/* derivative */ #include "stdafx.h" #include "defs.h" #define F p3 #define X p4 #define N p5 void eval_derivative(void) { int i, n; // evaluate 1st arg to get function F p1 = cdr(p1); push(car(p1)); eval(); // evaluate 2nd arg and then... // example result of 2nd arg what to do // // d(f) nil guess X, N = nil // d(f,2) 2 guess X, N = 2 // d(f,x) x X = x, N = nil // d(f,x,2) x X = x, N = 2 // d(f,x,y) x X = x, N = y p1 = cdr(p1); push(car(p1)); eval(); p2 = pop(); if (p2 == symbol(NIL)) { guess(); push(symbol(NIL)); } else if (isnum(p2)) { guess(); push(p2); } else { push(p2); p1 = cdr(p1); push(car(p1)); eval(); } N = pop(); X = pop(); F = pop(); while (1) { // N might be a symbol instead of a number if (isnum(N)) { push(N); n = pop_integer(); if (n == (int) 0x80000000) stop("nth derivative: check n"); } else n = 1; push(F); if (n >= 0) { for (i = 0; i < n; i++) { push(X); derivative(); } } else { n = -n; for (i = 0; i < n; i++) { push(X); integral(); } } F = pop(); // if N is nil then arglist is exhausted if (N == symbol(NIL)) break; // otherwise... // N arg1 what to do // // number nil break // number number N = arg1, continue // number symbol X = arg1, N = arg2, continue // // symbol nil X = N, N = nil, continue // symbol number X = N, N = arg1, continue // symbol symbol X = N, N = arg1, continue if (isnum(N)) { p1 = cdr(p1); push(car(p1)); eval(); N = pop(); if (N == symbol(NIL)) break; // arglist exhausted if (isnum(N)) ; // N = arg1 else { X = N; // X = arg1 p1 = cdr(p1); push(car(p1)); eval(); N = pop(); // N = arg2 } } else { X = N; // X = N p1 = cdr(p1); push(car(p1)); eval(); N = pop(); // N = arg1 } } push(F); // final result } void derivative(void) { save(); p2 = pop(); p1 = pop(); if (isnum(p2)) stop("undefined function"); if (istensor(p1)) if (istensor(p2)) d_tensor_tensor(); else d_tensor_scalar(); else if (istensor(p2)) d_scalar_tensor(); else d_scalar_scalar(); restore(); } void d_scalar_scalar(void) { if (issymbol(p2)) d_scalar_scalar_1(); else { // Example: d(sin(cos(x)),cos(x)) // Replace cos(x) <- X, find derivative, then do X <- cos(x) push(p1); // sin(cos(x)) push(p2); // cos(x) push(symbol(SECRETX)); // X subst(); // sin(cos(x)) -> sin(X) push(symbol(SECRETX)); // X derivative(); push(symbol(SECRETX)); // X push(p2); // cos(x) subst(); // cos(X) -> cos(cos(x)) } } void d_scalar_scalar_1(void) { // d(x,x)? if (equal(p1, p2)) { push(one); return; } // d(a,x)? if (!iscons(p1)) { push(zero); return; } if (isadd(p1)) { dsum(); return; } if (car(p1) == symbol(MULTIPLY)) { dproduct(); return; } if (car(p1) == symbol(POWER)) { dpower(); return; } if (car(p1) == symbol(DERIVATIVE)) { dd(); return; } if (car(p1) == symbol(LOG)) { dlog(); return; } if (car(p1) == symbol(SIN)) { dsin(); return; } if (car(p1) == symbol(COS)) { dcos(); return; } if (car(p1) == symbol(TAN)) { dtan(); return; } if (car(p1) == symbol(ARCSIN)) { darcsin(); return; } if (car(p1) == symbol(ARCCOS)) { darccos(); return; } if (car(p1) == symbol(ARCTAN)) { darctan(); return; } if (car(p1) == symbol(SINH)) { dsinh(); return; } if (car(p1) == symbol(COSH)) { dcosh(); return; } if (car(p1) == symbol(TANH)) { dtanh(); return; } if (car(p1) == symbol(ARCSINH)) { darcsinh(); return; } if (car(p1) == symbol(ARCCOSH)) { darccosh(); return; } if (car(p1) == symbol(ARCTANH)) { darctanh(); return; } if (car(p1) == symbol(ABS)) { dabs(); return; } if (car(p1) == symbol(SGN)) { dsgn(); return; } if (car(p1) == symbol(HERMITE)) { dhermite(); return; } if (car(p1) == symbol(ERF)) { derf(); return; } if (car(p1) == symbol(ERFC)) { derfc(); return; } /* if (car(p1) == symbol(BESSELJ)) { if (iszero(caddr(p1))) dbesselj0(); else dbesseljn(); return; } if (car(p1) == symbol(BESSELY)) { if (iszero(caddr(p1))) dbessely0(); else dbesselyn(); return; } */ if (car(p1) == symbol(INTEGRAL) && caddr(p1) == p2) { derivative_of_integral(); return; } dfunction(); } void dsum(void) { int h = tos; p1 = cdr(p1); while (iscons(p1)) { push(car(p1)); push(p2); derivative(); p1 = cdr(p1); } add_all(tos - h); } void dproduct(void) { int i, j, n; n = length(p1) - 1; for (i = 0; i < n; i++) { p3 = cdr(p1); for (j = 0; j < n; j++) { push(car(p3)); if (i == j) { push(p2); derivative(); } p3 = cdr(p3); } multiply_all(n); } add_all(n); } //----------------------------------------------------------------------------- // // v // y = u // // log y = v log u // // 1 dy v du dv // - -- = - -- + (log u) -- // y dx u dx dx // // dy v v du dv // -- = u (- -- + (log u) --) // dx u dx dx // //----------------------------------------------------------------------------- void dpower(void) { push(caddr(p1)); // v/u push(cadr(p1)); divide(); push(cadr(p1)); // du/dx push(p2); derivative(); multiply(); push(cadr(p1)); // log u logarithm(); push(caddr(p1)); // dv/dx push(p2); derivative(); multiply(); add(); push(p1); // u^v multiply(); } void dlog(void) { push(cadr(p1)); push(p2); derivative(); push(cadr(p1)); divide(); } // derivative of derivative // // example: d(d(f(x,y),y),x) // // p1 = d(f(x,y),y) // // p2 = x // // cadr(p1) = f(x,y) // // caddr(p1) = y void dd(void) { // d(f(x,y),x) push(cadr(p1)); push(p2); derivative(); p3 = pop(); if (car(p3) == symbol(DERIVATIVE)) { // sort dx terms push_symbol(DERIVATIVE); push_symbol(DERIVATIVE); push(cadr(p3)); if (lessp(caddr(p3), caddr(p1))) { push(caddr(p3)); list(3); push(caddr(p1)); } else { push(caddr(p1)); list(3); push(caddr(p3)); } list(3); } else { push(p3); push(caddr(p1)); derivative(); } } // derivative of a generic function void dfunction(void) { p3 = cdr(p1); // p3 is the argument list for the function if (p3 == symbol(NIL) || find(p3, p2)) { push_symbol(DERIVATIVE); push(p1); push(p2); list(3); } else push(zero); } void dsin(void) { push(cadr(p1)); push(p2); derivative(); push(cadr(p1)); cosine(); multiply(); } void dcos(void) { push(cadr(p1)); push(p2); derivative(); push(cadr(p1)); sine(); multiply(); negate(); } void dtan(void) { push(cadr(p1)); push(p2); derivative(); push(cadr(p1)); cosine(); push_integer(-2); power(); multiply(); } void darcsin(void) { push(cadr(p1)); push(p2); derivative(); push_integer(1); push(cadr(p1)); push_integer(2); power(); subtract(); push_rational(-1, 2); power(); multiply(); } void darccos(void) { push(cadr(p1)); push(p2); derivative(); push_integer(1); push(cadr(p1)); push_integer(2); power(); subtract(); push_rational(-1, 2); power(); multiply(); negate(); } // Without simplify With simplify // // d(arctan(y/x),x) -y/(x^2*(y^2/x^2+1)) -y/(x^2+y^2) // // d(arctan(y/x),y) 1/(x*(y^2/x^2+1)) x/(x^2+y^2) void darctan(void) { push(cadr(p1)); push(p2); derivative(); push_integer(1); push(cadr(p1)); push_integer(2); power(); add(); inverse(); multiply(); simplify(); } void dsinh(void) { push(cadr(p1)); push(p2); derivative(); push(cadr(p1)); ycosh(); multiply(); } void dcosh(void) { push(cadr(p1)); push(p2); derivative(); push(cadr(p1)); ysinh(); multiply(); } void dtanh(void) { push(cadr(p1)); push(p2); derivative(); push(cadr(p1)); ycosh(); push_integer(-2); power(); multiply(); } void darcsinh(void) { push(cadr(p1)); push(p2); derivative(); push(cadr(p1)); push_integer(2); power(); push_integer(1); add(); push_rational(-1, 2); power(); multiply(); } void darccosh(void) { push(cadr(p1)); push(p2); derivative(); push(cadr(p1)); push_integer(2); power(); push_integer(-1); add(); push_rational(-1, 2); power(); multiply(); } void darctanh(void) { push(cadr(p1)); push(p2); derivative(); push_integer(1); push(cadr(p1)); push_integer(2); power(); subtract(); inverse(); multiply(); } void dabs(void) { push(cadr(p1)); push(p2); derivative(); push(cadr(p1)); sgn(); multiply(); } void dsgn(void) { push(cadr(p1)); push(p2); derivative(); push(cadr(p1)); dirac(); multiply(); push_integer(2); multiply(); } void dhermite(void) { push(cadr(p1)); push(p2); derivative(); push_integer(2); push(caddr(p1)); multiply(); multiply(); push(cadr(p1)); push(caddr(p1)); push_integer(-1); add(); hermite(); multiply(); } void derf(void) { push(cadr(p1)); push_integer(2); power(); push_integer(-1); multiply(); exponential(); push_symbol(PI); push_rational(-1,2); power(); multiply(); push_integer(2); multiply(); push(cadr(p1)); push(p2); derivative(); multiply(); } void derfc(void) { push(cadr(p1)); push_integer(2); power(); push_integer(-1); multiply(); exponential(); push_symbol(PI); push_rational(-1,2); power(); multiply(); push_integer(-2); multiply(); push(cadr(p1)); push(p2); derivative(); multiply(); } /* void dbesselj0(void) { push(cadr(p1)); push(p2); derivative(); push(cadr(p1)); push_integer(1); besselj(); multiply(); push_integer(-1); multiply(); } void dbesseljn(void) { push(cadr(p1)); push(p2); derivative(); push(cadr(p1)); push(caddr(p1)); push_integer(-1); add(); besselj(); push(caddr(p1)); push_integer(-1); multiply(); push(cadr(p1)); divide(); push(cadr(p1)); push(caddr(p1)); besselj(); multiply(); add(); multiply(); } void dbessely0(void) { push(cadr(p1)); push(p2); derivative(); push(cadr(p1)); push_integer(1); besselj(); multiply(); push_integer(-1); multiply(); } void dbesselyn(void) { push(cadr(p1)); push(p2); derivative(); push(cadr(p1)); push(caddr(p1)); push_integer(-1); add(); bessely(); push(caddr(p1)); push_integer(-1); multiply(); push(cadr(p1)); divide(); push(cadr(p1)); push(caddr(p1)); bessely(); multiply(); add(); multiply(); } */ void derivative_of_integral(void) { push(cadr(p1)); } #if SELFTEST static char *s[] = { "x=quote(x)", "", "f=quote(f)", "", "g=quote(g)", "", "d(a,x)", "0", "d(x,x)", "1", "d(x^2,x)", "2*x", "d(log(x),x)", "1/x", "d(exp(x),x)", "exp(x)", "d(a^x,x)", "a^x*log(a)", "d(x^x,x)-(x^x+x^x*log(x))", "0", "d(log(x^2+5),x)-(2*x/(5+x^2))", "0", "d(d(f(x),x),y)", "0", "d(d(f(x),y),x)", "0", "d(d(f(y),x),y)", "0", "d(d(f(y),y),x)", "0", "d((x*y*z,y,x+z),(x,y,z))", "((y*z,x*z,x*y),(0,1,0),(1,0,1))", "d(x+z,(x,y,z))", "(1,0,1)", "d(cos(theta)^2,cos(theta))", "2*cos(theta)", "d(f())", "d(f(),x)", "d(x^2)", "2*x", "d(t^2)", "2*t", "d(t^2 x^2)", "2*t^2*x", // trig functions "d(sin(x),x)-cos(x)", "0", "d(cos(x),x)+sin(x)", "0", "d(tan(x),x)-cos(x)^(-2)", "0", "d(arcsin(x),x)-1/sqrt(1-x^2)", "0", "d(arccos(x),x)+1/sqrt(1-x^2)", "0", "d(arctan(x),x)-1/(1+x^2)", "0", "d(arctan(y/x),x)", "-y/(x^2+y^2)", "d(arctan(y/x),y)", "x/(x^2+y^2)", // hyp functions "d(sinh(x),x)-cosh(x)", "0", "d(cosh(x),x)-sinh(x)", "0", "d(tanh(x),x)-cosh(x)^(-2)", "0", "d(arcsinh(x),x)-1/sqrt(x^2+1)", "0", "d(arccosh(x),x)-1/sqrt(x^2-1)", "0", "d(arctanh(x),x)-1/(1-x^2)", "0", "d(sin(cos(x)),x)+cos(cos(x))*sin(x)", "0", "d(sin(x)^2,x)-2*sin(x)*cos(x)", "0", "d(sin(cos(x)),cos(x))-cos(cos(x))", "0", "d(abs(x),x)", "sgn(x)", "d(sgn(x),x)", "2*dirac(x)", // generic functions "d(f(),x)", "d(f(),x)", "d(f(x),x)", "d(f(x),x)", "d(f(y),x)", "0", "d(g(f(x)),f(x))", "d(g(f(x)),f(x))", "d(g(f(x)),x)", "d(g(f(x)),x)", // other functions "d(erf(x))-2*exp(-x^2)/sqrt(pi)", "0", // arg lists "f=x^5*y^7", "", "d(f)", "5*x^4*y^7", "d(f,x)", "5*x^4*y^7", "d(f,x,0)", "x^5*y^7", "d(f,x,1)", "5*x^4*y^7", "d(f,x,2)", "20*x^3*y^7", "d(f,2)", "20*x^3*y^7", "d(f,2,y)", "140*x^3*y^6", "d(f,x,x,y,y)", "840*x^3*y^5", "f=quote(f)", "", }; void test_derivative(void) { test(__FILE__, s, sizeof s / sizeof (char *)); } #endif