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/* Copyright (c) 2008 PrimeBase Technologies GmbH, Germany
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* PrimeBase Media Stream for MySQL
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
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* Original author: Paul McCullagh (H&G2JCtL)
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* Continued development: Barry Leslie
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* Common definitions that may be required be included at the
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* top of every header file.
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#include <sys/types.h>
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// Use standard portable data types
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* An unsigned integer, 1 byte long:
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#define u_char unsigned char
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* An usigned integer, 1 byte long:
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#define s_char unsigned char
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/* PBMS assumes that off_t is 8 bytes so to ensure this always use off64_t*/
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#define off64_t uint64_t
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* A signed integer at least 32 bits long.
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* The size used is whatever is most
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* convenient to the machine.
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#define s_int int_fast32_t
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/* Forward declartion of a thread: */
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#define CS_DEFAULT_EOL "\r\n"
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#define CS_DIR_CHAR '\\'
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#define CS_DIR_DELIM "\\"
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#define IS_DIR_CHAR(ch) ((ch) == CS_DIR_CHAR || (ch) == '/')
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#define CS_DEFAULT_EOL "\n"
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#define CS_DIR_CHAR '/'
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#define CS_DIR_DELIM "/"
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#define IS_DIR_CHAR(ch) ((ch) == CS_DIR_CHAR)
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#define CS_CALL_STACK_SIZE 100
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#define CS_RELEASE_STACK_SIZE 200
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#define CS_JUMP_STACK_SIZE 20
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/* Fixed length types */
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#define PATH_MAX MAX_PATH
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#define NAME_MAX MAX_PATH
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/* C string display width sizes including space for a null terminator and possible sign. */
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#define CS_WIDTH_INT_8 5
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#define CS_WIDTH_INT_16 7
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#define CS_WIDTH_INT_32 12
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#define CS_WIDTH_INT_64 22
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typedef uint8_t CSDiskValue1[1];
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typedef uint8_t CSDiskValue2[2];
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typedef uint8_t CSDiskValue3[3];
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typedef uint8_t CSDiskValue4[4];
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typedef uint8_t CSDiskValue6[6];
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typedef uint8_t CSDiskValue8[8];
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* Byte order on the disk is little endian! This is the byte order of the i386.
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* Little endian byte order starts with the least significan byte.
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* The reason for choosing this byte order for the disk is 2-fold:
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* Firstly the i386 is the cheapest and fasted platform today.
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* Secondly the i386, unlike RISK chips (with big endian) can address
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* memory that is not aligned!
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* Since the disk image of PrimeBase XT is not aligned, the second point
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* is significant. A RISK chip needs to access it byte-wise, so we might as
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* well do the byte swapping at the same time.
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* The macros below are of 4 general types:
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* GET/SET - Get and set 1,2,4,8 byte values (short, int, long, etc).
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* Values are swapped only on big endian platforms. This makes these
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* functions very efficient on little-endian platforms.
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* COPY - Transfer data without swapping regardless of platform. This
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* function is a bit more efficient on little-endian platforms
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* because alignment is not an issue.
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* MOVE - Similar to get and set, but the deals with memory instead
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* of values. Since no swapping is done on little-endian platforms
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* this function is identical to COPY on little-endian platforms.
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* SWAP - Transfer and swap data regardless of the platform type.
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* Aligment is not assumed.
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* The DISK component of the macro names indicates that alignment of
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* the value cannot be assumed.
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#if BYTE_ORDER == BIG_ENDIAN
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/* The native order of the machine is big endian. Since the native disk
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* disk order of XT is little endian, all data to and from disk
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#define CS_SET_DISK_1(d, s) ((d)[0] = (uint8_t) (s))
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#define CS_SET_DISK_2(d, s) do { (d)[0] = (uint8_t) (((uint16_t) (s)) & 0xFF); (d)[1] = (uint8_t) ((((uint16_t) (s)) >> 8 ) & 0xFF); } while (0)
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#define CS_SET_DISK_3(d, s) do { (d)[0] = (uint8_t) (((uint32_t) (s)) & 0xFF); (d)[1] = (uint8_t) ((((uint32_t) (s)) >> 8 ) & 0xFF); \
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(d)[2] = (uint8_t) ((((uint32_t) (s)) >> 16) & 0xFF); } while (0)
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#define CS_SET_DISK_4(d, s) do { (d)[0] = (uint8_t) (((uint32_t) (s)) & 0xFF); (d)[1] = (uint8_t) ((((uint32_t) (s)) >> 8 ) & 0xFF); \
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(d)[2] = (uint8_t) ((((uint32_t) (s)) >> 16) & 0xFF); (d)[3] = (uint8_t) ((((uint32_t) (s)) >> 24) & 0xFF); } while (0)
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#define CS_SET_DISK_6(d, s) do { (d)[0] = (uint8_t) (((uint64_t) (s)) & 0xFF); (d)[1] = (uint8_t) ((((uint64_t) (s)) >> 8 ) & 0xFF); \
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(d)[2] = (uint8_t) ((((uint64_t) (s)) >> 16) & 0xFF); (d)[3] = (uint8_t) ((((uint64_t) (s)) >> 24) & 0xFF); \
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(d)[4] = (uint8_t) ((((uint64_t) (s)) >> 32) & 0xFF); (d)[5] = (uint8_t) ((((uint64_t) (s)) >> 40) & 0xFF); } while (0)
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#define CS_SET_DISK_8(d, s) do { (d)[0] = (uint8_t) (((uint64_t) (s)) & 0xFF); (d)[1] = (uint8_t) ((((uint64_t) (s)) >> 8 ) & 0xFF); \
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(d)[2] = (uint8_t) ((((uint64_t) (s)) >> 16) & 0xFF); (d)[3] = (uint8_t) ((((uint64_t) (s)) >> 24) & 0xFF); \
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(d)[4] = (uint8_t) ((((uint64_t) (s)) >> 32) & 0xFF); (d)[5] = (uint8_t) ((((uint64_t) (s)) >> 40) & 0xFF); \
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(d)[6] = (uint8_t) ((((uint64_t) (s)) >> 48) & 0xFF); (d)[7] = (uint8_t) ((((uint64_t) (s)) >> 56) & 0xFF); } while (0)
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#define CS_GET_DISK_1(s) ((s)[0])
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#define CS_GET_DISK_2(s) ((uint16_t) (((uint16_t) (s)[0]) | (((uint16_t) (s)[1]) << 8)))
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#define CS_GET_DISK_3(s) ((uint32_t) (((uint32_t) (s)[0]) | (((uint32_t) (s)[1]) << 8) | (((uint32_t) (s)[2]) << 16)))
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#define CS_GET_DISK_4(s) (((uint32_t) (s)[0]) | (((uint32_t) (s)[1]) << 8 ) | \
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(((uint32_t) (s)[2]) << 16) | (((uint32_t) (s)[3]) << 24))
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#define CS_GET_DISK_6(s) (((uint64_t) (s)[0]) | (((uint64_t) (s)[1]) << 8 ) | \
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(((uint64_t) (s)[2]) << 16) | (((uint64_t) (s)[3]) << 24) | \
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(((uint64_t) (s)[4]) << 32) | (((uint64_t) (s)[5]) << 40))
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#define CS_GET_DISK_8(s) (((uint64_t) (s)[0]) | (((uint64_t) (s)[1]) << 8 ) | \
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(((uint64_t) (s)[2]) << 16) | (((uint64_t) (s)[3]) << 24) | \
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(((uint64_t) (s)[4]) << 32) | (((uint64_t) (s)[5]) << 40) | \
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(((uint64_t) (s)[6]) << 48) | (((uint64_t) (s)[7]) << 56))
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/* Move will copy memory, and swap the bytes on a big endian machine.
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* On a little endian machine it is the same as COPY.
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#define CS_MOVE_DISK_1(d, s) ((d)[0] = (s)[0])
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#define CS_MOVE_DISK_2(d, s) do { (d)[0] = (s)[1]; (d)[1] = (s)[0]; } while (0)
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#define CS_MOVE_DISK_3(d, s) do { (d)[0] = (s)[2]; (d)[1] = (s)[1]; (d)[2] = (s)[0]; } while (0)
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#define CS_MOVE_DISK_4(d, s) do { (d)[0] = (s)[3]; (d)[1] = (s)[2]; (d)[2] = (s)[1]; (d)[3] = (s)[0]; } while (0)
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#define CS_MOVE_DISK_8(d, s) do { (d)[0] = (s)[7]; (d)[1] = (s)[6]; \
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(d)[2] = (s)[5]; (d)[3] = (s)[4]; \
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(d)[4] = (s)[3]; (d)[5] = (s)[2]; \
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(d)[6] = (s)[1]; (d)[7] = (s)[0]; } while (0)
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* Copy just copies the number of bytes assuming the data is not alligned.
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#define CS_COPY_DISK_1(d, s) (d)[0] = s
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#define CS_COPY_DISK_2(d, s) do { (d)[0] = (s)[0]; (d)[1] = (s)[1]; } while (0)
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#define CS_COPY_DISK_3(d, s) do { (d)[0] = (s)[0]; (d)[1] = (s)[1]; (d)[2] = (s)[2]; } while (0)
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#define CS_COPY_DISK_4(d, s) do { (d)[0] = (s)[0]; (d)[1] = (s)[1]; (d)[2] = (s)[2]; (d)[3] = (s)[3]; } while (0)
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#define CS_COPY_DISK_6(d, s) memcpy(&((d)[0]), &((s)[0]), 6)
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#define CS_COPY_DISK_8(d, s) memcpy(&((d)[0]), &((s)[0]), 8)
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#define CS_COPY_DISK_10(d, s) memcpy(&((d)[0]), &((s)[0]), 10)
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#define CS_SET_NULL_DISK_1(d) CS_SET_DISK_1(d, 0)
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#define CS_SET_NULL_DISK_2(d) do { (d)[0] = 0; (d)[1] = 0; } while (0)
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#define CS_SET_NULL_DISK_4(d) do { (d)[0] = 0; (d)[1] = 0; (d)[2] = 0; (d)[3] = 0; } while (0)
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#define CS_SET_NULL_DISK_6(d) do { (d)[0] = 0; (d)[1] = 0; (d)[2] = 0; (d)[3] = 0; (d)[4] = 0; (d)[5] = 0; } while (0)
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#define CS_SET_NULL_DISK_8(d) do { (d)[0] = 0; (d)[1] = 0; (d)[2] = 0; (d)[3] = 0; (d)[4] = 0; (d)[5] = 0; (d)[6] = 0; (d)[7] = 0; } while (0)
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#define CS_IS_NULL_DISK_1(d) (!(CS_GET_DISK_1(d)))
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#define CS_IS_NULL_DISK_4(d) (!(d)[0] && !(d)[1] && !(d)[2] && !(d)[3])
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#define CS_IS_NULL_DISK_8(d) (!(d)[0] && !(d)[1] && !(d)[2] && !(d)[3] && !(d)[4] && !(d)[5] && !(d)[6] && !(7)[3])
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#define CS_EQ_DISK_4(d, s) ((d)[0] == (s)[0] && (d)[1] == (s)[1] && (d)[2] == (s)[2] && (d)[3] == (s)[3])
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#define CS_EQ_DISK_8(d, s) ((d)[0] == (s)[0] && (d)[1] == (s)[1] && (d)[2] == (s)[2] && (d)[3] == (s)[3] && \
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(d)[4] == (s)[4] && (d)[5] == (s)[5] && (d)[6] == (s)[6] && (d)[7] == (s)[7])
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#define CS_IS_FF_DISK_4(d) ((d)[0] == 0xFF && (d)[1] == 0xFF && (d)[2] == 0xFF && (d)[3] == 0xFF)
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* The native order of the machine is little endian. This means the data to
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* and from disk need not be swapped. In addition to this, since
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* the i386 can access non-aligned memory we are not required to
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* handle the data byte-for-byte.
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#define CS_SET_DISK_1(d, s) ((d)[0] = (uint8_t) (s))
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#define CS_SET_DISK_2(d, s) (*((uint16_t *) &((d)[0])) = (uint16_t) (s))
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#define CS_SET_DISK_3(d, s) do { (*((uint16_t *) &((d)[0])) = (uint16_t) (s)); *((uint8_t *) &((d)[2])) = (uint8_t) (((uint32_t) (s)) >> 16); } while (0)
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#define CS_SET_DISK_4(d, s) (*((uint32_t *) &((d)[0])) = (uint32_t) (s))
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#define CS_SET_DISK_6(d, s) do { *((uint32_t *) &((d)[0])) = (uint32_t) (s); *((uint16_t *) &((d)[4])) = (uint16_t) (((uint64_t) (s)) >> 32); } while (0)
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#define CS_SET_DISK_8(d, s) (*((uint64_t *) &((d)[0])) = (uint64_t) (s))
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#define CS_GET_DISK_1(s) ((s)[0])
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#define CS_GET_DISK_2(s) *((uint16_t *) &((s)[0]))
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#define CS_GET_DISK_3(s) ((uint32_t) *((uint16_t *) &((s)[0])) | (((uint32_t) *((uint8_t *) &((s)[2]))) << 16))
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#define CS_GET_DISK_4(s) *((uint32_t *) &((s)[0]))
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#define CS_GET_DISK_6(s) ((uint64_t) *((uint32_t *) &((s)[0])) | (((uint64_t) *((uint16_t *) &((s)[4]))) << 32))
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#define CS_GET_DISK_8(s) *((uint64_t *) &((s)[0]))
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#define CS_MOVE_DISK_1(d, s) ((d)[0] = (s)[0])
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#define CS_MOVE_DISK_2(d, s) CS_COPY_DISK_2(d, s)
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#define CS_MOVE_DISK_3(d, s) CS_COPY_DISK_3(d, s)
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#define CS_MOVE_DISK_4(d, s) CS_COPY_DISK_4(d, s)
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#define CS_MOVE_DISK_8(d, s) CS_COPY_DISK_8(d, s)
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#define CS_COPY_DISK_1(d, s) (d)[0] = s
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#define CS_COPY_DISK_2(d, s) (*((uint16_t *) &((d)[0])) = (*((uint16_t *) &((s)[0]))))
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#define CS_COPY_DISK_3(d, s) do { *((uint16_t *) &((d)[0])) = *((uint16_t *) &((s)[0])); (d)[2] = (s)[2]; } while (0)
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#define CS_COPY_DISK_4(d, s) (*((uint32_t *) &((d)[0])) = (*((uint32_t *) &((s)[0]))))
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#define CS_COPY_DISK_6(d, s) do { *((uint32_t *) &((d)[0])) = *((uint32_t *) &((s)[0])); *((uint16_t *) &((d)[4])) = *((uint16_t *) &((s)[4])); } while (0)
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#define CS_COPY_DISK_8(d, s) (*((uint64_t *) &(d[0])) = (*((uint64_t *) &((s)[0]))))
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#define CS_COPY_DISK_10(d, s) memcpy(&((d)[0]), &((s)[0]), 10)
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#define CS_SET_NULL_DISK_1(d) CS_SET_DISK_1(d, 0)
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#define CS_SET_NULL_DISK_2(d) CS_SET_DISK_2(d, 0)
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#define CS_SET_NULL_DISK_3(d) CS_SET_DISK_3(d, 0)
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#define CS_SET_NULL_DISK_4(d) CS_SET_DISK_4(d, 0L)
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#define CS_SET_NULL_DISK_6(d) CS_SET_DISK_6(d, 0LL)
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#define CS_SET_NULL_DISK_8(d) CS_SET_DISK_8(d, 0LL)
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#define CS_IS_NULL_DISK_1(d) (!(CS_GET_DISK_1(d)))
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#define CS_IS_NULL_DISK_2(d) (!(CS_GET_DISK_2(d)))
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#define CS_IS_NULL_DISK_3(d) (!(CS_GET_DISK_3(d)))
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#define CS_IS_NULL_DISK_4(d) (!(CS_GET_DISK_4(d)))
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#define CS_IS_NULL_DISK_8(d) (!(CS_GET_DISK_8(d)))
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#define CS_EQ_DISK_4(d, s) (CS_GET_DISK_4(d) == CS_GET_DISK_4(s))
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#define CS_EQ_DISK_8(d, s) (CS_GET_DISK_8(d) == CS_GET_DISK_8(s))
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#define CS_IS_FF_DISK_4(d) (CS_GET_DISK_4(d) == 0xFFFFFFFF)
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#define CS_CMP_DISK_4(a, b) ((int32_t) CS_GET_DISK_4(a) - (int32_t) CS_GET_DISK_4(b))
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#define CS_CMP_DISK_8(d, s) memcmp(&((d)[0]), &((s)[0]), 8)
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//#define CS_CMP_DISK_8(d, s) (CS_CMP_DISK_4((d).h_number_4, (s).h_number_4) == 0 ? CS_CMP_DISK_4((d).h_file_4, (s).h_file_4) : CS_CMP_DISK_4((d).h_number_4, (s).h_number_4))
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#define CS_SWAP_DISK_2(d, s) do { (d)[0] = (s)[1]; (d)[1] = (s)[0]; } while (0)
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#define CS_SWAP_DISK_3(d, s) do { (d)[0] = (s)[2]; (d)[1] = (s)[1]; (d)[2] = (s)[0]; } while (0)
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#define CS_SWAP_DISK_4(d, s) do { (d)[0] = (s)[3]; (d)[1] = (s)[2]; (d)[2] = (s)[1]; (d)[3] = (s)[0]; } while (0)
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#define CS_SWAP_DISK_8(d, s) do { (d)[0] = (s)[7]; (d)[1] = (s)[6]; (d)[2] = (s)[5]; (d)[3] = (s)[4]; \
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(d)[4] = (s)[3]; (d)[5] = (s)[2]; (d)[6] = (s)[1]; (d)[7] = (s)[0]; } while (0)
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} CSIntRec, *CSIntPtr;
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const char *rec_cchars;
added
removed
plugin/pbms/src/cslib/CSDefs.h
