Contents

Textbooks

Electronic options are available for all required sources. At least one physical copy of each text is also available in the physical SCI L037 CS Systems Lab for use within the CS department area. Please use them in the data lab area and return them to the shelf when you are done.

We use one primary textbook extensively:

Other textbooks are used during the first part of the course:

We recommend a good reference on the C programming language. Here are a couple solid options:

Additional materials will be posted directly on the course website.

Preparing for Class Meetings

Before each class meeting, complete the required preparation steps listed in the topics for the day. Preparation varies from day to day, but usually consists of some combination of watching videos, reading, or trying small exercises. Expect the preparation to take more than a few minutes. Synchronous class activities will build on ideas in preparation material.

How to watch videos for CS 240

Many topics will have videos attached. When asked to watch these videos for preparation, or if you use them for reference at any time:

  • You can view them on YouTube (nocookie version without tracking) or download/watch the MP4 files directly.
  • Take notes like you would in class.
  • You might find it helpful to download a copy of the slides to follow along or take notes.
  • It’s fine to pause and take breaks whenever you want!
  • You do not need to watch all the videos from one topic or even all the videos assigned for one day of preparation in one sitting. The videos are usually broken up into chunks usually between 5 and 15 minutes length, occasionally a little shorter or longer.
  • When the talking head says to “try this,” pause the video to freeze the talking head in a bizarre pose, then actually try the example, just like you would in class when we do an exercise together.

How to read for CS 240

Effective reading for computer science courses demands a staged approach. Aim for two types of reading:

Before class, do an initial reading of the any reading material assigned as preparation for class.

Do not worry about understanding every last detail.

Do aim to acquire:

  • A big-picture view of the pieces we will consider about this topic.
  • Some familiarity with basic mechanics of the ideas introduced.

To help distinguish core points from secondary concerns during initial reading, each reading is listed with one of two style directives:

  • Read means read for enough detail to do indicated reading exercises. If you do get stuck or confused by some details, do not worry. Make a note and move on. If we do not clear up your confusion in class, ask a question or come to office hours.
  • Skim means read for high-level ideas. Perhaps pick out a couple details that look interesting and accessible. Do not spend much time trying to understand all the details before moving on.

Learning how to identify essential vs. inessential details during a first reading is an important skill that takes time to develop. As the semester progresses, we will leave more of this to you.

Readings assignments may indicate specific exercises to try as you read before class. These are typically practice problems from the reading.

  • Try means work through enough of the exercise to see how the basics work. Do not feel obligated to finish every example. Do what is useful to you. (Do not submit anything.)

We typically highlight exercises that practice mechanics. Feel free to try other practice problems as well. They may require more time and critical thinking. We will explore such interesting examples in class.

After class, revisit readings in more depth and try more practice problems to work out details as needed.

More advice for reading

Our main text (CSAPP) sometimes goes into more detail than we will cover, so learning to “read around” extra detail is a useful skill, especially in your pre-class reading.

When reading from CSAPP:

  • “Asides” are optional. If you read them, skim them.
  • “New to C?” blocks can be useful, but usually only if they are short.
  • Some sections (e.g., 2.2 - 2.4 on integer and floating point representations) can be too dense for our purposes. We try steer you around them, but if you find other things getting dense, flip to another reading or just make a note and jump ahead.
  • This book really shines with later material about machine/assembly language, caching, memory management, and other topics. We use it intermittently in the first section of the course, then extensively for the latter two.

Tia Newhall (Swarthmore College) has more good advice on reading computer science textbooks.

Material by Topic

This list of topics includes:

  • Topics covered in class meetings, with preparation directions and listings of all lecture materials, associated readings, and activities.
  • +Optional items that offer opportunities to explore further, but are not required.

The Plan

Preparation

Welcome to CS 240! Labs and lectures–including the first lab and lecture this week–are generally preceded by some asynchronous preparation to allow us to use meeting time productively. Please complete these steps in advance.

Before most CS 240 lectures:

  1. Prepare for topics listed on day of lecture on the course calendar. Each lecture topic on the calendar links to a section on this page with preparation steps to complete ahead of lecture and materials for the topic. For Monday, there is no required preparation, but it may be helpful to skim the Digital Logic reading. For Thursday, there is required preparation.

Before your first CS 240 lab:

  1. Complete the first pre-lab assignment by watching this playlist of three “Computer Science Crash Course” videos about computing history and basic electronic building blocks for digital computation. For following labs, lab preparation and materials will be provided separately by Peter on the lab page.
  2. Bookmark and tour the main CS 240 course website, your central source for all course info and materials, and review course logistics and policies.

By the end of the day on Wednesday:

  1. Complete the intros survey, in which you will introduce yourself to your instructors, learn about the course, and remind yourself how to connect to cs.wellesley.edu = tempest.wellesly.edu.
  2. Skim reading 3 (listed just below, in “Materials”) for general background on the working of modern computers.

Materials

Slides: ➊ plan.pdf ➍ plan-4up.pdf

Readings:

  1. Read: About CS 240 (syllabus and policies)
  2. Read: Lab policies
  3. Skim: CSAPP 1.0 - 1.7, 1.9.2 - 1.10

Computational Building Blocks

Digital Logic

Preparation

After Monday’s class:

  • Reading 1 (below).

Materials

Exercises:

Slides: ➊ gates.pdf ➍ gates-4up.pdf

Readings:

  1. Read: DDCA 1.5, 2.1-2.4 (pages 51-65), 2.8.1 (pages 79-80)

Data as Bits

Preparation

Before class Thurs Jan 25:

  1. Reading 1 (below).
  2. Watch videos 1–7.

The YouTube viewing option may be useful if you wish to watch faster or slower.

After class Mon Jan 29

  1. Follow up with videos on any remaining topics we did not cover in class.
  2. Review extra detail in Readings 2-4 as needed.
  3. Sometime before starting on next week’s Zero and Bits assignments, try out the practice Binary & Hex + Bitwise, Logical & Shift Operators in C exercises and compare your solutions with the SOLUTIONS doc.

Materials

Exercises:

Slides: ➊ bits.pdf ➍ bits-4up.pdf

Videos: YouTube☰ yt playlist Data as Bits

  1. ▸ mp4 YouTube yt Positional Number Representation and Binary
  2. ▸ mp4 YouTube yt Conversion Between Binary and Decimal
  3. ▸ mp4 YouTube yt Binary Arithmetic
  4. ▸ mp4 YouTube yt Bytes and Hexadecimal
  5. ▸ mp4 YouTube yt Fixed-size Data Types
  6. ▸ mp4 YouTube yt Bitwise Operators
  7. ▸ mp4 YouTube yt Bitwise Operator Practice
  8. ▸ mp4 YouTube yt Bit Sets
    Errors:
    • The ~a set complement example should be ~b. The slides have been updated.
  9. ▸ mp4 YouTube yt Boolean Logical Operators
  10. ▸ mp4 YouTube yt Card Encoding Ideas
  11. ▸ mp4 YouTube yt Compact Encodings with Bit Fields and Masks
  12. Mask Practice (see exercise above)
  13. ▸ mp4 YouTube yt Bit Shifting
  14. ▸ mp4 YouTube yt Shift-and-Mask Puzzle
  15. ▸ mp4 YouTube yt Shift-and-Mask Review

Readings:

  1. Preparing for Class Meetings in CS 240, including tips for effective watching and reading.
  2. Binary and hexadecimal number systems
  3. Information as bits + context
    • Read: CSAPP 2 - 2.1.2
    • Skim: CSAPP 2.1.4 - 2.1.5.
  4. Bitwise Boolean algebra and bit manipulation
    • Read: CSAPP 2.1.6 - 2.1.9 (including the Asides.)
    • Optional: K&R 2.7, 2.9 for C reference

Integer Representation

Preparation

Before lecture on Mon Jan 29:

  1. Videos 1-4. Short on time? Skip videos 2 and 4.

After the second lecture on Thur Feb 1:

  1. Follow up with videos on any remaining topics we did not cover in class, most likely including:
    • Shifts as arithmetic (video 11) and how to compose them to accomplish general multiplication (videos 12-14).
    • Converting between types (video 15).
  2. Sometime before starting the Bits assignment: complete the Fixed-Sized Integer Exercises and review their solutions. These are excellent practice to prepare for the two’s-complement puzzles in Bits.
  3. Review any other videos or readings as needed.

Materials

Exercises:

Slides: ➊ integers.pdf ➍ integers-4up.pdf

Videos: YouTube☰ yt playlist Integer Representation

  1. ▸ mp4 YouTube yt Unsigned Representation, Modular Arithmetic, Overflow
  2. ▸ mp4 YouTube yt Sign-Magnitude Representation
  3. ▸ mp4 YouTube yt Two's Complement Representation
  4. ▸ mp4 YouTube yt Two's Complement Examples
  5. ▸ mp4 YouTube yt Two's Complement Addition
  6. ▸ mp4 YouTube yt Two's Complement Overflow
  7. ▸ mp4 YouTube yt Overflow and Reliability
  8. ▸ mp4 YouTube yt Two's Complement is Awesome, Complement Rules
  9. ▸ mp4 YouTube yt Deriving Two's Complement
  10. ▸ mp4 YouTube yt Sign Extension
  11. ▸ mp4 YouTube yt Shift Arithmetic
  12. ▸ mp4 YouTube yt Shift and Add
  13. ▸ mp4 YouTube yt Shift and Add Puzzle Review
  14. ▸ mp4 YouTube yt Muliplication
  15. ▸ mp4 YouTube yt Converting Between Unsigned and Signed Types

Readings:

Refer to this material only after videos/class. We’d like to introduce signed integer representations before you read about them.

As you read, focus on the positional representation of signed integers more than the mechanics of how to convert from integer representation to the representation you know well.

  1. For the basics, read one of:

  2. Then, for reference on integer multiplication and division, their relation to bitwise operations, and sign extension:

    • Skim: CSAPP 2.2.4 - 2.2.8.
    • Read: CSAPP 2.3.4-2.3.8

Combinational Logic

Preparation

Before lecture on Mon Feb 5

  • Do Reading 1 on multi-bit muxes and decoders.

Materials

Slides: ➊ mux.pdf ➍ mux-4up.pdf

Readings:

  1. Multiplexers and decoders: DDCA 2.8 (pages 79-84)

Arithmetic Logic

Preparation

Before lecture on Mon Feb 5

  • Skim Readings 1 & 2.

Before lab on Wed Feb 7

  • Go over the reading in more detail as needed.

Materials

Slides: ➊ alu.pdf ➍ alu-4up.pdf

Readings:

  1. Adders, one of:
    • DDCA 5.1 - 5.2.1 (pages 233-240) up through Ripple Carry Adders (feel free to skim beyond if you are curious, ignore Verilog and VHDL)
    • Digital Circuits: Adders up until Carry Lookahead Adder (feel free to skim beyond if you are curious)
  2. Arithmetic Logic Unit (high-level organization), one of:

    We will look at details of a specific ALU design in class.

Sequential Logic

Preparation

Before lecture on Thurs Feb 8

  • Skim Reading 1.

Before lab on Weds Feb 7

  • Redo Reading 1 for details.
  • Skim Reading 2 for a bit more on RAM.

Materials

Slides: ➊ registers.pdf ➍ registers-4up.pdf

Readings:

  1. Latches, Flip-Flops, Registers:
    • DDCA 3.0 - 3.2.4 (pages 103-109)
      • Note for context: In class, we use the terms leader and follower to describe the component latches of a D flip-flop. This textbook uses a different terminology that has been widely used in the past to describe flip-flops (and a handful of other computer systems concepts that CS 240 does not consider) by analogy to enslavement. We do not use that terminology in class. We ask that you also use the leader/follower terms.
  2. Random Access memory (basics):

A Simple Processor

Preparation

Before lecture on Mon Feb 12:

  • Skim one option for Reading 1.

Before lecture on Thurs Feb 15:

  • Review the reading as needed.

Solutions to in-class exercises

You can find the solutions to the in-class exercises can be found here. Please do not open these until we go through the in-class exercises.

Materials

Slides: ➊ arch.pdf ➍ arch-4up.pdf

Readings:

Read for general organization and design points about instruction set architecture and microarchitecture. We will build our own toy architecture in class and lab.

  1. Read one of:

Hardware-Software Interface

Programming with Memory

Preparation

Before class on Feb 20

No lecture prep (focus on studying for Exam 1).

Before class on Feb 26

  • Read CSAPP 2.1.0, 2.1.3.
  • Read Section 1 of Pointer Basics.
  • Videos: 1-2 (some overlap with what we covered in the HW ISA).

Before lab on Feb 28

  • Videos: 13 (C strings), 15-17 (null-termination, dynamic memory intro).
  • We will go over these topics on Thursday with a special focus on the exercises, but seeing the material before lab will help you complete this week’s lab notebook.

Before class on Feb 29

  • Consult readings for additional information on the low-level memory model and programming in C.

After class on Feb 29

  • Finish videos 19-21.

Materials

Slides: ➊ memory.pdf ➍ memory-4up.pdf

Videos: YouTube☰ yt playlist Programming with Memory

  1. ▸ mp4 YouTube yt Byte-Addressable Memory
  2. ▸ mp4 YouTube yt Multi-Byte Values in Memory
  3. ▸ mp4 YouTube yt Data, Addresses, Pointers
  4. ▸ mp4 YouTube yt C Variables as Memory Locations
  5. ▸ mp4 YouTube yt C Pointer Primitives
  6. ▸ mp4 YouTube yt C Pointer Example
  7. ▸ mp4 YouTube yt C Arrays
  8. ▸ mp4 YouTube yt C Arrays and Pointers
  9. ▸ mp4 YouTube yt C Pointer Arithmetic
  10. ▸ mp4 YouTube yt C Array Sizing
  11. ▸ mp4 YouTube yt C Array Expression Examples
  12. ▸ mp4 YouTube yt Pointer Exercises Intro
  13. ▸ mp4 YouTube yt C Strings
  14. ▸ mp4 YouTube yt C Strings as char* and Cursor Pointer Style
  15. ▸ mp4 YouTube yt C 0, '\0', and NULL
  16. ▸ mp4 YouTube yt Memory Address Space Layout
  17. ▸ mp4 YouTube yt C Memory Allocation with malloc/free
  18. ▸ mp4 YouTube yt C Arrays of Pointers to Arrays
  19. ▸ mp4 YouTube yt zipCount Review
  20. ▸ mp4 YouTube yt C scanf and Memory Errors Teaser
  21. ▸ mp4 YouTube yt Why C?

Readings:

General memory model:

  • +Optionally, read: SCO 2.2.2 - 2.2.3, 5.1.2 (stop at “Note that having separate address spaces for instructions and data”)
  • Read: CSAPP 2.1.0, 2.1.3 - 2.1.4

Mix and match to start learning about addresses and pointers in C:

+Reasoning about Programs (optional)

+Optional: This topic is an optional opportunity for further depth or exploration.

Preparation

No preparation.

Materials

Slides: ➊ assertions.pdf ➍ assertions-4up.pdf

Readings:

In most semesters, we do not have time to cover this topic in lecture, but we ask you to skim these resources.

x86 Basics

Preparation

For Monday, March 4:

  • Videos 1 (Intro & History).

Before lab on Wednesday, March 6:

  • Videos 7-9.

After Thursday, March 7:

  • Videos TBA based on Thursday’s class.

Materials

Exercises:

Slides: ➊ x86-basics.pdf ➍ x86-basics-4up.pdf

Videos: YouTube☰ yt playlist x86 Basics

  1. ▸ mp4 YouTube yt Intro and History
  2. ▸ mp4 YouTube yt Registers, Data Movement Instructions, and Memory Addressing Modes
  3. ▸ mp4 YouTube yt Memory Examples
  4. ▸ mp4 YouTube yt Memory Addressing Review
  5. ▸ mp4 YouTube yt Load Effective Address (lea)
  6. ▸ mp4 YouTube yt Procedure Call Stack Basics
  7. ▸ mp4 YouTube yt Arithmetic and Logic Instructions, arith Exercise Setup
  8. ▸ mp4 YouTube yt arith Exercise Review, logical Exercise Setup
  9. ▸ mp4 YouTube yt logical Exercise Review

Readings:

  1. Background

  2. Data Movement

    • Read: CSAPP 3.3 - 3.4 (including “New to C?” to help remember those pointers…)
    • Suggested Exercises: try CSAPP practice problems 3.1, 3.2. Take a look at practice problem 3.5, but don’t spend too long on it. We’ll try more like this in class.
  3. Load Effective Address:

  4. Arithmetic

    • Read: CSAPP 3.5 - 3.5.4
    • Suggested Exercises: try CSAPP practice problems 3.8, 3.9. (Note x <<= 4; is the same as x = x << 4;.)
    • Skim: CSAPP 3.5.5
  5. x86 Machine Diagram

x86 Control Flow

Preparation

Before lab on Wednesday, March 6:

  • Videos 1-2.

Before lecture on Thursday, March 7:

  • Readings 1-2.

Materials

Exercises:

Slides: ➊ x86-control.pdf ➍ x86-control-4up.pdf

Videos: YouTube☰ yt playlist x86 Control Flow

  1. ▸ mp4 YouTube yt Condition Codes, Comparisons, and Tests
    Errors:
    • The example for the gt function should use long, not int, as the type of its arguments.
  2. ▸ mp4 YouTube yt Jumps, Translating If-Else, and absdiff Exercise Setup
  3. ▸ mp4 YouTube yt absdiff Exercise Review, goto, and If Compilation Exercise Setup
  4. ▸ mp4 YouTube yt If Compilation Exercise Review and PC-Relative Addressing
  5. ▸ mp4 YouTube yt Translating Loops
  6. ▸ mp4 YouTube yt Conditional Moves
  7. ▸ mp4 YouTube yt Translating Switch Statements with Jump Tables
  8. ▸ mp4 YouTube yt Translating Switch Statement Cases, Reverse Engineering Switches

Readings:

  1. Comparisons, Tests, and Jumps

    • Read: CSAPP 3.6 - 3.6.4
    • Suggested Exercises: Try CSAPP practice problems 3.13 - 3.14. Just consider what operator you’d put in place of COMP or TEST to match the assembly code. (Don’t worry about #define etc. if you don’t remember how macros work.)
  2. Translating if conditionals

    • Read: CSAPP 3.6.5
    • Suggested Exercises: CSAPP practice problem 3.16
  3. Translating loops

    • Read: CSAPP 3.6.7
    • Suggested Exercises: CSAPP practice problems 3.23, 3.24
  4. Translating switch statements

    • Skim: CSAPP 3.6.8, 3.6.6
  5. x86 Machine Diagram

x86 Procedures, Call Stack

Preparation

Before lecture on Monday, March 11:

  • Skim readings 1-2.

Before lab Wednesday, March 13

  • Watch videos 5-6 for register saving conventions and a recursion example. We’ll go over register saving conventions in class on Thursday.

After lecture Thursday, March 14

  • Review readings and videos as needed.

Materials

Exercises:

Slides: ➊ x86-procedures.pdf ➍ x86-procedures-4up.pdf

Videos: YouTube☰ yt playlist x86 Procedures, Call Stack

  1. ▸ mp4 YouTube yt The Call Stack Stores Procedure Context
  2. ▸ mp4 YouTube yt Procedure Control Flow Instructions (call/ret), Data Flow Conventions, Puzzle Setup
  3. ▸ mp4 YouTube yt Procedure Puzzle Review
  4. ▸ mp4 YouTube yt Procedure and Stack Frame Example
  5. ▸ mp4 YouTube yt Register Saving Conventions, Callee-Save Example
  6. ▸ mp4 YouTube yt Recursion Example
  7. ▸ mp4 YouTube yt Stack Storage Example, Procedure Summary

Readings:

  1. Read: CSAPP 3.7 - 3.7.4
  2. Read: CSAPP 3.7.5 - 3.7.6
  3. x86 Machine Diagram

Representing Data Structures

Preparation

Before lecture Thursday, March 14

  • Complete reading 1.

After lecture Thursday, March 14

  • Videos 3-4 (2D array details) and 7 (linked-list struct example).
  • Review readings as needed.

Materials

Exercises:

Slides: ➊ data-structures.pdf ➍ data-structures-4up.pdf

Videos: YouTube☰ yt playlist Representing Data Structures

  1. ▸ mp4 YouTube yt Simple Arrays
  2. ▸ mp4 YouTube yt Multi-Level Arrays (Arrays of Pointers to Arrays of...)
    Errors:
    • In the copyleft example, the second and third movq should be movl and should be moved to and from %ecx instead of %rcx.
  3. ▸ mp4 YouTube yt Row-Major Multidimensional Arrays
  4. ▸ mp4 YouTube yt Row-Major Array Review
  5. ▸ mp4 YouTube yt Structs
  6. ▸ mp4 YouTube yt Struct Alignment
  7. ▸ mp4 YouTube yt Linked List Representation

Readings:

  1. Read: CSAPP 3.8.1 - 3.8.2 (review simple arrays)
  2. Read: CSAPP 3.8.3 - 3.8.4 (nested arrays)
  3. Read: CSAPP 3.9 (heterogeneous data structures)
  4. Read: CSAPP 3.10.1 (pointer review)
  5. x86 Machine Diagram

Buffer Overflows

Preparation

Before lecture Monday, March 25

  • Complete reading 1.

Before lecture Thursday, March 28

  • Review reading 1 as needed.

Materials

Exercises:

Slides: ➊ buffer.pdf ➍ buffer-4up.pdf

Videos: YouTube☰ yt playlist Buffer Overflows

  1. ▸ mp4 YouTube yt Overview
  2. ▸ mp4 YouTube yt Stack Layout and No Bounds Checking in C
  3. ▸ mp4 YouTube yt Example Overview
  4. ▸ mp4 YouTube yt Example 1 - Overwrite Padding (Lucky)
  5. ▸ mp4 YouTube yt Example 2 - Corruption and Segfault
  6. ▸ mp4 YouTube yt Example 3 - Silent Corruption and Arbitrary Code Execution
  7. ▸ mp4 YouTube yt Remote Code Execution and Avoiding Vulnerabilities

Readings:

  1. Read: CSAPP 3.10.3-3.10.4
  2. x86 Machine Diagram

Abstractions for Practical Systems

Process Model

Preparation

Before lecture Thursday, March 28

  • No preparation.

Materials

Slides: ➊ process.pdf ➍ process-4up.pdf

Readings:

  • Read: CSAPP 1.7, 8.2 - 8.4

Shells, Signals

Preparation

No preparation.

Materials

Slides: ➊ shell.pdf ➍ shell-4up.pdf

Memory Allocation

Preparation

For class on Thursday, April 4

No preparation.

For class on Monday, April 22

  • (Optional) skim readings 1-3.

For class on Thursday, April 25

  • Reviews readings 1-3.

Materials

Slides: ➊ malloc.pdf ➍ malloc-4up.pdf

Videos: YouTube☰ yt playlist Memory Allocation

  1. ▸ mp4 YouTube yt Allocator Basics
  2. ▸ mp4 YouTube yt Determining Block Size
  3. ▸ mp4 YouTube yt Block Format and Heap Layout
  4. ▸ mp4 YouTube yt Implicit Free List Search
  5. ▸ mp4 YouTube yt Implicit Free List Allocation and Splitting
  6. ▸ mp4 YouTube yt Implicit Free List Freeing and Coalescing
  7. ▸ mp4 YouTube yt Explicit Free Lists
  8. ▸ mp4 YouTube yt Explicit Free List Search, Allocation, and Splitting
  9. ▸ mp4 YouTube yt Explicit Free List Freeing and Coalescing
  10. ▸ mp4 YouTube yt Seglists and Allocation Summary
  11. ▸ mp4 YouTube yt Malloc Assignment - Block Format
    Errors:

Readings:

  1. Read: CSAPP 9.9 - 9.9.5 (basics)
  2. Read: CSAPP 9.9 - 9.9.12 (implicit free lists)
  3. Read: CSAPP 9.9.13 - 9.9.14 (explicit free lists and beyond)
  4. Skim: CSAPP 9.10 - 9.11 (garbage collection, C memory errors)

Memory Hierarchy, Cache

Preparation

Async class on Monday, April 29, 2024

Watch videos 1-8. Skim Reading 1.

Materials

Exercises:

Slides: ➊ cache.pdf ➍ cache-4up.pdf

Videos: YouTube☰ yt playlist Memory Hierarchy, Cache

  1. ▸ mp4 YouTube yt Motivating Example
  2. ▸ mp4 YouTube yt Cache Overview
  3. ▸ mp4 YouTube yt Cache Mechanics
  4. ▸ mp4 YouTube yt Locality
  5. ▸ mp4 YouTube yt More Locality Examples
  6. ▸ mp4 YouTube yt Cache Performance and the Hierarchical Memory Design
  7. ▸ mp4 YouTube yt Cache Organization
  8. ▸ mp4 YouTube yt Cache Blocks
  9. ▸ mp4 YouTube yt Direct-Mapped Cache Placement Policy and Cache Tags
  10. ▸ mp4 YouTube yt Address Fields
  11. ▸ mp4 YouTube yt Why Not Another Direct Mapping (Aside)
  12. ▸ mp4 YouTube yt Cache Puzzle 1
  13. ▸ mp4 YouTube yt Cache Conflicts and Associative Cache Placement Policies
  14. ▸ mp4 YouTube yt Cache Puzzle 2
  15. ▸ mp4 YouTube yt General Cache Dimensions and Organization
  16. ▸ mp4 YouTube yt General Cache Read Mechanics
  17. Cache Analysis Example 1: Spatial Locality in Direct-Mapped Caches
  18. Cache Analysis Example 2: Cache Conflicts in Direct-Mapped Caches
  19. Cache Analysis Example 3: Cache Conflicts Resolved by Associativity
  20. Types of Cache Misses
  21. Cache Write Policies
  22. Cache-Friendly Code and Summary

Readings:

  1. Memory Hierarchy, Locality, General Cache Mechanics, Direct-Mapped Caches
  2. Associative Caches, Cache Policies, and Performance
  3. Cache-Friendly Code

+Virtual Memory (optional)

+Optional: This topic is an optional opportunity for further depth or exploration.

Preparation

No preparation.

Materials

Slides: ➊ virtual-memory.pdf ➍ virtual-memory-4up.pdf

Readings:

+Threads (optional)

+Optional: This topic is an optional opportunity for further depth or exploration.

Preparation

No preparation.

Materials

Slides: ➊ threads.pdf ➍ threads-4up.pdf

Readings:

Code Examples: examples