/* Symbolic addition Terms in a sum are combined if they are identical modulo rational coefficients. For example, A + 2A becomes 3A. However, the sum A + sqrt(2) A is not modified. Combining terms can lead to second-order effects. For example, consider the case of 1/sqrt(2) A + 3/sqrt(2) A + sqrt(2) A The first two terms are combined to yield 2 sqrt(2) A. This result can now be combined with the third term to yield 3 sqrt(2) A */ #include "stdafx.h" #include "defs.h" static int flag; void eval_add(void) { int h = tos; p1 = cdr(p1); while (iscons(p1)) { push(car(p1)); eval(); p2 = pop(); push_terms(p2); p1 = cdr(p1); } add_terms(tos - h); } /* Add n terms, returns one expression on the stack. */ void add_terms(int n) { int i, h; U **s; h = tos - n; s = stack + h; /* ensure no infinite loop, use "for" */ for (i = 0; i < 10; i++) { if (n < 2) break; flag = 0; qsort(s, n, sizeof (U *), cmp_terms); if (flag == 0) break; n = combine_terms(s, n); } tos = h + n; switch (n) { case 0: push_integer(0); break; case 1: break; default: list(n); p1 = pop(); push_symbol(ADD); push(p1); cons(); break; } } /* Compare terms for order, clobbers p1 and p2. */ int cmp_terms(const void *q1, const void *q2) { int i, t; p1 = *((U **) q1); p2 = *((U **) q2); /* numbers can be combined */ if (isnum(p1) && isnum(p2)) { flag = 1; return 0; } /* congruent tensors can be combined */ if (istensor(p1) && istensor(p2)) { if (p1->u.tensor->ndim < p2->u.tensor->ndim) return -1; if (p1->u.tensor->ndim > p2->u.tensor->ndim) return 1; for (i = 0; i < p1->u.tensor->ndim; i++) { if (p1->u.tensor->dim[i] < p2->u.tensor->dim[i]) return -1; if (p1->u.tensor->dim[i] > p2->u.tensor->dim[i]) return 1; } flag = 1; return 0; } if (car(p1) == symbol(MULTIPLY)) { p1 = cdr(p1); if (isnum(car(p1))) { p1 = cdr(p1); if (cdr(p1) == symbol(NIL)) p1 = car(p1); } } if (car(p2) == symbol(MULTIPLY)) { p2 = cdr(p2); if (isnum(car(p2))) { p2 = cdr(p2); if (cdr(p2) == symbol(NIL)) p2 = car(p2); } } t = cmp_expr(p1, p2); if (t == 0) flag = 1; return t; } /* Compare adjacent terms in s[] and combine if possible. Returns the number of terms remaining in s[]. n number of terms in s[] initially */ int combine_terms(U **s, int n) { int i, j, t; for (i = 0; i < n - 1; i++) { check_esc_flag(); p3 = s[i]; p4 = s[i + 1]; if (istensor(p3) && istensor(p4)) { push(p3); push(p4); tensor_plus_tensor(); p1 = pop(); if (p1 != symbol(NIL)) { s[i] = p1; for (j = i + 1; j < n - 1; j++) s[j] = s[j + 1]; n--; i--; } continue; } if (istensor(p3) || istensor(p4)) continue; if (isnum(p3) && isnum(p4)) { push(p3); push(p4); add_numbers(); p1 = pop(); if (iszero(p1)) { for (j = i; j < n - 2; j++) s[j] = s[j + 2]; n -= 2; } else { s[i] = p1; for (j = i + 1; j < n - 1; j++) s[j] = s[j + 1]; n--; } i--; continue; } if (isnum(p3) || isnum(p4)) continue; p1 = one; p2 = one; t = 0; if (car(p3) == symbol(MULTIPLY)) { p3 = cdr(p3); t = 1; /* p3 is now denormal */ if (isnum(car(p3))) { p1 = car(p3); p3 = cdr(p3); if (cdr(p3) == symbol(NIL)) { p3 = car(p3); t = 0; } } } if (car(p4) == symbol(MULTIPLY)) { p4 = cdr(p4); if (isnum(car(p4))) { p2 = car(p4); p4 = cdr(p4); if (cdr(p4) == symbol(NIL)) p4 = car(p4); } } if (!equal(p3, p4)) continue; push(p1); push(p2); add_numbers(); p1 = pop(); if (iszero(p1)) { for (j = i; j < n - 2; j++) s[j] = s[j + 2]; n -= 2; i--; continue; } push(p1); if (t) { push(symbol(MULTIPLY)); push(p3); cons(); } else push(p3); multiply(); s[i] = pop(); for (j = i + 1; j < n - 1; j++) s[j] = s[j + 1]; n--; i--; } return n; } void push_terms(U *p) { if (car(p) == symbol(ADD)) { p = cdr(p); while (iscons(p)) { push(car(p)); p = cdr(p); } } else if (!iszero(p)) push(p); } /* add two expressions */ void add() { int h; save(); p2 = pop(); p1 = pop(); h = tos; push_terms(p1); push_terms(p2); add_terms(tos - h); restore(); } void add_all(int k) { int h, i; U **s; save(); s = stack + tos - k; h = tos; for (i = 0; i < k; i++) push_terms(s[i]); add_terms(tos - h); p1 = pop(); tos -= k; push(p1); restore(); } void subtract(void) { negate(); add(); }