Page 5 through 18: http://userweb.cs.utexas.edu/users/EWD/ewd02xx/EWD249.PDF

Mid. page 3 through end: http://userweb.cs.utexas.edu/users/EWD/ewd04xx/EWD473.PDF

End page 5 through end: http://userweb.cs.utexas.edu/users/EWD/ewd06xx/EWD641.PDF

All: http://userweb.cs.utexas.edu/users/EWD/transcriptions/EWD02xx/EWD261.html ^{(Dutch, translation=below)}

_{Note: Dijkstra numbers his pages starting at 0. Given page numbers are starting at 1, the PDF page number, and not the written page numbers.}

*My translation of EWD261 in English*:

**How to program mathematically**

A (well-defined) programme is structured just like a (well-defined) mathematical theory. The programmers' work is not different from that of a creative mathematician.

There are small, but important, differences, though:

- There are not much basic concepts of programming and they are not difficult to comprehend (though misleadingly simple); this is why it's an ideal for development practice. (Besides this, there is the fact that a demand for correctness, the programme should really work!)
- With most mathematical education one learns about existing theorems, viz. equipping a student with a specific (detailed) set of concepts; a programmer, however, has to develop the needed concept himself. Programming requires the abstractions which leads to a type of creativity, while the same in mathematics is limited to applying existing theorems.
- Because programmes are big and nevertheless have to work will programmers learn how to develop carefully and consciously. This is exactly what one should teach! To teach extensive knowledge is, for me, not justified.