Modern Assembly Language Programming with the ARM ProcessorNewnes, 2016 M05 3 - 504 pages Modern Assembly Language Programming with the ARM Processor is a tutorial-based book on assembly language programming using the ARM processor. It presents the concepts of assembly language programming in different ways, slowly building from simple examples towards complex programming on bare-metal embedded systems. The ARM processor was chosen as it has fewer instructions and irregular addressing rules to learn than most other architectures, allowing more time to spend on teaching assembly language programming concepts and good programming practice. In this textbook, careful consideration is given to topics that students struggle to grasp, such as registers vs. memory and the relationship between pointers and addresses, recursion, and non-integral binary mathematics. A whole chapter is dedicated to structured programming principles. Concepts are illustrated and reinforced with a large number of tested and debugged assembly and C source listings. The book also covers advanced topics such as fixed and floating point mathematics, optimization, and the ARM VFP and NEONTM extensions. PowerPoint slides and a solutions manual are included. This book will appeal to professional embedded systems engineers, as well as computer engineering students taking a course in assembly language using the ARM processor.
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Larry D Pyeatt. 178 179 181 190 194 220 220 226 230 231 232 234 236 7.2.4 Signed Multiplication...................................................................... 7.2.5 Multiplying Large Numbers 7.3 Binary ....................
... signed 8-bit math, 110110012 is −3910 In unsigned 8-bit math, 110110012 is 21710 Multiplication of large numbers Longhand division in decimal and binary Flowchart for binary division Examples of fixed-point signed arithmetic ARM ...
... signed and unsigned 32-bit and 64-bit division functions ARM assembly code for division by constant 193 ARM assembly code for division of a variable by a constant without using a multiply instruction Header file for a big integer ...
... signed integer data are two's complement, sign-magnitude, and excess-N, Fig. 1.4 shows how the same binary pattern of bits can be interpreted as a number in four different ways. Sign-magnitude representation The sign-magnitude ...
... signed numbers involves representing negative numbers as the radix complements of their positive counterparts. The complement is the amount that must be added to something to make it “whole.” For instance, in geometry, two angles are ...
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Modern Assembly Language Programming with the ARM Processor Larry D. Pyeatt No preview available - 2016 |