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- // -*- mode: c++; coding: utf-8 -*-
- // ra-ra/examples - Demo shape agreement rules
- // (c) Daniel Llorens - 2015-2016
- // This library is free software; you can redistribute it and/or modify it under
- // the terms of the GNU Lesser General Public License as published by the Free
- // Software Foundation; either version 3 of the License, or (at your option) any
- // later version.
- #include "ra/ra.hh"
- #include <iostream>
- using std::cout, std::endl;
- int main()
- {
- // The general shape agreement rule is 'prefix agreement': all the first
- // dimensions must match, all the second dimensions, etc. If some arguments
- // have lower rank than others, then the missing dimensions are ignored.
- // For example:
- ra::Big<float, 3> A({3, 4, 5}, 1.);
- ra::Big<float, 2> B({3, 4}, 2.);
- ra::Big<float, 1> C({3}, 3.);
- ra::Big<float, 3> X({3, 4, 5}, 99.);
- // In the following expression, the shapes of the arguments are:
- // A: [3 4 5]
- // B: [3 4]
- // C: [3]
- // X: [3 4 5] (taken from the shape of the right hand side)
- // All the first dimensions are 3, all the second dimensions are 4, and all
- // the third dimensions are 5, so the expression is valid.
- // Note that the agreement rules are applied equally to the destination argument.
- X = map([](auto && a, auto && b, auto && c) { return a+b-c; }, A, B, C);
- cout << "\nX: " << X << endl;
- // (you can write the expression above as X = A+B-C).
- // This rule comes from the array language J (for function rank 0; see J's
- // documentation). Obvious examples include:
- {
- // multiply any array by a scalar. The shape of a scalar is [];
- // therefore, a scalar agrees with anything.
- ra::Big<float, 2> X = B*7.;
- cout << "\nB*7: " << X << endl;
- }
- {
- // multiply each row of B by a different element of C, X(i, j) = B(i, j)*C(i)
- ra::Big<float, 2> X = B*C;
- cout << "\nB*C: " << X << endl;
- }
- {
- // multiply arrays componentwise (identical shapes agree).
- ra::Big<float, 2> X = B*B;
- cout << "\nB*B: " << X << endl;
- }
- // Some special expressions, such as tensor indices, do not have a
- // shape. Therefore they need to be accompanied by some other expression
- // that does have a shape, or the overall expression is not valid.
- {
- constexpr auto i = ra::iota<0>();
- constexpr auto j = ra::iota<1>();
- // That's why you can do
- ra::Big<float, 2> X({3, 4}, i-j);
- cout << "\ni-j: " << X << endl;
- // but the following would be invalid:
- // ra::Big<float, 2> X = i-j; // no shape to construct X with
- }
- // Axis insertion lets you match arguments more flexibly than simple prefix matching.
- {
- ra::Big<float, 2> A({3, 4}, 0);
- ra::Big<float, 1> b({3}, ra::_0);
- ra::Big<float, 1> c({4}, ra::_0);
- // Compare:
- // [3 4] matches [3] - normal prefix matching. Assign b(i) to A(i, ...)
- A = b;
- cout << "\nA: " << A << endl;
- // [3 4] matches [X 4] - skip 1 dimension when matching. Assign c(i) to A(..., i)
- A = c(ra::insert<1>);
- cout << "\nA: " << A << endl;
- }
- return 0;
- }
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