stasis-aries-wal/stasis/page/compression/tuple.h

#ifndef _ROSE_COMPRESSION_TUPLE_H__
#define _ROSE_COMPRESSION_TUPLE_H__

// Copyright 2007 Google Inc. All Rights Reserved.
// Author: sears@google.com (Rusty Sears)

/**
  @file Implementation of tuples (Tuple) and dispatch routines for
  column wide compression (PluginDispatcher).
*/

#include <limits.h>
#include <ctype.h>

#include "compression.h"
#include "for.h"
#include "rle.h"
#include "nop.h"
#include "string.h"

namespace rose {

template<class TYPE>
class Tuple {
 public:
  explicit Tuple(column_number_t count) : count_(count),
    cols_(new TYPE[count]), 
    byteArray_(new byte[sizeof(count_)+count_*sizeof(TYPE)]) {}

  /*explicit Tuple(byte* b) : count_(*(column_number_t*)b),
    cols_(new TYPE[count_]),
    byteArray_(new byte[sizeof(count_)+count_*sizeof(TYPE)]) {
       memcpy(cols_,b+sizeof(column_number_t), sizeof(TYPE)*count_);
       } */
 explicit Tuple(Tuple& t) : count_(t.count_), cols_(new TYPE[count_]),
    byteArray_(new byte[sizeof(count_)+count_*sizeof(TYPE)]) {
    for(column_number_t c = 0; c < count_; c++) {
      cols_[c] = t.cols_[c];
    }
  }
  Tuple(TYPE t) : count_(0), cols_(new TYPE[1]),
    byteArray_(new byte[sizeof(count_)+sizeof(TYPE)]) {
    cols_[0] = t;
  }
  /* Tuple(Tuple *t) : count_(t->count_),cols_(new TYPE[count_]) {
    for(column_number_t c = 0; c < count_; c++) {
       cols_[c] = t->cols_[c];
     }
     } */
  inline ~Tuple() { delete[] cols_; delete[] byteArray_; }
  inline bool tombstone() {
    return false;
  }
  inline TYPE * set(column_number_t col,void* val) {
    cols_[col] = *(TYPE*)val;
    return (TYPE*)val;
  }
  inline TYPE * get(column_number_t col) const {
    return &(cols_[col]);
  }
  inline void copyFrom(Tuple<TYPE> t) {
    for(int i = 0; i < count_; i++) {
      set(i,t.get(i));
    }
  }
  inline column_number_t column_count() const {
    return count_;
  }
  inline byte_off_t column_len(column_number_t col) const {
    return sizeof(TYPE);
  }
  /*  inline void fromByteArray(byte * b) {
    assert(count_ == *(column_number_t*)b);
    //    memcpy(cols_,b+sizeof(column_number_t),sizeof(TYPE)*count_);
    TYPE *newCols = (int*)(b + sizeof(column_number_t));
    for(column_number_t i = 0; i < count_; i++) {
      cols_[i] = newCols[i];
    }
    } */
  inline byte* toByteArray() {
    byte* ret = byteArray_;
    memcpy(ret, &count_, sizeof(count_));
    memcpy(ret+sizeof(count_), cols_, count_ * sizeof(TYPE));
    return ret;
  }
  /*  inline operator const byte * () {
    return toByteArray();
    } */
  inline operator TYPE () { 
    return cols_[0]; //*get(0);
  }
  /*  inline operator TYPE () {
    assert(count_ == 0);
    return cols_[0];
    } */
  static inline size_t sizeofBytes(column_number_t cols) {
    return sizeof(column_number_t) + cols * sizeof(TYPE);
  }
  static const int TUPLE_ID = 0;

  /*  inline bool operator==(Tuple *t) { 
    return *this == *t;
    } */
   inline bool operator==(Tuple &t) {
     //if(t.count_ != count_) return 0;
    for(column_number_t i = 0; i < count_; i++) {
      if(cols_[i] != t.cols_[i]) { return 0;}
    }
    return 1;
   }
   inline bool operator<(Tuple &t) {
     //if(t.count_ != count_) return 0;
    for(column_number_t i = 0; i < count_; i++) {
      if(cols_[i] < t.cols_[i]) { return 1;}
    }
    return 0;
   }

  /*  inline bool operator==(TYPE val) { 
    assert(count_ == 1);
    return cols_[0] == val;
    }*/
  class iterator {
   public:
    inline iterator(column_number_t c, TYPE const *const *const dataset, int offset) :
        c_(c),
        dat_(dataset),
        off_(offset),
        scratch_(c_) {}
    inline explicit iterator(const iterator &i) : c_(i.c_), dat_(i.dat_), off_(i.off_),
	scratch_(c_) {}

    inline Tuple<TYPE>& operator*() {
      for(column_number_t i = 0; i < c_; i++) {
        scratch_.set(i,(void*)&dat_[i][off_]);
      }
      return scratch_;
    }
    inline bool operator==(const iterator &a) const {
      //assert(dat_==a.dat_ && c_==a.c_);
      return (off_==a.off_);
    }
    inline bool operator!=(const iterator &a) const {
      //assert(dat_==a.dat_ && c_==a.c_);
      return (off_!=a.off_);
    }
    inline void operator++() { off_++; }
    inline void operator--() { off_--; }
    inline void operator+=(int i) { abort(); }
    inline int  operator-(iterator&i) {
      return off_ - i.off_;
    }
    inline void operator=(iterator &i) {
      assert(c_==i.c_);
      assert(dat_==i.dat_);
      off_=i.off_;
    }
    inline void offset(int off) {
      off_=off;
    }
   private:
    column_number_t c_;
    TYPE const * const * dat_;
    int off_;
    Tuple<TYPE> scratch_;
  };
  static const uint32_t TIMESTAMP = 0;
 private:
  Tuple() { abort(); }
  explicit Tuple(const Tuple& t) { abort(); }
  column_number_t count_;
  TYPE * const cols_;
  byte * byteArray_;
 };
}
#endif  // _ROSE_COMPRESSION_TUPLE_H__
Initial ROSE check in. 2007-10-15 17:46:44 +00:00			`#ifndef _ROSE_COMPRESSION_TUPLE_H__`
			`#define _ROSE_COMPRESSION_TUPLE_H__`

			`// Copyright 2007 Google Inc. All Rights Reserved.`
			`// Author: sears@google.com (Rusty Sears)`

			`/**`
			`@file Implementation of tuples (Tuple) and dispatch routines for`
			`column wide compression (PluginDispatcher).`
			`*/`

			`#include <limits.h>`
			`#include <ctype.h>`

			`#include "compression.h"`
Initial refactoring of rose.cpp into reusable components. (Just shuffles the code around.) 2007-10-18 18:52:12 +00:00			`#include "for.h"`
			`#include "rle.h"`
Added "no-op" compressor (to allow compression to be disabled...) 2008-03-08 07:43:53 +00:00			`#include "nop.h"`
Initial refactoring of rose.cpp into reusable components. (Just shuffles the code around.) 2007-10-18 18:52:12 +00:00			`#include "string.h"`
Initial ROSE check in. 2007-10-15 17:46:44 +00:00
Initial refactoring of rose.cpp into reusable components. (Just shuffles the code around.) 2007-10-18 18:52:12 +00:00			`namespace rose {`
Initial ROSE check in. 2007-10-15 17:46:44 +00:00
			`template<class TYPE>`
			`class Tuple {`
			`public:`
			`explicit Tuple(column_number_t count) : count_(count),`
			`cols_(new TYPE[count]),`
			`byteArray_(new byte[sizeof(count_)+count_*sizeof(TYPE)]) {}`

			`/explicit Tuple(byte b) : count_((column_number_t)b),`
			`cols_(new TYPE[count_]),`
			`byteArray_(new byte[sizeof(count_)+count_*sizeof(TYPE)]) {`
			`memcpy(cols_,b+sizeof(column_number_t), sizeof(TYPE)*count_);`
			`} */`
			`explicit Tuple(Tuple& t) : count_(t.count_), cols_(new TYPE[count_]),`
			`byteArray_(new byte[sizeof(count_)+count_*sizeof(TYPE)]) {`
			`for(column_number_t c = 0; c < count_; c++) {`
			`cols_[c] = t.cols_[c];`
			`}`
			`}`
			`Tuple(TYPE t) : count_(0), cols_(new TYPE[1]),`
			`byteArray_(new byte[sizeof(count_)+sizeof(TYPE)]) {`
			`cols_[0] = t;`
			`}`
			`/* Tuple(Tuple *t) : count_(t->count_),cols_(new TYPE[count_]) {`
			`for(column_number_t c = 0; c < count_; c++) {`
			`cols_[c] = t->cols_[c];`
			`}`
			`} */`
			`inline ~Tuple() { delete[] cols_; delete[] byteArray_; }`
Partial implementation of a collection oriented interface for ROSE. (Checking in to create version to diff against.) 2007-11-01 20:09:55 +00:00			`inline bool tombstone() {`
			`return false;`
			`}`
Initial ROSE check in. 2007-10-15 17:46:44 +00:00			`inline TYPE * set(column_number_t col,void* val) {`
			`cols_[col] = (TYPE)val;`
			`return (TYPE*)val;`
			`}`
			`inline TYPE * get(column_number_t col) const {`
			`return &(cols_[col]);`
			`}`
Partial implementation of a collection oriented interface for ROSE. (Checking in to create version to diff against.) 2007-11-01 20:09:55 +00:00			`inline void copyFrom(Tuple<TYPE> t) {`
			`for(int i = 0; i < count_; i++) {`
			`set(i,t.get(i));`
			`}`
			`}`
Initial ROSE check in. 2007-10-15 17:46:44 +00:00			`inline column_number_t column_count() const {`
			`return count_;`
			`}`
			`inline byte_off_t column_len(column_number_t col) const {`
			`return sizeof(TYPE);`
			`}`
			`/* inline void fromByteArray(byte * b) {`
			`assert(count_ == (column_number_t)b);`
			`// memcpy(cols_,b+sizeof(column_number_t),sizeof(TYPE)*count_);`
			`TYPE newCols = (int)(b + sizeof(column_number_t));`
			`for(column_number_t i = 0; i < count_; i++) {`
			`cols_[i] = newCols[i];`
			`}`
			`} */`
			`inline byte* toByteArray() {`
			`byte* ret = byteArray_;`
			`memcpy(ret, &count_, sizeof(count_));`
			`memcpy(ret+sizeof(count_), cols_, count_ * sizeof(TYPE));`
			`return ret;`
			`}`
			`/* inline operator const byte * () {`
			`return toByteArray();`
			`} */`
			`inline operator TYPE () {`
			`return cols_[0]; //*get(0);`
			`}`
			`/* inline operator TYPE () {`
			`assert(count_ == 0);`
			`return cols_[0];`
			`} */`
			`static inline size_t sizeofBytes(column_number_t cols) {`
			`return sizeof(column_number_t) + cols * sizeof(TYPE);`
			`}`
			`static const int TUPLE_ID = 0;`

			`/* inline bool operator==(Tuple *t) {`
			`return this == t;`
			`} */`
			`inline bool operator==(Tuple &t) {`
			`//if(t.count_ != count_) return 0;`
			`for(column_number_t i = 0; i < count_; i++) {`
			`if(cols_[i] != t.cols_[i]) { return 0;}`
			`}`
			`return 1;`
			`}`
			`inline bool operator<(Tuple &t) {`
			`//if(t.count_ != count_) return 0;`
			`for(column_number_t i = 0; i < count_; i++) {`
			`if(cols_[i] < t.cols_[i]) { return 1;}`
			`}`
			`return 0;`
			`}`

			`/* inline bool operator==(TYPE val) {`
			`assert(count_ == 1);`
			`return cols_[0] == val;`
			`}*/`
			`class iterator {`
			`public:`
			`inline iterator(column_number_t c, TYPE const const const dataset, int offset) :`
			`c_(c),`
			`dat_(dataset),`
			`off_(offset),`
			`scratch_(c_) {}`
			`inline explicit iterator(const iterator &i) : c_(i.c_), dat_(i.dat_), off_(i.off_),`
			`scratch_(c_) {}`

			`inline Tuple<TYPE>& operator*() {`
			`for(column_number_t i = 0; i < c_; i++) {`
			`scratch_.set(i,(void*)&dat_[i][off_]);`
			`}`
			`return scratch_;`
			`}`
			`inline bool operator==(const iterator &a) const {`
			`//assert(dat_==a.dat_ && c_==a.c_);`
			`return (off_==a.off_);`
			`}`
			`inline bool operator!=(const iterator &a) const {`
			`//assert(dat_==a.dat_ && c_==a.c_);`
			`return (off_!=a.off_);`
			`}`
			`inline void operator++() { off_++; }`
			`inline void operator--() { off_--; }`
			`inline void operator+=(int i) { abort(); }`
			`inline int operator-(iterator&i) {`
			`return off_ - i.off_;`
			`}`
			`inline void operator=(iterator &i) {`
			`assert(c_==i.c_);`
			`assert(dat_==i.dat_);`
			`off_=i.off_;`
			`}`
			`inline void offset(int off) {`
			`off_=off;`
			`}`
			`private:`
			`column_number_t c_;`
			`TYPE const * const * dat_;`
			`int off_;`
			`Tuple<TYPE> scratch_;`
			`};`
Partial implementation of a collection oriented interface for ROSE. (Checking in to create version to diff against.) 2007-11-01 20:09:55 +00:00			`static const uint32_t TIMESTAMP = 0;`
Initial ROSE check in. 2007-10-15 17:46:44 +00:00			`private:`
			`Tuple() { abort(); }`
			`explicit Tuple(const Tuple& t) { abort(); }`
			`column_number_t count_;`
			`TYPE * const cols_;`
			`byte * byteArray_;`
			`};`
			`}`
			`#endif // _ROSE_COMPRESSION_TUPLE_H__`