Computer games have greatly improved hardware execution efficiency and display resolution, and many computer games that have many impossible or very difficult or very difficult-to-realization have been successfully completed. Although the presentation of computer games is diversified, but the theme of our discussion today, artificial intelligence has almost unpryunated relationships.
In the role playing game, the programmer and the planner need to accurately create a so-called "monster" in the computer, so that the half-orc people are seriously injured and know how to escape, the Master knows how to show the attack .
It is currently able to immediately think of two games with close relationships with artificial intelligence:
One is the so-called war / strategy to simulate game, two is a chess game. The specific gravity of artificial intelligence is different, and there are different in different game types. Some computer games are not marigned with high artificial intelligence. Otherwise no one is buying; some is almost embarrassing to make players can't feel any artificial intelligence.
Guided thinking
The way Ai is most likely, and it is also the main direction of early game Ai development is the rules orientation or called hypothesis orientation. In some simple computer games, programmers can do not difficult to convert rules in the game with settings into a rule, and then write them into computer programs. Let us play a role playing game as an example. Most of the plans to set the so-called computer monsters, the settings are usually the following:
Life attack power defensive force attribute
The last "attribute" is one of the items I like to increase during setting. Through this attribute setting, I can set the monster into "fear of death", or set the soldiers to "deceiving". With the information we have mastered, the outline in the battle system is born:
Rule one
IF (health <10) // is there?
{IF (attribute == greed is afraid of death)
Result = tried to escape
IF (there is any item or spell that restores your life)
Result = Use or to display related items or spells
}
Rule two
IF (can attacked aerodynamic && has enough mana)
{
Result = Show attacks
}
The most basic AI is established by the above series of "if-" rules set. Saying such a method can only establish basic AI is actually not correct. As long as there is sufficient and accurate rules, this way still has a certain level of performance.
The biggest advantage of rules orientation is easy to learn. Without the premise of the theoretical concept of the Olympics, there is still a large number of uses. Therefore, many old players often don't touch the enemy's attack strategy, mobile methods, and so on.
Inference thinking
I believe that friends who have come into contact with computer language or self-study have heard a famous procedure, which is a well-known program. Using a well-word game as a introductory textbook that discusses AI, I personally feel the most appropriate example. Maybe someone still doesn't know how to play in the well. As long as any party, first, first, first, first, first, first line. We can also derive the field here in the previously talked.
If any line of IF has, we have two sons && seasonal, still empty // is it coming to a line?
Result = This space
If any one of the IF has an enemy, two sons && is still empty / / prevents the enemy from making a line
Result = This space
If any one of the IF has, we have a son && seasonal, still empty //
Result = This space
Once I was on a computer book, I also saw some examples introduced in a well-known game. Different, I can't see any rule-oriented shadow. But after careful analysis of the program code, I got a great inspiration. It turns out that AI can be made without so many rules. It is used by the method in the computer AI course: the great ministerial method. I only explain the concept of this law here. Continue to take a well-known game as an example, the computer will take a certain place, followed by a hypothetical manner, of course, must assume that the other party is the best position, otherwise everything is meaningless. In the process of assumed the other party, naturally need to suppress our next step in response, so that it is until the full bureau game. Under the bottom of the program fragment in the festival:
Bestmove (int P, int * v)
{INT I;
Int lasttie;
Int lastmove;
int SUBV;
/ * First, Check for a TIE * /
IF (ISTIE ()) {
* v = 0;
Return (0);
}
/ * If not a TIE, TRY Each Potential Move * /
FOR (* v = -1, lasttie = lastmove = -1, i = 0; i <9; i )
{
/ * If this isn't a possible, skip it * /
IF (Board [i]! = 0) Continue;
/ * Make the move. * /
Lastmove = i;
Board [i] = p;
/ * DID IT WIN? * /
IF (Haswon (P)) * V = 1;
Else {
/ * If not, Find Out How Good The Other Side Can do * /
Bestmove (-P, & SUBV);
/ * If They can only Lose, this is stock a win. * /
IF (SUBV == - 1) * v = 1;
/ * OR, IF IT'S A TIE, Remember it. * /
Else IF (SUBV == 0) {
* v = 0;
Lasttie = i;
}
}
/ * Take back the move. * /
Board [i] = 0;
/ * If We found a win, returnimmediately
(can't do any better than That * /
IF (* v == 1) Return (i);
/ * If We Didn't Find Any Wins, Return A TIE MOVE. * /
IF (* v == 0) Return (Lasttie);
/ * If there at't Even Any Ties, Return a LOOSIME. * /
Else Return (Lastmove);
}
Some of the foreign forums have held 256 bytes of game design competitions. There are a lot of works, one of which is just a well-known game. The author used more than two hundred lines in the district, and the same work is exactly the same as the above program, and the visible skills are indeed. In addition, I also hope that similar activities can be launched in China. By the way, in such a chance limit, there is almost no other choice in addition to assembly language.
.386C
Code segment byte public use6
Assume CS: Code, DS: Code
ORG 100H
Tictac Proc Far
Start:
Push CS
POP DS
MOV AX, 0B800H; Clear Screen MOV ES, AX;
XOR DI, DI;
MOV CX, 7D0H;
MOV AX, 0F20H;
Rep Stosw;
XOR CX, CX;
MOV DL, 5
LOC_1:
Call Printboard
LOC_2:
MOV AH, 8; Waiting button
Int 21h
Movzx BX, Al
SUB BL, 31H; if not 1..9
JC LOC_2;
CMP BL, 8
JA LOC_2
CMP Data_1 [BX], Al
JNE LOC_2
MOV BYTE PTR DATA_1 [BX], 'X'
DEC DL
JZ Short Loc_3
MOV Al, 'o'
Call bestmove
MOV [Si], Al
Call iswin; judgment if it has been victorious
JNC LOC_1
LOC_3:
Call Printboard
MOV AX, 4C00H
Int 21h
Data_1 DB '12'
DATA_2 DB '3456789'
DATA_3 DB 0
Tictac ENDP
Printboard Proc Near
MOV SI, Offset Data_1
MOV DI, 548H
MOV CL, 3
LOCLOOP_4:
Movsb
Add di, 5
Movsb
Add di, 5
Movsb
Add di, 133h
LOOP LOCLOOP_4
Retn
Printboard endp
Iswin proc near
MOV BX, 1
MOV BP, 3
Call Sub_3; Check if the horizontal is completed
Inc BX
Inc BX
Dec BP
Dec BP
Call Sub_3; Check if the longitudinal direction is completed
Call Sub_4; check if the oblique is completed
CLC
Retn
Iswin endp
LOC_5:
STC
Retn
SUB_3 Proc Near
Mov AH, 3
MOV SI, Offset Data_1
LOC_6:
MOV Di, Si
Call Sub_5
Add Si, BP
Dec ah
JNZ LOC_6
Retn
SUB_3 ENDP
SUB_4 Proc Near
MOV DI, OFFSET DATA_1
Inc BX
Call Sub_5
MOV DI, OFFSET DATA_2
Dec BX
Dec BX
Call Sub_5
Retn
SUB_4 ENDP
SUB_5 Proc Near
MOV CL, 3
LOCLOOP_7:
CMP [DI], Al
JNE Short Loc_ret_8
Add di, BX
LOOP LOCLOOP_7
Add &
