Difference between revisions of "Simple Computer Simulator Instruction-Set"
(→Other) |
(→Instructions that use the Index Register to Access Data) |
||
(13 intermediate revisions by the same user not shown) | |||
Line 12: | Line 12: | ||
<center>[[Image:SimpleComputerSimulatorFace.png|600px|link=http://cs.smith.edu/dftwiki/media/simulator/]]<br />[http://cs.smith.edu/dftwiki/media/simulator/ Simple Computer Simulator]</center> | <center>[[Image:SimpleComputerSimulatorFace.png|600px|link=http://cs.smith.edu/dftwiki/media/simulator/]]<br />[http://cs.smith.edu/dftwiki/media/simulator/ Simple Computer Simulator]</center> | ||
<br /> | <br /> | ||
− | =An Instruction | + | =Table Format= |
+ | <br /> | ||
+ | All the instructions supported by our Simple Computer Simulator are presented in tables below. The format of the table is explained below. | ||
+ | ;The Instruction | ||
+ | : The first column contains the instruction and the type of operand it supports. Some instructions have no operands (for example '''TXA''', '''TAX''', or '''HALT'''), some have a number, as in '''LOAD 3''', some a number in brackets, as in '''STORE [10]''', and some still have something different, as in '''LOAD [X]'''. | ||
+ | ; The Decimal Code | ||
+ | : All instructions are stored in memory in binary. Binary contains only 0s and 1s. Therefore anything in memory is a number. We use words to represent instructions, for example '''LOAD''' or '''STORE''', simply because it is much easier for us to remember words than numbers. But actually the language we are using is a code. Each instruction is associated with a number. This is the number shown in this column. We show it in decimal as it is the easiest system for humans to comprehend. <br />Assume that our program contains the instruction '''LOAD 7''', and that it is located at Address 0. When this instruction is translated (programmers say ''assembled'') into numbers so that it can be stored in memory, we see from the second table below that its decimal code is 4, and its binary code is 00000100. The memory will contain 2 numbers representing the instruction, a 4 at Address 0, and a 7 (00000111 in binary) at Address 1. The first number, at Address 0, is the '''code''', the second number, at Address 1, is the '''data'''.<br />Illustration of how the simulator will show '''LOAD 7''' in memory. | ||
+ | <br /> | ||
+ | <center>[[Image:SCS_Load7_decimal.png|300px]] [[Image:SCS_Load7_binary.png|300px]]</center> | ||
+ | <br /> | ||
+ | ; The Binary Code | ||
+ | : This number is simply the binary representation of the previous number. | ||
+ | ;Description | ||
+ | : Just a few words to help you understand what the instruction actually does, and how it uses its operands, if any. | ||
+ | <br /> | ||
+ | |||
+ | =An Instruction to end a Program = | ||
<br /> | <br /> | ||
Every program must stop execution at some point. The way to do this is to have a special instruction that stops the execution. In our case, this instruction is '''HALT'''. In the simulator, the HALT forces animation to stop and prevents the ''Step'' button to operate. In real computers, there is an instruction similar to HALT that actually forces operating system to take over the computer, and remove the program from memory, making the space it was occupying available for other programs the user may want or need to load. | Every program must stop execution at some point. The way to do this is to have a special instruction that stops the execution. In our case, this instruction is '''HALT'''. In the simulator, the HALT forces animation to stop and prevents the ''Step'' button to operate. In real computers, there is an instruction similar to HALT that actually forces operating system to take over the computer, and remove the program from memory, making the space it was occupying available for other programs the user may want or need to load. | ||
Line 32: | Line 48: | ||
|} | |} | ||
<br /> | <br /> | ||
+ | |||
=Instructions Using the Accumulator and a Number= | =Instructions Using the Accumulator and a Number= | ||
<br /> | <br /> | ||
Line 316: | Line 333: | ||
|- | |- | ||
| | | | ||
− | COMPX ''address'' | + | COMPX [''address''] |
| | | | ||
94 | 94 | ||
Line 378: | Line 395: | ||
<br /> | <br /> | ||
− | =Other= | + | |
+ | |||
+ | <br /> | ||
+ | |||
+ | =Other Instructions= | ||
+ | <br /> | ||
+ | The instructions in this section are extra; they are instructions that are logical to have, but they are not necessary for writing programs for solving problems. They might provide for simpler solution, but we would have been able to write code with that would have performed just the same with the instructions presented above. None-the-less, you may be interested in exploring assembly language with the simulator some more, in which case you'll find that your ability to program will be fairly improved with the additions of the instructions below. | ||
+ | |||
+ | Some of the instructions use a new type of operand: "[X]". The instruction '''ADD [X]''' for example, adds a number to the contents of the Accumulator, but this number is found in memory at the address contained in the Index register. For example, if the Accumulator contains 10, and the Index register IX contains 30, and if at Address 30 we have the number 5, then '''ADD [X]''' will fetch 5 from address 30 that it gets from IX, add it to 10 that is in the Accumulator. The result of the addition is 30 + 10, or 40, and this number gets stored back in the Accumulator. | ||
+ | |||
<br /> | <br /> | ||
{| class="wikitable" width="100%" | {| class="wikitable" width="100%" | ||
Line 387: | Line 413: | ||
|- | |- | ||
| | | | ||
− | + | ADDX [X] | |
| | | | ||
29 | 29 | ||
Line 393: | Line 419: | ||
00011101 | 00011101 | ||
| | | | ||
− | * | + | * Fetches the number in memory whose address is currently in the Index register. This number is then added to the Index register. |
− | |||
|- | |- | ||
| | | | ||
− | + | ADDX ''number'' | |
| | | | ||
25 | 25 | ||
Line 403: | Line 428: | ||
00011001 | 00011001 | ||
| | | | ||
− | * | + | * Adds ''number'' to the contents of the Index register. |
|- | |- | ||
| | | | ||
− | + | COMPX [X] | |
| | | | ||
93 | 93 | ||
Line 414: | Line 439: | ||
01011101 | 01011101 | ||
| | | | ||
− | * | + | * Compares the Index register to the value stored in memory at an address which is currently stored in the same Index register. |
|- | |- | ||
| | | | ||
− | + | DIVX ''number'' | |
| | | | ||
45 | 45 | ||
| | | | ||
00101101 | 00101101 | ||
− | | | + | | |
− | * | + | * Divides the contents of the Index register by ''number'' and keeps only the integer part (without decimals). This result replaces the old contents of the Index register. |
Line 432: | Line 457: | ||
|- | |- | ||
| | | | ||
− | + | LOADX [''address''] | |
| | | | ||
10 | 10 | ||
Line 438: | Line 463: | ||
00001010 | 00001010 | ||
| | | | ||
− | * | + | * Fetches the data stored in memory at the location specified by ''address'' and copies it into the Index register. |
|- | |- | ||
| | | | ||
− | + | LOADX [X] | |
| | | | ||
9 | 9 | ||
Line 447: | Line 472: | ||
00001001 | 00001001 | ||
| | | | ||
− | * | + | * Fetches the number stored in memory at the address that is currently stored in the Index register, and copies this number in the Index register. |
|- | |- | ||
| | | | ||
− | + | LOADX ''number'' | |
| | | | ||
5 | 5 | ||
Line 457: | Line 482: | ||
00000101 | 00000101 | ||
| | | | ||
− | * | + | * Replaces the current contents of the Index register by ''number''. |
|- | |- | ||
| | | | ||
− | + | MULX ''number'' | |
| | | | ||
41 | 41 | ||
Line 468: | Line 493: | ||
00101001 | 00101001 | ||
| | | | ||
− | * | + | * Takes the contents of the Index register and multiplies it by ''number''. The result is then stored back in the Index register, replacing its original contents. |
|- | |- | ||
| | | | ||
− | + | STOREX [X] | |
| | | | ||
21 | 21 | ||
Line 479: | Line 504: | ||
00010101 | 00010101 | ||
| | | | ||
− | * | + | * Stores the contents of the Index register in memory at an address which is also the contents of the Index register. For example, if the Index register contains the value 40, then '''STOREX [X]''' will store the number 40 at Address 40 in memory. |
|- | |- | ||
| | | | ||
− | + | STOREX [''address''] | |
| | | | ||
17 | 17 | ||
Line 489: | Line 514: | ||
00010001 | 00010001 | ||
| | | | ||
− | * | + | * Copies the contents of the Index register in memory at a location specified by ''address''. |
Line 495: | Line 520: | ||
|- | |- | ||
| | | | ||
− | + | SUBX [X] | |
| | | | ||
37 | 37 | ||
Line 501: | Line 526: | ||
00100101 | 00100101 | ||
| | | | ||
− | * | + | * Fetches the value stored in memory at the address specified in the Index register and subtracts that number from the Index Register. |
|- | |- | ||
| | | | ||
− | + | SUBX ''number'' | |
| | | | ||
33 | 33 | ||
Line 511: | Line 536: | ||
00100001 | 00100001 | ||
| | | | ||
− | * | + | * Subtracts ''number'' from the value stored in the Index register. Replaces the contents of the Index register with the result of the subtraction. |
|- | |- | ||
|} | |} | ||
<br /> | <br /> | ||
+ | |||
=Miscellaneous Instructions= | =Miscellaneous Instructions= | ||
<br /> | <br /> | ||
Line 534: | Line 560: | ||
00000000 | 00000000 | ||
| | | | ||
− | * | + | * This instruction simply makes the processor go to the next instruction. No register is modified except the Program Counter (PC). |
|} | |} | ||
Latest revision as of 11:14, 31 August 2014
--D. Thiebaut (talk) 16:57, 26 August 2014 (EDT)
Contents
- 1 Table Format
- 2 An Instruction to end a Program
- 3 Instructions Using the Accumulator and a Number
- 4 Instructions Using the Accumulator and Memory
- 5 Instructions Manipulating the Index Register
- 6 The Jump instruction
- 7 Compare and Jump-If Instructions
- 8 Register-Exchange Instructions
- 9 Other Instructions
- 10 Miscellaneous Instructions
This page documents all the instructions that are supported by the Simple Computer Simulator shown below. You can click on the image to go to the Javascript simulator. This simulator is used in the CSC103 How Computers Work course at Smith College.
The instructions are presented in functional groups, rather than in logical ones, so that simple programs can be created with just the first 3 groups, allowing more programming sophistication as subsequent groups are explored.
Simple Computer Simulator
Table Format
All the instructions supported by our Simple Computer Simulator are presented in tables below. The format of the table is explained below.
- The Instruction
- The first column contains the instruction and the type of operand it supports. Some instructions have no operands (for example TXA, TAX, or HALT), some have a number, as in LOAD 3, some a number in brackets, as in STORE [10], and some still have something different, as in LOAD [X].
- The Decimal Code
- All instructions are stored in memory in binary. Binary contains only 0s and 1s. Therefore anything in memory is a number. We use words to represent instructions, for example LOAD or STORE, simply because it is much easier for us to remember words than numbers. But actually the language we are using is a code. Each instruction is associated with a number. This is the number shown in this column. We show it in decimal as it is the easiest system for humans to comprehend.
Assume that our program contains the instruction LOAD 7, and that it is located at Address 0. When this instruction is translated (programmers say assembled) into numbers so that it can be stored in memory, we see from the second table below that its decimal code is 4, and its binary code is 00000100. The memory will contain 2 numbers representing the instruction, a 4 at Address 0, and a 7 (00000111 in binary) at Address 1. The first number, at Address 0, is the code, the second number, at Address 1, is the data.
Illustration of how the simulator will show LOAD 7 in memory.
- The Binary Code
- This number is simply the binary representation of the previous number.
- Description
- Just a few words to help you understand what the instruction actually does, and how it uses its operands, if any.
An Instruction to end a Program
Every program must stop execution at some point. The way to do this is to have a special instruction that stops the execution. In our case, this instruction is HALT. In the simulator, the HALT forces animation to stop and prevents the Step button to operate. In real computers, there is an instruction similar to HALT that actually forces operating system to take over the computer, and remove the program from memory, making the space it was occupying available for other programs the user may want or need to load.
Instruction | Code (decimal) |
Code ( binary) |
Description |
---|---|---|---|
HALT |
127 |
01111111 |
|
Instructions Using the Accumulator and a Number
These instructions operate with a single number (we refer to them as constants) that is either loaded into, added, or subtracted from the accumulator register.
Instruction | Code (decimal) |
Code ( binary) |
Description |
---|---|---|---|
ADD number |
24 |
00011000 |
|
DIV number |
44 |
00101100 |
|
LOAD number |
4 |
00000100 |
|
MUL number |
40 |
00101000 |
|
SUB number |
32 |
00100000 |
|
Instructions Using the Accumulator and Memory
These instructions are followed by a number in brackets. This number refers to the location, or address in memory where the actual operand is located. So, if the number following the instruction is [100], it means that the instruction will use whatever number is stored at 100. A simple analogy might help here. Think of the difference between these two statements:
- "Please read the book The Little Prince."
and the statement
- "Please read the book from the library, with Call Number PQ2637.A274 P4613 2000".
Both statements refer to reading the same book. The first one refers to the book directly. The instructions in the section above operate similarly with their operands. The second statement refers to the book indirectly, by giving you its address in the library. The instructions in this section perform the same way. By putting brackets around the numbers that follow the instructions, we indicate that the numbers used are not the actual numbers we want to combine with the accumulator, but the address of the cells where we will find the numbers of interest.
This may still be a bit obscure, but read on the description for each instruction and this will hopefully become a bit clearer.
Instruction | Code (decimal) |
Code ( binary) |
Description |
---|---|---|---|
ADD [address] |
26 |
00011010 |
|
DIV [address] |
46 |
00101110 |
|
LOAD [address] |
6 |
00000110 |
|
MUL [address] |
42 |
00101010 |
|
STORE [address] |
18 |
00010010 |
|
SUB [address] |
34 |
00100010 |
|
Instructions Manipulating the Index Register
The Index, IX in the simulator, is a register in the processor that contains numbers, just as the Accumulator does. However, the numbers in the index represent addresses of cells containing numbers. The Index is useful is situations where we have several numbers in consecutive memory locations, and we want to perform the same operation on each one, say add 1 to each of the numbers. In this case we store in the Index the address of the first number, say, 100, and operate on that number through the Index. We'll need new instructions for that, but for right now we just want to see how we can load numbers in the index.
Instruction | Code (decimal) |
Code ( binary) |
Description |
---|---|---|---|
ADDX number |
28 |
00011100 |
|
ADDX [address] |
30 |
00011110 |
|
LOADX number |
8 |
00001000 |
|
STOREX [address] |
22 |
00010110 |
|
SUBX number |
36 |
00100100 |
|
SUBX [address] |
38 |
00100110 |
|
The Jump instruction
The jump instruction forces the processor to continue executing instructions at the address specified in the instruction. For example, JUMP 30 forces the processor to go to Address 30 and take the instruction it finds there as the new instruction to execute. It will then continue on with the executions that sequentially follow the one at Address 30.
Instruction | Code (decimal) |
Code ( binary) |
Description |
---|---|---|---|
JUMP address |
64 |
01000000 |
|
Compare and Jump-If Instructions
The compare and jump-If instructions operate together. We always want to use them together to test conditions and execute one sequence of instruction or another. When programming, when we want to test something we need to create two paths for the execution of the program. One path will be taken if the test is true (say, is the contents of the accumulator less than 10), and another path if it is false.
For example, imagine that we do not know if the number in the Accumulator contains a number greater than 100. If so, we'll want to stop the program, otherwise we'll want to continue with some more computation
... 10: COMP 100 12: JLT 16 14: HALT 16: some more computation ...
The instruction at Address 10 compares the contents of the accumulator to 100. Some information about this comparison is kept inside the processor. The next instruction, at Address 12, is JLT 16. Its behavior is to force the processor to jump to Address 16 if, and only if, the result of the previous comparison is true, i.e. the accumulator is less than 100. If the accumulator is actually less than 100, the processor will jump to Address 16 and execute some more instructions. Otherwise, if the accumulator contains a number equal to or greater than 100, then it simply does not jump. And since a processor always execute instuctions in sequence, it moves on to the next instruction which is HALT and which forces it to stop.
Instruction | Code (decimal) |
Code ( binary) |
Description |
---|---|---|---|
COMP number |
84 |
01010100 |
|
COMP [address] |
86 |
01010110 |
|
COMPX number |
92 |
01011100 |
|
COMPX [address] |
94 |
01011110 |
|
JEQ address |
68 |
01000100 |
|
JLT address |
72 |
01001000 |
|
Register-Exchange Instructions
These instructions allow the programmer to copy the contents of the Accumulator in the Index register, and vice versa.
Instruction | Code (decimal) |
Code ( binary) |
Description |
---|---|---|---|
TAX |
79 |
01001111 |
|
TXA |
83 |
01010011 |
|
Other Instructions
The instructions in this section are extra; they are instructions that are logical to have, but they are not necessary for writing programs for solving problems. They might provide for simpler solution, but we would have been able to write code with that would have performed just the same with the instructions presented above. None-the-less, you may be interested in exploring assembly language with the simulator some more, in which case you'll find that your ability to program will be fairly improved with the additions of the instructions below.
Some of the instructions use a new type of operand: "[X]". The instruction ADD [X] for example, adds a number to the contents of the Accumulator, but this number is found in memory at the address contained in the Index register. For example, if the Accumulator contains 10, and the Index register IX contains 30, and if at Address 30 we have the number 5, then ADD [X] will fetch 5 from address 30 that it gets from IX, add it to 10 that is in the Accumulator. The result of the addition is 30 + 10, or 40, and this number gets stored back in the Accumulator.
Instruction | Code (decimal) |
Code ( binary) |
Description |
---|---|---|---|
ADDX [X] |
29 |
00011101 |
|
ADDX number |
25 |
00011001 |
|
COMPX [X] |
93 |
01011101 |
|
DIVX number |
45 |
00101101 |
|
LOADX [address] |
10 |
00001010 |
|
LOADX [X] |
9 |
00001001 |
|
LOADX number |
5 |
00000101 |
|
MULX number |
41 |
00101001 |
|
STOREX [X] |
21 |
00010101 |
|
STOREX [address] |
17 |
00010001 |
|
SUBX [X] |
37 |
00100101 |
|
SUBX number |
33 |
00100001 |
|
Miscellaneous Instructions
Most processor supports an instruction that doesn't do anything. It is often used for padding programs.
Instruction | Code (decimal) |
Code ( binary) |
Description |
---|---|---|---|
NOP |
0 |
00000000 |
|