What I need to do is read a file which contains equations. I need to take the derivative of each equation and then write those derivative equations in a different .txt file. I\'
This function will parse the text, cut it in to different parts identified by type[i]
, stores in a structure. It recognizes x
, +, -, and numbers. It can be expand it to include other operators etc.
#define maxlen 50
#define idx 0 //X variable
#define idnumber 1 //number
#define idplus 2 //+ sign
#define idminus 3 //- sign
struct foo
{
int type[10];//each type can be a number (idnum), +, -, etc.
int num[10];//if type[i] is number then num[i] identifies that number
int count;//total number of parts
};
void parse_one_line(struct foo *v, const char *s)
{
char buf[maxlen];
memset(buf, 0, maxlen);
int j = 0;
//remove white spaces
for (int i = 0, len = strlen(s); i < len; i++)
{
if (s[i] == ' ') continue;
buf[j] = s[i];
j++;
}
char part[maxlen];
v->count = 0;
for (int i = 0, len = strlen(buf); i < len; i++)
{
char c = buf[i];
if (c == 'x')
{
v->type[v->count] = idx;
v->count++;
}
else if (c == '+')
{
v->type[v->count] = idplus;
v->count++;
}
else if (c == '-')
{
v->type[v->count] = idminus;
v->count++;
}
else if (c >= '0' && c <= '9')
{
int j = 0;
memset(part, 0, maxlen);
for (; i < len; i++)
{
c = buf[i];
if (c >= '0' && c <= '9')
{
part[j] = c;
j++;
}
else
{
break;
}
}
i--;
v->num[v->count] = atoi(part);
v->type[v->count] = idnumber;
v->count++;
}
}
for (int i = 0; i < v->count; i++)
{
switch (v->type[i])
{
case idnumber: printf("%d", v->num[i]); break;
case idx: printf("X"); break;
case idplus: printf("+"); break;
case idminus: printf("-"); break;
default:break;
}
}
printf("\n");
}
int main()
{
struct foo st;
parse_one_line(&st, "-23x + 2 + 2x - 3");
return 0;
}
What you're really asking for is a parser. A parser is basically a set of rules to read those equations and change/read (parse) each of them. I'd try to iterate over each line of the file, and differentiate it considering you have a specific character set (i.e ^ means power, x is the parameter, etc.);
For example, some pseudo code:
Open the file.
While there's lines to read:
Read a line -
Seperate it by the operands (+,-,/,*)
For each part:
Find the power of x,
Reduce it by one,
...(derivating rules) // no way around, you have to implement each function if you want this to work as others mentioned in the comments.
Reconnect the parts into a string,
Add it to a list.
Print each element of the list.
If you need help translating that into C, just ask for it; I'll happily help you.
What you need to do, by the looks of things, is separate the expression into individual terms so that you can find the derivative of each in turn.
You can define a term as the largest sequence of characters not containing term separators such as (in your examples) +
and -
.
Hence the terms for your examples are:
-2x^2+2x-3 => 2x^2 2x 3
-2x+sinx-3 => 2x sinx 3
-x+sin2x-tanx => x sin2x tanx
For each term, you then need to evaluate the form of the term. The form will dictate how you create the derivative.
For example, you can detect if it contains a trigonometric function of the form [n]sin[m]x
where n
and m
are optional numbers. To simplify things, you could add in those terms if they're not there, such as sinx
becoming 1sin1x
(I'll call this the full-form of the term). Being able to assume all subterms are present will greatly ease the derivative calculation.
Let's say the term is sin4x
. Expanding that will give you 1sin4x
which you can then split into term-multiplier 1
, function sin
and x-multiplier 4
. Then using standard derivative knowledge nsinmx => (n*m)cosmx
, this would become 4cos(4x)
and that term would be done.
If it doesn't contain a trigonometric function, you can use the same full-form trick to cover all of the power/constant expressions with the following rules in turn:
x^0
(multiply by 1).x
, append ^1
, so 4x
becomes 4x^1
.x
, prefix it with 1
, so x^3
becomes 1x^3
.Once that's done, you will have a full-form of ax^b
and you can then create the derivative (ab)x^(b-1)
and post-process it:
x
is ^0
, remove the whole x^0
.x
is ^1
, remove the ^1
.x
is 1
, remove it.x
is 0
, remove the entire term (and preceding term separator, if any).So, taking a complex combination of your test data:
-2x^2 + 5x + 4sin3x - 3
which can be treated as:
0 - 2x^2 + 5x + 4sin3x - 3
The following actions happen to each term:
0 [0x^1] (derives as) 0, remove it.
2x^2 [2x^2] (derives as) (2*2)x^(2-1) => 4x^1 => 4x
5x [5x^1] (derives as) (5x1)x^(1-1) => 5x^0 => 5
4sin3x [4sin3x] (derives as) 12cos3x
3 [3x^0] (derives as) 0, remove it and preceding '-'
Thus you end up with - 4x + 5 + 12cos3x
which, although my calculus education is some thirty years in the past (and I don't think I've used it since, though I will no doubt be using it next year when my eldest hits secondary school), Wolfram Alpha appears to agree with me :-)