source: source/ariba/utility/serialization/DataUtilities.hpp@ 6828

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/* This file implements some common bit operations for unsigned integer types

 * and arrays. There are two different approaches in indexing bits inside arrays

 * and integrals:

 *

 * In simple integer types the least significant bit (LSB) is identified by index zero.

 * A length is specified from the LSB to the MSB. On the other hand, there is an

 * inverted form of this representation. In this case, the MSB is identfied by index

 * zero and the length identifies a range from the MSB to the LSB.

 *

 *                   Normal                      Inverted

 *             MSB            LSB           MSB            LSB

 *              v              v             v              v

 *             +----------------+           +----------------+

 *             | uint16_t       |           | uint16_t       |

 *             +----------------+           +----------------+

 *              ^              ^             ^              ^

 *     Index   15              0             0              15

 *     Length          |<------+             +----->|

 *

 * Inside arrays the inverted form is used. Therefore an index of zero identifies the

 * MSB of the first word in the array.

 *

 * TODO: TBC

 */

#ifndef DATAUTILITIES_HPP_

#define DATAUTILITIES_HPP_



#include "../internal/Utilities.hpp"



#include <boost/cstdint.hpp>



#include <memory>

#include <string>



template<typename X> finline

static X shr( const X& value, unsigned int bits ) {

        return (sizeof(X)*8 == bits) ? 0 : (value >> bits);

}



template<typename X> finline

static X shl( const X& value, unsigned int bits ) {

        return (sizeof(X)*8 == bits) ? 0 : (value << bits);

}



/**

 * TODO: Doc

 */

template<typename X> finline

static X bitblk(size_t index, size_t length, bool value, if_uint(X)) {

        if (index == 0 && length >= sizeof(X) * 8) return value ? ~0 : 0;

        X x = shl(( shl( ((X) 1), length) - 1), index);

        return value ? x : ~x;

}



/**

 * TODO: Doc

 */

template<typename X, bool value> finline

static X bitblk(size_t index, size_t length, if_uint(X)) {

        return bitblk<X> (index, length, value);

}



/**

 * TODO: Doc

 */

template<typename X, bool value> finline

static X bitblk(size_t length, if_uint(X)) {

        if (length >= sizeof(X) * 8) return value ? ~0 : 0;

        return value ? (((X) 1 << length) - 1) : ~(((X) 1 << length) - 1);

}



/**

 * This method copies bits from one integral to another

 */

template<typename X, typename Y> finline

static Y bitcpy(X src, size_t srcIdx, Y dst, size_t dstIdx, size_t len =

                sizeof(X) * 8, bool srcInvert = false, bool dstInvert = false,

                if_uint(X),if_uint (Y) ) {

        if (srcInvert) srcIdx = sizeof(X) * 8 - srcIdx - len;

        if (dstInvert) dstIdx = sizeof(Y) * 8 - dstIdx - len;

        Y value = ((Y)shr(src, srcIdx)) << dstIdx;

        Y mask = bitblk<Y, 0> (dstIdx, len);

        return (dst & mask) | (value & ~mask);

}



/**

 * This method copies bits from an array to another of the same

 * integral type.

 */

template<typename X> finline

static void bitcpy(X* src, size_t srcIdx, X* dst, size_t dstIdx, size_t len) {



        // word width

        const size_t w = sizeof(X) * 8;



        // calculate indexes

        size_t dwp = dstIdx % w, swp = srcIdx % w;

        size_t idwp = w - dwp, iswp = w - swp;

        dst += dstIdx / w;

        src += srcIdx / w;



        // check direct copy

        if (dwp == 0 && swp == 0 && len % w == 0) {

                memcpy(dst, src, len / 8);

                return;

        }



        // check if first word only is affected

        if ((dwp + len) <= w) {

                X fw = shl(src[0],swp) | shr(src[1],iswp);

                *dst = bitcpy(fw, 0, *dst, dwp, len, true, true);

                return;

        }



        // set first word

        if (idwp != 0) {

                X fw = shl(src[0],swp) | shr(src[1],iswp);

                *dst = (*dst & ~(((X) 1 << idwp) - 1)) | shr(fw,dwp);



                // recalculate indexes & lengths

                dst++;

                src++;

                len -= idwp;

                swp = (swp + idwp) % w;

                iswp = w - swp;

        }



        X a, b;



        // copy whole words

        if (swp == 0) {

                size_t numWords = len / w;

                // use memory copy

                memcpy(dst, src, numWords * sizeof(X));

                src += numWords;

                dst += numWords;

                len = len % w;

                a = src[0], b = src[1];

        } else {

                // use shifted copy

                a = src[0], b = src[1];

                while (len >= w) {

                        *dst = shl(a,swp) | shr(b,iswp);

                        dst++;

                        src++;

                        len -= w;

                        a = b;

                        b = *src;

                }

        }



        // set last word

        X lw = shl(a,swp) | shr(b,iswp), lm = (shl((X) 1,(w - len)) - 1);

        *dst = (*dst & lm) | (lw & ~lm);

}







/**

 * array -> integral

 */

template<typename X, typename Y> finline

static void bitcpy(X* src, size_t srcIdx, Y& dst, size_t dstIdx, size_t len =

                sizeof(Y) * 8, if_uint(Y),if_uint (X) ) {



        // word width

                const size_t w = sizeof(X) * 8;



                // calculate indexes

                size_t swp = srcIdx % w, iswp = w - swp;

                src += srcIdx / w;



                // mask off bits

                dst &= bitblk<Y,0>(dstIdx,len);



                // copy whole words

                X a = src[0], b = src[1];

                Y value = 0;

                src++;

                while (len >= w) {

                        X x = shl(a,swp) | shr(b,iswp);

                        value <<= w;

                        value |= x;

                        src++;

                        len -= w;

                        a = b; b = *src;

                }



                // copy leftover

                if ( len> 0 ) {

                        value <<= len;

                        value |= ((shl(a,swp) | shr(b,iswp)) >> (w - len)) & (shl(1,len)-1);

                }



                // set value

                dst |= (value << dstIdx);

        }



/**

 * TODO: Doc

 */

// word -> array

template<typename X> finline

static void bitcpy(X src, size_t srcIdx, X* dst, size_t dstIdx, size_t len =

                sizeof(X) * 8, bool srcInvert = false, if_uint(X)) {



        // check inversion

        if (srcInvert) srcIdx = sizeof(X) * 8 - srcIdx - len;



        // word width

        const size_t w = sizeof(X) * 8;



        // calculate indexes

        size_t dwp = dstIdx % w;

        dst += dstIdx / w;



        // copy directly

        if (dwp == 0 && srcIdx == 0 && len == w) {

                *dst = src;

        } else



        // copy non-overlapping word

        if ((dwp + len) <= w) {

                *dst = bitcpy(src, srcIdx, *dst, dwp, len, false, true);



                // copy overlapping word

        } else {

                size_t idwp = w - dwp;

                src >>= srcIdx;

                X mask1 = ~(shl(1,idwp) - 1);

                dst[0] = (dst[0] & mask1) | (shr(src,(len - idwp)) & ~mask1);

                X mask2 = shl(1,(w - len + idwp)) - 1;

                dst[1] = (dst[1] & mask2) | (shl(src, (w - len + idwp)) & ~mask2);

        }

}



/**

 * TODO: Doc

 */

// integral -> array

template<typename Y, typename X> finline

static void bitcpy(Y src, size_t srcIdx, X* dst, size_t dstIdx, size_t len =

                sizeof(Y) * 8, bool srcInvert = false, if_uint(X),if_uint (Y) ) {



        if (sizeof(Y) <= sizeof(X)) {

                // check inversion

                if (srcInvert)

                srcIdx = sizeof(Y) * 8 - srcIdx - len + (sizeof(X)-sizeof(Y))*8;

                bitcpy((X)src,srcIdx,dst,dstIdx,len,false);

        } else {

                // check inversion

                if (srcInvert) srcIdx = sizeof(Y) * 8 - srcIdx - len;

                src = shr(src, srcIdx);



                const size_t dw = sizeof(X)*8;

                while (len >= dw) {

                        X word = (X)shr(src,(len-dw));

                        bitcpy(word,0,dst,dstIdx,dw);

                        dstIdx += dw;

                        len -= dw;

                }

                X word = (X)src;

                bitcpy(word,0,dst,dstIdx,len);

        }

}



/**

 * TODO: Doc

 */

template<typename T, typename X> finline

static T bitget(X* src, size_t idx, size_t len = sizeof(T) * 8, if_uint(X),if_uint (T) ) {

        T x = 0;

        bitcpy(src, idx, x, 0, len );

        return x;

}



/**

 * TODO: Doc

 */

template<typename T, typename X> finline

static T bitget(X src, size_t idx, size_t len = sizeof(T) * 8, if_uint(X),if_uint (T) ) {

        T x = 0;

        bitcpy(src, idx, x, 0, len );

        return x;

}



/**

 * TODO: Doc

 */

template<typename X> finline

static bool bitget(X* src, size_t index, if_uint(X)) {

        uint8_t x = 0;

        bitcpy(src, index, x, 0, 1);

        return x != 0;

}



/**

 * TODO: Doc

 */

template<typename X> finline

static bool bitget(X src, size_t index, if_uint(X)) {

        uint8_t x = 0;

        x = bitcpy(src, index, x, 0, 1);

        return x != 0;

}



/**

 * TODO: Doc

 */

template<typename T, typename X> finline

static void bitset(T src, X* dst, size_t index, if_uint(X),if_uint (T) ) {

        bitcpy(src,0,dst,index);

}



/**

 * TODO: Doc

 */

template<typename X> finline

static void bitset(bool src, X* dst, size_t index, if_uint(X) ) {

        bitcpy(src != 0, 0, dst, index, 1);

}



/**

 * TODO: Doc

 */

template<typename X> finline

static X bitset(bool src, X dst, size_t index, if_uint(X)) {

        return bitcpy(src != 0, 0, dst, index, 1);

}



/**

 * TODO: Doc

 */

template<typename X> finline

static X bitrev(X src, if_uint(X) ) {

        const size_t width = sizeof(X) * 8;

        X dst = 0;

        for (size_t i = 0; i < width; i++)

                dst = bitset(bitget(src, i), dst, width - i - 1);

        return dst;

}



/**

 * TODO: Doc

 */

template<typename X> finline

static void bitrev(X* src, size_t len, if_uint(X) ) {

        for (size_t i = 0; i < len / 2; i++) {

                bool b0 = bitget(src, i);

                bool b1 = bitget(src, len - i - 1);

                bitset(b1, src, i);

                bitset(b0, src, len - i - 1);

        }

}



/**

 * TODO: Doc

 */

template<typename X> finline

static X switch_endian(X src, if_uint(X) ) {

        if (sizeof(X) == 1) return src;

        X ret = 0;

        for (size_t i = 0; i < sizeof(X); i++) {

                ret <<= 8;

                ret |= src & 0xFF;

                src >>= 8;

        }

        return ret;

}



/**

 * TODO: Doc

 */

template<typename X> finline

static std::string bitstr(X src, int log2base = 4, if_uint(X)) {

        const size_t word_width = sizeof(src) * 8;

        const char digit[37] = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ";



        std::string str;

        for (int i = word_width - log2base, j = 0; i >= 0; i -= log2base, j++)

                str.append(1, digit[(src >> i) & ((1 << log2base) - 1)]);

        return str;

}



/**

 * TODO: Doc

 */

template<typename X> finline

static std::string bitstr(X* src, size_t len, int log2base = 4, bool dot =

                false, if_uint(X)) {

        std::string str;

        for (size_t i = 0; i < len / 8 / sizeof(X); i++) {

                if (i != 0 && dot) str.append(".");

                str.append(bitstr(src[i], log2base));

        }

        return str;

}



#endif /* DATAUTILITIES_HPP_ */