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/**********************************************************************
Utilities for converting data from the database file
to the machine format.
(c) 1995 Innobase Oy
Created 11/28/1995 Heikki Tuuri
***********************************************************************/
#include "ut0mem.h"
/***********************************************************
The following function is used to store data in one byte. */
UNIV_INLINE
void
mach_write_to_1(
/*============*/
byte* b, /* in: pointer to byte where to store */
ulint n) /* in: ulint integer to be stored, >= 0, < 256 */
{
ut_ad(b);
ut_ad(n <= 0xFFUL);
b[0] = (byte)n;
}
/************************************************************
The following function is used to fetch data from one byte. */
UNIV_INLINE
ulint
mach_read_from_1(
/*=============*/
/* out: ulint integer, >= 0, < 256 */
byte* b) /* in: pointer to byte */
{
ut_ad(b);
return((ulint)(b[0]));
}
/***********************************************************
The following function is used to store data in two consecutive
bytes. We store the most significant byte to the lowest address. */
UNIV_INLINE
void
mach_write_to_2(
/*============*/
byte* b, /* in: pointer to two bytes where to store */
ulint n) /* in: ulint integer to be stored */
{
ut_ad(b);
ut_ad(n <= 0xFFFFUL);
b[0] = (byte)(n >> 8);
b[1] = (byte)(n);
}
/************************************************************
The following function is used to fetch data from 2 consecutive
bytes. The most significant byte is at the lowest address. */
UNIV_INLINE
ulint
mach_read_from_2(
/*=============*/
/* out: ulint integer */
byte* b) /* in: pointer to 2 bytes */
{
ut_ad(b);
return( ((ulint)(b[0]) << 8)
+ (ulint)(b[1])
);
}
/************************************************************
The following function is used to convert a 16-bit data item
to the canonical format, for fast bytewise equality test
against memory. */
UNIV_INLINE
uint16
mach_encode_2(
/*==========*/
/* out: 16-bit integer in canonical format */
ulint n) /* in: integer in machine-dependent format */
{
uint16 ret;
ut_ad(2 == sizeof ret);
mach_write_to_2((byte*) &ret, n);
return(ret);
}
/************************************************************
The following function is used to convert a 16-bit data item
from the canonical format, for fast bytewise equality test
against memory. */
UNIV_INLINE
ulint
mach_decode_2(
/*==========*/
/* out: integer in machine-dependent format */
uint16 n) /* in: 16-bit integer in canonical format */
{
ut_ad(2 == sizeof n);
return(mach_read_from_2((byte*) &n));
}
/***********************************************************
The following function is used to store data in 3 consecutive
bytes. We store the most significant byte to the lowest address. */
UNIV_INLINE
void
mach_write_to_3(
/*============*/
byte* b, /* in: pointer to 3 bytes where to store */
ulint n) /* in: ulint integer to be stored */
{
ut_ad(b);
ut_ad(n <= 0xFFFFFFUL);
b[0] = (byte)(n >> 16);
b[1] = (byte)(n >> 8);
b[2] = (byte)(n);
}
/************************************************************
The following function is used to fetch data from 3 consecutive
bytes. The most significant byte is at the lowest address. */
UNIV_INLINE
ulint
mach_read_from_3(
/*=============*/
/* out: ulint integer */
byte* b) /* in: pointer to 3 bytes */
{
ut_ad(b);
return( ((ulint)(b[0]) << 16)
+ ((ulint)(b[1]) << 8)
+ (ulint)(b[2])
);
}
/***********************************************************
The following function is used to store data in four consecutive
bytes. We store the most significant byte to the lowest address. */
UNIV_INLINE
void
mach_write_to_4(
/*============*/
byte* b, /* in: pointer to four bytes where to store */
ulint n) /* in: ulint integer to be stored */
{
ut_ad(b);
b[0] = (byte)(n >> 24);
b[1] = (byte)(n >> 16);
b[2] = (byte)(n >> 8);
b[3] = (byte)n;
}
/************************************************************
The following function is used to fetch data from 4 consecutive
bytes. The most significant byte is at the lowest address. */
UNIV_INLINE
ulint
mach_read_from_4(
/*=============*/
/* out: ulint integer */
byte* b) /* in: pointer to four bytes */
{
ut_ad(b);
return( ((ulint)(b[0]) << 24)
+ ((ulint)(b[1]) << 16)
+ ((ulint)(b[2]) << 8)
+ (ulint)(b[3])
);
}
/*************************************************************
Writes a ulint in a compressed form where the first byte codes the
length of the stored ulint. We look at the most significant bits of
the byte. If the most significant bit is zero, it means 1-byte storage,
else if the 2nd bit is 0, it means 2-byte storage, else if 3rd is 0,
it means 3-byte storage, else if 4th is 0, it means 4-byte storage,
else the storage is 5-byte. */
UNIV_INLINE
ulint
mach_write_compressed(
/*==================*/
/* out: compressed size in bytes */
byte* b, /* in: pointer to memory where to store */
ulint n) /* in: ulint integer (< 2^32) to be stored */
{
ut_ad(b);
if (n < 0x80UL) {
mach_write_to_1(b, n);
return(1);
} else if (n < 0x4000UL) {
mach_write_to_2(b, n | 0x8000UL);
return(2);
} else if (n < 0x200000UL) {
mach_write_to_3(b, n | 0xC00000UL);
return(3);
} else if (n < 0x10000000UL) {
mach_write_to_4(b, n | 0xE0000000UL);
return(4);
} else {
mach_write_to_1(b, 0xF0UL);
mach_write_to_4(b + 1, n);
return(5);
}
}
/*************************************************************
Returns the size of a ulint when written in the compressed form. */
UNIV_INLINE
ulint
mach_get_compressed_size(
/*=====================*/
/* out: compressed size in bytes */
ulint n) /* in: ulint integer (< 2^32) to be stored */
{
if (n < 0x80UL) {
return(1);
} else if (n < 0x4000UL) {
return(2);
} else if (n < 0x200000UL) {
return(3);
} else if (n < 0x10000000UL) {
return(4);
} else {
return(5);
}
}
/*************************************************************
Reads a ulint in a compressed form. */
UNIV_INLINE
ulint
mach_read_compressed(
/*=================*/
/* out: read integer (< 2^32) */
byte* b) /* in: pointer to memory from where to read */
{
ulint flag;
ut_ad(b);
flag = mach_read_from_1(b);
if (flag < 0x80UL) {
return(flag);
} else if (flag < 0xC0UL) {
return(mach_read_from_2(b) & 0x7FFFUL);
} else if (flag < 0xE0UL) {
return(mach_read_from_3(b) & 0x3FFFFFUL);
} else if (flag < 0xF0UL) {
return(mach_read_from_4(b) & 0x1FFFFFFFUL);
} else {
ut_ad(flag == 0xF0UL);
return(mach_read_from_4(b + 1));
}
}
/***********************************************************
The following function is used to store data in 8 consecutive
bytes. We store the most significant byte to the lowest address. */
UNIV_INLINE
void
mach_write_to_8(
/*============*/
byte* b, /* in: pointer to 8 bytes where to store */
dulint n) /* in: dulint integer to be stored */
{
ut_ad(b);
mach_write_to_4(b, ut_dulint_get_high(n));
mach_write_to_4(b + 4, ut_dulint_get_low(n));
}
/************************************************************
The following function is used to fetch data from 8 consecutive
bytes. The most significant byte is at the lowest address. */
UNIV_INLINE
dulint
mach_read_from_8(
/*=============*/
/* out: dulint integer */
byte* b) /* in: pointer to 8 bytes */
{
ulint high;
ulint low;
ut_ad(b);
high = mach_read_from_4(b);
low = mach_read_from_4(b + 4);
return(ut_dulint_create(high, low));
}
/***********************************************************
The following function is used to store data in 7 consecutive
bytes. We store the most significant byte to the lowest address. */
UNIV_INLINE
void
mach_write_to_7(
/*============*/
byte* b, /* in: pointer to 7 bytes where to store */
dulint n) /* in: dulint integer to be stored */
{
ut_ad(b);
mach_write_to_3(b, ut_dulint_get_high(n));
mach_write_to_4(b + 3, ut_dulint_get_low(n));
}
/************************************************************
The following function is used to fetch data from 7 consecutive
bytes. The most significant byte is at the lowest address. */
UNIV_INLINE
dulint
mach_read_from_7(
/*=============*/
/* out: dulint integer */
byte* b) /* in: pointer to 7 bytes */
{
ulint high;
ulint low;
ut_ad(b);
high = mach_read_from_3(b);
low = mach_read_from_4(b + 3);
return(ut_dulint_create(high, low));
}
/***********************************************************
The following function is used to store data in 6 consecutive
bytes. We store the most significant byte to the lowest address. */
UNIV_INLINE
void
mach_write_to_6(
/*============*/
byte* b, /* in: pointer to 6 bytes where to store */
dulint n) /* in: dulint integer to be stored */
{
ut_ad(b);
mach_write_to_2(b, ut_dulint_get_high(n));
mach_write_to_4(b + 2, ut_dulint_get_low(n));
}
/************************************************************
The following function is used to fetch data from 6 consecutive
bytes. The most significant byte is at the lowest address. */
UNIV_INLINE
dulint
mach_read_from_6(
/*=============*/
/* out: dulint integer */
byte* b) /* in: pointer to 7 bytes */
{
ulint high;
ulint low;
ut_ad(b);
high = mach_read_from_2(b);
low = mach_read_from_4(b + 2);
return(ut_dulint_create(high, low));
}
/*************************************************************
Writes a dulint in a compressed form (5..9 bytes). */
UNIV_INLINE
ulint
mach_dulint_write_compressed(
/*=========================*/
/* out: size in bytes */
byte* b, /* in: pointer to memory where to store */
dulint n) /* in: dulint integer to be stored */
{
ulint size;
ut_ad(b);
size = mach_write_compressed(b, ut_dulint_get_high(n));
mach_write_to_4(b + size, ut_dulint_get_low(n));
return(size + 4);
}
/*************************************************************
Returns the size of a dulint when written in the compressed form. */
UNIV_INLINE
ulint
mach_dulint_get_compressed_size(
/*============================*/
/* out: compressed size in bytes */
dulint n) /* in: dulint integer to be stored */
{
return(4 + mach_get_compressed_size(ut_dulint_get_high(n)));
}
/*************************************************************
Reads a dulint in a compressed form. */
UNIV_INLINE
dulint
mach_dulint_read_compressed(
/*========================*/
/* out: read dulint */
byte* b) /* in: pointer to memory from where to read */
{
ulint high;
ulint low;
ulint size;
ut_ad(b);
high = mach_read_compressed(b);
size = mach_get_compressed_size(high);
low = mach_read_from_4(b + size);
return(ut_dulint_create(high, low));
}
/*************************************************************
Writes a dulint in a compressed form (1..11 bytes). */
UNIV_INLINE
ulint
mach_dulint_write_much_compressed(
/*==============================*/
/* out: size in bytes */
byte* b, /* in: pointer to memory where to store */
dulint n) /* in: dulint integer to be stored */
{
ulint size;
ut_ad(b);
if (ut_dulint_get_high(n) == 0) {
return(mach_write_compressed(b, ut_dulint_get_low(n)));
}
*b = (byte)0xFF;
size = 1 + mach_write_compressed(b + 1, ut_dulint_get_high(n));
size += mach_write_compressed(b + size, ut_dulint_get_low(n));
return(size);
}
/*************************************************************
Returns the size of a dulint when written in the compressed form. */
UNIV_INLINE
ulint
mach_dulint_get_much_compressed_size(
/*=================================*/
/* out: compressed size in bytes */
dulint n) /* in: dulint integer to be stored */
{
if (0 == ut_dulint_get_high(n)) {
return(mach_get_compressed_size(ut_dulint_get_low(n)));
}
return(1 + mach_get_compressed_size(ut_dulint_get_high(n))
+ mach_get_compressed_size(ut_dulint_get_low(n)));
}
/*************************************************************
Reads a dulint in a compressed form. */
UNIV_INLINE
dulint
mach_dulint_read_much_compressed(
/*=============================*/
/* out: read dulint */
byte* b) /* in: pointer to memory from where to read */
{
ulint high;
ulint low;
ulint size;
ut_ad(b);
if (*b != (byte)0xFF) {
high = 0;
size = 0;
} else {
high = mach_read_compressed(b + 1);
size = 1 + mach_get_compressed_size(high);
}
low = mach_read_compressed(b + size);
return(ut_dulint_create(high, low));
}
/*************************************************************
Reads a double. It is stored in a little-endian format. */
UNIV_INLINE
double
mach_double_read(
/*=============*/
/* out: double read */
byte* b) /* in: pointer to memory from where to read */
{
double d;
ulint i;
byte* ptr;
ptr = (byte*)&d;
for (i = 0; i < sizeof(double); i++) {
#ifdef WORDS_BIGENDIAN
ptr[sizeof(double) - i - 1] = b[i];
#else
ptr[i] = b[i];
#endif
}
return(d);
}
/*************************************************************
Writes a double. It is stored in a little-endian format. */
UNIV_INLINE
void
mach_double_write(
/*==============*/
byte* b, /* in: pointer to memory where to write */
double d) /* in: double */
{
ulint i;
byte* ptr;
ptr = (byte*)&d;
for (i = 0; i < sizeof(double); i++) {
#ifdef WORDS_BIGENDIAN
b[i] = ptr[sizeof(double) - i - 1];
#else
b[i] = ptr[i];
#endif
}
}
/*************************************************************
Reads a float. It is stored in a little-endian format. */
UNIV_INLINE
float
mach_float_read(
/*============*/
/* out: float read */
byte* b) /* in: pointer to memory from where to read */
{
float d;
ulint i;
byte* ptr;
ptr = (byte*)&d;
for (i = 0; i < sizeof(float); i++) {
#ifdef WORDS_BIGENDIAN
ptr[sizeof(float) - i - 1] = b[i];
#else
ptr[i] = b[i];
#endif
}
return(d);
}
/*************************************************************
Writes a float. It is stored in a little-endian format. */
UNIV_INLINE
void
mach_float_write(
/*=============*/
byte* b, /* in: pointer to memory where to write */
float d) /* in: float */
{
ulint i;
byte* ptr;
ptr = (byte*)&d;
for (i = 0; i < sizeof(float); i++) {
#ifdef WORDS_BIGENDIAN
b[i] = ptr[sizeof(float) - i - 1];
#else
b[i] = ptr[i];
#endif
}
}
/*************************************************************
Reads a ulint stored in the little-endian format. */
UNIV_INLINE
ulint
mach_read_from_n_little_endian(
/*===========================*/
/* out: unsigned long int */
byte* buf, /* in: from where to read */
ulint buf_size) /* in: from how many bytes to read */
{
ulint n = 0;
byte* ptr;
ut_ad(buf_size <= sizeof(ulint));
ut_ad(buf_size > 0);
ptr = buf + buf_size;
for (;;) {
ptr--;
n = n << 8;
n += (ulint)(*ptr);
if (ptr == buf) {
break;
}
}
return(n);
}
/*************************************************************
Writes a ulint in the little-endian format. */
UNIV_INLINE
void
mach_write_to_n_little_endian(
/*==========================*/
byte* dest, /* in: where to write */
ulint dest_size, /* in: into how many bytes to write */
ulint n) /* in: unsigned long int to write */
{
byte* end;
ut_ad(dest_size <= sizeof(ulint));
ut_ad(dest_size > 0);
end = dest + dest_size;
for (;;) {
*dest = (byte)(n & 0xFF);
n = n >> 8;
dest++;
if (dest == end) {
break;
}
}
ut_ad(n == 0);
}
/*************************************************************
Reads a ulint stored in the little-endian format. */
UNIV_INLINE
ulint
mach_read_from_2_little_endian(
/*===========================*/
/* out: unsigned long int */
byte* buf) /* in: from where to read */
{
return((ulint)(*buf) + ((ulint)(*(buf + 1))) * 256);
}
/*************************************************************
Writes a ulint in the little-endian format. */
UNIV_INLINE
void
mach_write_to_2_little_endian(
/*==========================*/
byte* dest, /* in: where to write */
ulint n) /* in: unsigned long int to write */
{
ut_ad(n < 256 * 256);
*dest = (byte)(n & 0xFFUL);
n = n >> 8;
dest++;
*dest = (byte)(n & 0xFFUL);
}
/*************************************************************
Convert integral type from storage byte order (big endian) to
host byte order. */
UNIV_INLINE
void
mach_read_int_type(
/*===============*/
byte* dest, /* out: where to write */
const byte* src, /* in: where to read from */
ulint len, /* in: length of src */
ibool unsigned_type) /* in: signed or unsigned flag */
{
#ifdef WORDS_BIGENDIAN
memcpy(dest, src, len);
if (!unsigned_type) {
dest[0] ^= 128;
}
#else
byte* ptr;
/* Convert integer data from Innobase to a little-endian format,
sign bit restored to normal. */
for (ptr = dest + len; ptr != dest; ++src) {
--ptr;
*ptr = *src;
}
if (!unsigned_type) {
dest[len - 1] ^= 128;
}
#endif
}
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