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1: 位元與位元組

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    123241
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    • 1.1: Representing integers
      This page explains how computers represent numbers using binary and two's complement, which simplifies operations for negative numbers. It describes the process of flipping the binary and adding 1 to find a negative number's two's complement and notes that the leftmost bit indicates the sign. Additionally, it covers sign extension when converting from 8-bit to 16-bit numbers and mentions that integer types in C are signed by default unless declared otherwise, which influences their operation.
    • 1.2: Bitwise operators
      This page explains bitwise operators in C, including AND, OR, and XOR, detailing their effects on bits of integers. It illustrates how these operators clear, set, and toggle bits with examples using binary numbers. Furthermore, it introduces shift operators that move bits left or right, effectively doubling or halving values. The summary emphasizes the practical uses of these operators in manipulating bit vectors.
    • 1.3: Representing floating-point numbers
      This page explains the representation of floating-point numbers in binary scientific notation using the IEEE 32-bit standard, which consists of a sign bit, an exponent with a bias of 127, and a 23-bit coefficient. It covers normalization and how to unpack the representation in C using unions and bitwise operations, illustrating the extraction of components with an example. Additionally, it encourages readers to explore double representation as further practice.
    • 1.4: Unions and memory errors
      This page discusses the use of C unions for accessing binary data and storing varied types while highlighting their error-prone nature. It emphasizes the programmer's need to accurately track the stored data type to avoid misinterpretation and unpredictable results, similar to problems caused by reading out of array bounds. The challenges of debugging outputs, especially when data types vary, are also noted, emphasizing the potential issues with memory alignment across different compilers.
    • 1.5: Representing strings
      This page covers essential aspects of C strings, emphasizing their null-terminated nature and the need for extra byte allocation. It explains ASCII encoding, focusing on the distinction between digit and letter codes, particularly how the sixth bit differentiates upper and lower case letters. A function to toggle case is suggested, along with warnings about common mistakes in string handling, illustrated by an example of type interpretation issues.


    1: 位元與位元組 is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by LibreTexts.

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