Difference between revisions of "SPO600 64-bit Assembly Language Lab"

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[[Category:SPO600-future]]{{Chris Tyler Draft}}
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[[Category:SPO600 Labs]]
  
 
{{Admon/note|Purpose of this Lab|In this lab, you will experiment with assembler on the x86_64 and aarch64 platforms.}}
 
{{Admon/note|Purpose of this Lab|In this lab, you will experiment with assembler on the x86_64 and aarch64 platforms.}}
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     │  │  └── Makefile
 
     │  │  └── Makefile
 
     │  └── x86_64                # x86_64 assembler versions
 
     │  └── x86_64                # x86_64 assembler versions
     │      ├── hello-gas.s      # 64-bit instructions for assembley with the gnu assembler (called 'gas', /usr/bin/as)
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     │      ├── hello-gas.s      # 64-bit instructions with AT&T/gnu assembler syntax (called 'gas', /usr/bin/as)
     │      ├── hello-nasm.s      # 32-bit instructions for assembley with the nasm assembler (/usr/bin/nasm)
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     │      ├── hello-nasm.s      # 32-bit instructions with Intel/nasm assembler syntax (/usr/bin/nasm)
 
     │      └── Makefile
 
     │      └── Makefile
 
     └── c
 
     └── c
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Throughout this lab, take advantage of ''[[make and Makefiles|make]]'' whenever possible.
 
Throughout this lab, take advantage of ''[[make and Makefiles|make]]'' whenever possible.
  
=== Lab Tasks ===
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=== Group Lab Tasks ===
  
1. Build and run the C versions of the program for x86_64. Use objdump to disassemble and review the [[Machine Language|machine code]] in the binaries - make sure you understand it. Save the binaries for later review.
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1. Build and run the C versions of the program for x86_64.
  
2. Review, build, and run the x86_64 assembler code. Use objdump to disassemble and review the [[Machine Language|machine code]] in the binaries - make sure you understand it.
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2. Review, build, and run the x86_64 assembler code. Make sure you understand the code.
  
 
4. Build and run the C versions of the program for aarch64 (note: you may need to <code>make clean</code>).
 
4. Build and run the C versions of the program for aarch64 (note: you may need to <code>make clean</code>).
  
5. Review, build, and run the aarch64 assembler code. Use objdump to disassemble and review the machine code in the binaries, and make sure you understand it.
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5. Review, build, and run the aarch64 assembler code. Make sure you understand the code.
  
 
6. Here is a basic loop in x86_64 assembler:
 
6. Here is a basic loop in x86_64 assembler:
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  Loop: 9
 
  Loop: 9
  
{{Admon/tip|Character conversion|In order to print the loop index value, you will need to convert from an integer to digit character. In ASCII/ISO-9959-1/Unicode UTF-8, the digit characters are in the range 48-57 (0x30-0x39). You will also need to assemble the message that is output on each line - you can do this by writing the digit into the message buffer before outputting it to stdout, or you can perform a sequence of writes for the various portions of the message.}}
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{{Admon/tip|Character conversion|In order to print the loop index value, you will need to convert from an integer to digit character. In ASCII/ISO-9959-1/Unicode UTF-8, the digit characters are in the range 48-57 (0x30-0x39). You will also need to assemble the message to be printed for each line - you can do this by writing the digit into the message buffer before outputting it to stdout, or you can perform a sequence of writes for the various portions of the message.}}
  
7. Print
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7. Repeat step 6 for aarch64.
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 +
8. Extend the code to loop from 00-30, printing each value as a 2-digit decimal number.
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{{Admon/tip|2-Digit Conversion|You will need to take the loop index and convert it to a 2-digit decimal number by dividing by 10. To do this, use the <code>div</code> instruction, which takes the dividend from rax and the divisor from register supplied as an argument. The quotient will be placed in rax and the remainder will be placed in rdx.}}
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9. Repeat step 8 for aarch64.
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 +
=== Deliverable ===
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 +
1. Complete the group lab section, above.
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 +
2. Extend the assembler programs (both x86_64 and aarch64) to suppress the high digits when they are 0. In other words, the printed values should progress from 0-30 instead of from 00-30.
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 +
3. Blog about the programs you've written. Describe the experience of writing in assembler, as compared to writing in other languages. Contrast x86_64 and aarch64 assembler, and your experience with each.

Revision as of 16:48, 23 January 2014


Note.png
Purpose of this Lab
In this lab, you will experiment with assembler on the x86_64 and aarch64 platforms.
Idea.png
Ireland
Perform this lab on ireland.proximity.on.ca.)

Lab 3

Ireland - Configuration

The host Ireland (ireland.proximity.on.ca) has been set up so that you can use it normally as an x86_64 host, or use an emulation environment to build and run aarch64 binaries.

The directory ~/arm64/spo600/examples<code>, which is also accessible as <code>~/spo600-examples, contains these files:

── hello
   ├── assembler                 # 'hello world' example programs
   │   ├── aarch64               # aarch64 assembler version
   │   │   ├── hello.s
   │   │   └── Makefile
   │   └── x86_64                # x86_64 assembler versions
   │       ├── hello-gas.s       # 64-bit instructions with AT&T/gnu assembler syntax (called 'gas', /usr/bin/as)
   │       ├── hello-nasm.s      # 32-bit instructions with Intel/nasm assembler syntax (/usr/bin/nasm)
   │       └── Makefile
   └── c
       ├── hello2.c              # C version using the write() syscall wrapper
       ├── hello.c               # C version using printf()
       └── Makefile

Throughout this lab, take advantage of make whenever possible.

Group Lab Tasks

1. Build and run the C versions of the program for x86_64.

2. Review, build, and run the x86_64 assembler code. Make sure you understand the code.

4. Build and run the C versions of the program for aarch64 (note: you may need to make clean).

5. Review, build, and run the aarch64 assembler code. Make sure you understand the code.

6. Here is a basic loop in x86_64 assembler:

.text
.globl    _start

start = 0                       /* starting value for the loop index */
max = 10                        /* loop exits when the index hits this number (loop condition is i<max) */

_start:
    mov     $start,%r15             /* loop index */

loop:
    /* ... do something useful here ... */

    inc     %r15                /* increment register 15 */
    cmpq    $10,%r15            /* see if we're done */
    jne     loop                /* loop if we're not */

    movq    $0,%rdi             /* exit status */
    movq    $60,%rax            /* syscall sys_exit */
    syscall

Extend this code, combining it with code from the "Hello World" example, so that it prints each digit from 0 to 9 like this:

Loop: 0
Loop: 1
Loop: 2
Loop: 3
Loop: 4
Loop: 5
Loop: 6
Loop: 7
Loop: 8
Loop: 9
Idea.png
Character conversion
In order to print the loop index value, you will need to convert from an integer to digit character. In ASCII/ISO-9959-1/Unicode UTF-8, the digit characters are in the range 48-57 (0x30-0x39). You will also need to assemble the message to be printed for each line - you can do this by writing the digit into the message buffer before outputting it to stdout, or you can perform a sequence of writes for the various portions of the message.

7. Repeat step 6 for aarch64.

8. Extend the code to loop from 00-30, printing each value as a 2-digit decimal number.

Idea.png
2-Digit Conversion
You will need to take the loop index and convert it to a 2-digit decimal number by dividing by 10. To do this, use the div instruction, which takes the dividend from rax and the divisor from register supplied as an argument. The quotient will be placed in rax and the remainder will be placed in rdx.

9. Repeat step 8 for aarch64.

Deliverable

1. Complete the group lab section, above.

2. Extend the assembler programs (both x86_64 and aarch64) to suppress the high digits when they are 0. In other words, the printed values should progress from 0-30 instead of from 00-30.

3. Blog about the programs you've written. Describe the experience of writing in assembler, as compared to writing in other languages. Contrast x86_64 and aarch64 assembler, and your experience with each.