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[maxima/cygwin.git] / tests / rtestsum.mac

kill (all);
done;

(assume_pos_save: assume_pos, assume_pos: true);
true;

/* Verify that we at least get errors when passing the wrong number
 * of arguments to sum and product.
 *
 * The ev tests are significant.  In the 2 and 3 arg cases, we used
 * to get bogus results.  In the case of more than 4 args, the extra
 * args used to be effectively ignored.  (In the 0 and 1 arg cases,
 * we got obscure error messages about assigning to false.  The tests
 * below don't do any checking about *why* we got an error.)
 */

errcatch (sum ());
[];

errcatch (ev (sum ()));
[];

errcatch (sum (f (x)));
[];

errcatch (ev (sum (f (x))));
[];

errcatch (sum (f (x), x));
[];

errcatch (ev (sum (f (x), x)));
[];

errcatch (sum (f (x), x, 0));
[];

errcatch (ev (sum (f (x), x, 0)));
[];

errcatch (sum (f (x), x, 0, 1, 2));
[];

errcatch (ev (sum (f (x), x, 0, 1, 2)));
[];

errcatch (product ());
[];

errcatch (ev (product ()));
[];

errcatch (product (f (x)));
[];

errcatch (ev (product (f (x))));
[];

errcatch (product (f (x), x));
[];

errcatch (ev (product (f (x), x)));
[];

errcatch (product (f (x), x, 1));
[];

errcatch (ev (product (f (x), x, 1)));
[];

errcatch (product (f (x), x, 1, 2, 3));
[];

errcatch (ev (product (f (x), x, 1, 2, 3)));
[];

/* Known failure: concat (q, k) => gensym
 */
sum (concat (q, k), k, a, b);
(b - a + 1) * qk;

/* Known failure: concat (q, k) => gensym
 */
product (concat (q, k), k, a, b);
qk ^ (b - a + 1);

/* Known failure: causes asksign to ask an unanswerable question about index variable;
 * this is a bug in integrate and/or asksign.
(assume (b > 0, a > 0, b > a), sum (integrate (1/x^k, x, a, b), k, 1, n));
integrate (1/x, x, a, b) + sum (integrate (1/x^k, x, a, b), k, 2, n);
 */

/* Known failure: causes asksign to ask an unanswerable question about index variable;
 * this is a bug in integrate and/or asksign.
product (integrate (1/x^k, x, a, b), k, 1, n);
integrate (1/x, x, a, b) * product (integrate (1/x^k, x, a, b), k, 2, n);
 */

block ([prederror: false], sum(if k < 1 then a else b,k,0,n));
'( 'sum(if k < 1 then a else b,k,0,n));

/* see SF bug report # 625278 */

'sum(binomial(2,2-k)-binomial(2,1-k),k,1,2),simpsum;
2;

'sum(binomial(2,2-k)-binomial(2,1-k),k,1,2),sum;
2;

'sum(binomial(x,2-k)-binomial(x,1-k),k,1,2),simpsum;
x;

'sum(binomial(x,2-k)-binomial(x,1-k),k,1,2),sum;
x;

sum (f(k) + 1, k, 1, n), simpsum;
n + 'sum (f(k), k, 1, n);

/* further examples in the same vein: part of summand depends on index, part doesn't. */

sum (sin(g(j)) - %pi^j + cos(h(k)) - %e^l, j, 1, m), simpsum;
m*cos(h(k)) - m*%e^l + sum (sin(g(j)), j, 1, m) - ((%pi^(m + 1) - %pi)/(%pi - 1));

sum (sum (f(j) + g(k), j, 1, m), k, 1, n), simpsum;
m * 'sum (g(k), k, 1, n) + n * 'sum (f(j), j, 1, m);

sum (sum (f(j) + g(k) - %pi^l + 2, j, 1, m), k, 1, n), simpsum;
m * 'sum (g(k), k, 1, n) + n * 'sum (f(j), j, 1, m) - m*n*%pi^l + 2*m*n;

sum (sum (sum (%pi + %phi - 1, i, 1, n_i), j, 1, n_j), k, 1, n_k);
n_i * n_j * n_k * (%pi + %phi - 1);

sum (sum (sum (f(%pi, i) + g(%phi, j) - h(k), i, 1, n_i), j, 1, n_j), k, 1, n_k);
'sum ('sum ('sum (f(%pi, i) + g(%phi, j) - h(k), i, 1, n_i), j, 1, n_j), k, 1, n_k);

/* see SF bug report # 649428 */

(factsum3 (mt, ej) := sum ((-1)^(k + 1)/(k*mt^k)*sum((1 - l)^k - l^k, l, 1, ej),k,1,inf), t% : taylor (factsum3 (mt, ej), [mt, 0, 3, asymp])); 
'sum(1-2*l,l,1,ej)/mt-('sum(1-2*l,l,1,ej)/(2*mt^2))+'sum(-2*l^3+3*l^2-3*l+1,l,1,ej)/(3*mt^3);

%, simpsum, ratsimp;
-((6*ej^2*mt^2-3*ej^2*mt+ej^4+ej^2)/(6*mt^3));

/* Known failure: interaction of taylor and simpsum
 */
taylor (factsum3 (mt, ej), [mt, 0, 3, asymp]), simpsum;
-(6*ej^2*mt^2-3*ej^2*mt+ej^4+ej^2)/(6*mt^3);

/* see SF bug report # 740134 */

(foo: i^2, [sum ('foo, i, 0, 2), sum (foo, i, 0, 2), sum (foo, i, 0, n)]);
[3*foo, 5, 'sum (i^2, i, 0, n)];

/* summand is a function which has a side effect --
 * outcome here differs from recommendation by Stavros in 740134
 */
block ([L:[]], f(i) := (L: append (L, [i]), i), S: sum (f (i), i, 1, 3), [S, L]);
[6, [1, 2, 3]];

sum (integrate (x^i ,x), i, 0, 2);
x^3/3 + x^2/2 + x;

sum (integrate (1/(x^i + 1), x), i, 0, 1);
log(x+1) + x/2;

(f[i](x) := x^i, g[i](x) := x^i, h[i](x) := x^i, 0);
0;

(f[i], g[i](t), 0);
0;

sum (f[i](x), i, 0, n);
'sum (x^i, i, 0, n);

sum (g[i](x), i, 0, n);
'sum (x^i, i, 0, n);

sum (h[i](x), i, 0, n);
'sum (x^i, i, 0, n);

/* see SF bug report # 817521 */

(kill (foo), foo (n):= block([aaa,m], modedeclare([m,n], fixnum), m:n, [ aaa[1], aaa[n], aaa[m], aaa[1]+aaa[2], sum(aaa[i],i,1,m) ] ), foo (2));
[aaa[1],aaa[2],aaa[2],aaa[2]+aaa[1], aaa[2]+aaa[1]];

(translate(foo), 0);
0;

foo (2);
[aaa[1],aaa[2],aaa[2],aaa[2]+aaa[1], aaa[2]+aaa[1]];

/* see SF bug report # 851765 */

(apply (forget, facts ()), assume (i >= a), sum (i, i, a, b), facts ());
[i >= a];

is (i >= a);
true;

(assume (i < 0), sum (abs (i), i, 1, a));
'sum (i, i, 1, a);

(apply (forget, facts ()), 0);
0;

/* see SF bug report # 1007094 */

(u: 'sum((-1/(8*i+6)-1/(8*i+5)-2/(8*i+4)+4/ (8*i+1))/16^i,i,1,a), 0);
0;

u, a=2, simpsum;
1618091/196035840;

%, numer;
0.0082540570132481894$ 

u, a=2, simpsum, numer;
0.0082540570132481911$ 

u, a=2, simpsum, bfloat;
8.25405701324819B-3;

/* see SF bug report # 1192935 */

(f(x) := x^2, b: 1/10, Ak: b*f(k*b), sum (Ak, k, 0, 9));
57/200;

/* When A(k) is defined as A(k) := b*f(k*b) instead of define(A(k), b*f(k*b)),
 * A(k) evaluates to k^2/n^3 even if n is bound to something;
 * this is a consequence of Maxima's evaluation policies:
 * rhs of := is not evaluated, and variables (b in this case)
 * are evaluated just once.
 */
(b:1/n, define (A(k), b*f(k*b)), A(k));
k^2/n^3;

sum (A(k), k, 0, n-1);
('sum (k^2, k, 0, n-1))/n^3;

sum (A(k), k, 0, n-1), simpsum;
(n+2*(n-1)^3+3*(n-1)^2-1)/(6*n^3);

[''%, sum (A(k), k, 0, n-1)], n=10;
[57/200, 57/200];

(B(k) := k*f(k*b), B(k));
k^3/n^2;

sum (B(k), k, 0, n-1), simpsum;
((n-1)^4 + 2*(n-1)^3 + (n-1)^2) / (4*n^2);

/* see SF bug report # 1363411 */

(kill (f), 'sum(1+f(k),k,1,2)), simpsum;
2 + f(1) + f(2);

is(equal(block([gcd:subres], ratsimp((-x^3+1)/(2*x^5+2) + (-sqrt(5)+5)/(20*x^2+(-10*sqrt(5)-10)*x+20))),
         block([gcd:spmod],  ratsimp((-x^3+1)/(2*x^5+2) + (-sqrt(5)+5)/(20*x^2+(-10*sqrt(5)-10)*x+20)))));
true;

/* General tests from here on */

sum (x, x, p, p + 2);
p + (p + 1) + (p + 2);

product (x, x, p, p + 2);
p * (p + 1) * (p + 2);

sum (x, x, %i, %i + 2);
%i + (%i + 1) + (%i + 2);

product (x, x, %i, %i + 2);
%i * (%i + 1) * (%i + 2);

sum (imagpart (1 + %i*k), k, 1, n), simpsum;
(n^2 + n)/2;

product (imagpart (1 + %i*k), k, 1, n), simpproduct;
n!;

(g(x) := q(x^2), sum (g(k), k, 1, n));
'sum (q (k^2), k, 1, n);

(g(x) := q(x^2), product (g(k), k, 1, n));
'product (q (k^2), k, 1, n);

sum (integrate (x^k, x, 0, 1), k, 1, n);
'sum (1/(k + 1), k, 1, n);

product (integrate (x^k, x, 0, 1), k, 1, n);
'product (1/(k + 1), k, 1, n);

(kill(b), sum ('concat (q, k), k, a, b));
'sum ('concat (q, k), k, a, b);

sum ('concat (q, k), k, a, b), nouns, a=1, b=5;
q5 + q4 + q3 + q2 + q1;

product ('concat (q, k), k, a, b);
'product ('concat (q, k), k, a, b);

product ('concat (q, k), k, a, b), nouns, a=1, b=5;
q5 * q4 * q3 * q2 * q1;

(assume (n>= 1), sum (if k <= n then a else b, k, 1, n));
a * n$

product (if k <= n then a else b, k, 1, n);
a ^ n$

sum (sin (%pi * k), k, 0, nn);
0$

product (cos (2 * %pi * k), k, 0, nn);
1$

sum (lambda ([x], x^i), i, 1, 3);
lambda ([x], x) + lambda ([x], x^2) + lambda ([x], x^3);

sum (k: k^2, k, 1, 3);
14;

sum (a, k, inf, minf);
0;

(assume (i < 0, j < 0, n > 0), sum(sum(abs(i) + abs(j),i,1,j),j,1,n));
'sum ('sum (i + j, i, 1, j), j, 1, n);

sum (sum (sqrt (i + j), i, 1, j), j, 1, n), simpsum;
'sum ('sum (sqrt (i + j), i, 1, j), j, 1, n);

sum (1/k, k, rat(1), rat(n));
'sum (1/k, k, 1, n);

sum (taylor (x^i, x, 0, 5), i, 0, 5);
''(taylor (x^5 + x^4 + x^3 + x^2 + x + 1,x,0,5));

(i: 888, sum (lambda ([i], i^2), i, 1, 3));
3 * lambda ([i], i^2);

sum (lambda ([i], i^2), i, 1, n);
n * lambda ([i], i^2);

(f(x) := sum (x, i, 1, 3), f(-x));
-3*x;

(ak : k^2,  g(a,n) := sum(a,k,1,n), g(ak, 5));
55;

(translate (g), g(ak,5));
55;

sum (integrate (x^i, x), i, 0, n);
'sum (x^(i+1) / (i+1), i, 0, n);

(assume (k < 0), assume (0 < n, m > n), sum (sqrt (k^2), k, n, m));
'sum (k, k, n, m);

(assume (i >= n_1, i <= n_2), sum (z(i), i, n_1, n_2));
'sum (z(i), i, n_1, n_2);

block ([prederror: false], [is (i >= n_1), is (i <= n_2)]);
[true, true];

/* some examples adapted from describe("sum") */

(old_facts: facts (), foo: 42, bar: 12 + exp(7), baz: 1/quux, 0);
0;

sum (foo^2, foo, 1, 7);
140;

sum (aa[bar], bar, 1, 7);
aa[7] + aa[6] + aa[5] + aa[4] + aa[3] + aa[2] + aa[1];

sum (aa(baz), baz, 1, 7);
aa(7) + aa(6) + aa(5) + aa(4) + aa(3) + aa(2) + aa(1);

sum (aa(foo), foo, 1, n);
'sum (aa(foo), foo, 1, n);

sum (2^bar + bar^2, bar, 0, n), simpsum;
2^(n + 1) + (2*n^3 + 3*n^2 + n)/6 - 1;

sum (1/3^baz, baz, 1, inf), simpsum;
1/2;

sum (foo^2, foo, 1, 4) * sum (1/foo^2, foo, 1, inf), simpsum;
5*%pi^2;

(gg(bar) := 1/bar^2, sum (gg(bar)^2, bar, 1, inf));
sum (1/bar^4, bar, 1, inf);

sum (gg(baz)^2, baz, 1, inf), simpsum;
%pi^4/90;

[is (foo = 42), is (bar = 12 + exp(7)), is (baz = 1/quux)];
[true, true, true];

(new_facts: facts(), is (sort (old_facts) = sort (new_facts)));
true;

/* redo all of the tests, this time with product */

product (lambda ([x], x^i), i, 1, 3);
lambda ([x], x) * lambda ([x], x^2) * lambda ([x], x^3);

product (k: k^2, k, 1, 3);
36;

product (a, k, inf, minf);
1;

(assume (i < 0, j < 0, n > 0), product(product(abs(i) + abs(j),i,1,j),j,1,n));
'product ('product (i + j, i, 1, j), j, 1, n);

product (1/k, k, rat(1), rat(n));
'product (1/k, k, 1, n);

product (taylor (x^i, x, 0, 5), i, 0, 5);
''(taylor (x^15,x,0,15));

(i: 888, product (lambda ([i], i^2), i, 1, 3));
(lambda ([i], i^2))^3;

product (lambda ([i], i^2), i, 1, n);
lambda([i],i^2)^n;

(f(x) := product (x, i, 1, 3), f(-x));
-x^3;

(f(x) := x^2, b: 1/10, Ak: b*f(k*b), product (Ak, k, 1, 9));
(9!)^2/1000^9;

(A(k) := k*f(k*b), b:1/n, A(k));
k^3/n^2;

product (A(k), k, 0, n-1);
('product (k^3/n^2, k, 0, n-1));

(assume (n > 0, m > n), ev (product (k, k, n, m), simpproduct));
m!/(n - 1)!;

(ak : k^2,  g(a,n) := product(a,k,1,n), g(ak, 5));
(5!)^2;

(translate (g), g(ak,5));
(5!)^2;

/* multiplicand is a function which has a side effect */

block ([L:[]], f(i) := (L: append (L, [i]), i), S: product (f (i), i, 1, 3), [S, L]);
[6, [1, 2, 3]];

product (integrate (x^i ,x), i, 0, 2);
x^3/3 * x^2/2 * x;

product (integrate (1/(x^i + 1), x), i, 0, 1);
log(x+1) * x/2;

(f[i](x) := x^i, g[i](x) := x^i, h[i](x) := x^i, 0);
0;

/* reference f[i] and g[i] -- see 740134 for the effect this has on previous defn of sum */

(f[i], g[i](t), 0);
0;

product (f[i](x), i, 0, n);
'product (x^i, i, 0, n);

product (g[i](x), i, 0, n);
'product (x^i, i, 0, n);

product (h[i](x), i, 0, n);
'product (x^i, i, 0, n);

product (integrate (x^i, x), i, 0, n);
'product (x^(i+1) / (i+1), i, 0, n);

(assume (k < 0), assume (0 < n, m > n), ev (product (sqrt (k^2), k, n, m), simpproduct));
m!/(n - 1)!;

(assume (i >= n_1, i <= n_2), product (z(i), i, n_1, n_2));
'product (z(i), i, n_1, n_2);

block ([prederror: false], [is (i >= n_1), is (i <= n_2)]);
[true, true];

/* some examples adapted from describe("sum") */

(old_facts: facts (), foo: 42, bar: 12 + exp(7), baz: 1/quux, 0);
0;

product (foo^2, foo, 1, 7);
(7!)^2;

product (aa[bar], bar, 1, 7);
aa[7] * aa[6] * aa[5] * aa[4] * aa[3] * aa[2] * aa[1];

product (aa(baz), baz, 1, 7);
aa(7) * aa(6) * aa(5) * aa(4) * aa(3) * aa(2) * aa(1);

product (aa(foo), foo, 1, n);
product (aa(foo), foo, 1, n);

product (2^bar + bar^2, bar, 0, n), simpsum;
product (2^bar + bar^2, bar, 0, n);

product (1/3^baz, baz, 1, inf), simpsum;
product (1/3^baz, baz, 1, inf);

product (foo^2, foo, 1, 4) * product (1/foo^2, foo, 1, inf), simpsum;
(4!)^2 * 'product (1/'foo^2, 'foo, 1, inf);

(gg(bar) := 1/bar^2, product (gg(bar)^2, bar, 1, inf));
'product (1/'bar^4, 'bar, 1, inf);

product (gg(baz)^2, baz, 1, inf), simpsum;
'product (1/'baz^4, 'baz, 1, inf);

[is (foo = 42), is (bar = 12 + exp(7)), is (baz = 1/quux)];
[true, true, true];

(new_facts: facts(), is (sort (old_facts) = sort (new_facts)));
true;

/*---- new tests from bw ------*/

sum(0,i,a,b);
0$

sum(0,i,minf,inf);
0$

sum(0,i,42,inf);
0$

sum(sqrt(3),i,0,inf);
inf$

sum(sqrt(3),i,-1932,inf);
inf$

sum(5,i,minf, inf);
inf$

sum(-sqrt(3),i,0,inf);
minf$

sum(sqrt(3),i,1,3);
3 * sqrt(3)$

sum(sqrt(3),i,-1,1);
3 * sqrt(3)$

sum(p(i + 1) - p(i),i,1,5);
p(6) - p(1)$

product(1,i,a,b);
1$

product(1,i,minf,inf);
1$

product(1,i,-42,inf);
1$

product(%pi,i,1,3);
%pi^3$

product(%pi,i,-1,1);
%pi^3$

product(%pi,i,0,inf);
inf$

product(%pi - 3,i,0,inf);
0$

product(%pi - 3,i,minf,inf);
0$

product(-%pi,i,0,inf);
infinity$

product(0,i,0,n);
0$

product(-%pi,i,minf,inf);
infinity$

product((1 + %i)/sqrt(2),k,1,inf);
und$

product(-1,k,1,inf);
und$

product(a,i,0,inf);
'product(a,i,0,inf);

product(p(i + 1) / p(i),i,1,5);
p(6) / p(1)$

sum(lambda([x],x^i),i,1,3);
lambda([x],x) + lambda([x],x^2) + lambda([x],x^3);

product(lambda([x],x^i),i,1,3);
lambda([x],x) * lambda([x],x^2) * lambda([x],x^3);

sum([1,k],k,1,5);
[5,15];

sum([1,k],k,1,n),simpsum;
[n, (n^2 + n)/2];

(old_facts : facts(),0);
0$

errcatch(sum(1/k,k,-1,1));
[];

(new_facts: facts(), is (sort (old_facts) = sort (new_facts)));
true;

(old_facts : facts(),0);
0$

errcatch(product(1/k,k,-1,1));
[];

(new_facts: facts(), is (sort (old_facts) = sort (new_facts)));
true;

sum(diff(log(x),x,k),k,1,2);
1/x - 1/x^2$

product(diff(log(x),x,k),k,1,2);
-1/x^3;

sum(x^k * at(diff(sin(x),x,k)/k!,x=0),k,0,5) - taylor(sin(x),x,0,5);
''(taylor(0,x,0,5));

product(%i-x,k,1,inf);
'product(%i-x,k,1,inf);

sum(%i,k,0,-1);
0$

sum(%i,k,inf,minf);
0$

sum(%i,k, 0, minf);
0$

product(%i,k,0,-1);
1$

product(%i,k,inf,minf);
1$

product(%i,k, 0, minf);
1$

sum(p,p,p,p);
p$

product(p,p,p,p);
p$

sum(k,k,p,p+1);
2*p+1$

sum(k,k,p,p-1);
0$

sum(k,k,%i,%i+1);
2*%i + 1$

product(k,k,%i,%i+1);
%i * (%i + 1)$

product(k,k,p,p+1);
p*(p+1)$

product(k,k,p,p-1);
1$

sum(k,k,1,entier(4/3));
1$

sum(k,k,entier(4/3),1);
1$

sum(a,k,entier(4/3),entier(5/2));
2*a$

product(k,k,1,entier(4/3));
1$

product(k,k,entier(4/3),1);
1$

product(a,k,entier(4/3),entier(5/2));
a^2$

sum(q(k),k,n^2 + 1,-n^2 - 1); /* It's an empty sum */
0$

product(q(k),k,n^2 + 1,-n^2 - 1);
1$

sum(concat(q,k),k,1,3);
q1 + q2 + q3$

(s : sum('concat(q,k),k,1,n),0);
0$

(s : subst(n=3,s), ev(s,nouns));
q1 + q2 + q3$

sum(product(concat(q,i),i,1,j),j,1,3);
q1 + q1 * q2 + q1 * q2 * q3$

product(concat(q,k),k,1,3);
q1 * q2 * q3$

(s : product('concat(q,k),k,1,n),0);
0$

(s : subst(n=3,s), ev(s,nouns));
q1 * q2 * q3$

(a : k^2,0);
0$

sum(realpart(a + %i * k),k,1,3);
14$

(assume(k < 0),0);
0$

sum(sum(abs(k),k,1,n),n,1,m);
sum(sum(k,k,1,n),n,1,m)$

sum(sum(k,k,1,i),i,1,n),simpsum,ratsimp;
''(ratsimp(n^3/6+n^2/2+n/3))$

sum(sum(abs(k),k,1,n) + sum(abs(k),k,1,n),n,1,m);
2 * sum(sum(k,k,1,n),n,1,m)$

(forget(k < 0),0);
0$

(remvalue(a,b),0);
0$

sum(if k < 1 then a else b,k,0,2);
a + 2*b$

block ([prederror : true], sum(if k < 1 then a else b,k,0,2));
a + 2*b$

sum(1/3^k,k,1,inf),simpsum;
1/2$

sum(3^-i,i,1,inf),simpsum;
1/2$

(kill(x), assume(abs(x)-1 < 0));
[abs(x) < 1];

sum(x^k,k,0,inf),simpsum;
1/(1-x)$

(forget(abs(x) - 1 < 0),0);
0$

/*--- A few challenging sums ----*/

(assume (n >= 1), sum (if k <= n then a else b, k, 1, n));
a * n$

(declare(nn,integer), sum(sin(%pi * k),k,0,nn));
0$

sum(sin(x),x,1/2,1/2 + nn);
'sum(sin(x),x,1/2,1/2 + nn);

remove (nn, integer);
done;

(assume_pos: assume_pos_save, apply (forget, facts ()), 0);
0;

nusum ((n - 1)*(n - 1)!, n, 1, n);
n! - 1;

nusum (n!, n, 1, n);
'sum (n!, n, 1, n);

nusum ((2*m)!/(m!*(m + 1)!), m, 0, n);
'sum ((2*m)!/(m!*(m + 1)!), m, 0, n);


/*--- A test for sumcontract ---*/

sumcontract(sum(k,k,1,n) + sum(k^2, k, 1, n));
sum(k^2+k,k,1,n);

/* Bug ID: 2770575 - rtestsum test 226
 * This test simplifies correctly after revision 1.12 of sumcon.lisp.
 */
sumcontract(sum(k, k, 1, n) + sum(k, k, 1, n+1));
n+2*sum(k,k,1,n)+1;

/* Tests for bug report [ 1497706 ] sum(1/k^2,k,2,inf), simpsum; */

/* sum (1/k^2, ...) not simplified unless specifically requested */
(sum (1/k^2, k, 1, inf), [op (%%), args (%%)]);
[''(nounify (sum)), [1/k^2, k, 1, inf]];

sum (1/k^2, k, 1, inf), simpsum;
%pi^2/6;

/* this is the case cited in the bug report */
sum (1/k^2, k, 2, inf), simpsum;
%pi^2/6 - 1;

sum (1/k^2, k, 1, 9);
9778141/6350400;

sum (1/k^2, k, 10, inf), simpsum;
%pi^2/6 - 9778141/6350400;

sum (1/k^4, k, 1, 5);
14001361/12960000;

sum (1/k^4, k, 6, inf), simpsum;
%pi^4/90 - 14001361/12960000;

sum (1/k^7, k, 1, inf), simpsum;
zeta (7);

sum (1/k^7, k, 1, 3);
282251/279936;

sum (1/k^7, k, 4, inf), simpsum;
zeta (7) - 282251/279936;

/* Tests for bug report [ 1550985 ] niceindices
 * Test the cases mentioned in the bug report & some others for good measure
 */

(reset (niceindicespref), 0);
0;

niceindices (sum (1/kk, kk, 1, n) - sum (1/ii, ii, 1, n));
0;

niceindices (sum (1/k, k, 1, n) - sum(1/i, i, 1, n));
0;

niceindices (sum (F(foo), foo, 1, inf));
'sum (F(i), i, 1, inf);

(niceindicespref : '[foo, bar, baz, quux], 0);
0;

niceindices (sum (1/kk, kk, 1, n) - sum (1/ii, ii, 1, n));
0;

niceindices (sum (1/k, k, 1, n) - sum(1/i, i, 1, n));
0;

niceindices (sum (F(foo), foo, 1, inf));
'sum (F(foo), foo, 1, inf);

niceindices (product (sum (product (sum (product (m*F(i) + cos(G(j))^k/sin(l), m, 1, n5), l, 1, n4), k, 1, n3), j, 1, n2), i, 1, n1));
'product ('sum ('product ('sum ('product (foo*F(foo0) + cos(G(quux))^baz/sin(bar), foo, 1, n5), bar, 1, n4), baz, 1, n3), quux, 1, n2), foo0, 1, n1);

niceindices (sum (sum (foo/foo0, foo, 1, n), foo0, 1, m));
('sum (1/foo, foo, 1, m)) * 'sum (foo, foo, 1, n);

niceindices (sum (sum (1/(foo + foo0), foo, 1, n), foo0, 1, m));
'sum ('sum (1/(foo + bar), foo, 1, n), bar, 1, m);

(reset (niceindicespref), 0);
0;

/* Tests for bashindices, which used to not transform all indices in nested
 * sums and products (only the outermost)
 */

(reset (gensumnum), 0);
0;

bashindices (sum (product (sum (F (l, m, n), l, 0, m), m, 0, n), n, 0, N));
'sum ('product ('sum (F (j1, j2, j3), j1, 0, j2), j2, 0, j3), j3, 0, N);

(reset (gensumnum), 0);
0;

/* Test for bug report [ 1552710 ] product(sum(f(i),i,1,inf),j,1,inf) => inf (wrong) */

/* Since sum(f(i), i, 1, inf) is free of j, another result
 * such as limit(sum(f(i), i, 1, inf)^n, n, inf) would be OK, too.
 * In any event, inf (observed in the bug report) is not OK.
 */
(kill(f), block ([x : product (sum (f(i), i, 1, inf), j, 1, inf)], block ([simp : false], is (x = 'product ('sum (f(i), i, 1, inf), j, 1, inf)))));

true;

/* Test for bug reported by Amit Aronovitch to mailing list 2006/01/06
 */

(kill(f), f(x) := sum (x^n/n!, n, 0, inf), f(2*x));
'sum (2^n*x^n/n!, n, 0, inf);


/* Test for intosum */

intosum(2*sum(k,k,1,inf));
sum(2*k,k,1,inf);

/* correct a bug in SUBST-IF-NOT-FREEOF (src/asum.lisp):
 * array flag in CAR was lost before, but it's OK now
 */
(kill (a, i), x : a[i], sum (x, i, 1, 3));
a[1] + a[2] + a[3];

/* Restore treatment of definite summations as it was before summation
 * revisions of December 2005: simplify definite summation to explicit
 * sum only if simpsum is true.
 */

(kill (f), sum (f(i), i, 1, 3));
f(1) + f(2) + f(3);

'sum (f(i), i, 1, 3);
'sum (f(i), i, 1, 3);

'sum (f(i), i, 1, 3), simpsum;
f(1) + f(2) + f(3);

/* (analogous tests for product) */

product (f(i), i, 1, 3);
f(1)*f(2)*f(3);

'product (f(i), i, 1, 3);
'product (f(i), i, 1, 3);

'product (f(i), i, 1, 3), simpproduct;
f(1)*f(2)*f(3);

/* Differentiate wrt a subscripted symbol in a summation.
 * Should work the same as for an ordinary symbol.
 */
(kill (x, a, a1), 0);
0;

diff ('sum (sin (a1 * x[i]), i, 1, n), a1);
'sum (x[i] * cos (a1 * x[i]), i, 1, n);

diff ('sum (x[i]^a1, i, 1, n), a1);
'sum (x[i]^a1 * log(x[i]), i, 1, n);

diff ('sum (sin (a[1] * x[i]), i, 1, n), a[1]);
'sum (x[i] * cos (a[1] * x[i]), i, 1, n);

diff ('sum (x[i]^a[1], i, 1, n), a[1]);
'sum (x[i]^a[1] * log(x[i]), i, 1, n);

/* Feature request 1848704: no way to convert log(product(...)) to sum(log(...)...)
 */

(kill (u, a, x, T), 0);
0;

log (product (u[k], k, 1, n));
log (product (u[k], k, 1, n));

log (product (u[k], k, 1, n)), logexpand=true;
log (product (u[k], k, 1, n));

log (product (u[k], k, 1, n)), logexpand=all;sum (log (u[k]), k, 1, n);

log (product (u[k], k, 1, n)), logexpand=super;
sum (log (u[k]), k, 1, n);

log (product (a*%e^x(i), i, 1, T));
log (product (a*%e^x(i), i, 1, T));

log (product (a*%e^x(i), i, 1, T)), logexpand=all;
/* Yields sum(const + ...) instead of const*T + sum(...)
 * since sum is not known to be linear by default.
 * Change this result if default ever changes.
 */
sum (log(a) + x(i), i, 1, T);

/* bug reported to mailing list 2008-04-17:
 * simpsum causes two evaluations of summand, should be only one
 */
(bar (x, y) := sum (F (i, x, y), i, 1, n),
 ev (bar (y, x), simpsum=false));
'sum (F (i, y, x), i, 1, n);

ev (bar (y, x), simpsum=true);
'sum (F (i, y, x), i, 1, n);

/* original problem */

(kill (all),
 geom(x,m,n):= (x^m-x^(n+1))/(1-x),
 B(s,sp):=-phi[1](s)*phi[1](s+sp)*phi[0](s+sp)/(1-phi[1](s+sp)*phi[0](s +sp))
 +(1-phi[1](s))*sum((phi[1](s)*phi[0](s))^n*(
     geom( (phi[0](s+sp)*phi[1](s+sp))/(phi[0](s)*phi[1](s)), 1, n-1 )
     -phi[1](s+sp)/phi[1](s)
     *geom((phi[0](s+sp)*phi[1](s+sp))/(phi[0](s)*phi[1](s)), 0, n-1))
   , n , 1, inf ),
 A(s):=phi[1](s)*(1+phi[0](s))/(1-phi[1](s)*phi[0](s)),
 C(s,sp):=A(s+sp)+B(s,sp)+B(sp,s),
 0);
0;

(expr_1 : ev (C (s, sp), simpsum=false),
 expr_2 : ev (C (s, sp), simpsum=true),
 is (expr_1 = expr_2));
true;

(expr_1 : ev (C (sp, s), simpsum=false),
 expr_2 : ev (C (sp, s), simpsum=true),
 is (expr_1 = expr_2));
true;

is (sublis ([s=sp, sp=s], C (s, sp)) = C (s, sp)), simpsum;
true;

is (sublis ([s=sp, sp=s], C (sp, s)) = C (sp, s)), simpsum;
true;

is (C (sp, s) = C (s, sp)), simpsum;
true;

/* Tests for fbino in combin.lisp */
sum(binomial(2*n-k,k), k, 0, n), simpsum;
fib(2*n+1);

sum(binomial(n-k,k), k, 1, n), simpsum;
fib(n+1)-1;

(assume(n>1), 0);
0;

sum(binomial(n-k,k+1), k, 1, n-1), simpsum;
fib(n+2)-n-1;

sum(binomial(2*n,2*k), k, 0, n), simpsum;
2^(2*n-1);

sum(binomial(n,2*k+1), k, 0, n), simpsum;
2^(n-1);

sum(binomial(n,2*k), k, 0, n), simpsum;
2^(n-1);

sum(binomial(n,2*k), k, 1, n), simpsum;
2^(n-1)-1;

sum(binomial(n+1,k), k, 1, n), simpsum;
2^(n+1)-2;

sum(binomial(n,k), k, -1, n+1), simpsum;
2^n;

sum(binomial(t+i,t),i,0,k), simpsum;
binomial(t+k+1,t+1);

/* Because of revision 1.43 of csimp2.lisp binomial(x,x) no longer simplifies
 * automatically to 1. The sign must be known not be negative. 
 * Therefore, we add a fact about the sign of t.
 */ 
(assume(t>0),done);
done;
sum(binomial(t+i,t),i,1,k), simpsum;
binomial(t+k+1,t+1)-1;
(forget(t>0),done);
done;

sum(binomial(t+i,i),i,0,k), simpsum;
binomial(t+k+1,t+1);

(forget(n>1), 0);
0;

/* bug in assume database causes trouble for conditional in summation
 * see mailing list 2009-07-29 "Fourier Series using fourie.mac"
 */

/* If ever the assume stuff is revised, this next test can go away.
 * It's here to ensure the underlying problem is fixed.
 */
?dcomp (1, 1.0);
zero;

(kill (all), assume (xx >= 1), 0);
0;

is (xx > 1);
unknown;

if xx > 1 then aa else bb;
if xx > 1 then aa else bb;

sum (if xx > 1 then aa else bb, xx, 1, 3);
2*aa + bb;

foo : 'sum (if xx > 1 then aa else bb, xx, 1, 3);
'sum (if xx > 1 then aa else bb, xx, 1, 3);

ev (foo, nouns);
2*aa + bb;

foo : sum (if equal (xx, 1) then aa else bb, xx, 1, nn);
'sum (if equal (xx, 1) then aa else bb, xx, 1, nn);

ev (foo, nouns, nn=3);
aa + 2*bb;

(reset(assume_pos),1);
1;

/* SF bug #3605: "Variable confusion in function handling Taylor series" */

kill(x, y);
done;

/* function definition copied verbatim from bug report */

(test(f) := block([i:taylorinfo(f)[1]], sum(coeff(f, i[1], x) * i[1]^x, x, 0, i[3])), 0);
0;

ratdisrep (test(taylor(cos(y), y, 0, 4)));
(y^4-12*y^2+24)/24;

ratdisrep (test(taylor(cos(x), x, 0, 4)));
29/3;

/* declare summation index with different name in block to distinguish from global */
(test1(f) := block([i:taylorinfo(f)[1], x%], sum(coeff(f, i[1], x%) * i[1]^x%, x%, 0, i[3])), 0);
0;

ratdisrep (test1(taylor(cos(y), y, 0, 4)));
(y^4-12*y^2+24)/24;

ratdisrep (test1(taylor(cos(x), x, 0, 4)));
(x^4-12*x^2+24)/24;

/* Bug #2267: simpsum error */

sum((2^(k+i))/(2^(k+i)+2^(i)),i,0,k), simpsum;
(2^k*(1 + k))/(1 + 2^k);