/* * * (c) Copyright 1989 OPEN SOFTWARE FOUNDATION, INC. * (c) Copyright 1989 HEWLETT-PACKARD COMPANY * (c) Copyright 1989 DIGITAL EQUIPMENT CORPORATION * To anyone who acknowledges that this file is provided "AS IS" * without any express or implied warranty: * permission to use, copy, modify, and distribute this * file for any purpose is hereby granted without fee, provided that * the above copyright notices and this notice appears in all source * code copies, and that none of the names of Open Software * Foundation, Inc., Hewlett-Packard Company, or Digital Equipment * Corporation be used in advertising or publicity pertaining to * distribution of the software without specific, written prior * permission. Neither Open Software Foundation, Inc., Hewlett- * Packard Company, nor Digital Equipment Corporation makes any * representations about the suitability of this software for any * purpose. * */ /* ** ** NAME: ** ** upkibml.c.h ** ** FACILITY: ** ** IDL Stub Runtime Support ** ** ABSTRACT: ** ** This module contains code to extract information from an IBM ** long floating number and to initialize an UNPACKED_REAL structure ** with those bits. ** ** This module is meant to be used as an include file. ** ** VERSION: DCE 1.0 ** */ #if HAVE_CONFIG_H #include #endif /* **++ ** Functional Description: ** ** This module contains code to extract information from an IBM ** long floating number and to initialize an UNPACKED_REAL structure ** with those bits. ** ** See the header files for a description of the UNPACKED_REAL ** structure. ** ** A normalized IBM long floating number looks like: ** ** [0]: Sign bit, 7 exp bits (bias 64), 24 fraction bits ** [1]: 32 low order fraction bits ** ** 0.0625 <= fraction < 1.0, from 0 to 3 leading zeros ** to compensate for the hexadecimal exponent. ** ** ** Implicit parameters: ** ** input_value: a pointer to the input parameter. ** ** r: an UNPACKED_REAL structure. ** ** i: a temporary integer variable. ** **-- */ #if (NDR_LOCAL_INT_REP == ndr_c_int_big_endian) memcpy(&r[1], input_value, 8); #if (defined(_IBMR2) && defined(_AIX)) || \ (defined(__hppa) && defined(__hpux)) { idl_ulong_int tmp; tmp = r[1]; r[1] = r[2]; r[2] = tmp; } #endif #else memcpy(r, input_value, 8); /* Shuffle bytes to little endian format */ r[2] = ((r[1] << 24) | (r[1] >> 24)); r[2] |= ((r[1] << 8) & 0x00FF0000L); r[2] |= ((r[1] >> 8) & 0x0000FF00L); r[1] = ((r[0] << 24) | (r[0] >> 24)); r[1] |= ((r[0] << 8) & 0x00FF0000L); r[1] |= ((r[0] >> 8) & 0x0000FF00L); #endif /* Initialize FLAGS and perhaps set NEGATIVE bit */ r[U_R_FLAGS] = (r[1] >> 31); /* Clear sign bit */ r[1] &= 0x7FFFFFFFL; if ((r[1] == 0) && (r[2] == 0)) { r[U_R_FLAGS] |= U_R_ZERO; } else { /* Get unbiased hexadecimal exponent and convert it to binary */ r[U_R_EXP] = U_R_BIAS + (((r[1] >> 24) - 64) * 4); /* Count leading zeros */ i = 0; while (!(r[1] & 0x00800000L)) { i += 1; if (i > 3) break; r[1] <<= 1; } if (i > 3) { r[U_R_FLAGS] |= U_R_INVALID; } else { /* Adjust exponent to compensate for leading zeros */ r[U_R_EXP] -= i; /* Left justify fraction bits */ r[1] <<= 8; i += 8; r[1] |= (r[2] >> (32 - i)); r[2] <<= i; /* Clear uninitialized part of unpacked real */ r[3] = 0; r[4] = 0; } }