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cacheItem.cpp
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306 lines (295 loc) · 8.24 KB
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#include "cacheItem.hpp"
using namespace std;
data_cell_num_type cache_data_cell_size = 0;
const dims_type cacheItem::conjunction(const dims_type &left, const dims_type &right)
{
if (left == right)
{
return left;
}
dims_type res;
for (int i = 0; i < dimsNum; ++i)
{
res[i] = left[i] == right[i] ? left[i] : (left[i] != 0 ? left[i] : right[i]);
}
return res;
}
ca_type cacheItem::std_ca(const pair<dims_type, dims_type> ®ion)
{
const dims_type &up = region.first;
const dims_type &low = region.second;
layer_type layer_up = dimsNum - count(up.begin(), up.end(), 0);
layer_type layer_low = dimsNum - count(low.begin(), low.end(), 0);
return pow(2, layer_up - layer_low);
}
void Cij(int i, int j, vector<int> &r, int num, vector<vector<int>> &result)
{
if (j == 1)
{
for (int k = 0; k < i; k++)
{
vector<int> temp(num);
r[num - 1] = k;
for (int i = 0; i < num; i++)
{
temp[i] = r[i];
}
result.push_back(temp);
}
}
else if (j == 0)
{
}
else
{
for (int k = i; k >= j; k--)
{
r[j - 2] = k - 1;
Cij(k - 1, j - 1, r, num, result);
}
}
}
cacheItem::cacheItem(queryItem self_queryItem)
{
upper.insert(self_queryItem.getDims());
lowers.clear();
measure = self_queryItem.getMeasure();
sz = 1;
ca = 1;
low_min_layer = self_queryItem.getLayer();
}
void cacheItem::update_state()
{
if (upper.size() != 1)
{
data_cell_num_type bef_up_size = upper.size();
dims_type common_upper = {0};
for (int i = 0; i < dimsNum; ++i)
{
for (auto every_upper : upper)
{
if (every_upper[i] != 0)
{
common_upper[i] = every_upper[i];
break;
}
}
}
upper.clear();
upper.insert(common_upper);
cache_data_cell_size = cache_data_cell_size - bef_up_size + 1;
}
if (lowers.empty())
{
dims_type unique_upper = *upper.begin();
low_min_layer = static_cast<int>(dimsNum - count(unique_upper.begin(), unique_upper.end(), 0));
}
else
{
int temp_layer = dimsNum;
for_each(lowers.begin(), lowers.end(), [&temp_layer](const dims_type &every_lower)
{
int every_layer = static_cast<int> (dimsNum - count(every_lower.begin(), every_lower.end(),0));
if(temp_layer > every_layer){
temp_layer = every_layer;
} });
low_min_layer = temp_layer;
}
}
void cacheItem::update_eqClass_sz()
{
sz = upper.size() + lowers.size();
cache_data_cell_size = cache_data_cell_size + sz;
}
void cacheItem::update_ca()
{
vector<dims_type> regions;
map<int, dims_type> index;
if (lowers.empty())
{
regions.push_back(*upper.begin());
}
else
{
for (auto every_lower : lowers)
{
regions.push_back(every_lower);
}
}
int num = 0;
ca = 0;
for (int i = 0; i < regions.size(); ++i)
{
vector<int> resulttemp(i + 1);
vector<vector<int>> result;
Cij((int)regions.size(), i + 1, resulttemp, i + 1, result);
num = 0;
for (auto a : result)
{
dims_type temp = {0};
string index_str;
for (auto b : a)
{
temp = cacheItem::conjunction(regions[b], temp);
}
num += cacheItem::std_ca(make_pair(*upper.begin(), temp));
}
resulttemp.clear();
result.clear();
if (i % 2 != 0)
{
ca += -1 * num;
}
else
{
ca += num;
}
}
}
bool cacheItem::cover(const dims_type &left_queryItem_dims, const dims_type &right_queryItem_dims)
{
bool flag = false;
for (int i = 0; i < dimsNum; ++i)
{
if ((left_queryItem_dims[i] == 0) || (left_queryItem_dims[i] == right_queryItem_dims[i]))
{
flag = true;
}
else
{
flag = false;
break;
}
}
return flag;
}
bool cacheItem::addToCacheItem(const dims_type &queryItem_dims, int &state)
{
bool only_cover_low = false;
if (lowers.empty())
{
if (cacheItem::cover(queryItem_dims, *upper.begin()))
{
cout << "the lower bound that query items can cover cache items" << endl;
state = 2; // 4
lowers.insert(queryItem_dims);
update_state();
cache_data_cell_size++;
return true;
}
else if (cacheItem::cover(*upper.begin(), queryItem_dims))
{
state = 1; // 3
cout << "the lower bound that cache items can cover query items" << endl;
lowers.insert(*upper.begin());
upper.clear();
upper.insert(queryItem_dims);
cache_data_cell_size++;
return true;
}
}
else
{
if (cacheItem::cover(*upper.begin(), queryItem_dims))
{
state = 1;
cout << "the upper bound of the cache item can cover query item" << endl;
upper.clear();
upper.insert(queryItem_dims);
return true;
}
else
{
for (auto iter = lowers.begin(); iter != lowers.end(); ++iter)
{
if (cacheItem::cover(*iter, queryItem_dims))
{
state = 3;
cout << "the lower bound of the cache item can cover query item" << endl;
upper.insert(queryItem_dims);
cache_data_cell_size++;
update_state();
return true;
}
}
}
for (auto iter = lowers.begin(); iter != lowers.end();)
{
if (cacheItem::cover(queryItem_dims, *iter))
{
cout << "query items can cover the lower bound of the cache items" << endl;
state = 4;
lowers.erase(iter++);
cache_data_cell_size--;
only_cover_low = true;
}
else
{
++iter;
}
}
if (only_cover_low)
{
lowers.insert(queryItem_dims);
update_state();
cache_data_cell_size++;
return true;
}
if (cacheItem::cover(queryItem_dims, *upper.begin()))
{
state = 2;
cout << "query items only cover the uppqer bound of the cache items" << endl;
lowers.insert(queryItem_dims);
cache_data_cell_size++;
update_state();
return true;
}
}
return false;
}
void cacheItem::merge_up(const cacheItem &merged_cacheItem)
{
for (auto up : merged_cacheItem.getUp())
{
upper.insert(up);
}
for (auto low : merged_cacheItem.getLow())
{
lowers.insert(low);
}
}
void cacheItem::merge_low(const cacheItem &merged_cacheItem)
{
for (auto up : merged_cacheItem.getUp())
{
upper.insert(up);
}
for (auto low : merged_cacheItem.getLow())
{
lowers.insert(low);
}
}
void cacheItem::display() const
{
cout << "one upper bound:" << endl;
for_each(upper.begin(), upper.end(), [](const dims_type &every_upper)
{
for_each(every_upper.begin(), every_upper.end(), [](const int& dims ){
cout<<dims<<",";
});
cout<<endl; });
cout << endl
<< "multi lower bounds: (if no upper bounds,lower bound itself" << endl;
for_each(lowers.begin(), lowers.end(), [](const dims_type &every_lower)
{
for_each(every_lower.begin(), every_lower.end(), [](const int& dims ){
cout<<dims<<",";
});
cout<<endl; });
cout << "measure: " << measure;
cout << endl
<< "the sum of the upper bounds and lower bounds" << getSz() << endl;
cout << "the value of the least layer level number of lower bound " << getLow_min_layer() << endl;
cout << "covering capacity:" << getCa() << endl;
cout << "---------bound line-----------" << endl;
}