Sheaves are defined next, along with several examples of sheaves that illustrate the sometimes non-Hausdorff topology of sheaves. The cohomology of sheaves is discussed in the next chapter, and many examples are given illustrating the main points, along with relative cohomology. Most of the usual constructions from algebraic topology that carry through to sheaf cohomology, such as the Kunneth and universal coefficient theorems, the Mayer-Vietoris sequence, and Steenrod squares.

Sheaf cohomology is compared with other cohomology theories in the next chapter. Although short, the author's discussion is effective in that he clarifies the need for a paracompactifying family of supports, generalizing the paracompactness hypothesis needed in the usual cohomology theories.

Spectral sequences follow in chapter four, and, as is usual with discussions of these, the treatment is very abstract. There are however many examples, and the section on fiber bundles makes even clearer the constructions employed. The Thom class, the Thom isomorphism, the Euler class, and the Gysin sequence all make their appearances.

The most well-written chapter is the next one on Borel-Moore homology. The author does an excellent job of explaining why this homology theory was invented, namely to fix the some of the pathologies of ordinary homology theories. But he also explains effectively that this new homology theory does have some peculiarities of its own. It is a very lengthy chapter however, and very detailed, taking much effort to read and digest.

The book has solutions to most of the exercises in one of the appendices, and these serve to enhance even further the didactic quality of the book. It can serve well for students entering the field, and also to physicists who need an introduction to sheaf theory, as these ideas on now permeating high energy physics via superstring and M-theories.