; } } else { /* if underflows and no callback, do nothing except turn on * the sign bit because 0x80...00 is the biggest negative value. */ if (conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_RANGE_LOW, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) H5T__bit_set(d, (dst.offset + dst.prec - 1), (size_t)1, true); else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); else if (except_ret == H5T_CONV_HANDLED) { /*No need to reverse the order of destination because user handles it*/ reverse = false; goto next; } } } else { /*source is positive*/ if (new_msb_pos >= (ssize_t)dst.prec - 1) { /*overflow*/ if (conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) H5T__bit_set(d, dst.offset, dst.prec - 1, true); else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); else if (except_ret == H5T_CONV_HANDLED) { /*No need to reverse the order of destination because user handles it*/ reverse = false; goto next; } } else if (new_msb_pos < (ssize_t)dst.prec - 1) { if (truncated && conv_ctx->u.conv.cb_struct .func) { /*If user's exception handler is present, use it*/ /*reverse order first*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_TRUNCATE, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_UNHANDLED) { /*copy source value into it if case is ignored by user handler*/ if (new_msb_pos >= 0) H5T__bit_copy(d, dst.offset, int_buf, (size_t)0, (size_t)new_msb_pos + 1); } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); else if (except_ret == H5T_CONV_HANDLED) { /*No need to reverse the order of destination because user handles it*/ reverse = false; goto next; } } } } padding: /* * Set padding areas in destination. */ if (dst.offset > 0) { assert(H5T_PAD_ZERO == dst.lsb_pad || H5T_PAD_ONE == dst.lsb_pad); H5T__bit_set(d, (size_t)0, dst.offset, (bool)(H5T_PAD_ONE == dst.lsb_pad)); } if (dst.offset + dst.prec != 8 * dst_p->shared->size) { assert(H5T_PAD_ZERO == dst.msb_pad || H5T_PAD_ONE == dst.msb_pad); H5T__bit_set(d, dst.offset + dst.prec, 8 * dst_p->shared->size - (dst.offset + dst.prec), (bool)(H5T_PAD_ONE == dst.msb_pad)); } /* * Put the destination in the correct byte order. See note at * beginning of loop. */ if (H5T_ORDER_BE == dst.order && reverse) { half_size = dst_p->shared->size / 2; for (i = 0; i < half_size; i++) { tmp1 = d[dst_p->shared->size - (i + 1)]; d[dst_p->shared->size - (i + 1)] = d[i]; d[i] = tmp1; } } next: /* * If we had used a temporary buffer for the destination then we * should copy the value to the true destination buffer. */ if (d == dbuf) H5MM_memcpy(dp, d, dst_p->shared->size); if (buf_stride) { sp += direction * (ssize_t)buf_stride; dp += direction * (ssize_t)buf_stride; } else { sp += direction * (ssize_t)src_p->shared->size; dp += direction * (ssize_t)dst_p->shared->size; } memset(int_buf, 0, buf_size); } break; default: HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); } /* end switch */ done: if (int_buf) H5MM_xfree(int_buf); if (src_rev) H5MM_free(src_rev); FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_f_i() */ /*------------------------------------------------------------------------- * Function: H5T__conv_i_f * * Purpose: Convert one integer type to a floating-point type. This is * the catch-all function for integer-float conversions and * is probably not particularly fast. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T__conv_i_f(H5T_t *src_p, H5T_t *dst_p, H5T_cdata_t *cdata, const H5T_conv_ctx_t *conv_ctx, size_t nelmts, size_t buf_stride, size_t H5_ATTR_UNUSED bkg_stride, void *buf, void H5_ATTR_UNUSED *bkg) { /* Traversal-related variables */ H5T_atomic_t src; /*atomic source info */ H5T_atomic_t dst; /*atomic destination info */ int direction; /*forward or backward traversal */ size_t elmtno; /*element number */ size_t half_size; /*half the type size */ size_t tsize; /*type size for swapping bytes */ size_t olap; /*num overlapping elements */ uint8_t *s, *sp, *d, *dp; /*source and dest traversal ptrs*/ uint8_t *src_rev = NULL; /*order-reversed source buffer */ uint8_t dbuf[64] = {0}; /*temp destination buffer */ uint8_t tmp1, tmp2; /*temp variables for swapping bytes*/ /* Conversion-related variables */ hsize_t expo; /*destination exponent */ hsize_t expo_max; /*maximal possible exponent value */ size_t sign; /*source sign bit value */ bool is_max_neg; /*source is maximal negative value*/ bool do_round; /*whether there is roundup */ uint8_t *int_buf = NULL; /*buffer for temporary value */ size_t buf_size; /*buffer size for temporary value */ size_t i; /*miscellaneous counters */ size_t first; /*first bit(MSB) in an integer */ ssize_t sfirst; /*a signed version of `first' */ H5T_conv_ret_t except_ret; /*return of callback function */ bool reverse; /*if reverse the order of destination */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_PACKAGE switch (cdata->command) { case H5T_CONV_INIT: if (NULL == src_p || NULL == dst_p) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); src = src_p->shared->u.atomic; dst = dst_p->shared->u.atomic; if (H5T_ORDER_LE != dst.order && H5T_ORDER_BE != dst.order && H5T_ORDER_VAX != dst.order) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unsupported byte order"); if (dst_p->shared->size > sizeof(dbuf)) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "destination size is too large"); if (8 * sizeof(expo) - 1 < src.u.f.esize) HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "exponent field is too large"); cdata->need_bkg = H5T_BKG_NO; break; case H5T_CONV_FREE: break; case H5T_CONV_CONV: if (NULL == src_p || NULL == dst_p) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a datatype"); if (NULL == conv_ctx) HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "invalid datatype conversion context pointer"); src = src_p->shared->u.atomic; dst = dst_p->shared->u.atomic; /* * Do we process the values from beginning to end or vice versa? Also, * how many of the elements have the source and destination areas * overlapping? */ if (src_p->shared->size == dst_p->shared->size || buf_stride) { sp = dp = (uint8_t *)buf; direction = 1; olap = nelmts; } else if (src_p->shared->size >= dst_p->shared->size) { double olap_d = ceil((double)(dst_p->shared->size) / (double)(src_p->shared->size - dst_p->shared->size)); olap = (size_t)olap_d; sp = dp = (uint8_t *)buf; direction = 1; } else { double olap_d = ceil((double)(src_p->shared->size) / (double)(dst_p->shared->size - src_p->shared->size)); olap = (size_t)olap_d; sp = (uint8_t *)buf + (nelmts - 1) * src_p->shared->size; dp = (uint8_t *)buf + (nelmts - 1) * dst_p->shared->size; direction = -1; } /* Allocate enough space for the buffer holding temporary * converted value */ buf_size = ((src.prec > dst.u.f.msize ? src.prec : dst.u.f.msize) + 7) / 8; int_buf = (uint8_t *)H5MM_calloc(buf_size); /* Allocate space for order-reversed source buffer */ src_rev = (uint8_t *)H5MM_calloc(src_p->shared->size); /* The conversion loop */ for (elmtno = 0; elmtno < nelmts; elmtno++) { /* Set these variables to default */ except_ret = H5T_CONV_UNHANDLED; reverse = true; /* Make sure these variables are reset to 0. */ sign = 0; /*source sign bit value */ is_max_neg = 0; /*source is maximal negative value*/ do_round = 0; /*whether there is roundup */ sfirst = 0; /* * If the source and destination buffers overlap then use a * temporary buffer for the destination. */ if (direction > 0) { s = sp; d = elmtno < olap ? dbuf : dp; } else { s = sp; d = elmtno + olap >= nelmts ? dbuf : dp; } #ifndef NDEBUG /* I don't quite trust the overlap calculations yet --rpm */ if (d == dbuf) { assert((dp >= sp && dp < sp + src_p->shared->size) || (sp >= dp && sp < dp + dst_p->shared->size)); } else { assert((dp < sp && dp + dst_p->shared->size <= sp) || (sp < dp && sp + src_p->shared->size <= dp)); } #endif /* Put the data in little endian order so our loops aren't so * complicated. We'll do all the conversion stuff assuming * little endian and then we'll fix the order at the end. */ if (H5T_ORDER_BE == src.order) { half_size = src_p->shared->size / 2; for (i = 0; i < half_size; i++) { tmp1 = s[src_p->shared->size - (i + 1)]; s[src_p->shared->size - (i + 1)] = s[i]; s[i] = tmp1; } } /* Zero-set all destination bits*/ H5T__bit_set(d, dst.offset, dst.prec, false); /* Copy source into a temporary buffer */ H5T__bit_copy(int_buf, (size_t)0, s, src.offset, src.prec); /* Find the sign bit value of the source */ if (H5T_SGN_2 == src.u.i.sign) sign = (size_t)H5T__bit_get_d(int_buf, src.prec - 1, (size_t)1); /* What is the bit position(starting from 0 as first one) for the most significant * bit(MSB) of S which is set? */ if (H5T_SGN_2 == src.u.i.sign) { sfirst = H5T__bit_find(int_buf, (size_t)0, src.prec - 1, H5T_BIT_MSB, true); if (sign && sfirst < 0) /* The case 0x80...00, which is negative with maximal value */ is_max_neg = 1; } else if (H5T_SGN_NONE == src.u.i.sign) sfirst = H5T__bit_find(int_buf, (size_t)0, src.prec, H5T_BIT_MSB, true); /* Handle special cases here. Integer is zero */ if (!sign && sfirst < 0) goto padding; /* Convert source integer if it's negative */ if (H5T_SGN_2 == src.u.i.sign && sign) { if (!is_max_neg) { /* Equivalent to ~(i - 1) */ H5T__bit_dec(int_buf, (size_t)0, buf_size * 8); H5T__bit_neg(int_buf, (size_t)0, buf_size * 8); sfirst = H5T__bit_find(int_buf, (size_t)0, src.prec - 1, H5T_BIT_MSB, true); } else { /* If it's maximal negative number 0x80...000, treat it as if it overflowed * (create a carry) to help conversion. i.e. a character type number 0x80 * is treated as 0x100. */ sfirst = (ssize_t)(src.prec - 1); is_max_neg = 0; } if (sfirst < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "zero bit not found"); /* Sign bit has been negated if bit vector isn't 0x80...00. Set all bits in front of * sign bit to 0 in the temporary buffer because they're all negated from the previous * step. */ H5T__bit_set(int_buf, src.prec, (buf_size * 8) - src.prec, 0); /* Set sign bit in destination */ H5T__bit_set_d(d, dst.u.f.sign, (size_t)1, (hsize_t)sign); } /* end if */ first = (size_t)sfirst; /* Calculate the true destination exponent by adjusting according to * the destination exponent bias. Implied and non-implied normalization * should be the same. */ if (H5T_NORM_NONE == dst.u.f.norm || H5T_NORM_IMPLIED == dst.u.f.norm) { expo = first + dst.u.f.ebias; } else { HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "normalization method not implemented yet"); } /* Handle mantissa part here */ if (H5T_NORM_IMPLIED == dst.u.f.norm) { /* Imply first bit */ H5T__bit_set(int_buf, first, (size_t)1, 0); } else if (H5T_NORM_NONE == dst.u.f.norm) { first++; } /* Roundup for mantissa */ if (first > dst.u.f.msize) { /* If the bit sequence is bigger than the mantissa part, there'll be some * precision loss. Let user's handler deal with the case if it's present */ if (conv_ctx->u.conv.cb_struct.func) { H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); /*reverse order first*/ except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_PRECISION, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); } if (except_ret == H5T_CONV_HANDLED) { reverse = false; goto padding; } else if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); /* If user's exception handler does deal with it, we do it by dropping off the * extra bits at the end and do rounding. If we have .50...0(decimal) after radix * point, we do roundup when the least significant digit before radix is odd, we do * rounddown if it's even. */ /* Check 1st dropoff bit, see if it's set. */ if (H5T__bit_get_d(int_buf, ((first - dst.u.f.msize) - 1), (size_t)1)) { /* Check all bits after 1st dropoff bit, see if any of them is set. */ if (((first - dst.u.f.msize) - 1) > 0 && H5T__bit_get_d(int_buf, (size_t)0, ((first - dst.u.f.msize) - 1))) do_round = 1; else { /* The .50...0 case */ /* Check if the least significant bit is odd. */ if (H5T__bit_get_d(int_buf, (first - dst.u.f.msize), (size_t)1)) do_round = 1; } } /* Right shift to drop off extra bits */ H5T__bit_shift(int_buf, (ssize_t)(dst.u.f.msize - first), (size_t)0, buf_size * 8); if (do_round) { H5T__bit_inc(int_buf, (size_t)0, buf_size * 8); do_round = 0; /* If integer is like 0x0ff...fff and we need to round up the * last f, we get 0x100...000. Treat this special case here. */ if (H5T__bit_get_d(int_buf, dst.u.f.msize, (size_t)1)) { if (H5T_NORM_IMPLIED == dst.u.f.norm) { /* The bit at this 1's position was impled already, so this * number should be 0x200...000. We need to increment the * exponent in this case. */ expo++; } else if (H5T_NORM_NONE == dst.u.f.norm) { /* Right shift 1 bit to let the carried 1 fit in the mantissa, * and increment exponent by 1. */ H5T__bit_shift(int_buf, (ssize_t)-1, (size_t)0, buf_size * 8); expo++; } } } } else { /* The bit sequence can fit mantissa part. Left shift to fit in from high-order of * bit position. */ H5T__bit_shift(int_buf, (ssize_t)(dst.u.f.msize - first), (size_t)0, dst.u.f.msize); } /* Check if the exponent is too big */ expo_max = (hsize_t)(pow(2.0, (double)dst.u.f.esize) - 1); if (expo > expo_max) { /*overflows*/ if (conv_ctx->u.conv.cb_struct .func) { /*user's exception handler. Reverse back source order*/ H5T__reverse_order(src_rev, s, src_p->shared->size, src_p->shared->u.atomic.order); /*reverse order first*/ except_ret = (conv_ctx->u.conv.cb_struct.func)( H5T_CONV_EXCEPT_RANGE_HI, conv_ctx->u.conv.src_type_id, conv_ctx->u.conv.dst_type_id, src_rev, d, conv_ctx->u.conv.cb_struct.user_data); if (except_ret == H5T_CONV_ABORT) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTCONVERT, FAIL, "can't handle conversion exception"); else if (except_ret == H5T_CONV_HANDLED) { reverse = false; goto padding; } } if (!conv_ctx->u.conv.cb_struct.func || (except_ret == H5T_CONV_UNHANDLED)) { /*make destination infinity by setting exponent to maximal number and *mantissa to zero.*/ expo = expo_max; memset(int_buf, 0, buf_size); } } if (except_ret == H5T_CONV_UNHANDLED) { /* Set exponent in destination */ H5T__bit_set_d(d, dst.u.f.epos, dst.u.f.esize, expo); /* Copy mantissa into destination */ H5T__bit_copy(d, dst.u.f.mpos, int_buf, (size_t)0, (buf_size * 8) > dst.u.f.msize ? dst.u.f.msize : buf_size * 8); } padding: /* * Set padding areas in destination. */ if (dst.offset > 0) { assert(H5T_PAD_ZERO == dst.lsb_pad || H5T_PAD_ONE == dst.lsb_pad); H5T__bit_set(d, (size_t)0, dst.offset, (bool)(H5T_PAD_ONE == dst.lsb_pad)); } if (dst.offset + dst.prec != 8 * dst_p->shared->size) { assert(H5T_PAD_ZERO == dst.msb_pad || H5T_PAD_ONE == dst.msb_pad); H5T__bit_set(d, dst.offset + dst.prec, 8 * dst_p->shared->size - (dst.offset + dst.prec), (bool)(H5T_PAD_ONE == dst.msb_pad)); } /* * Put the destination in the correct byte order. See note at * beginning of loop. */ if (H5T_ORDER_BE == dst.order && reverse) { half_size = dst_p->shared->size / 2; for (i = 0; i < half_size; i++) { uint8_t tmp = d[dst_p->shared->size - (i + 1)]; d[dst_p->shared->size - (i + 1)] = d[i]; d[i] = tmp; } } else if (H5T_ORDER_VAX == dst.order && reverse) { tsize = dst_p->shared->size; assert(0 == tsize % 2); for (i = 0; i < tsize; i += 4) { tmp1 = d[i]; tmp2 = d[i + 1]; d[i] = d[(tsize - 2) - i]; d[i + 1] = d[(tsize - 1) - i]; d[(tsize - 2) - i] = tmp1; d[(tsize - 1) - i] = tmp2; } } /* * If we had used a temporary buffer for the destination then we * should copy the value to the true destination buffer. */ if (d == dbuf) H5MM_memcpy(dp, d, dst_p->shared->size); if (buf_stride) { sp += direction * (ssize_t)buf_stride; dp += direction * (ssize_t)buf_stride; } else { sp += direction * (ssize_t)src_p->shared->size; dp += direction * (ssize_t)dst_p->shared->size; } memset(int_buf, 0, buf_size); } break; default: HGOTO_ERROR(H5E_DATATYPE, H5E_UNSUPPORTED, FAIL, "unknown conversion command"); } /* end switch */ done: if (int_buf) H5MM_xfree(int_buf); if (src_rev) H5MM_free(src_rev); FUNC_LEAVE_NOAPI(ret_value) } /* end H5T__conv_i_f() */ /*------------------------------------------------------------------------- * Function: H5T__reverse_order * * Purpose: Internal assisting function to reverse the order of * a sequence of byte when it's big endian or VAX order. * The byte sequence simulates the endian order. * * Return: Success: A pointer to the reversed byte sequence * * Failure: Null * *------------------------------------------------------------------------- */ static herr_t H5T__reverse_order(uint8_t *rev, uint8_t *s, size_t size, H5T_order_t order) { size_t i; FUNC_ENTER_PACKAGE_NOERR assert(s); assert(size); if (H5T_ORDER_VAX == order) { for (i = 0; i < size; i += 2) { rev[i] = s[(size - 2) - i]; rev[i + 1] = s[(size - 1) - i]; } } else if (H5T_ORDER_BE == order) { for (i = 0; i < size; i++) rev[size - (i + 1)] = s[i]; } else { for (i = 0; i < size; i++) rev[i] = s[i]; } FUNC_LEAVE_NOAPI(SUCCEED) } /*------------------------------------------------------------------------- * Function: H5T_reclaim * * Purpose: Frees the buffers allocated for storing variable-length data * in memory. Only frees the VL data in the selection defined in the * dataspace. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T_reclaim(H5T_t *type, H5S_t *space, void *buf) { H5S_sel_iter_op_t dset_op; /* Operator for iteration */ H5T_vlen_alloc_info_t vl_alloc_info; /* VL allocation info */ herr_t ret_value = FAIL; /* Return value */ FUNC_ENTER_NOAPI_NOINIT /* Check args */ assert(type); assert(space); assert(buf); /* Get the allocation info */ if (H5CX_get_vlen_alloc_info(&vl_alloc_info) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTGET, FAIL, "unable to retrieve VL allocation info"); /* Call H5S_select_iterate with args, etc. */ dset_op.op_type = H5S_SEL_ITER_OP_LIB; dset_op.u.lib_op = H5T_reclaim_cb; ret_value = H5S_select_iterate(buf, type, space, &dset_op, &vl_alloc_info); done: FUNC_LEAVE_NOAPI(ret_value) } /* end H5T_reclaim() */ /*------------------------------------------------------------------------- * Function: H5T_reclaim_cb * * Purpose: Iteration callback to reclaim conversion allocated memory for a * buffer element. * * Return: Non-negative on success/Negative on failure * *------------------------------------------------------------------------- */ herr_t H5T_reclaim_cb(void *elem, H5T_t *dt, unsigned H5_ATTR_UNUSED ndim, const hsize_t H5_ATTR_UNUSED *point, void *op_data) { herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT /* Sanity check */ assert(elem); assert(dt); if (dt->shared->type == H5T_REFERENCE) { if (H5T__ref_reclaim(elem, dt) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTFREE, FAIL, "can't reclaim ref elements"); } else { assert(op_data); /* Allow vlen reclaim to recurse into that routine */ if (H5T__vlen_reclaim(elem, dt, (H5T_vlen_alloc_info_t *)op_data) < 0) HGOTO_ERROR(H5E_DATATYPE, H5E_CANTFREE, FAIL, "can't reclaim vlen elements"); } done: FUNC_LEAVE_NOAPI(ret_value) } /* end H5T_reclaim_cb() */