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日期:2024-11-13 08:52

Project Three: Simple World

Due: Nov. 17, 2024

I. Motivation

1. To give you experience in using arrays, pointers, structs, enums, and different I/O streams and

writing program that takes arguments.

2. To let you have fun with an application that is extremely captivating.

II. Introduction

The simple world program we will write for this project simulates a number of creatures running

around in a simple square world. The world is an m-by-n two-dimensional grid of squares (The

number m represents the height of the grid and the number n represents the width of the grid.).

Each creature lives in one of the squares, faces in one of the major compass directions (north,

east, south, or west) and belongs to a particular species, which determines how that creature

behaves.

la ho

fl

fl ho Figure 1. A 4-by-4 grid, which contains five creatures. Two creatures belong to the species

flytrap (whose short name is “fl”), two belong to the species hop (whose short name is “ho”), and

one belongs to the species landmine (whose short name is “la”). The direction of each creature

is represented by the direction of the arrow.

Figure 1 shows a 4-by-4 grid populated by five creatures. Two of them belong to the species

flytrap (whose short name is “fl”), two belong to the species hop (whose short name is “ho”), and

one belongs to the species landmine (whose short name is “la”). The direction of each creature is

represented by the direction of the arrow. For example, the flytrap at the top row is facing east

and the flytrap at the bottom row is facing west.

Table 1. The list of instructions and their explanations.

hop

The creature moves forward as long as the square it is facing is empty. If

moving forward would put the creature outside the boundaries of the grid or

would cause it to land on top of another creature, the hop instruction does

nothing.

left The creature turns left 90 degrees to face in a new direction.

right The creature turns right 90 degrees to face in a new direction.

infect

If the square immediately in front of this creature is occupied by a creature of

a different species (an “enemy”), that enemy creature is infected to become

the same as the infecting species. When a creature is infected, it keeps its

position and orientation, but changes its internal species indicator and begins

executing the same program as the infecting creature, starting at step 1. If the

square immediately in front of this creature is empty, outside the grid, or

occupied by a creature of the same species, the infect instruction does

nothing.

ifempty n

If the square in front of the creature is inside the grid boundary and

unoccupied, jump to step n of the program; otherwise, go on with the next

instruction in sequence.

ifwall n

If the creature is facing the border of the grid (which we imagine as

consisting of a huge wall) jump to step n of the program; otherwise, go on

with the next instruction in sequence.

ifsame n

If the square the creature is facing is occupied by a creature of the same

species, jump to step n; otherwise, go on with the next instruction.

ifenemy n

If the square the creature is facing is occupied by a creature of an enemy

species, jump to step n; otherwise, go on with the next instruction.

go n This instruction always jumps to step n, independent of any condition.

Each species has an associated program which controls how each creature of that species

behaves. Programs are composed of a sequence of instructions. The instructions that can be

part of a program are listed in Table 1. There are nine legal instructions in total. The last five

instructions have an additional integer argument.

Program is an attribute associated with species. Creatures of the same species have the same

program. However, different species have different programs.

For example, the program of the species flytrap is composed of the following five instructions:

ifenemy 4

left

go 1

infect

go 1

The meaning of each instruction for this example is commented below:

(step 1) ifenemy 4 # If there is an enemy ahead, go to step 4

(step 2) left # Turn left

(step 3) go 1 # Go to step 1

(step 4) infect # Infect the adjacent creature

(step 5) go 1 # Go to step 1

We will simulate the behaviors of all the creatures for a user specified number of rounds. In each

round, creatures take their turns one by one, starting from the first creature. After the first

creature finishes its turn, the second creature begins its turn. So on and so forth. One round ends

with the last creature finishing its turn. Then the next round begins with the first creature taking

its turn. Note that during the simulation, a creature may infect another creature so that the

infected one changes its species. However, the simulation order of the infected creature does not

change.

Each creature also maintains a variable called program counter which stores the index of the

instruction it is going to execute. On each turn of a creature, it executes a number of instructions

of its program, starting from the step indicated by the program counter. A program ordinarily

continues with each new instruction in sequence, although this order can be changed by certain

instructions in the program such as the if*** instructions. In each turn, a creature can execute

any number of if*** or go instructions without relinquishing this turn. Its turn ends only when

the creature executes one of the instructions: hop, left, right, or infect. After its turn ends, the

creature updates the program counter to point to the next instruction, which will be executed at

the beginning of its next turn.

Note that each creature maintains its own program counter, so that two different creatures

belonging to the same species can have different program counters. The indices of the

instructions start from one, i.e., the first instruction of each program is “step 1”. At the very

beginning of the simulation process, the program counters of all the creatures are set to their first

instructions.

III. Available Types

In completing this project, you will have the following types available to you. They are defined

in the file world_type.h.

const unsigned int MAXSPECIES = 10; // Max number of species in the

// world

const unsigned int MAXPROGRAM = 40; // Max size of a species program

const unsigned int MAXCREATURES = 50; // Max number of creatures in

// the world

const unsigned int MAXHEIGHT = 20; // Max height of the grid

const unsigned int MAXWIDTH = 20; // Max width of the grid

struct point_t

{

int r;

int c;

};

/*

// Type: point_t

// ------------

// This type is used to represent a point in the grid.

// Its component r corresponds to the row number; its component

// c corresponds to the column number.

*/

enum direction_t { EAST, SOUTH, WEST, NORTH };

/*

// Type: direction_t

// ----------------

// This type is used to represent direction, which can take on

// one of the four values: East, South, West, and North.

*/

const std::string directName[] = {"east", "south", "west", "north"};

// An array of strings representing the direction name.

const std::string directShortName[] = {"e", "s", "w", "n"};

// An array of strings representing the short names for directions.

enum opcode_t {HOP, LEFT, RIGHT, INFECT, IFEMPTY, IFENEMY,

IFSAME, IFWALL, GO};

/*

// Type: opcode_t

// -------------

// The type opcode_t is an enumeration of all of the legal

// command names.

*/

const std::string opName[] = {"hop", "left", "right", "infect",

"ifempty", "ifenemy", "ifsame", "ifwall", "go"};

// An array of strings representing the command name.

struct instruction_t

{

opcode_t op;

unsigned int address;

};

/*

// Type: instruction_t

// ------------------

// The type instruction_t is used to represent an instruction

// and consists of a pair of an operation code and an integer.

// For some operation code, the integer stores the address of

// the instruction it jumps to. The address is optional.

*/

struct species_t

{

std::string name;

unsigned int programSize;

instruction_t program[MAXPROGRAM];

};

/*

// Type: species_t

// ------------------

// The type species_t is used to represent a species

// and consists of a string, an unsigned int, and an array

// of instruction_t. The string gives the name of the

// species. The unsigned int gives the number of instructions

// in the program of the species. The array stores all the

// instructions in the program according to their sequence.

*/

struct creature_t

{

point_t location;

direction_t direction;

species_t *species;

unsigned int programID;

};

/*

// Type: creature_t

// ------------------

// The type creature_t is used to represent a creature.

// It consists of a point_t, a direction_t, a pointer to

// species_t and an unsigned int. The point_t gives the location of

// the species. The direction_t gives the direction of the species.

// The pointer to species_t points to the species the creature belongs

// to. The programID gives the index of the instruction to be

// executed in the instruction_t array of the species.

*/

struct grid_t

{

unsigned int height;

unsigned int width;

creature_t *squares[MAXHEIGHT][MAXWIDTH];

};

/*

// Type: grid_t

// ------------------

// The type grid_t consists of the height and the width of the grid

// and a two-dimensional array of pointers to creature_t. If there is

// a creature at the point (r, c) in the grid, then squares[r][c]

// stores a pointer to that creature. If point (r, c) is not occupied

// by any creature, then squares[r][c] is a NULL pointer.

*/

struct world_t

{

unsigned int numSpecies;

species_t species[MAXSPECIES];

unsigned int numCreatures;

creature_t creatures[MAXCREATURES];

grid_t grid;

};

/*

// Type: world_t

// --------------

// This type consists of two unsigned ints, an array of species_t,

// an array of creature_t, and a grid_t object. The first unsigned

// int numSpecies specifies the number of species in the creature

// world. The second unsigned int numCreatures specifies the number

// of creatures in the world. All the species are stored in the array

// species and all the creatures are stored in the array creatures.

// The grid is given in the object grid.

*/

IV. File Input

All the species, the programs for all the species, and the initial layout of the creature world are

stored in files and these files will be read by your program to set up the simulation environment.

Note: when you read files, you must use input file stream ifstream. Otherwise, since the

files are read-only on our online judge, you may fail to read the files.

As we described before, each species has an associated program. The program for each species is

stored in a separate file whose name is just the name of that species. For example, the program

for the species flytrap is stored in a file called flytrap.

A file describing a program contains all the instructions of that program in order. Each line lists

just one instruction. The first line lists the first instruction; the second line lists the second

instruction; so on and so forth. Each instruction is one of the nine legal instructions described in

Table 1. The program ends with the end of file or a blank line. Comments may appear after the

blank line or at the end of each instruction line. For example, the program file for the flytrap

species looks like:

ifenemy 4 If there is an enemy, go to step 4.

left If no enemy, turn left.

go 1

infect

go 1

The flytrap sits in one place and spins.

It infects anything which comes in front.

Flytraps do well when they clump.

Note that in writing functions for reading these program files, you should handle the comments

correctly, which means that you should ignore these comments when setting up the program for a

species.

Since there are many species, we stored all of their program files in a directory.

To help you get all the species and their program files, we also have a file telling the directory

where the program files are stored and listing all the species. We call this file a species summary.

The first line of this file shows the directory where all of the program files are stored. The next

lines list all the species, with one species per line. For example, the following is a species

summary file:

creatures

flytrap

hop

landmine

From this file, we can learn that the program files are stored in the directory called creatures

located relative to the current working directory (i.e., where the program locates). We have three

species to simulate, which are flytrap, hop, and landmine. By first reading the species summary

file, you will know where to find the program file for each species.

Finally, there is a file describing the initial state of the creature world. We call it a world file. The

first line of this file gives the height of the two-dimensional grid (i.e., the number of rows) and

the second line gives the width of the grid (i.e., the number of columns). The remaining lines of

this file describe all the creatures to simulate and their initial directions and locations, with one

creature per line. Each of these lines has the following format:

<species> <initial-direction> <initial-row> <initial-column>

where <species> is one of the species from the species summary file,

<initial-direction> describes the initial direction and is one of the strings “east”,

“south”, “west”, and “north”. <initial-row> describes the initial row location of the

creature. We use the convention that the top-most row of the grid is row 0 and the row

number increases from top to bottom. <initial-column> describes the initial column

location of the creature. We use the convention that the left-most column of the grid is column

0 and the column number increases from left to right. An example of a world file looks like:

4

4

hop east 2 0

flytrap east 2 2

It says that the size of the grid is 4-by-4 and there are two creatures in the world. The first

creature belongs to the species hop. It faces east and lives at point (2, 0) initially. The second

creature belongs to the species flytrap. It faces east and lives at point (2, 2) initially.

In the simulation, the order on the creatures to simulate is important. This order is

determined by the order that these creatures appear in the world file.

V. Program Arguments

Your program will obtain the names of the species summary file and the world file via program

arguments. Additionally, your program will be told the number of rounds to simulate and

whether it should print the simulation result verbosely or not.

The expected order of arguments is:

<species-summary> <world-file> <rounds> [v|verbose]

The first three arguments are mandatory. They give the name of the species summary file, the

name of the world file, and the number of simulation rounds, respectively. The fourth argument

is optional. If the fourth argument is the string “v” or the string “verbose”, your program should

print the simulation result verbosely, which will be explained later. Otherwise, if it is omitted or

is any other string, your program should print the result concisely, which will also be explained

later. If there are more than four arguments, your program should just read the first four and

ignore the remaining.

Suppose that you program is called p3. It may be invoked by typing in a terminal:

./p3 species world 10 v

Then your program should read the species summary from the file called “species” and the world

file from the file called “world”. The number of simulation rounds is 10. Your program should

print the simulation information verbosely.

VI. Error Checking and Error Message

Your program should check for errors before it starts to simulate the moves of the creatures. If

any error happens, your program should issue an error message and then exit. If there are no

errors happening, then the initial state of the creature world is legal and your program can start

simulating the creature world.

We require you to do the following error checking and print the error message in exactly the

same way as described below. Note that some of the output error message has two lines and each

error message should be ended with a newline character. All error messages should be sent to

the standard output stream cout; none to the standard error stream cerr.

1. Check whether the number of arguments is less than three. If it is less than three, then one of

the mandatory arguments is missing. You should print the following error message:

Error: Missing arguments!

Usage: ./p3 <species-summary> <world-file> <rounds> [v|verbose]

2. Check whether the value <rounds> supplied by the user is negative. If it is negative, you

should print the following error message:

Error: Number of simulation rounds is negative!

3. Check whether file open is successful. If opening species summary file, world file, or any

species program file fails (for example, the file to be opened does not exist), print the following

error message:

Error: Cannot open file <filename>!

where <filename> should be replaced with the name of the file that fails to be opened. If that

file is not in the same directory as your program, you need to include its path in the

<filename>. As you may know, there are multiple ways to specify a path. For us, the path

name should be specified in the most basic way, i.e., “<dir>/<filename>” (not

“./<dir>/<filename>”, “<dir>//filename”, etc.). Once you find a file that cannot be

opened, issue the above error message and terminate your program.

4. Check whether the number of species listed in the species summary file exceeds the maximal

number of species MAXSPECIES. If so, print the following error message:

Error: Too many species!

Maximal number of species is <MAXSPECIES>.

where <MAXSPECIES> should be replaced with the maximal number of species set by your

program.

5. Check whether the number of instructions for a species exceeds the maximal size of a species

program MAXPROGRAM. If so, print the following error message:

Error: Too many instructions for species <SPECIES_NAME>!

Maximal number of instructions is <MAXPROGRAM>.

where <SPECIES_NAME> should be replaced with the name of the species whose program has

more instructions than the maximal number allowed and <MAXPROGRAM> should be replaced

with the maximal size of a species program set by your program.

6. Check whether the species program file contains illegal instructions. We only allow nine

instructions as listed in Table 1. Your program needs to check whether the instruction name is

one of the nine legal instruction names listed in the string array opName (which is defined in

Section III). If an instruction name is not recognized, you should print the following error

message:

Error: Instruction <UNKNOWN_INSTRUCTION> is not recognized!

where <UNKNOWN_INSTRUCTION> should be replaced with the name of the unrecognized

instruction. You can assume that for any recognized instruction, it is given in the correct format.

Thus, you don’t need to check whether an integer is appended after the instruction name or not.

If there are multiple unrecognized instruction names, you only need to print out the first one and

then terminate the program.

7. Check whether the number of creatures listed in the world file exceeds the maximal number of

creatures MAXCREATURES. If so, print the following error message:

Error: Too many creatures!

Maximal number of creatures is <MAXCREATURES>.

where <MAXCREATURES> should be replaced with the maximal number of creatures allowed

by your program.

8. Check whether each creature in the world file belongs to one of the species listed in the

species summary file. If the species for a creature is not recognized, print the following error

message:

Error: Species <UNKNOWN_SPECIES> not found!

where <UNKNOWN_SPECIES> should be replaced with the unrecognized species. If there are

multiple unrecognized species, you only need to print out the first one and then terminate the

program.

9. Check whether the direction string for each creature in the world file is one of the strings in

the array directName (which is defined in Section III). If the direction string is not recognized,

print the following error message:

Error: Direction <UNKNOWN_DIRECTION> is not recognized!

where <UNKNOWN_DIRECTION> should be replaced with the unrecognized direction name. If

there are multiple unrecognized direction names, you only need to print out the first one and then

terminate the program.

10. Check whether the grid height given by the world file is legal. A legal grid height is at least

ONE and less than or equal to a maximal value MAXHEIGHT. If the grid height is illegal, print

the following error message:

Error: The grid height is illegal!

11. Check whether the grid width given by the world file is legal. A legal grid width is at least

ONE and less than or equal to a maximal value MAXWIDTH. If the grid width is illegal, print the

following error message:

Error: The grid width is illegal!

12. Check whether each creature is inside the boundary of the grid. If any creature is outside the

boundary, print the following error message:

Error: Creature (<SPECIES> <DIR> <R> <C>) is out of bound!

The grid size is <HEIGHT>-by-<WIDTH>.

where <SPECIES> should be replaced with the species the creature belongs to, <DIR> be

replaced with the direction the creature is facing, <R> be replaced with the row location of the

creature, <C> be replaced with the column location of the creature, <HEIGHT> be replaced with

the height of the grid, and <WIDTH> be replaced with the width of the grid. Here, we use the

four-tuple (<SPECIES> <DIR> <R> <C>) to identify the creature. For example, if given

the following world file:

3

3

flytrap east 0 0

hop south 3 2

food west 2 1

then Creature (hop south 3 2) is outside the boundary. Then, the error message should be:

Error: Creature (hop south 3 2) is out of bound!

The grid size is 3-by-3.

If there are multiple creatures outside the boundary, you only need to print out the first one and

then terminate the program.

13. Check whether each square in the grid is occupied by at most one creature. If any square is

occupied by more than one creature, print the following error message:

Error: Creature (<SP1> <DIR1> <R> <C>) overlaps with creature

(<SP2> <DIR2> <R> <C>)!

where (<R> <C>) identifies the square which is occupied by more than one creature, the first

four-tuple (<SP1> <DIR1> <R> <C>) identifies the second creature in order that

occupies the square, and the second four-tuple (<SP2> <DIR2> <R> <C>) identifies the

first creature in order that occupies the square. Once you find two creatures occupying the

same square, you issue the above error message and then terminate the program.

Since you may implement the error checking in different order and in the case that there is

more than one error, the first error message printed out may be different. Therefore, we

will only test your error checking using test cases containing just one error.

You can also assume that except the above errors, there are no other errors.

You can assume that the species program file is non-empty and a file without errors 5 and

6 above could be executed for infinite rounds.

VII. Simulation Output

Once all of the above error checkings on the initial state of the creature world are passed, you

can start simulating the creature world. You should print to the standard output the simulation

information, either in a verbose mode or in a concise mode, depending on whether an

additional argument “v” or “verbose” is provided by the user.

In the verbose mode, you first print the initial state of the world. In doing so, you begin with

printing the string “Initial state” followed by a newline. Then you graphically show the

layout of the initial grid using just characters. Each square takes a four-character field in your

terminal. Adjacent squares on the same row are separated by one space. If a square in the grid is

not occupied by any creature, the field for that square is filled with FOUR “_”. If a square is

occupied by a creature, then the first two characters of the field for that square are the first two

letters of the name of the species the creature belongs to. (We assume that all the species names

contain at least two characters and no two species names have the identical first two characters.)

The third character in the field is a “_” and the fourth character is the first character of the

direction the creature faces, i.e., “e” for “east”, “s” for “south”, “w” for “west”, and “n” for

“north”.

For example, suppose a world file looks like

4

4

hop east 2 0

flytrap east 2 2

Then the layout of the initial grid is printed as

____ ____ ____ ____

____ ____ ____ ____

ho_e ____ fl_e ____

____ ____ ____ ____

Note that there is a space at the end of each line.

After printing the initial layout, we begin the simulation from the first round to the last round

specified by the user. In the i-th simulation round, you first print “Round <i>” followed by the

newline. For example, in the first round, you should first print

Round 1

During each simulation round, you simulate the moves of all the creatures in turn. When starting

simulating a creature, you announce that this creature takes action by printing

Creature (<SPECIES> <DIR> <R> <C>) takes action:

followed by a newline. In the above output, the four-tuple (<SPECIES> <DIR> <R> <C>)

shows the state of the creature right before it takes the action, where <SPECIES> should be

replaced with the species the creature belongs to, <DIR> be replaced with the direction the

creature is facing, <R> be replaced with the row location of the creature, and <C> be replaced

with the column location of the creature.

After this, you print the sequence of instructions that the creature executes for its turn. This

sequence may include any number of if*** and go instructions and end with one of the hop, left,

right, and infect instruction. You should print the sequence of instructions the creature executes

in order, with one instruction per line. The output format for an instruction is:

Instruction <INSTR_NO>: <INSTR_NAME> [GOTO_STEP]

where <INSTR_NO> should be replaced with the number of that instruction in the program (the

number starts from 1), <INSTR_NAME> should be replaced with the name of the instruction,

and [GOTO_STEP] is the number in an if*** or a go instruction and is optional.

After printing the last instruction of the creature under consideration, you should print the

updated layout of the grid, using the same rule as you print the initial layout.

Now let’s look at an example. Suppose that the program for the species hop is

hop

go 1

and the program for the species flytrap is

ifenemy 4 If there is an enemy, go to step 4.

left If no enemy, turn left.

go 1

infect

go 1

Then, given the following world file

4

4

hop east 2 0

flytrap east 2 2

the simulation information for the first round is printed as

Round 1

Creature (hop east 2 0) takes action:

Instruction 1: hop

____ ____ ____ ____

____ ____ ____ ____

____ ho_e fl_e ____

____ ____ ____ ____

Creature (flytrap east 2 2) takes action:

Instruction 1: ifenemy 4

Instruction 2: left

____ ____ ____ ____

____ ____ ____ ____

____ ho_e fl_n ____

____ ____ ____ ____

The simulation information for the second round is printed as

Round 2

Creature (hop east 2 1) takes action:

Instruction 2: go 1

Instruction 1: hop

____ ____ ____ ____

____ ____ ____ ____

____ ho_e fl_n ____

____ ____ ____ ____

Creature (flytrap north 2 2) takes action:

Instruction 3: go 1

Instruction 1: ifenemy 4

Instruction 2: left

____ ____ ____ ____

____ ____ ____ ____

____ ho_e fl_w ____

____ ____ ____ ____

In the concise mode, you print the initial state of the world in the same way as in the verbose

mode. When printing the simulation information for the i-th round, you first print “Round <i>”

followed by the newline. Then you print the final action of each creature in turn, with one

creature per line. The format is:

Creature (<SPECIES> <DIR> <R> <C>) takes action: <LAST_INSTR>

Same as in the verbose mode, the four-tuple (<SPECIES> <DIR> <R> <C>) shows the

state of the creature right before it takes the action. <LAST_INSTR> should be replaced with

the last instruction the creature executes for its turn, which is one of the hop, left, right, and

infect instruction.

After printing the final actions for all the creatures, you print the updated layout at the end of

this round.

For the same world file as above:

4

4

hop east 2 0

flytrap east 2 2

In the concise mode, the simulation information for the first round is printed as

Round 1

Creature (hop east 2 0) takes action: hop

Creature (flytrap east 2 2) takes action: left

____ ____ ____ ____

____ ____ ____ ____

____ ho_e fl_n ____

____ ____ ____ ____

The simulation information for the second round is printed as

Round 2

Creature (hop east 2 1) takes action: hop

Creature (flytrap north 2 2) takes action: left

____ ____ ____ ____

____ ____ ____ ____

____ ho_e fl_w ____

____ ____ ____ ____

There are no blank lines in the output for both the verbose and concise mode.

VIII. Source Code Files and Compiling

There is a source code file located in the Project-3-Related-Files.zip from our

Canvas Resources:

world_type.h: The header file that defines a number of types for you to use.

You should copy this file into your working directory. DO NOT modify it!

You need to write three other source code files. The first file is named as simulation.h,

which contains the declarations for all the functions you write, just like the p2.h in our project

two. The second file is named as simulation.cpp, which contains all the implementations of

those functions declared in the simulation.h. The third file is named as p3.cpp, which

contains only the main function. After you have written these files, you can type the following

command in the terminal to compile the program:

g++ -Wall -o p3 p3.cpp simulation.cpp

This will generate a program called p3 in your working directory. In order to ensure that the

online judge compiles your program successfully, you should name you source code files exactly

like how they are specified above.

IX. Implementation Requirements and Restrictions

1. When writing your code, you may use the following standard header files: <iostream>,

<fstream>, <sstream>, <iomanip>, <string>, <cstdlib>, and <cassert>. No

other header files can be included.

2. You may not define any global variables yourself. You can only use the global constant ints

and string arrays defined in world_type.h.

3. Pass large structs by reference rather than value. Where appropriate, pass const references /

pointers-to-const. Do not pass lots of little arguments when you can pass an appropriate, larger

structure instead.

4. All required output should be sent to the standard output stream; none to the standard error

stream.

5. You should strive not to duplicate identical or nearly‐identical code, and instead collect such

code into a single function that can be called from various places. Each function should do a

single job, though the definition of "job" is obviously open to interpretation. Most students write

too few functions that are too large.

X. Hints and Tips

1. This project will take you longer than project 2 did, so start early!

2. Do this project in stages. First, be able to read the species summary file. Second, be able to

read the programs for all the species. Third, be able to read the world file. Write some diagnostic

code that can print out the species summary, the program for each species, and the creatures, to

make sure that you are reading them correctly. Implement the error checking and test it with

different illegal inputs. Once you can read the structures in, implement the simple moves such as

left and right. Once you have that working, implement moves such as hop and infect. Finally,

implement if*** and go instructions.

3. Take advantage of the fact that enumerations are sequentially numbered from 0 to N‐1.

4. Use the right methods of input file stream to read file. In some cases, you may first use the

getline() function to read the entire line of a file and then use an input string stream to

extract the content from that line.

5. The hop instruction will only cause the creature to move forward when the square it is facing

is empty. If moving forward would put the creature outside the boundaries of the grid or would

cause it to land on top of another creature, the hop instruction does nothing. However, although

the hop action is not executed successfully, you should update the program counter so that it

points to the next instruction after this hop instruction. The similar situation also applies to the

infect instruction. If there is no enemy to infect, the infect operation does nothing. However, you

should update the program counter to its next instruction.

6. As a hint, you probably need to write the following eight functions or some variations of them.

However, these are not the only functions you have to write. You probably need to write more

functions for different jobs.

bool initWorld(world_t &world, const string &speciesFile,

const string &creaturesFile);

// MODIFIES: world

//

// EFFECTS: Initialize "world" given the species summary file

// "speciesFile" and the world description file

// "creaturesFile". This initializes all the components of

// "world". Returns true if initialization is successful.

void simulateCreature(creature_t &creature, grid_t &grid, bool

verbose);

// REQUIRES: creature is inside the grid.

//

// MODIFIES: creature, grid, cout.

//

// EFFECTS: Simulate one turn of "creature" and update the creature,

// the infected creature, and the grid if necessary.

// The creature programID is always updated. The function

// also prints to the stdout the procedure. If verbose is

// true, it prints more information.

void printGrid(const grid_t &grid);

// MODIFIES: cout.

//

// EFFECTS: print a grid representation of the creature world.

point_t adjacentPoint(point_t pt, direction_t dir);

// EFFECTS: Returns a point that results from moving one square

// in the direction "dir" from the point "pt".

direction_t leftFrom(direction_t dir);

// EFFECTS: Returns the direction that results from turning

// left from the given direction "dir".

direction_t rightFrom(direction_t dir);

// EFFECTS: Returns the direction that results from turning

// right from the given direction "dir".

instruction_t getInstruction(const creature_t &creature);

// EFFECTS: Returns the current instruction of "creature".

creature_t *getCreature(const grid_t &grid, point_t location);

// REQUIRES: location is inside the grid.

//

// EFFECTS: Returns a pointer to the creature at "location" in "grid".

XI. Testing

We provide you with a few test cases in the directory called tests, which can be found inside

Project-3-Related-Files.zip from our Canvas Resources.

Inside the tests directory, there is an example species summary file called species and two

subdirectories called creatures and world-tests. The creatures directory contains a

number of species program files. The world-tests directory contains five world files and the

files recording the correct outputs.

The first world file is called outside-world, which describes an illegal world with one

creature located outside the boundary of the grid.

To run this test case, type the following commands:

./p3 species world-tests/outside-world 5 > outside-world.out

Then the output of your program is redirected to a file named outside-world.out. The

correct output is recorded in the file outside-world.answer in the directory world tests. You can use the diff command to check whether the file outside-world.out is

same as the file outside-world.answer.

The second world file is called overlap-world, which describes an illegal world with two

creatures located at the same square in the grid. You can run this test case using a similar

command as shown above and compare your output with the correct output recorded in the file

overlap-world.answer.

The next three world files world1, world2, and world3 are legal world files. You can run

these test cases in the similar way. The number of simulation rounds for world1, world2, and

world3 are 5, 20, and 40, respectively. For these test cases, we provide you with both the

verbose and the concise output files. The verbose output files are these files named as

*-verbose.answer and the concise output files are these files named as

*-concise.answer.

These are the minimal amount of tests you should run to check your program. Those programs

that do not pass these tests are not likely to receive much credit. You should also write other

different test cases yourself to test your program extensively. In doing so, you need to write your

own legal/illegal species summary files, legal/illegal world files, and species program files.

Indeed, it will be very interesting to create new species yourself and observe what kind of

species will finally dominate the SIMPLE WORLD given different initial layout!

XII. Submitting and Due Date

You should submit your source code files simulation.h, simulation.cpp, and p3.cpp.

These files should be submitted via the online judgment system. See announcement from the

TAs for details about submission. The due date is 11:59 pm on Nov. 17, 2024.

XIII. Grading

Your program will be graded along three criteria:

1. Functional Correctness

2. Implementation Constraints

3. General Style

Functional Correctness is determined by running a variety of test cases against your program,

checking against our reference solution. We will grade Implementation Constraints to see if you

have met all of the implementation requirements and restrictions. General Style refers to the ease

with which TAs can read and understand your program, and the cleanliness and elegance of your

code. For example, significant code duplication will lead to General Style deductions.


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