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1107 lines
37 KiB
Plaintext
1107 lines
37 KiB
Plaintext
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ROBOTWAR
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Welcome to the battlefield of the future! It is the year 2002. Wars
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still rage, but finally, they have been officially declared hazardous to
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human health. Now, the only warriors are robots - built in secret and
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programmed to fight each other to the death!
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Your country has just developed the most efficient battle robot to date.
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It should be unbeatable - but part of its micro-computer "brain" is
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still blank. Only when a strategy is programmed into its memory will the
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robot be able to fight.
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The task set before you is to program a robot that no other robot can
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destroy.
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RobotWar is a fascinating and highly competitive game where robots
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battle each other to the death! RobotWar is not a game using manual
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dexterity, instead the robots are controlled by pre-programmed
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strategies and highly spectator interest.
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As well as providing hours of entertainment, RobotWar is designed to
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teach and sharpen the skills of creative computer programming. Whether
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you are a beginner or an accomplished programmer, RobotWar will prove to
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be fun and challenging.
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Robot war players design and write robot programs. The program is
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written with the help of a text-editor, and then translated by an
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assembler into robot-understandable instructions. The program can then
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be tested on a simulated robot to make sure it is working properly. Once
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the player is assured that the program is running as planned, it is
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installed in a battle robot and sent out to do battle with the other
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robots.
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From the main menu, several options are selectable. These options are
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described below:
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Option 1
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This will access the Battle branch where the player can setup and
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execute one robot battle. See "robots and robot battles".
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Option 2
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This will access the robotwar assembler and testing branch where the
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programs are translated and checked for errors, or tested on a simulated
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robot. See "the assembler" and "the test bench".
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Option 3
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This will access the text-editor where an existing program can be edited
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or a new program can be written. See "writing and editing source code".
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Option 4
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This is a simple control that turns the battle sounds on or off.
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Pressing the 4 key will change the position of the sound switch.
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Option 5
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This will access the disk storage branch where a disk can be initialized
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for storing robot code. See "storing robots on auxiliary disks".
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Option 6
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This will cause the computer to exit from the robotwar program to
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applesoft basic.
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Option 7
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This will access the match scheduling branch where the player can
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schedule and execute a series of battles. See "robots and robot
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battles".
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Option 8
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This will allow the player to run a previously scheduled or interrupted
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match (a series of battles). If you resume a previously interrupted
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match it will begin with the battle after the one which was
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interrupted.
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Note: If no option is selected from the main menu, the program will
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automatically select option 8. Robots and Robot Battles Locomotion
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Each robot is moved by tracks mounted on a 1.5 meter square chassis. The
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two independent motors, driving the tracks, enable the robot to move
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vertically (north/south) and horizontally (east/west).
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Power Supply
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The power supply will take the severest damage from the enemy shells. It
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is built into the central body of the robot, along with damage sensors.
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These sensors monitor the damage to the power supply and when 100%
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damage is attained, the robot will explode.
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Radar
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On top of the robot is a radar unit that emits a beam in any desired
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directions. This beam reflects from walls and other robots and returns
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to the robot. The beam is accurately timed, enabling the robot to find
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it's position and to spot enemy robots.
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Guns and Ammunition
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Your robot is equipped with one gun that swivels through 360 degrees and
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is automatically loaded. It uses time-fused shells that can be set to
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explode at any specified distance. The gun also has a cooling period
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between each shot to keep it from overheating.
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The Brain
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Inside the robot is a micro-computer "brain" that executes the
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instructions exactly as they have been programmed. The brain has several
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parts: an accumulator where a robot performs all arithmetic operations,
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a program storage area where the instructions are stored in memory, and
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registers where numbers are stored. the brain links to input sensors
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monitoring damage and position as well as to the drive motors, radar,
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and gun. While the robot is on the battlefield the brain is in complete
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control!
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The battlefield
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Robot battles take place on a square battlefield inside four strong
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walls. Each wall is 260 meters long and strong enough that a robot
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cannot crash or shoot through it. As many as five robots can fight at
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once, but only one will emerge as the winner.
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There is an observations station, directly above the battlefield,
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enclosed in blast-proof glass to protect you and the other observers.
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Damage
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Robots are eliminated from battle by incurring over 100% damage. When a
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shell hits a robot or explodes nearby, the robot is damaged. The extent
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of that damage depends on the proximity of the shell to the robot. A
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shell exploding directly on top of a robot can do 30% damage.
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A robot can also be damaged through collisions with walls or other
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robots. The extend of damage would depend on the angle of collision. A
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head-on collision between two robots can do 25% damage to both robots.
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The Scoring System
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Each robot has a score associated with it. As each battle is fought the
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robots earn points which are added to it's cumulative score. Every time
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a robot's program is changed, it's score is reset to 0.
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Robots earn points in the following manner. during a battle, every time
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a robot is destroyed, 1 point is earned by all of the survivors. Thus in
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a five-robot battle, the first to be destroyed receives 0 points. For
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outlasting that first robot, all other robots on the battlefield earn 1
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point. For outlasting 4 other robots, the winner of a 5-robot battle
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earns 4 points!
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Controlling Robots
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A robot computer contains 34 registers. The 34 registers are divided
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into three categories:
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1. Memory registers which are used to contain numbers for latter
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recall.
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2. Input/Output (I/O) registers which are used to monitor and control
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specific robot functions.
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3. The Index/Data pair of registers which are used to access the other
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registers by their numbers instead of their names.
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1. Memory Registers
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There are 24 memory registers used to store numbers. The memory
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registers are named A through W and Z. (X and Y are not included - they
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are input registers as described below).
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2. Input/Output Registers
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There are nine I/O registers that allow the computer to control the
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robot's actions. Each controls or monitors a specific robot function as
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described below:
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a) The X register:
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The X register is used to monitor the horizontal position of the robot.
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It always contains the current horizontal position of the robot on the
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battlefield, as a number from 0 to 256. o is at the extreme left of the
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battlefield and 256 is at the extreme right.
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b) The Y register:
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The y register is used to monitor the vertical position of the robot. 0
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is at the top of the battlefield and 256 is at the bottom.
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c) The AIM Register:
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The AIM register is used to monitor and control the angle at which the
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gun is aimed. when a number from 0 to 359 is stored in the Aim register,
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the robot's gun will turn to that angle. 0 aims the gun due north, 90
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aims it due east, etc. The AIM register always contains the current
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angular position of the gun.
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d) The RADAR register:
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The RADAR register is used to control the radar unit on top of the robot
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and monitor the results of the radar beam. Storing a number from 0 to
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359 in the RADAR register, sends a beam out in that direction.
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e) The SHOT register:
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The SHOT register is used to fire the robot's gun and monitor the state
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of readiness of the gun. Storing a new number in the SHOT register: Sets
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the timer on the shell so that it will travel that number of meters
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before exploding, and then fires it. After a shot is fired the SHOT
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register will contain the state of the gun's cooling process. When the
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SHOT register contains a zero the gun is ready to be fired again.
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f) The DAMAGE register:
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The DAMAGE register is used to monitor the amount of damage detected by
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the damage sensors. the DAMAGE register starts at 100 at the beginning
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of each battle and decreases towards 0 as damage is incurred. When the
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register reaches 0, the robot is completely destroyed and will disappear
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from the battlefield. The DAMAGE register always contains the current
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extend of damage.
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g) the SPEEDX register:
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This register is used to control and monitor the horizontal speed of the
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robot. The number stored in the SPEEDX register can range from -255 to
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255 and controls the direction and speed of the robot. A negative number
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moves the robot to the left at that many decimeters/second, and a
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positive number moves the robot to the right at that many
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decimeters/second. If a zero is stored in this register the robot will
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stop moving in the horizontal direction. The SPEEDX register always
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contains the horizontal speed of the robot.
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h) The SPEEDY register:
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Acts the same as the SPEEDX register, only in the vertical direction. A
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positive number is in a downward direction and a negative number is in
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an upward direction.
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i) The Random register:
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This register is used to control the random number generator. Storing a
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number in the RANDOM register sets the limit for the generator. Then,
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each time the RANDOM register is accessed, it will contain a different
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integer (whole number) between 0 and th random number limit which was
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previously set.
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[----------------------------------------------------------]
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| (0,0) (256,0) |
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| o |
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| o 0 o |
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| 315 | 45 |
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| o \ |/ o |
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| 270------.------90 |
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| o/ |\ o |
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| 225 | 135 |
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| | o |
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| 180 |
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| (0,256) (256,256) |
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[----------------------------------------------------------]
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3. The index/Data Registers
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The robot registers are usually referenced by their names. The
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Index/Data pair allows registers to be accessed by number instead of
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name.
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Storing a number from 0 to 34 in the INDEX register causes the
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corresponding register to be used whenever the DATA register is
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referenced.
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For example, assume the INDEX register contains 27. When the DATA
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register is referenced in an instruction, register #27 (AIM) will be
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substituted for DATA.
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Number Name Type
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1-23 A-W Storage
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24 X Current X position
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25 Y Current Y position
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26 Z Storage
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27 AIM Aims gun
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28 SHOT fires the gun
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29 RADAR pulses the radar
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30 DAMAGE monitors damage
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31 SPEEDX control horizontal speed
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32 SPEEDY control vertical speed
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33 RANDOM random number generator
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34 INDEX Index other registers
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The Language of Robots
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The Source Code
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Robot programs are written in source code and then translated by the
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assembler into robot-understandable object code. Source code is composed
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of comments, labels, and instructions.
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1. Comments:
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Comments are used for documenting the source code. Comments can appear
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anywhere in the program as long as they are preceded by a semi-colon.
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] A TO B ;This stores a in b
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This is an example of a comment on the same line as an instruction.
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2. Labels:
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A label is a reference point used to identify sections within a program.
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Labels are used in instructions to change the order of execution of the
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program.
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A label is composed of a group of 2 or more alpha-numeric characters
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immediately following a RETURN symbol (]). A label must start with an
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alpha character (A to Z) and must be less than 32 characters long. A
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label can not be the same as any of the register names or command
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words.
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3. Instructions
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Instructions are used to control the robot's micro-computer brain.
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Instructions may contain register names, command words and numbers
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(-1024 to +1024)
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Command words: a) 'TO' stores a value in a register
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b) 'IF' compares two values and alters program flow. use these
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conditions:
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= equal
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# not equal
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< less than
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> greater than
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c) 'GOTO' jumps to a label in the prog.
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d) 'GOSUB' calls a subroutine
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e) 'ENDSUB' returns from a subroutine
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f) math operators
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+ adds two values
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- subtracts two values
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* multiplies two values
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/ divides two values
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Restrictions:
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a) no parentheses allowed
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b) use only integer numbers between +1024 and -1024
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c) you must use a condition sign when using an 'IF'
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d) you may store negative NUMBERS in a register, but you can't store
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negative REGISTERS in a register.
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e) all math operations are done from left to right
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The TO command
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The TO command is used to store a value in a register.
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] 240 TO A
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This example line of source code causes the computer to load the
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accumulator with a value of 240 and the store it in the A register.
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] B TO A
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This example causes the computer to load the accumulator with the
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contents of the B register and then store it in the A register.
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] 0 TO SPEEDX TO SPEEDY
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This example causes the computer to load the accumulator with 0 and
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store it first in the SPEEDX and register and then in the SPEEDY
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register. This could be used to stop a robot's movement.
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NOTE: Negative numbers can be stored as in the following example:
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] -240 TO SPEEDX
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But, you CANNOT store the negative of a register in that manner. For
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example:
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] -B TO A
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Will NOT store the negative of B in A. To store a negative of a register
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subtract the register from zero. For example:
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] 0 -B TO A
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Arithmetic commands (+ - * /)
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Arithmetic operations can be performed on a value stored in the
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accumulator. Whenever the program encounters one of the arithmetic signs
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it performs the calculation using the contents of the accumulator and
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the value that follows. It then stores the results of the calculation in
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the accumulator.
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] 240 + 100 TO A
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This example loads 240 into the accumulator, adds 100 to it, and stores
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the result (340) in the A register.
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The IF command
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The IF command is used to compare a value with the contents of a
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register. It can test to see if a register is less than (<), greater
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than (>), equal to (=), or not equal to (#) a value. If the comparison
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is true the computer executes the next TO, GOTO, GOSUB or ENDSUB
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command. If the comparison is false the computer skips the next TO,
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GOTO, GOSUB or ENDSUB commands.
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The GOTO command
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A GOTO command causes the program to change it's sequence of execution
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by going to a designated label and continuing its execution from there.
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A GOTO instruction must always be followed by a label.
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The GOSUB command
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Another way to change the execution sequence is to use a GOSUB command.
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A GOSUB instruction is similar to a GOTO command. GOSUB must always be
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followed by a label. GOSUB will cause the program to go to the
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designated label and continue the execution until it reaches an ENDSUB.
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When it encounters the ENDSUB, the program will then return to the next
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instruction after the GOSUB.
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Caution:
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Some illegal statements will be translated by the assembler, but then
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will do odd things when executed.
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Programming a Robot
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In order to make a robot perform, you must construct a program using the
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RobotWar language and your own strategy. This chapter gives examples of
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how instructions can be constructed, suing registers. numbers, and
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commands, and how those instructions can be labeled and sequenced to
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create program routines.
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Movement
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Moving about the battlefield is an action a robot performs. To start a
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robot moving, store a value in the speedx or speedy register.
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] 20 to speedx
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] 250 to speedy
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would start the robot moving down and to the right. However, the robot
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would continue to move in those directions, and would eventually hit a
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wall. Therefore, you must stop it at some point, by storing a zero in
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the speedx and speedy registers.
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] 0 to speedx
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A robot can only accelerate or brake at 40 decimeters/second. Even
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though 120 is entered into speedx register, it takes 3 seconds of
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acceleration to obtain that speed. Conversely, if your robot is
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travelling at 120 decimeters/sec it takes 3 seconds to stop the robot,
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after storing 0 in the speedx register.
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A movement routine can be established, by incorporating the starting and
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stopping procedures into a test loop.
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] 256 TO SPEEDX
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]MOVER1
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] IF X > 230 GOTO STOP
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]STOP
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] 0 TO SPEEDX
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Moves the robot to the right until it's X position is tested to be
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greater than 230 and then it stops.
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Monitoring Damage
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Monitoring damage is vital to a robot's survival. When a robot detects a
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hit, it usually moves to avoid being repeatedly hit by the enemy. By
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using the DAMAGE register, a damage detection routine can be
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established. This routine is usually nested inside another routine's
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loop so that the robot can be checking for damage while it is performing
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some other action.
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] DAMAGE TO D
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Saves current damage in register D.
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]DAM1
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] IF DAMAGE # D GOTO MOVE
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When any damage is incurred, the DAMAGE register will change, but
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register D will not. Therefor, any difference between the two registers
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will indicate that the robot has been hit. In this example any
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difference will cause the program to go to the label MOVE.
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Scanning
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Another important action a robot performs is scanning. When a robot
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scans it is using it's radar beams to detect the location of other
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robots and walls. To emit a radar beam, store a number, between 0 and
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359 in the RADAR register.
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] 90 TO RADAR
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Will send a radar beam in the 90-degree direction, and when the beam
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returns, it's value will be stored in the RADAR register. A routine to
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determine if the robot has spotted another robot is:
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]LOOK
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] AIM + 5 TO AIM
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] AIM TO RADAR
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] IF RADAR < 0 GOTO SHOOT
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] GOTO LOOK
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When the program executes this routine, it first encounters the label
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LOOK and goes on to the next instruction. This instruction (AIM + 5 TO
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AIM) increments the angle in which the gun is aimed, five degrees. The
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next instruction (AIM TO RADAR) aligns the angle of the radar to the
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angle of the gun, emits a radar beam in that direction, and then stores
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the results of that beam in the RADAR register.
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The next instruction (IF RADAR < O GOTO SHOOT) analyzes the results of
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the radar's findings. If the RADAR register contains a positive number,
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there are no robots in that direction and the comparison will be false.
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Since the comparison is false, the next command will be ignored and the
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program will go on to the next command (GOTO LOOK). This command will
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cause the program to go to the label LOOK. This completes the loop and
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the scan routine will continue until a robot is found.
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If the RADAR register contains a negative number, After the beam
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returns, the comparison (IF RADAR < 0) will be true. Therefor, the next
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command (GOTO SHOOT) will be executed. In this case the program sequence
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would branch to the instruction following the label SHOOT.
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Shooting
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|
|
|
|
It is usual procedure to execute a shooting routine when an enemy is
|
|
spotted.
|
|
|
|
]SHOOT
|
|
|
|
] 0 - RADAR TO SHOT
|
|
|
|
] GOTO LOOK
|
|
|
|
Is an example of a simple shoot routine. Since a robot has been spotted
|
|
by radar, a negative number is presently stored in the RADAR register.
|
|
The enemy robot is that number (ignoring the negative sign) of meters
|
|
away. In order to obtain a positive number of the distance, the program
|
|
subtracts RADAR from 0. This new positive number is then stored in the
|
|
SHOT register. Storing the number in the SHOT register causes the gun to
|
|
fire a shell that has been set to explode at that distance, in the
|
|
direction indicated by the contents of the AIM register.
|
|
|
|
Random Number Generation
|
|
|
|
|
|
The RANDOM register is used to generate random numbers. A few examples
|
|
of random number routines are:
|
|
|
|
] 100 TO RANDOM
|
|
|
|
] RANDOM TO A
|
|
|
|
This routine stores 100 in the RANDOM register, which sets the limit for
|
|
the generator. The generator then returns a random number from 0 to 99
|
|
and stores it in the RANDOM register. That value is then stored in A by
|
|
the TO command. From then on each time the contents of the RANDOM
|
|
register is stored in a register, the generator will return a different
|
|
number. The limit of the generator will only change when a new value is
|
|
stored in the RANDOM register by using the TO command.
|
|
|
|
] B + 1 - A TO RANDOM
|
|
|
|
] RANDOM + A TO C
|
|
|
|
This routine stores a random number between A and B into the C
|
|
register.
|
|
|
|
A Sample robot in source code
|
|
|
|
;SAMPLE ROBOT 'RANDOM'
|
|
|
|
] 250 TO RANDOM ;INITIALIZE RANDOM -- 250
|
|
MAXIMUM
|
|
]
|
|
]START
|
|
] DAMAGE TO D ;SAVE CURRENT DAMAGE
|
|
]
|
|
]SCAN
|
|
] IF DAMAGE # D GOTO MOVE ;TEST -- MOVE IF HURT
|
|
] AIM+17 TO AIM ;CHANGE AIM IF OK
|
|
]
|
|
]SPOT
|
|
] AIM TO RADAR ;LINE RADAR WITH LAUNCHER
|
|
] IF RADAR>0 GOTO SCAN ;CONTINUE SCAN IF NO ROBOT
|
|
] 0-RADAR TO SHOT ;CONVERT RADAR READING TO
|
|
]DISTANCE AND FIRE
|
|
] GOTO SPOT ;CHECK IF ROBOT STILL THERE
|
|
]
|
|
]MOVE
|
|
] RANDOM TO H
|
|
] RANDOM TO V ;PICK RANDOM PLACE TO GO
|
|
]
|
|
]MOVEX
|
|
] H-X*100 TO SPEEDX ;TRAVEL TO NEW X POSITION
|
|
] IF H-X>10 GOTO MOVEX ;TEST X POSITION
|
|
] IF H-X<-10 GOTO MOVEX ;TEST X POSITION
|
|
] 0 TO SPEEDX ;STOP HORIZONTAL MOVEMENT
|
|
]
|
|
]MOVEY
|
|
] V-Y*100 TO SPEEDY ;TRAVEL TO NEW Y POSITION
|
|
] IF V-Y>10 GOTO MOVEY ;TEST Y POSITION
|
|
] IF V-Y<-10 GOTO MOVEY ;TEST Y POSITION
|
|
] 0 TO SPEEDY ;STOP VERTICAL MOVEMENT
|
|
] GOTO START ;START SCANNING AGAIN
|
|
]
|
|
|
|
Writing and Editing Source Code
|
|
|
|
Robot programs are entered into the computer using a text editor.
|
|
|
|
The text editor may be entered by selecting option 3 from the Main Menu,
|
|
or by selecting option 6 from the Assembler menu.
|
|
|
|
Text-Editor Procedure
|
|
|
|
When you first enter the text editor, you will see a blank screen with
|
|
some numbers at the bottom and a flashing square at the top. The numbers
|
|
at the bottom show the length of the text, and the file name under which
|
|
it is stored. The flashing square is called the cursor, and is the
|
|
computer equivalent of a pen for writing characters. As you use the
|
|
text-editor you will be operating in two modes; the add mode and the
|
|
cursor mode. The add mode is used to delete text at the cursor, move the
|
|
cursor around in the text, adjust the position of the text on the
|
|
screen, load source code files from the catalog, and save source code
|
|
files to the catalog.
|
|
|
|
The blank screen indicates that the current text-editor file is empty.
|
|
At this point there are two available options. One option is to begin
|
|
writing a new source code, and the other option is to edit a robot that
|
|
has already been stored.
|
|
|
|
|
|
Ctrl-A to enter the add mode. The letter "A" will appear in the lower
|
|
RIGHT corner of the screen. You can now create a new source code file.
|
|
|
|
Esc Esc exits you from the add mode.
|
|
|
|
Ctrl-S to save the file on the disk. The word "SAVE" will appear on the
|
|
left side of the screen. To save the new robot program you just created
|
|
you must give it a name. The name can be no longer than 7 characters and
|
|
must not be the same as any other robot on the disk.
|
|
|
|
Ctrl-L loads a file from the disk. The word "LOAD" will appear on the
|
|
left side of the screen.
|
|
|
|
Cursor Mode
|
|
|
|
|
|
You are now ready to perform the second available option when the
|
|
text-editor has been loaded, which is editing the source code file. When
|
|
editing source code you will use the cursor mode to delete text at the
|
|
cursor, move the cursor around in the text, adjust the position of the
|
|
text on the screen, load source code files, and save source code files.
|
|
These functions are described below:
|
|
|
|
1. Cursor Movement
|
|
|
|
The cursor can be moved to any location in the file by using the five
|
|
keys on the right side of the keyboard.
|
|
|
|
A) The RETURN key moves the cursor up one line
|
|
|
|
B) The left and right arrow keys.
|
|
|
|
C) The slash (/) key moves the cursor down one line.
|
|
|
|
To move the cursor all the way in any direction on the screen, press the
|
|
Esc key and then the direction key.
|
|
|
|
Once you have positioned the cursor where you want it, there are several
|
|
options. Either exit to the add mode, and write some text or stay in the
|
|
cursor mode and use a cursor function.
|
|
|
|
|
|
2. Moving Text
|
|
|
|
There are also methods of moving the text itself, when in the cursor
|
|
mode. The direction, in which the text moves, is set by pressing the '+'
|
|
key (a forward direction) or the '-' key (a backward direction) prior to
|
|
pressing the L, P, or A keys.
|
|
|
|
A) The L key will move the text up or down one line.
|
|
|
|
B) The P key will move the text up or down one full page.
|
|
|
|
C) The A key will set the text in continuous scrolling motion.
|
|
|
|
You can move to the beginning or end of the text by pressing the Esc key
|
|
first and then the '-' key or the '+' key respectively.
|
|
|
|
3. Deleting Text
|
|
|
|
This function deletes text from the screen and the memory if the Apple,
|
|
but not from the disk. There are three methods of deleting text:
|
|
|
|
A) Ctrl-D Any character may be deleted by positioning the cursor over
|
|
the character and pressing Ctrl-D.
|
|
|
|
B) Ctrl-G Any line, or portion of a line, may be deleted by positioning
|
|
the cursor over a character and pressing Ctrl-G. This will delete the
|
|
character and the rest of the line that follows it.
|
|
|
|
C) Esc Ctrl-Z All of the text, presently in the text-editor may be
|
|
deleted by pressing Esc and then Ctrl-Z. You will have to confirm the
|
|
command by pressing the # key. This protects against accidental
|
|
erasures.
|
|
|
|
4. Block Operations
|
|
|
|
This function allows you to mark a portion of the current source code,
|
|
and then manipulate that block to another place in the file. You must
|
|
designate the beginning and the end of a block by placing block markers
|
|
at those two points. To insert a block marker immediately after the
|
|
cursor, press Ctrl-V to mark the beginning and end of th block, and it
|
|
will be represented on the screen by a flashing ')' sign. Only one block
|
|
can exist in a file at any one time and any attempt to insert a block
|
|
mark when a block has already been defined will result in the error
|
|
message "BLOCK ALREADY MARKED".
|
|
|
|
When a block is marked, press Esc V and the block options will be
|
|
displayed on the bottom of the screen. They are Copy, Delete, and
|
|
Unmark.
|
|
|
|
To copy a block, move the cursor to the location in the file where you
|
|
want to insert the copy of the block and press C. This is a
|
|
non-destructive copy.
|
|
|
|
To delete a block. Pressing D will remove the block and the block
|
|
markers from memory.
|
|
|
|
To unmark the block press U. You may also remove markers with normal
|
|
delete commands. Remember, these changes only exits in the memory and
|
|
not on the disk.
|
|
|
|
5. Find Operations
|
|
|
|
Fo find all occurrences of a word or phrase in a file, use the find
|
|
command. Press Ctrl-F and you will be prompted wit the "FIND:>" message.
|
|
At this point, type in the word or phrase you wish to locate and press
|
|
return.
|
|
|
|
The first occurrence of the word or phrase will be displayed in the
|
|
center of the screen. To find all subsequent occurrences press Ctrl-F
|
|
and Return.
|
|
|
|
You need not enter the word each time, the search will always begin at
|
|
the current cursor location and search in the direction that the
|
|
indicator in the lower left corner of the screen shows.
|
|
|
|
6. Printing Source Code Files
|
|
|
|
To print the source code on a printer, press Ctrl-P. The screen will
|
|
prompt you to type in the printer slot number. Once this has been done,
|
|
and the RETURN key has been pressed, the text will print out.
|
|
|
|
7. Adding Text
|
|
|
|
Position the cursor to where you want to begin adding text and enter the
|
|
add mode by pressing Ctrl-A. To return from add mode to cursor mode,
|
|
press Esc twice.
|
|
|
|
8. Loading files
|
|
|
|
To load a file into memory which was previously saved on disk press
|
|
Ctrl-L. The loading operation works similar to loading any other file.
|
|
|
|
9. Saving Files
|
|
|
|
To save a file on disk, press Ctrl-S. Use the space bar to select the
|
|
file name from disk, or type one in. Press RETURN when done.
|
|
|
|
10. Entering the Assembler
|
|
|
|
To save the current robot program and enter the assembler, press Ctrl-R.
|
|
This will save the text as it appears in the memory on the disk, and
|
|
then exit the text-editor to the assembler. Before a robot can be
|
|
assembled, it must have been given a name by being saved to disk.
|
|
|
|
The Assembler
|
|
|
|
The Assembler translates source code programs into robot-understandable
|
|
object code. It also checks for errors in the source code and displays a
|
|
message if one is found.
|
|
|
|
The assembler can be entered from the Main Menu by selecting option 2,
|
|
or from the editor by pressing Ctrl-R. If the assembler is entered from
|
|
the editor, a robot source program is loaded and ready to assemble.
|
|
|
|
It is possible to assemble a robot from source code on the disk, or load
|
|
an assembled robot from disk to test. There is also an option to print
|
|
the assembled robot on the printer.
|
|
|
|
Assembly Errors
|
|
|
|
There are eight errors that the RobotWar assembler can detect. When the
|
|
assembler detects an error it will display a message such as:
|
|
|
|
NO DATA FIELD IN LINE 27
|
|
|
|
10 + TO C
|
|
|
|
^
|
|
|
|
|
|
The error message indicates the type of error, the program line number
|
|
and the position in the line (^) where it occurred. Following are the
|
|
possible error messages:
|
|
|
|
1. NO DATA FIELD - There is no register or number after a command.
|
|
|
|
2. UNKNOWN ITEM - You have tried to use a register or a label that is
|
|
not defined.
|
|
|
|
3. LARGE NUMBER - You have tried to store a number greater than 1,024,
|
|
or less than -1,024 into a register.
|
|
|
|
4. PROGRAM TOO LONG - Program is too big for the allotted program
|
|
storage area. Programs have a maximum length of 256 object code
|
|
instructions.
|
|
|
|
5. FATAL JUNK - You have included something that the computer cannot
|
|
understand, like an illegal statement.
|
|
|
|
6. STORE IN NUMBER - You have tried to store a value in a number instead
|
|
of a register.
|
|
|
|
7. RESERVED LABEL - You have tried to use a register name as a label.
|
|
|
|
8. NO PROGRAM CODE - There are no instructions in the program. Object
|
|
Code Exercise
|
|
|
|
The following pages list the object code's commands and registers and
|
|
the translation of the sample robot's source code. Using the list and
|
|
the two codes for the sample robot, compare and identify the source code
|
|
and it's object code translation. It will be very useful to understand
|
|
the object code when learning to use the test bench in the next
|
|
chapter.
|
|
|
|
List of Object Code Instructions
|
|
|
|
Instruction Action
|
|
|
|
, Load accumulator with next data item
|
|
|
|
IF Load accumulator with next data item
|
|
|
|
+ Add next data item to accumulator
|
|
|
|
- Subtract next data item from accumulator
|
|
|
|
* Multiply accumulator by next data item
|
|
|
|
/ divide accumulator by next data item
|
|
|
|
= Skips the next command unless the accumulator is equal to next
|
|
data item
|
|
|
|
> Skips the next command unless the accumulator is greater than the
|
|
next data item
|
|
|
|
< Skips the next command unless the accumulator is less than next
|
|
data item
|
|
|
|
# Skips the next command if the accumulator is equal to next data
|
|
item
|
|
|
|
TO Store accumulator in next dat item
|
|
GOTO Branch to the address given
|
|
GOSUB GOSUB to the address give
|
|
ENDSUB REturn from a subroutine
|
|
|
|
Assembly of Robot Sample
|
|
|
|
Code Building
|
|
==== ========
|
|
SCAN
|
|
0 , AIM
|
|
1 + 5
|
|
2 TO AIM
|
|
3 , AIM
|
|
4 TO RADAR
|
|
LOOP
|
|
5 IF RADAR
|
|
6 < 0
|
|
7 GOSUB FIRE
|
|
8 GOTO SCAN
|
|
FIRE
|
|
9 , 0
|
|
10 - RADAR
|
|
11 TO SHOT
|
|
12 ENDSUB
|
|
|
|
Code Statistics
|
|
=== ==========
|
|
140 Letters
|
|
13 Instructions
|
|
3 Labels
|
|
2 References
|
|
|
|
|
|
The Test Bench
|
|
|
|
The test bench is a micro-computer simulator of a robot. With the test
|
|
bench, you can monitor a robot's performance without actually putting it
|
|
on the battlefield. This simulator will prove an important device, as
|
|
you learn to debug robots, because it allows you to monitor the object
|
|
code and the contents of the registers.
|
|
|
|
Load a robot into the test bench by selecting option 2 from the
|
|
assembler menu or from the main menu.
|
|
|
|
Operating the Test Bench
|
|
|
|
As the test bench runs the program, each instruction (in object code)
|
|
will appear on the left side of the screen as it is executed. On the
|
|
right side of the screen are displayed the robot's position and register
|
|
contents. Also shown are the instruction number being executed (program
|
|
counter) and the accumulator.
|
|
|
|
Controlling the Test Bench
|
|
|
|
The test bench can be interrupted by pressing the space bar. Press the
|
|
space bar again to execute one more instruction. This can be useful when
|
|
analyzing a program to see if it is acting as you had planned. Pressing
|
|
RETURN will start the test bench running again. To change the speed of
|
|
the test bench, press a number from 0 to 9.
|
|
|
|
Simulating Radar
|
|
|
|
Pressing the R key will cause the radar display to light up and the
|
|
RADAR register will display a negative number to simulate an enemy robot
|
|
in view. This will allow your program to go into it's "enemy spotted"
|
|
routine.
|
|
|
|
Simulating Damage
|
|
|
|
Each time the G key is pressed, a random amount, up to 10% will be
|
|
subtracted from the DAMAGE register. This allows th program the
|
|
opportunity to use it's damage detection routine. The DAMAGE register
|
|
will also indicate damage if the simulated robot crashes into a wall.
|
|
The test bench will automatically stop when the DAMAGE register reaches
|
|
0.
|
|
|
|
Tracing Registers
|
|
|
|
The trace is used to check the contents of registers not normally
|
|
displayed on the test bench. Press the T key to access the tracer. The
|
|
test bench will stop, and the following question will be displayed:
|
|
"NAME REGISTER TO TRACE?" Enter the name of the register you want to
|
|
trace and press RETURN. The test bench will continue, with the contents
|
|
of the traced register displayed on the line above "X POSITION".
|
|
|
|
The Esc key will exit from the test bench.
|
|
|
|
Storing Robots
|
|
|
|
There is a limited amount of space on the RobotWar disk to store robot
|
|
files. However, robot files can be transferred to and from auxiliary
|
|
storage disks.
|
|
|
|
Auxiliary storage disks are used only to store robot files. Robot files
|
|
on auxiliary disks must be transferred back to the RobotWar program disk
|
|
before they can be tested, assembled, edited, or battled.
|
|
|
|
There is a utility in the menu to initialize a data disk. Only disks
|
|
initialized by RobotWar can be used as data disks.
|
|
|
|
To save or load a robot to or from a data disk simply remove the
|
|
RobotWar disk after entering the robot name and before pressing return.
|
|
After the file is loaded, swap the disks back again before continuing
|
|
with the program.
|
|
|
|
To delete a robot from a disk, exit to basic, and delete the file with
|
|
the DOS 3.3 command DELETE filename and press RETURN. When done, enter
|
|
PR#6 to re-start RobotWar.
|
|
|
|
Summary of Editor Keys Cursor Mode:
|
|
|
|
Moving keys
|
|
|
|
+ Set forward direction
|
|
|
|
- Set backward direction
|
|
|
|
Esc + Move to end of text
|
|
|
|
Esc - Move to beginning of text
|
|
|
|
A Sets text in continuous scrolling motion
|
|
|
|
RETURN Move cursor up one line
|
|
Esc RETURN Move cursor to top of page
|
|
|
|
/ Move cursor one line down
|
|
|
|
Esc / Move cursor to bottom of page
|
|
|
|
<- Move one space left
|
|
|
|
-> Move one space right
|
|
|
|
Esc -> Move cursor to right end of line
|
|
|
|
Esc <- Move cursor to left margin
|
|
|
|
P Move up or down one full page
|
|
|
|
L Move text up or down one line
|
|
|
|
Text deleting keys
|
|
|
|
|
|
Ctrl-D Delete the character at the cursor
|
|
|
|
Ctrl-G Delete the line at the cursor
|
|
|
|
Esc Ctrl-Z Delete the whole file
|
|
|
|
File handling keys
|
|
|
|
|
|
Ctrl-L Clear memory and load a source file
|
|
|
|
Ctrl-S Save text as a source file
|
|
|
|
Ctrl-R Save current file and enters assembler
|
|
|
|
Control keys
|
|
|
|
Esc Ctrl-Q Exits to main menu
|
|
|
|
Ctrl-F Executes FIND operation
|
|
|
|
Ctrl-P Prints file in memory
|
|
|
|
Ctrl-V Places block marker at cursor
|
|
|
|
Esc-V Displays block options
|
|
|
|
C-Copy block
|
|
|
|
D-Delete block
|
|
|
|
U-Remove block markers
|
|
|
|
Add Mode
|
|
|
|
Text adding keys
|
|
|
|
|
|
Ctrl-A Start adding text
|
|
Esc Esc Stop adding text
|
|
|
|
<- Backspace, erases as it goes
|
|
|
|
-> Moves text to the right
|
|
|
|
RETURN Acts as a carriage return
|
|
|
|
|
|
From the Assembler
|
|
|
|
Space Bar Stop the assembler or move it one step
|
|
RETURN Start the assembler operating again
|
|
|
|
0-9 Adjust the speed at which the assembler is
|
|
scrolling
|
|
|
|
From the Test Bench
|
|
|
|
RETURN Start the assembler operating again
|
|
|
|
0-9 Adjust the speed at which the assembler is
|
|
scrolling
|
|
|
|
R Simulate Radar
|
|
|
|
G Simulate a shell hit
|
|
|
|
T Trace a Register
|
|
|
|
Esc Exit the test bench
|
|
|
|
the DOS 3.3 command DELETE filename and press RETURN. When
|
|
done, enter PR#6 to re-start RobotWar.
|
|
|
|
Summary of Editor Keys
|
|
Cursor Mode:
|
|
|
|
Moving keys
|
|
|
|
+ Set forward direction
|
|
|
|
- Set backward direct
|