Book Image

Hands-On C++ Game Animation Programming

By : Gabor Szauer
Book Image

Hands-On C++ Game Animation Programming

By: Gabor Szauer

Overview of this book

Animation is one of the most important parts of any game. Modern animation systems work directly with track-driven animation and provide support for advanced techniques such as inverse kinematics (IK), blend trees, and dual quaternion skinning. This book will walk you through everything you need to get an optimized, production-ready animation system up and running, and contains all the code required to build the animation system. You’ll start by learning the basic principles, and then delve into the core topics of animation programming by building a curve-based skinned animation system. You’ll implement different skinning techniques and explore advanced animation topics such as IK, animation blending, dual quaternion skinning, and crowd rendering. The animation system you will build following this book can be easily integrated into your next game development project. The book is intended to be read from start to finish, although each chapter is self-contained and can be read independently as well. By the end of this book, you’ll have implemented a modern animation system and got to grips with optimization concepts and advanced animation techniques.
Table of Contents (17 chapters)

Inverting transforms

You already know that a transform maps from one space into another space. It's possible to reverse that mapping and map the transform back into the original space. As with matrices and quaternions, transforms can also be inverted.

When inverting scale, keep in mind that 0 can't be inverted. The case where scale is 0 will need to be treated specially

Implement the inverse transform method in Transform.cpp. Don't forget to declare the method in Transform.h:

Transform inverse(const Transform& t) {
    Transform inv;
    inv.rotation = inverse(t.rotation);
    inv.scale.x = fabs(t.scale.x) < VEC3_EPSILON ? 
                  0.0f : 1.0f / t.scale.x;
    inv.scale.y = fabs(t.scale.y) < VEC3_EPSILON ? 
           ...