1204 lines
44 KiB
Markdown
1204 lines
44 KiB
Markdown
---
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title: Instructions
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TARGET DECK: Obsidian::STEM
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FILE TAGS: x86-64
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tags:
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- x86-64
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---
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## Overview
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x86-64 instructions are designed so that commonly used instructions and those with fewer operands are encoded in a smaller number of bytes. Instructions range in length from 1 to 15 bytes.
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x86-64 assembly comes in two flavors: ATT and Intel. ATT is most common in Linux systems so I focus on that. The most important distinction between the two is operand ordering: Intel syntax lists multiple operands in reverse order compared to ATT.
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%%ANKI
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Basic
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x86-64 assembly comes in what two formats?
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Back: ATT and Intel.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1710959313804-->
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END%%
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%%ANKI
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Basic
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Which x86-64 assembly format does Linux use?
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Back: ATT.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1710959313810-->
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END%%
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%%ANKI
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Basic
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Which x86-64 assembly format does Microsoft use?
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Back: Intel.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1710959313814-->
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END%%
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%%ANKI
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Basic
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What is the "most confusing" difference between ATT and Intel assembly?
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Back: Multiple operands in one are listed in reverse order relative to the other.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1710959313818-->
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END%%
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%%ANKI
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Basic
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What term describes assembly lines with a leading `.`?
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Back: Directives.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1710959313822-->
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END%%
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%%ANKI
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Basic
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Assembly directives are important for what two programs?
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Back: The assembler and the linker.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1710959313826-->
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END%%
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## Instruction Classes
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There are three types of operands:
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* **Immediates**. These denote constant values. In ATT assembly, they are written with a `$` followed by an integer using standard C notation.
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* **Registers**. These denote the contents of a register.
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* **Memory**. These denote some memory location according to a computed address (i.e. the **effective address**).
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| Type | Form | Operand Value | Name |
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| --------- | ----------------- | ---------------------------------- | ------------------- |
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| Immediate | $\textdollar Imm$ | $Imm$ | Immediate |
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| Register | $r_a$ | $R[r_a]$ | Register |
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| Memory | $Imm$ | $M[Imm]$ | Absolute |
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| Memory | $(r_a)$ | $M[R[r_a]]$ | Indirect |
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| Memory | $Imm(r_b)$ | $M[Imm + R[r_b]]$ | Base + displacement |
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| Memory | $(r_b, r_i)$ | $M[R[r_b] + R[r_i]]$ | Indexed |
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| Memory | $Imm(r_b, r_i)$ | $M[Imm + R[r_b] + R[r_i]]$ | Indexed |
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| Memory | $(,r_i,s)$ | $M[R[r_i] \cdot s]$ | Scaled indexed |
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| Memory | $Imm(,r_i,s)$ | $M[Imm + R[r_i] \cdot s]$ | Scaled indexed |
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| Memory | $(r_b,r_i,s)$ | $M[R[r_b] + R[r_i] \cdot s]$ | Scaled indexed |
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| Memory | $Imm(r_b,r_i,s)$ | $M[Imm + R[r_b] + R[r_i] \cdot s]$ | Scaled indexed |
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%%ANKI
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Basic
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What are the three types of operands instructions can act on?
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Back: Immediates, registers, and memory addresses.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889877-->
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END%%
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%%ANKI
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Basic
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What are the types of source operands instructions can specify?
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Back: Immediates, registers, and memory addresses.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889887-->
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END%%
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%%ANKI
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Basic
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What are the types of destination operands instructions can specify?
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Back: Registers and memory addresses.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889894-->
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END%%
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%%ANKI
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Basic
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What does an immediate operand denote?
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Back: A constant value.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889897-->
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END%%
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%%ANKI
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Basic
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In ATT syntax, how is an immediate written?
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Back: As a `$$` followed by an integer using standard C notation.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889901-->
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END%%
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%%ANKI
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Basic
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In ATT syntax, how is a register written?
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Back: As a `%` followed by the name of the register.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889905-->
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END%%
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%%ANKI
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Basic
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What is the operand value of form $\textdollar Imm$?
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Back: $Imm$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889909-->
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END%%
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%%ANKI
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Basic
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What is the operand value of form $r_a$?
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Back: $R[r_a]$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889912-->
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END%%
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%%ANKI
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Basic
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What is the operand value of form $Imm$?
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Back: $M[Imm]$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889916-->
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END%%
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%%ANKI
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Basic
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What is the operand value of form $(r_a)$?
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Back: $M[R[r_a]]$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889920-->
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END%%
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%%ANKI
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Basic
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What is the operand value of form $Imm(r_b)$?
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Back: $M[Imm + R[r_b]]$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889923-->
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END%%
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%%ANKI
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Basic
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What is the operand value of form $(r_b, r_i)$?
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Back: $M[R[r_b] + R[r_i]]$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889927-->
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END%%
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%%ANKI
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Basic
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What is the operand value of form $Imm(r_b, r_i)$?
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Back: $M[Imm + R[r_b] + R[r_i]]$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889930-->
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END%%
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%%ANKI
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Basic
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What is the operand value of form $(,r_i,s)$?
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Back: $M[R[r_i] \cdot s]$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889933-->
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END%%
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%%ANKI
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Basic
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What is the operand value of form $Imm(,r_i,s)$?
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Back: $M[Imm + R[r_i] \cdot s]$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889937-->
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END%%
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%%ANKI
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Basic
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What is the operand value of form $(r_b,r_i,s)$?
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Back: $M[R[r_b] + R[r_i] \cdot s]$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889941-->
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END%%
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%%ANKI
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Basic
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What is the operand value of form $Imm(r_b,r_i,s)$?
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Back: $M[Imm + R[r_b] + R[r_i] \cdot s]$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889945-->
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END%%
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%%ANKI
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Basic
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What distinguishes operand value $r_a$ from $(r_a)$?
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Back: The former denotes the register value. The latter denotes the value in memory at the address stored in $r_a$.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889949-->
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END%%
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%%ANKI
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Basic
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What values can $s$ take on in operand form $Imm(r_b,r_i,s)$?
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Back: $1$, $2$, $4$, or $8$.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713212889952-->
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END%%
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%%ANKI
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Basic
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What operand form is named "immediate"?
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Back: $\textdollar Imm$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713213168875-->
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END%%
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%%ANKI
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Basic
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What operand form is named "register"?
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Back: $r_a$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713213168878-->
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END%%
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%%ANKI
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Basic
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What operand form is named "absolute"?
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Back: $Imm$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713213168881-->
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END%%
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%%ANKI
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Basic
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What operand form is named "indirect"?
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Back: $(r_a)$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713213168884-->
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END%%
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%%ANKI
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Basic
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What operand form is named "base + displacement"?
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Back: $Imm(r_b)$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713213168887-->
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END%%
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%%ANKI
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Basic
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What is the most general operand form named "indexed" (*not* "scaled indexed")?
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Back: $Imm(r_b, r_i)$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713213168890-->
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END%%
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%%ANKI
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Basic
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What is the most general operand form named "scaled indexed" (*not* indexed)?
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Back: $Imm(r_b, r_i, s)$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713213168894-->
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END%%
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### `MOV`
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The MOV instruction class has four primary variants: `movb`, `movw`, `movl`, and `movq`. There also exist zero extension and sign extension variations in the forms of MOVS and MOVZ.
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| Instruction | Operands | Effect | Description |
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| ------------ | -------- | ---------------- | ------------------------------------ |
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| `mov[bwlq]` | S, D | D <- S | Move byte/word/double word/quad word |
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| `movabsq` | I, R | R <- I | Move quad word |
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| `movzb[wlq]` | S, R | R <- ZE(S) | Move zero-extended byte |
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| `movzw[lq]` | S, R | R <- ZE(S) | Move zero-extended word |
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| `movsb[wlq]` | S, R | R <- SE(S) | Move sign-extended byte |
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| `movsw[lq]` | S, R | R <- SE(S) | Move sign-extended word |
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| `movslq` | S, R | R <- SE(S) | Move sign-extended double word |
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| `cltq` | | %rax <- SE(%eax) | Sign-extend `%eax` to `%rax` |
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Notice there is no `movzlq` instruction. `movl` covers this functionality since, by convention, instructions moving double words into a 64-bit register automatically zeroes out the upper 32 bits.
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%%ANKI
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Basic
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What four variants does `MOV` instructions take on in x86-64?
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Back: `movb`, `movw`, `movl`, `movq`
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713625933397-->
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END%%
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%%ANKI
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Basic
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How many bytes does a `movb` instruction operate on?
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Back: One.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713625933403-->
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END%%
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%%ANKI
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Basic
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How many bytes does a `movw` instruction operate on?
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Back: Two.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713625933406-->
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END%%
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%%ANKI
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Basic
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How many bytes does a `movl` instruction operate on?
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Back: Four.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713625933409-->
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END%%
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%%ANKI
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Basic
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How many bytes does a `movq` instruction operate on?
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Back: Eight.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713625933413-->
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END%%
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%%ANKI
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Basic
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What combination of source and destination types is prohibited in `MOV` instructions?
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Back: A source and destination memory address.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713625933416-->
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END%%
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%%ANKI
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Basic
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What is the result of `%rax` after instruction `movl $0x4050,%eax`?
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Back: Upper 32-bits is `0` and lower 32-bits is `0x4050`.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713625933419-->
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END%%
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%%ANKI
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Basic
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What is the result of `%rax` after instruction `movq $0x4050,%rax`?
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Back: The 64-bit value is `0x4050`.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713625933423-->
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END%%
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%%ANKI
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Basic
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What is the result of `%rax` after instruction `movw $0x4050,%ax`?
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Back: The upper 48 bits are unchanged and the lower 16 bits are `0x4050`.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713625933426-->
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END%%
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%%ANKI
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Basic
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What is the result of `%rax` after instruction `movb $0x4050,%al`?
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Back: The upper 56 bits are unchanged and the lower 8 bits are `0x50`.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713625933430-->
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END%%
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%%ANKI
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Basic
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What is the result of `%rax` after instruction `movw $0x4050,%al`?
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Back: N/A. Invalid operand for instruction.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713625933433-->
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END%%
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%%ANKI
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Basic
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What caveat is applied to the source operand of `movq`?
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Back: Immediates are 32-bit two's-complement numbers sign extended to 64-bits.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713625933437-->
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END%%
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%%ANKI
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Basic
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What `mov` instruction is needed when working with 64-bit immediate sources?
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Back: `movabsq`
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713625933441-->
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END%%
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%%ANKI
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Basic
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What purpose does `movabsq` solve that `movq` does not?
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Back: `movabsq` can have an arbitrary 64-bit immediate source.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713625933448-->
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END%%
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%%ANKI
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Basic
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What is the result of `%rax` after the following instructions?
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```asm
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movabsq $0x0011223344556677, %rax
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movb $-1, %al
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```
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Back: `0x00112233445566FF`
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1713625933452-->
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END%%
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%%ANKI
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Basic
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What is the result of `%rax` after the following instructions?
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```asm
|
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movabsq $0x0011223344556677, %rax
|
|
movw $-1, %ax
|
|
```
|
|
Back: `0x001122334455FFFF`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1713625933455-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What is the result of `%rax` after the following instructions?
|
|
```asm
|
|
movabsq $0x0011223344556677, %rax
|
|
movl $-1, %eax
|
|
```
|
|
Back: `0x00000000FFFFFFFF`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1713625933458-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What is the result of `%rax` after the following instructions?
|
|
```asm
|
|
movabsq $0x0011223344556677, %rax
|
|
movq $-1, %rax
|
|
```
|
|
Back: `0xFFFFFFFFFFFFFFFF`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1713625933461-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What is the `MOVZ` instruction class?
|
|
Back: `MOV` instructions that zero extend the source to fit into the destination.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1713625933464-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What is the `MOVS` instruction class?
|
|
Back: `MOV` instructions that sign extend the source to fit into the destination.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1713625933466-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What does the `movzbw` instruction do?
|
|
Back: Moves a zero-extended byte to a word.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1713625933469-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What does the `movslq` instruction do?
|
|
Back: Moves a sign-extended double word to a quad word.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1713625933472-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What does the `movslb` instruction do?
|
|
Back: N/A. This instruction does not exist.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1713625933475-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What combinatorial argument explains the number of `MOVS` instructions?
|
|
Back: There exists an instruction for each smaller declaration to larger declaration.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1713625933478-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What `MOVZ` instruction is "missing"?
|
|
Back: `movzlq`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1713625933481-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Why does there not exist a `movzlq` instruction?
|
|
Back: Because `movl` already zeroes out the upper bits of a destination register.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1713625933483-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What is the result of `%rax` after the following instructions?
|
|
```asm
|
|
movabsq $0x0011223344556677, %rax
|
|
movb $0xAA, %dl
|
|
movb %dl,%al
|
|
```
|
|
Back: `0x00112233445566AA`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1713625933486-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What is the result of `%rax` after the following instructions?
|
|
```asm
|
|
movabsq $0x0011223344556677, %rax
|
|
movb $0xAA, %dl
|
|
movsbq %dl,%rax
|
|
```
|
|
Back: `0xFFFFFFFFFFFFFFAA`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1713625933489-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What is the result of `%rax` after the following instructions?
|
|
```asm
|
|
movabsq $0x0011223344556677, %rax
|
|
movb $0xAA, %dl
|
|
movzbq %dl,%rax
|
|
```
|
|
Back: `0x00000000000000AA`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1713625933491-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Cloze
|
|
A {pointer} in C is a {memory address} in x86.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
Tags: c17
|
|
<!--ID: 1714677608754-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Dereferencing a pointer in C equates to what two operations in x86?
|
|
Back: Copying the pointer into a register and then using the register in a memory reference.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
Tags: c17
|
|
<!--ID: 1714677608758-->
|
|
END%%
|
|
|
|
### PUSH and POP
|
|
|
|
| Instruction | Operands | Effect | Description |
|
|
| ----------- | -------- | ------------------------------------------- | -------------- |
|
|
| `pushq` | S | R[%rsp] <- R[%rsp] - 8<br />M[R[%rsp]] <- S | Push quad word |
|
|
| `popq` | D | D <- M[R[%rsp]]<br />R[%rsp] <- R[%rsp] + 8 | Pop quad word |
|
|
|
|
In x86 processors, the stack grows downward, with the "top" of the stack corresponding to lower addresses.
|
|
|
|
%%ANKI
|
|
Basic
|
|
In what direction do x86-64 stacks grow?
|
|
Back: Downward.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715377284944-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Cloze
|
|
The x86-64 stack grows such that the top element has the {lowest} address of all stack elements.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715377284947-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What instruction is used to push elements onto the stack?
|
|
Back: `pushq`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715377284951-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What instruction is used to pop elements off of the stack?
|
|
Back: `popq`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715377284955-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
How is `pushq %rbp` equivalently written using a pair of instructions?
|
|
Back:
|
|
```asm
|
|
subq 8,%rsp
|
|
movq %rbp,(%rsp)
|
|
```
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715377284959-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
How is `popq %rax` equivalently written using a pair of instructions?
|
|
Back:
|
|
```asm
|
|
movq (%rsp),%rax
|
|
addq 8,%rsp
|
|
```
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715377284962-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Cloze
|
|
{1:`pushq`} is to {2:`subq`} as {2:`popq`} is to {1:`addq`}.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715377284966-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
If `%rsp` has value `0x108`, what value does it have after a `pushq` instruction?
|
|
Back: `0x100`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715377284971-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
If `%rsp` has value `0x108`, what value does it have after a `popq` instruction?
|
|
Back: `0x110`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715377284975-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Which register contains a pointer to the top of the stack?
|
|
Back: `%rsp`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715377284980-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What is the `%rsp` register typically used for?
|
|
Back: The stack pointer.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715377284985-->
|
|
END%%
|
|
|
|
### Load Effective Address
|
|
|
|
| Instruction | Operands | Effect | Description |
|
|
| ----------- | -------- | ------- | ---------------------- |
|
|
| `leaq` | S, D | D <- &S | Load effective address |
|
|
|
|
`leaq` is a variant of MOV. The first operand appears to be a memory address, but instead of reading from the designated location, the instruction copies the effective address to the designated location (a register).
|
|
|
|
%%ANKI
|
|
Basic
|
|
`leaq` is considered a variant of what other instruction class?
|
|
Back: `MOV`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715780601450-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Why is the `leaq` instruction named the way it is?
|
|
Back: It stands for **l**oad **e**ffective **a**ddress.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715780601455-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Cloze
|
|
The {`leaq`} instruction is to x86-64 as the {`&`} operator is to C.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
Tags: c17
|
|
<!--ID: 1715780601458-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Which x86-64 instruction is used to generate pointers?
|
|
Back: `leaq`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715780601461-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Why doesn't `leaq` have any other size variants?
|
|
Back: x96-64 addresses are always 64-bit.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715780601464-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Suppose `%rdx` contains $x$. Use `leaq` to set `%rax` to $5x + 7$.
|
|
Back: `leaq 7(%rdx, %rdx, 4), %rax`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715780601467-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Besides effective memory computations, how else is `leaq` used?
|
|
Back: For certain arithmetic operations.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715780601469-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Assume `%rdx` holds $q$. What is the value of `%rax` in the following?
|
|
```asm
|
|
leaq 9(%rdx),%rax
|
|
```
|
|
Back: $9 + q$
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715781031929-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Assume `%rbx` holds $p$ and `%rdx` holds $q$. What is the value of `%rax` in the following?
|
|
```asm
|
|
leaq (%rdx, %rbx),%rax
|
|
```
|
|
Back: $q + q$
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715781031935-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Assume `%rbx` holds $p$. What is the value of `%rax` in the following?
|
|
```asm
|
|
leaq 2(%rbx, %rbx, 7),%rax
|
|
```
|
|
Back: $2 + 8p$
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715781031938-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Assume `%rdx` holds $q$. What is the value of `%rax` in the following?
|
|
```asm
|
|
leaq 0xE(, %rdx, 3),%rax
|
|
```
|
|
Back: $14 + 3q$
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1715781031941-->
|
|
END%%
|
|
|
|
### Unary Operations
|
|
|
|
| Instruction | Operands | Effect | Description |
|
|
| ----------- | -------- | ---------- | ------------ |
|
|
| `inc[bwlq]` | D | D <- D + 1 | Increment |
|
|
| `dec[bwlq]` | D | D <- D - 1 | Decrement |
|
|
| `neg[bwlq]` | D | D <- -D | Negate |
|
|
| `not[bwlq]` | D | D <- ~D | Complement |
|
|
|
|
%%ANKI
|
|
Basic
|
|
What four variants do `INC` instructions take on in x86-64?
|
|
Back: `incb`, `incw`, `incl`, `incq`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716125986895-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Which instruction class corresponds to effect $D \leftarrow D + 1$?
|
|
Back: `INC`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716127743477-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What source/destination types are permitted in unary instructions?
|
|
Back: Registers and memory addresses.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716125986904-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What do the instructions in the `INC` instruction class do?
|
|
Back: Increments the specified destination by $1$.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716125986907-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Cloze
|
|
The {`INC`} instruction class is to x86-64 whereas the {`++`} operator is to C.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
Tags: c17
|
|
<!--ID: 1716126147793-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What do the instructions in the `DEC` instruction class do?
|
|
Back: Decrements the specified destination by $1$.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716125986910-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Which instruction class corresponds to effect $D \leftarrow D - 1$?
|
|
Back: `DEC`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716127743483-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Cloze
|
|
The {`DEC`} instruction class is to x86-64 whereas the {`--`} operator is to C.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
Tags: c17
|
|
<!--ID: 1716126147798-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What do the instructions in the `NEG` instruction class do?
|
|
Back: Negates the specified destination.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716125986913-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Which instruction class corresponds to effect $D \leftarrow -D$?
|
|
Back: `NEG`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716127743486-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Cloze
|
|
The {`NEG`} instruction class is to x86-64 whereas the {`-`} *unary* operator is to C.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
Tags: c17
|
|
<!--ID: 1716126147801-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What do the instructions in the `NOT` instruction class do?
|
|
Back: Complements the specified destination.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716125986916-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Which instruction class corresponds to effect $D \leftarrow \textasciitilde D$?
|
|
Back: `NOT`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716127743488-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Cloze
|
|
The {`NOT`} instruction class is to x86-64 whereas the {`~`} operator is to C.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
Tags: c17
|
|
<!--ID: 1716126147804-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Cloze
|
|
{1:`NEG`} is to {2:negation} whereas {2:`NOT`} is to {1:complement}.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716381321937-->
|
|
END%%
|
|
|
|
### Binary Operations
|
|
|
|
| Instruction | Operands | Effect | Description |
|
|
| ------------ | -------- | ----------- | -------------- |
|
|
| `add[bwlq]` | S, D | D <- D + S | Addition |
|
|
| `sub[bwlq]` | S, D | D <- D - S | Subtraction |
|
|
| `imul[bwlq]` | S, D | D <- D * S | Multiplication |
|
|
| `xor[bwlq]` | S, D | D <- D ^ S | Exclusive-or |
|
|
| `or[bwlq]` | S, D | D <- D \| S | Or |
|
|
| `and[bwlq]` | S, D | D <- D & S | And |
|
|
|
|
%%ANKI
|
|
Basic
|
|
What four variants do `ADD` instructions take on in x86-64?
|
|
Back: `addb`, `addw`, `addl`, `addq`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716127743491-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What combination of source and destination types is prohibited in `ADD` instructions?
|
|
Back: A source and destination memory address.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716127743494-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Which instruction class corresponds to effect $D \leftarrow D + S$?
|
|
Back: `ADD`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716127743497-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Cloze
|
|
The {`ADD`} instruction class is to x86-64 as the {`+=`} operator is to C.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
Tags: c17
|
|
<!--ID: 1716128138030-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Which instruction class corresponds to effect $D \leftarrow D - S$?
|
|
Back: `SUB`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716127743500-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Which `SUB` instruction is equivalent to `decq %rcx`?
|
|
Back:
|
|
```asm
|
|
subq $1, %rcx
|
|
```
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716127853102-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
How does Bryant et al. recommend reading `SUB` instructions?
|
|
Back: As subtracting the first operand *from* the second.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716127853106-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Cloze
|
|
The {`SUB`} instruction class is to x86-64 as the {`-=`} operator is to C.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
Tags: c17
|
|
<!--ID: 1716128138033-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Which instruction class corresponds to effect $D \leftarrow D * S$?
|
|
Back: `IMUL`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716127743502-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Cloze
|
|
The {`IMUL`} instruction class is to x86-64 as the {`*=`} operator is to C.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
Tags: c17
|
|
<!--ID: 1716128138036-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Which instruction class corresponds to effect $D \leftarrow D \;^\wedge\; S$?
|
|
Back: `XOR`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716127743505-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Cloze
|
|
The {`XOR`} instruction class is to x86-64 as the {`^=`} operator is to C.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
Tags: c17
|
|
<!--ID: 1716128138040-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Which instruction class corresponds to effect $D \leftarrow D \mid S$?
|
|
Back: `OR`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716127743508-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Cloze
|
|
The {`OR`} instruction class is to x86-64 as the {`|=`} operator is to C.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
Tags: c17
|
|
<!--ID: 1716128138043-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Which instruction class corresponds to effect $D \leftarrow D \;\&\; S$?
|
|
Back: `AND`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716127743511-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Cloze
|
|
The {`AND`} instruction class is to x86-64 as the {`&=`} operator is to C.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
Tags: c17
|
|
<!--ID: 1716128138046-->
|
|
END%%
|
|
|
|
### Shift Operations
|
|
|
|
| Instruction | Operands | Effect | Description |
|
|
| ----------- | -------- | ------------ | ---------------------- |
|
|
| `sal[bwlq]` | k, D | D <- D << k | Left shift |
|
|
| `shl[bwlq]` | k, D | D <- D << k | Left shift |
|
|
| `sar[bwlq]` | k, D | D <- D >> k | Arithmetic right shift |
|
|
| `shr[bwlq]` | k, D | D <- D >>> k | Logical right shift |
|
|
|
|
%%ANKI
|
|
Basic
|
|
What do instructions in the `SAL` instruction class do?
|
|
Back: Performs a left shift.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716226827710-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What do instructions in the `SHL` instruction class do?
|
|
Back: Performs a left shift.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716226827717-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Which instruction classes are related to left shifts?
|
|
Back: `SAL` and `SHL`.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716226827720-->
|
|
END%%
|
|
|
|
|
|
%%ANKI
|
|
Basic
|
|
Which instruction classes are related to right shifts?
|
|
Back: `SAR` and `SHR`.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716226827723-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What do instructions in the `SAR` instruction class do?
|
|
Back: Performs an arithmetic right shift.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716226827725-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What do instructions in the `SHR` instruction class do?
|
|
Back: Performs a logical right shift.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716226827729-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What distinguishes the `SAR` and `SHR` instruction classes?
|
|
Back: The former is arithmetic whereas the latter is logical.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716226827732-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What distinguishes the `SAL` and `SHL` instruction classes?
|
|
Back: N/A.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716226827736-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Which register are shift operations limited to?
|
|
Back: `%cl`
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716226827740-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
How many lower-order bits of `%cl` does e.g. `salb` look at?
|
|
Back: $3$
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716226827744-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What can the source of a shift operation be?
|
|
Back: An immediate or the `%cl` register.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716226827748-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What can the destination of a shift operation be?
|
|
Back: A register or memory location.
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716226827752-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
How many lower-order bits of `%cl` does e.g. `salw` look at?
|
|
Back: $4$
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716226827756-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
How many lower-order bits of `%cl` does e.g. `sall` look at?
|
|
Back: $5$
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716226827760-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
How many lower-order bits of `%cl` does e.g. `salq` look at?
|
|
Back: $6$
|
|
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
|
<!--ID: 1716226827764-->
|
|
END%%
|
|
|
|
## Bibliography
|
|
|
|
* Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|