# Using STL/Boost to find and modify matching elements in a vector

Let's say I have a vector declared like this:

``````struct MYSTRUCT
{
float a;
float b;
};

std::vector<MYSTRUCT> v;
``````

Now, I want to find all elements of v that share the same a, and average their b, i.e.

Say v contains these five elements {a, b}: {1, 1}, {1, 2}, {2, 1}, {1, 3}, {2, 2}

I want to get v[0], v[1], v[3] (where a is 1) and average b: (1 + 2 + 3)/3 = 2, and v[2] and v[4] (where a is 2) and average b: (1+2)/2 = 1.5

Afterwards v will look like this: {1, 2}, {1, 2}, {2, 1.5}, {1, 2}, {2, 1.5}

I'm not really familiar with STL or Boost so I can only figure out how to do this the "bruteforce" way in C++, but I'm guessing that the STL (for_each?) and Boost (lambda?) libraries can solve this more elegantly.

EDIT Just for reference, here's my (working) brute force way to do it:

``````for(int j = 0; j < tempV.size(); j++)
{
MYSTRUCT v = tempV.at(j);
int matchesFound = 0;

for(int k = 0; k < tempV.size(); k++)
{
if(k != j && v.a == tempV.at(k).a)
{
v.b += tempV.at(k).b;
matchesFound++;
}
}

if(matchesFound > 0)
{
v.b = v.b/matchesFound;
}

finalV.push_back(v);
}
``````
-
Be careful comparing floats for equality! Compare with epsilon: cygnus-software.com/papers/comparingfloats/comparingfloats.htm – Emile Cormier Jan 13 '10 at 9:23

Just thinking aloud, this may end up fairly silly:

``````struct Average {
Average() : total(0), count(0) {}
operator float() const { return total / count; }
Average &operator+=(float f) {
total += f;
++count;
}
float total;
int count;
};

struct Counter {
Counter (std::map<int, Average> &m) : averages(&m) {}
Counter operator+(const MYSTRUCT &s) {
(*averages)[s.a] += s.b;
return *this;
}
std::map<int, Average> *averages;
};

std::map<int, Average> averages;
std::accumulate(v.begin(), v.end(), Counter(averages));
BOOST_FOREACH(MYSTRUCT &s, v) {
s.b = averages[s.a];
}
``````

Hmm. Not completely silly, but perhaps not compelling either...

-
I kinda like that one, but then I'm a sucker for stuff implemented with fold and closures =) – me22 Sep 10 '09 at 19:30
I just noticed that Average class is horrid: you can add two of them together and get something completely meaningless. Still, it isn't supposed to be for general-purpose reasoning with averages. – Steve Jessop Sep 10 '09 at 19:36
True, I'd definitely get rid of the operator float(). But apart from that, it seems fine – jalf Sep 10 '09 at 23:26

Sketch of a solution:

``````sort(v.begin(), v.end());
vector<MYSTRUCT>::iterator b = v.begin(), e = v.end();
while (b != e) {
vector<MYSTRUCT>::iterator m = find_if(b, e, bind(&MYSTRUCT::a, _1) != b->a);
float x = accumulate(b, m, 0.f, _1 + bind(&MYSTRUCT::b,_2)) / (m-b);
for_each(b, m, bind(&MYSTRUCT::a, _1) = x);
b = m;
}
``````

It's not a great one, though, since it's not exactly what was asked for (thanks to the sort), and still doesn't really feel clean to me. I think that some filter_iterators and transform_iterators or something could possibly give a much more functional-style answer.

-
Can you explain why you think it is not a great solution? – fbrereto Sep 10 '09 at 18:56
@fbrereto, as @me22 says, the main issue is that it changes v's order (by sorting), so it can't provide the exact result requested (where v's order was lengt intact). – Alex Martelli Sep 10 '09 at 19:14
std::find_if doesn't require a sorted sequence ( sgi.com/tech/stl/find_if.html ). Neither does std::find. – Max Lybbert Sep 10 '09 at 21:55
@Max: I'm sorting so that identical MYSTRUCT::a's are adjacent, letting me run the accumulate. – me22 Sep 11 '09 at 2:23
Ahh. Thanks. I missed the accumulate. – Max Lybbert Sep 11 '09 at 20:00

Another approach, this one not in-place, though I think it's time-complexity-wise asymptotically the same.

``````typedef map<float, vector<float>> map_type;
map_type m;
BOOST_FOREACH(MYSTRUCT const &s, v) {
m[s.a].push_back(s.b);
}
BOOST_FOREACH(map_type::reference p, m) {
float x = accumulate(p.second.begin(), p.second.end(), 0.0f) / p.second.size();
p.second.assign(1, x);
}
BOOST_FOREACH(MYSTRUCT &s, v) {
s.b = m[s.a].front();
}
``````

Again, though, it's just a slightly elegant way to code the brute-force solution, not a nice functional-style way.

-
functional code, by definition, doesn't modify existing data structures, and here the problem specs are exactly to modify the existing data structure, so I think this code is fine. – Alex Martelli Sep 10 '09 at 19:18

Perhaps a brute force approach?...

``````struct MYAVG
{
int count;
float avg;
};

// first pass - calculate averages
for ( vector < MYSTRUCT >::iterator first = v.begin();
first != v.end(); ++first )
{
MYAVG myAvg;
myAvg.count = 1;
myAvg.avg = first->b;

if ( mapAvg.find( first->a ) == mapAvg.end() )
mapAvg[ first->a ] = myAvg;
else
{
mapAvg[ first->a ].count++;
mapAvg[ first->a ].avg =
( ( mapAvg[ first->a ].avg * ( mapAvg[ first->a ].count - 1 ) )
+ myAvg.avg ) / mapAvg[ first->a ].count;
}
}

// second pass - update average values
for ( vector < MYSTRUCT >::iterator second = v.begin();
second != v.end(); ++second )
second->b = mapAvg[ second->a ].avg;
``````

I've tested this with the values you've supplied and get the required vector - It's not exactly optimal, but I think it's quite easy to follow (might be more preferable to a complex algorithm).

-

Avoid C-style! It's not what C++ is designed for. I'd like to emphasize clarity and readability.

``````#include <algorithm>
#include <iostream>
#include <map>
#include <numeric>
#include <vector>

#include <boost/assign/list_of.hpp>

using namespace std;
using namespace boost::assign;

struct mystruct
{
mystruct(float a, float b)
: a(a), b(b)
{ }

float a;
float b;
};

vector <mystruct> v =
list_of ( mystruct(1, 1) ) (1, 2) (2, 1) (1, 3) (2, 2);

ostream& operator<<(
ostream& out, mystruct const& data)
{
out << "{" << data.a << ", " << data.b << "}";
return out;
}

ostream& operator<<(
ostream& out, vector <mystruct> const& v)
{
copy(v.begin(), v.end(),
ostream_iterator <mystruct> (out, " "));
return out;
}

struct average_b
{
map <float, float> sum;
map <float, int> count;

float operator[] (float a) const
{
return sum.find(a)->second / count.find(a)->second;
}
};

average_b operator+ (
average_b const& average,
mystruct const& s)
{
average_b result( average );

result.sum[s.a] += s.b;
++result.count[s.a];

return result;
}

struct set_b_to_average
{
set_b_to_average(average_b const& average)
: average(average)
{ }

mystruct operator()(mystruct const& s) const
{
return mystruct(s.a, average[s.a]);
}

average_b const& average;
};

int main()
{
cout << "before:" << endl << v << endl << endl;

transform(v.begin(), v.end(),
v.begin(), set_b_to_average(
accumulate(v.begin(), v.end(), average_b())
));

cout << "after:" << endl << v << endl << endl;
}
``````
-

You can use the "partition" algorithm along with "accumulate."

## Example

``````#include <iostream>
#include <vector>
#include <algorithm>
#include <numeric>

struct test
{
float a;
float b;

test(const float one, const float two)
: a(one), b(two)
{
}
};

struct get_test_a {
float interesting;

get_test_a(const float i)
: interesting(i)
{
}

bool operator()(const test &value) const
{
static const float epi = 1e-6;
return value.a < interesting + epi &&
value.a > interesting - epi;
}
};

float operator()(const float init, const test &value) const
{
return init + value.b;
}
};

int main(int argc, char **argv)
{
using std::partition;
using std::accumulate;
using std::distance;
typedef std::vector<test> container;

container myContainer;

// Say 'myVector' contains these five elements {a, b}:
// {1, 1}, {1, 2}, {2, 1}, {1, 3}, {2, 2}
myContainer.push_back(test(1, 1));
myContainer.push_back(test(1, 2));
myContainer.push_back(test(2, 1));
myContainer.push_back(test(1, 3));
myContainer.push_back(test(2, 2));

// I want to get v[0], v[1], v[3] (where a is 1) and
// average b: (1 + 2 + 3)/3 = 2,
// and v[2] and v[4] (where a is 2) and average b: (1+2)/2 = 1.5
const container::iterator split =
partition(myContainer.begin(), myContainer.end(),
get_test_a(1));

const float avg_of_one =
accumulate(myContainer.begin(), split, 0.0f, add_test_b())
/ distance(myContainer.begin(), split);

const float avg_of_others =
accumulate(split, myContainer.end(), 0.0f, add_test_b())
/ distance(split, myContainer.end());

std::cout << "The 'b' average of test values where a = 1 is "
<< avg_of_one << std::endl;

std::cout << "The 'b' average of the remaining test values is "
<< avg_of_others << std::endl;

return 0;
}
``````

## Documentation from the gcc headers

``````  /**
*  @brief Move elements for which a predicate is true to the beginning
*         of a sequence.
*  @ingroup mutating_algorithms
*  @param  first   A forward iterator.
*  @param  last    A forward iterator.
*  @param  pred    A predicate functor.
*  @return  An iterator @p middle such that @p pred(i) is true for each
*  iterator @p i in the range @p [first,middle) and false for each @p i
*  in the range @p [middle,last).
*
*  @p pred must not modify its operand. @p partition() does not preserve
*  the relative ordering of elements in each group, use
*  @p stable_partition() if this is needed.
*/
template<typename _ForwardIterator, typename _Predicate>
inline _ForwardIterator
partition(_ForwardIterator __first, _ForwardIterator __last,
_Predicate   __pred)

/**
*  @brief  Accumulate values in a range with operation.
*
*  Accumulates the values in the range [first,last) using the function
*  object @a binary_op.  The initial value is @a init.  The values are
*  processed in order.
*
*  @param  first  Start of range.
*  @param  last  End of range.
*  @param  init  Starting value to add other values to.
*  @param  binary_op  Function object to accumulate with.
*  @return  The final sum.
*/
template<typename _InputIterator, typename _Tp, typename _BinaryOperation>
inline _Tp
accumulate(_InputIterator __first, _InputIterator __last, _Tp __init,
_BinaryOperation __binary_op)
``````
-

It seems the easiest way is to run a moderately complex functor over the colelction:

``````struct CountAllAverages {
typedef std::pair<float, unsigned> average_t;
std::map<float, average_t> averages;
void operator()(mystruct& ms) {
average_t& average = averages[ms.a];
average.second++;
average.first += ms.b;
}
float getAverage(float a) { return averages[a].first/averages[a].second; }
};
``````
-

Writing C++, you should maintain balance between reusability (e.g. reuse existing algorithms and data structures) and readability. onebyone was close, but his solution can be further improved:

``````template<class T>
struct average {
T total;
int count;
mutable bool calculated;
mutable T average_value;

average & operator+=(T const & value) {
total += value;
++count;
calculated = false;
}

T value() const {
if(!calculated) {
calculated = true;
average_value = total / count;
}
return average_value;
}
};

std::map< float, average<float> > averages;
BOOST_FOREACH(MYSTRUCT &element, v) {
averages[element.a] += element.b;
}

BOOST_FOREACH(MYSTRUCT &element, v) {
element.b = averages[element.a].value();
}
``````

Bonus points for having reusable "average" type.

-
``````struct MYSTRUCT {
float x;
float y;

operator float() const { return y; }
};

class cmp {
float val;
public:
cmp(float v) : val(v) {}
bool operator()(MYSTRUCT const &a) { return a.x != val; }
};

float masked_mean(std::vector<MYSTRUCT> const &in, MYSTRUCT const &mask) {
std::vector<float> temp;
std::remove_copy_if(in.begin(), in.end(), std::back_inserter(temp), cmp(mask.x));
return std::accumulate(temp.begin(), temp.end(), 0.0f) / temp.size();
}
``````
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