-/* Polynomial ADT \r
-** A polynomial module with\r
-** ability to add,sub,mul derivate/integrate, compose ... polynomials \r
-** ..expansion in progress ...\r
- * Copyright (c) 2009 I. Soule\r
- * All rights reserved.\r
- *\r
- * Redistribution and use in source and binary forms, with or without\r
- * modification, are permitted provided that the following conditions\r
- * are met:\r
- * 1. Redistributions of source code must retain the above copyright\r
- * notice, this list of conditions and the following disclaimer.\r
- * 2. Redistributions in binary form must reproduce the above copyright\r
- * notice, this list of conditions and the following disclaimer in the\r
- * documentation and/or other materials provided with the distribution.\r
- *\r
- * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND\r
- * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE\r
- * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE\r
- * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE\r
- * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL\r
- * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS\r
- * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)\r
- * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT\r
- * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY\r
- * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF\r
- * SUCH DAMAGE.\r
- *\r
-** iasoule32@gmail.com\r
-*/\r
-\r
-#ifndef __POLYNOMIAL_ADT\r
-#define __POLYNOMIAL_ADT\r
-\r
-#include <assert.h>\r
-#include <stdlib.h>\r
-#include <stdbool.h> //C99 compliance\r
-#include <math.h>\r
-\r
-#define max(a, b) (a) > (b) ? (a) : (b)\r
-#define sgn(a) (a) < 0 ? '+' : '-' //for quadratic factored form\r
-\r
-typedef struct node {\r
- int exp;\r
- float coeff;\r
- struct node *next;\r
-}Node;\r
-\r
-typedef struct polynomial_adt {\r
- Node *head;\r
- int terms, hp; //hp highest power\r
-}PolyAdt;\r
-\r
-void display_poly(const PolyAdt *a);\r
-/**\r
-* create_adt - create a polynomial on the heap\r
-* @hp: the highest power in the polynomial\r
-*/\r
-PolyAdt *create_adt(int hp) \r
-{\r
- PolyAdt *pAdt = malloc(sizeof(PolyAdt));\r
- assert(pAdt != NULL);\r
- \r
- pAdt->head = NULL;\r
- pAdt->terms = 0;\r
- pAdt->hp = hp;\r
-\r
- return pAdt;\r
-}\r
-/**\r
-* create_node - creates a Node (exponent, constant and next pointer) on the heap \r
-* @constant: the contant in the term \r
-* @exp: the exponent on the term\r
-* @next: the next pointer to another term in the polynomial\r
-* \r
-* This should not be called by client code (hence marked static)\r
-* used to assist insert_term()\r
-*/ \r
-static Node *create_node(float constant, int exp, Node *next)\r
-{\r
- Node *nNode = malloc(sizeof(Node));\r
- assert(nNode != NULL);\r
- \r
- nNode->exp = exp;\r
- nNode->coeff = constant;\r
- nNode->next = next;\r
- return nNode;\r
-}\r
-\r
-/**\r
-* insert_term - inserts a term into the polynomial\r
-* @pAdt: the polynomial \r
-* @c: constant value on the term\r
-* @e: the exponent on the term \r
-*/\r
-void insert_term(PolyAdt *pAdt, float c, int e)\r
-{\r
- assert(pAdt != NULL); //assume client code didnt call create_adt()\r
- Node *n = malloc(sizeof(Node));\r
- \r
- if(pAdt->head == NULL)\r
- pAdt->head = create_node(c, e, pAdt->head);\r
- else\r
- for(n = pAdt->head; n->next != NULL; n = n->next); //go to the end of list\r
- n->next = create_node(c, e, NULL);\r
- \r
- pAdt->terms++;\r
-}\r
-\r
-/**\r
-* polyImage - returns an image (direct) copy of the polynomial\r
-* @orig: the polynomial to be duplicated\r
-*/\r
-PolyAdt *polyImage(const PolyAdt *orig)\r
-{\r
- PolyAdt *img = create_adt(orig->hp);\r
- Node *origHead = orig->head;\r
- \r
- for(; origHead; origHead = origHead->next)\r
- insert_term(img, origHead->coeff, origHead->exp);\r
- return img;\r
-}\r
-\r
-\r
-/**\r
-* add - adds two polynomials together, and returns their sum (as a polynomial)\r
-* @a: the 1st polynomial \r
-* @b: the 2nd polynomial\r
-*/\r
-PolyAdt *add(const PolyAdt *a, const PolyAdt *b)\r
-{\r
- PolyAdt *sum;\r
- Node *n, *np;\r
- _Bool state = true;\r
- \r
- assert(a != NULL && b != NULL);\r
- \r
- int hpow = max(a->hp, b->hp);\r
- sum = create_adt(hpow); //create space for it\r
- \r
- /* using state machine to compare the poly with the most terms to \r
- ** the poly with fewer, round robin type of effect comparison of\r
- ** exponents => 3 Cases: Equal, Less, Greater\r
- */\r
- n = a->head; np = b->head;\r
- while(state) {\r
- /* compare the exponents */\r
- if(n->exp == np->exp){\r
- insert_term(sum, n->coeff + np->coeff, n->exp);\r
- n = n->next;\r
- np = np->next;\r
- }\r
- \r
- else if(n->exp < np->exp){\r
- insert_term(sum, np->coeff, np->exp);\r
- np = np->next; //move to next term of b\r
- }\r
- \r
- else { //greater than\r
- insert_term(sum, n->coeff, n->exp);\r
- n = n->next;\r
- }\r
- /* check whether at the end of one list or the other */\r
- if(np == NULL && state == true){ //copy rest of a to sum\r
- for(; n != NULL; n = n->next)\r
- insert_term(sum, n->coeff, n->exp);\r
- state = false;\r
- }\r
- \r
- if(n == NULL && state == true){\r
- for(; np != NULL; np = np->next)\r
- insert_term(sum, np->coeff, np->exp);\r
- state = false;\r
- } \r
- } \r
- return sum; \r
-} \r
-\r
-/**\r
-* sub - subtracts two polynomials, and returns their difference (as a polynomial)\r
-* @a: the 1st polynomial \r
-* @b: the 2nd polynomial\r
-* Aids in code reuse by negating the terms (b) and then calls the add() function\r
-*/\r
-PolyAdt *subtract(const PolyAdt *a, const PolyAdt *b)\r
-{\r
- assert(a != NULL && b != NULL);\r
-\r
- PolyAdt *tmp = create_adt(b->hp);\r
- Node *bptr;\r
- \r
- for(bptr = b->head; bptr != NULL; bptr = bptr->next)\r
- insert_term(tmp,-bptr->coeff,bptr->exp); //negating b's coeffs\r
- return add(a,tmp);\r
-}\r
-\r
-/**\r
-* multiply - multiply two polynomials, and returns their product (as a polynomial)\r
-* @a: the 1st polynomial \r
-* @b: the 2nd polynomial\r
-*/\r
-PolyAdt *multiply(const PolyAdt *a, const PolyAdt *b)\r
-{\r
- assert(a != NULL && b != NULL);\r
-\r
- //the polys are inserted in order for now\r
- PolyAdt *prod = create_adt(a->head->exp + b->head->exp);\r
- Node *n = a->head, *np = b->head;\r
- Node *t = b->head; \r
- \r
- if(a->terms < b->terms){\r
- n = b->head;\r
- np = t = a->head;\r
- }\r
- \r
- for(; n != NULL; n = n->next){\r
- np = t; //reset to the beginning\r
- for(; np != NULL; np = np->next){ //always the least term in this loop\r
- insert_term(prod, n->coeff * np->coeff, n->exp + np->exp);\r
- }\r
- }\r
-\r
- return prod; \r
-}\r
-\r
-/**\r
-* derivative - computes the derivative of a polynomial and returns the result\r
-* @a: the polynomial to take the derivative upon\r
-*/\r
-PolyAdt *derivative(const PolyAdt *a)\r
-{\r
- assert(a != NULL);\r
- \r
- PolyAdt *deriv = create_adt(a->head->exp - 1);\r
- Node *n = a->head;\r
-\r
- for(; n != NULL; n = n->next){\r
- if(n->exp == 0) break;\r
- insert_term(deriv, n->coeff * n->exp, n->exp-1);\r
- }\r
- return deriv;\r
-}\r
-/**\r
-* integrate - computes the integral of a polynomial and returns the result\r
-* @a: the polynomial to take the integral of\r
-* \r
-* Will compute an indefinite integral over a\r
-*/\r
-PolyAdt *integrate(const PolyAdt *a)\r
-{\r
- assert(a != NULL);\r
- \r
- PolyAdt *integrand = create_adt(a->head->exp + 1);\r
- Node *n;\r
-\r
- for(n = a->head; n != NULL; n = n->next) //very simple term by term\r
- insert_term(integrand, (float)n->coeff/(n->exp+1.0F), n->exp + 1);\r
- \r
- return integrand;\r
-}\r
-/**\r
-* quadratic_roots - finds the roots of the polynomial ax^2+bx+c, a != 0 && b != 0\r
-* @a: the polynomial\r
-* @real: a pointer to float of the real(R) part of a\r
-* @cplx: a pointer to float of the imaginary(I) part of a\r
-*\r
-* Usage:\r
-* Two options can be done by the client \r
-* 1. Either pass NULL to real and cplx\r
-* this will display the roots by printf\r
-* quadratic_roots(myPolynomial, NULL, NULL);\r
-*\r
-* 2. Pass in pointers** to type float of the real and complex\r
-* if the discriminant is >0 cplx = -ve root of X\r
-* quadratic_roots(myPolynomial, &realPart, &complexPart);\r
-*/\r
-void quadratic_roots(const PolyAdt *a, float *real, float *cplx)\r
-{\r
- assert(a != NULL);\r
- \r
- float dscrmnt, _a, b, c;\r
- float u, v;\r
- \r
- Node *n = a->head;\r
- _a = n->coeff; b = n->next->coeff; c = n->next->next->coeff;\r
- \r
- dscrmnt = (b*b) - 4*_a*c;\r
- u = -b/(2*_a); v = sqrt((double)fabs(dscrmnt))/(2*_a);\r
- \r
- if(real && !cplx || !real && cplx)\r
- assert(true);\r
-\r
- if(real == NULL && cplx == NULL){\r
- if(a->hp != 2 && a->terms < 3){\r
- printf("Invalid Quadratic*, A and B must be non-zero");\r
- return;\r
- }\r
- \r
- if(dscrmnt != 0)\r
- printf("X = %.2f +/- %.2f%c\n",u,v,dscrmnt < 0 ? 'I':' ');\r
- else{\r
- printf("(X %c %.2f)(X %c %.2f)\n",sgn(u),fabs(u),sgn(u),fabs(u));\r
- printf("X1,2 = %.2f\n",u);\r
- }\r
- }\r
- //save values in pointers\r
- else {\r
- if(dscrmnt < 0){ //x = u +/- vI Re(x) = u, Im(x) = +v\r
- *real = u; \r
- *cplx = v; //understand +/- is not representable\r
- }\r
- else if(dscrmnt == 0){\r
- *real = u; \r
- *cplx = 0.00F;\r
- }\r
- else{\r
- *real = u + v;\r
- *cplx = u - v;\r
- }\r
- }\r
-}\r
-\r
-/**\r
-* exponentiate - computes polynomial exponentiation (P(x))^n, n E Z*\r
-* @a: the polynomial\r
-* @n: the exponent\r
-* Works fast for small n (n < 8) currently runs ~ O(n^2 lg n)\r
-*/\r
-PolyAdt *exponentiate(const PolyAdt *a, int n)\r
-{\r
- assert(a != NULL);\r
-\r
- PolyAdt *expn = create_adt(a->hp * n);\r
- PolyAdt *aptr = polyImage(a);\r
- int hl = n / 2;\r
- \r
- //check default cases before calculation\r
- if(n == 0){\r
- insert_term(expn, 1, 0);\r
- return expn;\r
- }\r
- else if(n == 1){\r
- return aptr;\r
- }\r
- \r
- for(; hl ; hl--)\r
- aptr = multiply(aptr, aptr);\r
-\r
- if(n % 2) //odd exponent do a^(n-1) * a = a^n\r
- expn = multiply(aptr, a);\r
- else\r
- expn = aptr;\r
- return expn;\r
-}\r
-/**\r
-* compose - computes the composition of two polynomials P(Q(x)) and returns the composition\r
-* @p: polynomial P(x) which will x will be equal to Q(x)\r
-* @q: polynomial Q(x) which is the argument to P(x)\r
-*/\r
-PolyAdt *compose(const PolyAdt *p, const PolyAdt *q)\r
-{\r
- assert(p && q);\r
- \r
- PolyAdt *comp = create_adt(p->head->exp * q->head->exp);\r
- PolyAdt *exp;\r
- \r
- Node *pp = p->head;\r
- Node *qq = q->head;\r
- \r
- int swap = 0;\r
- \r
- if(p->terms < q->terms){\r
- pp = q->head;\r
- qq = p->head;\r
- swap = 1;\r
- }\r
- \r
- /* going through, exponentiate each term with the exponent of p */\r
- for(; pp != NULL; pp = pp->next){\r
- exp = exponentiate(swap ? p: q, pp->exp);\r
- insert_term(comp, pp->coeff * exp->head->coeff, exp->head->exp);\r
- }\r
- \r
- return comp;\r
-}\r
-/** \r
-* destroy_poly - completely frees the polynomial from the heap and resets all values\r
-* @poly: the polynomial to release memory back to the heap\r
-* Usage:\r
-* destroy_poly(myPoly); //puts polynomial on free list\r
-*/\r
-void destroy_poly(PolyAdt *poly)\r
-{\r
- Node *ps = poly->head;\r
- Node *tmp = NULL;\r
- while(ps != NULL){\r
- tmp = ps;\r
- free(tmp);\r
- ps = ps->next;\r
- }\r
- poly->hp = poly->terms = 0;\r
- poly->head = NULL;\r
-}\r
-/**\r
-* display_poly - displays the polynomial to the console in nice format\r
-* @a: the polynomial to display \r
-*/\r
-void display_poly(const PolyAdt *a)\r
-{\r
- assert(a != NULL);\r
- Node *n;\r
- \r
- for(n = a->head; n != NULL; n = n->next){\r
- \r
- n->coeff < 0 ? putchar('-') : putchar('+'); \r
- if(n->exp == 0)\r
- printf(" %.2f ",fabs(n->coeff));\r
- else if(n->coeff == 1)\r
- printf(" X^%d ",n->exp);\r
- else if(n->exp == 1)\r
- printf(" %.2fX ",fabs(n->coeff));\r
- else if(n->coeff == 0)\r
- continue;\r
- else\r
- printf(" %.2fX^%d ",fabs(n->coeff),n->exp);\r
- }\r
- printf("\n\n");\r
-}\r
-\r
-#endif\r
+/* Polynomial ADT
+** A polynomial module with
+** ability to add,sub,mul derivate/integrate, compose ... polynomials
+** ..expansion in progress ...
+ * Copyright (c) 2009 I. Soule
+ * All rights reserved.
+ *
+ * Redistribution and use in source and binary forms, with or without
+ * modification, are permitted provided that the following conditions
+ * are met:
+ * 1. Redistributions of source code must retain the above copyright
+ * notice, this list of conditions and the following disclaimer.
+ * 2. Redistributions in binary form must reproduce the above copyright
+ * notice, this list of conditions and the following disclaimer in the
+ * documentation and/or other materials provided with the distribution.
+ *
+ * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
+ * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
+ * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
+ * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
+ * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
+ * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
+ * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
+ * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
+ * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
+ * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
+ * SUCH DAMAGE.
+ *
+** iasoule32@gmail.com
+*/
+
+#ifndef __POLYNOMIAL_ADT
+#define __POLYNOMIAL_ADT
+
+#include <assert.h>
+#include <stdlib.h>
+#include <stdio.h>
+#include <math.h>
+
+#define max(a, b) (a) > (b) ? (a) : (b)
+#define sgn(a) (a) < 0 ? '+' : '-' //for quadratic factored form
+
+typedef struct node {
+ int exp;
+ float coeff;
+ struct node *next;
+}Node;
+
+typedef struct polynomial_adt {
+ Node *head;
+ int terms, hp; //hp highest power
+}PolyAdt;
+
+/**
+* create_adt - create a polynomial on the heap
+* @hp: the highest power in the polynomial
+*/
+PolyAdt *create_adt(int hp);
+
+/**
+* create_node - creates a Node (exponent, constant and next pointer) on the heap
+* @constant: the contant in the term
+* @exp: the exponent on the term
+* @next: the next pointer to another term in the polynomial
+*
+* This should not be called by client code (hence marked static)
+* used to assist insert_term()
+*/
+static inline Node *create_node(float constant, int exp, Node *next) {
+ Node *nNode = malloc(sizeof(Node));
+ assert(nNode != NULL);
+
+ nNode->exp = exp;
+ nNode->coeff = constant;
+ nNode->next = next;
+ return nNode;
+}
+
+/**
+* insert_term - inserts a term into the polynomial
+* @pAdt: the polynomial
+* @c: constant value on the term
+* @e: the exponent on the term
+*/
+void insert_term(PolyAdt *pAdt, float c, int e);
+
+/**
+* polyImage - returns an image (direct) copy of the polynomial
+* @orig: the polynomial to be duplicated
+*/
+PolyAdt *polyImage(const PolyAdt *orig);
+
+
+/**
+* add - adds two polynomials together, and returns their sum (as a polynomial)
+* @a: the 1st polynomial
+* @b: the 2nd polynomial
+*/
+PolyAdt *add(const PolyAdt *a, const PolyAdt *b);
+
+/**
+* sub - subtracts two polynomials, and returns their difference (as a polynomial)
+* @a: the 1st polynomial
+* @b: the 2nd polynomial
+* Aids in code reuse by negating the terms (b) and then calls the add() function
+*/
+PolyAdt *subtract(const PolyAdt *a, const PolyAdt *b);
+
+/**
+* multiply - multiply two polynomials, and returns their product (as a polynomial)
+* @a: the 1st polynomial
+* @b: the 2nd polynomial
+*/
+PolyAdt *multiply(const PolyAdt *a, const PolyAdt *b);
+
+/**
+* derivative - computes the derivative of a polynomial and returns the result
+* @a: the polynomial to take the derivative upon
+*/
+PolyAdt *derivative(const PolyAdt *a);
+
+/**
+* integrate - computes the integral of a polynomial and returns the result
+* @a: the polynomial to take the integral of
+*
+* Will compute an indefinite integral over a
+*/
+PolyAdt *integrate(const PolyAdt *a);
+
+/**
+* quadratic_roots - finds the roots of the polynomial ax^2+bx+c, a != 0 && b != 0
+* @a: the polynomial
+* @real: a pointer to float of the real(R) part of a
+* @cplx: a pointer to float of the imaginary(I) part of a
+*
+* Usage:
+* Two options can be done by the client
+* 1. Either pass NULL to real and cplx
+* this will display the roots by printf
+* quadratic_roots(myPolynomial, NULL, NULL);
+*
+* 2. Pass in pointers** to type float of the real and complex
+* if the discriminant is >0 cplx = -ve root of X
+* quadratic_roots(myPolynomial, &realPart, &complexPart);
+*/
+void quadratic_roots(const PolyAdt *a, float *real, float *cplx);
+
+/**
+* exponentiate - computes polynomial exponentiation (P(x))^n, n E Z*
+* @a: the polynomial
+* @n: the exponent
+* Works fast for small n (n < 8) currently runs ~ O(n^2 lg n)
+*/
+PolyAdt *exponentiate(const PolyAdt *a, int n);
+
+/**
+* compose - computes the composition of two polynomials P(Q(x)) and returns the composition
+* @p: polynomial P(x) which will x will be equal to Q(x)
+* @q: polynomial Q(x) which is the argument to P(x)
+*/
+PolyAdt *compose(const PolyAdt *p, const PolyAdt *q);
+
+/**
+* destroy_poly - completely frees the polynomial from the heap and resets all values
+* @poly: the polynomial to release memory back to the heap
+* Usage:
+* destroy_poly(myPoly); //puts polynomial on free list
+*/
+void destroy_poly(PolyAdt *poly);
+
+/**
+* display_poly - displays the polynomial to the console in nice format
+* @a: the polynomial to display
+*/
+void display_poly(const PolyAdt *a);
+
+#endif