Maple Questions and Posts

Solving Diaphantine quadratics in two variables

by: dharr 8602 Product: Maple

1 hour ago

1 0

Maple's isolve can solve some but not all of the quadratic equations in two variables describing the conic sections. Here I show that by transforming the equations, Maple can then solve these missing cases.

>

I was recently surprised that isolve cannot solve the following simple Diophantine equation

>

which has the obvious (to a human) solution . This led me to think about the case of conic sections, which have the following general equation (= 0 implied), where I assume are integers.

>

The above equation has discriminant positive, indicating that is is a hyperbola.

>	$h_params := {a = 2, b = 4, c = 1, d = 0, e = 0, f = -7}; P__h := eval(P, h_params); disc := -4ac+b^2; eval(disc, h_params); plot__h := implicitplot(P__h, x = -10 .. 10, y = -10 .. 10, colour = red)$

Here's a parabola case (discriminant = 0) that isolve also has trouble with

>	$p_params := {a = 2, b = 4, c = 2, d = 1, e = 2, f = 7}; eval(disc, p_params); P__p := eval(P, p_params); {isolve(P__p)}; plot__h := implicitplot(P__p, x = -10 .. 10, y = -10 .. 10, colour = red)$

But this has at least one solution

>	$eval(P__p, {x = 7, y = -7})$

Maple seems to do better in the elliptic case (discriminant negative) and finds two solutions. Examination of the plot suggests there are no other solutions.

>	$e_params := {a = 2, b = 4, c = 3, d = 1, e = 2, f = -7}; eval(disc, e_params); P__e := eval(P, e_params); {isolve(P__e)}; plot__e := implicitplot(P__e, x = -10 .. 10, y = -10 .. 10, colour = red)$

I show that transformation of the general equation to the form , where D is the discriminant, allows Maple to solve the hyperbolic case, as well as the elliptic case it already knows how to solve; another transformation works for the parabolic case. Maple appears to be able to solve all (solvable) cases of the transformed equations, though this is not clear from the help page. The transformation is discussed in Bogdan Grechuk, Polynomial Diophantine Equations: A Systematic Approach, Springer, 2024, Sec. 3.1.7. doi: 10.1007/978-3-031-62949-5

A complete classification of the conics, including degenerate cases, is given in https://en.wikipedia.org/wiki/Matrix_representation_of_conic_sections. If the determinant, , of the following matrix is zero, we have a degenerate case.

>

A__Q := Matrix(3, 3, [a, (1/2)*b, (1/2)*d, (1/2)*b, c, (1/2)*e, (1/2)*d, (1/2)*e, f]); delta := LinearAlgebra:-Determinant(A__Q)

The case of is just the linear case, which Maple can solve, and is one case where . Other degenerate parabola cases are two coincident lines or two parallel lines. Degenerate hyperbolas are two intersecting lines, and degenerate ellipses are a single point. Maple can solve all these cases, e.g.,

>	$expand((2x+3y+1)(2x+3y)); {isolve(%)}; expand((2x+3y)(2x+3y)); {isolve(%)}; expand((x-2)*(y-3)); {isolve(%)}; x^2+y^2 = 0; {isolve(%)}$

${{x = -3*_Z1, y = 2*_Z1}, {x = -2-3*_Z1, y = 1+2*_Z1}}$

${{x = -3*_Z1, y = 2*_Z1}}$

${{x = _Z1, y = 3}}$

(The intersecting lines case above only finds one of the lines.) The transformation will consider only the case where at least one of or is non-zero. This misses hyperbolas with ; Maple seems to handle these bilinear equations, e.g.,

>	$bl_params := {a = 0, b = 2, c = 0, d = 1, e = 1, f = 2}; P__bl := eval(P, bl_params); {isolve(P__bl)}$

Transformation for non-zero discriminant
At least one of or must be non-zero; if necessary exchange and to ensure is non-zero.

We multiply by and change to new variables and .

>	$itr := {X = (-4ac+b^2)y+bd-2ae, Y = 2ax+b*y+d}; tr := solve(itr, {x, y})$

${X = (-4*a*c+b^2)*y+b*d-2*a*e, Y = 2*a*x+b*y+d}$

${x = (1/2)*(4*Y*a*c-Y*b^2+2*a*b*e-4*a*c*d+X*b)/((4*a*c-b^2)*a), y = -(2*a*e-b*d+X)/(4*a*c-b^2)}$

The transformed equation has the form or , where D is the discriminant.

>	$Q := collect(normal(eval(-4Pa(-4a*c+b^2), tr)), {X, Y}); m := -coeff(coeff(Q, X, 0), Y, 0)$

For positive discriminant D, this is a general Pell's equation, , which Maple knows how to solve. (The definition of Pell's equation requires that D is not a square, but Maple can also solve the simpler case where D is a square.) For the hyperbola above, we have an infinite number of solutions, parameterized by an arbitrary integer _Z1.

>	$Q__h := eval(Q, h_params); solXY__h := {isolve(Q__h)}$

${{X = -12*(1+2^(1/2))^(1+2*_Z1)-12*(1-2^(1/2))^(1+2*_Z1)-4*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)), Y = -3*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1))-2*(1+2^(1/2))^(1+2*_Z1)-2*(1-2^(1/2))^(1+2*_Z1)}, {X = -12*(1+2^(1/2))^(1+2*_Z1)-12*(1-2^(1/2))^(1+2*_Z1)-4*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)), Y = 3*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1))+2*(1+2^(1/2))^(1+2*_Z1)+2*(1-2^(1/2))^(1+2*_Z1)}, {X = -12*(1+2^(1/2))^(1+2*_Z1)-12*(1-2^(1/2))^(1+2*_Z1)+4*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)), Y = -3*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1))+2*(1+2^(1/2))^(1+2*_Z1)+2*(1-2^(1/2))^(1+2*_Z1)}, {X = -12*(1+2^(1/2))^(1+2*_Z1)-12*(1-2^(1/2))^(1+2*_Z1)+4*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)), Y = 3*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1))-2*(1+2^(1/2))^(1+2*_Z1)-2*(1-2^(1/2))^(1+2*_Z1)}, {X = 12*(1+2^(1/2))^(1+2*_Z1)+12*(1-2^(1/2))^(1+2*_Z1)-4*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)), Y = -3*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1))+2*(1+2^(1/2))^(1+2*_Z1)+2*(1-2^(1/2))^(1+2*_Z1)}, {X = 12*(1+2^(1/2))^(1+2*_Z1)+12*(1-2^(1/2))^(1+2*_Z1)-4*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)), Y = 3*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1))-2*(1+2^(1/2))^(1+2*_Z1)-2*(1-2^(1/2))^(1+2*_Z1)}, {X = 12*(1+2^(1/2))^(1+2*_Z1)+12*(1-2^(1/2))^(1+2*_Z1)+4*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)), Y = -3*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1))-2*(1+2^(1/2))^(1+2*_Z1)-2*(1-2^(1/2))^(1+2*_Z1)}, {X = 12*(1+2^(1/2))^(1+2*_Z1)+12*(1-2^(1/2))^(1+2*_Z1)+4*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)), Y = 3*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1))+2*(1+2^(1/2))^(1+2*_Z1)+2*(1-2^(1/2))^(1+2*_Z1)}}$

Transforming back to the original coordinates

>	$sol__h := {seq(eval(eval(tr, h_params), solXY), `in`(solXY, solXY__h))}$

${{x = -2*(1+2^(1/2))^(1+2*_Z1)-2*(1-2^(1/2))^(1+2*_Z1)-(5/4)*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)), y = (3/2)*(1+2^(1/2))^(1+2*_Z1)+(3/2)*(1-2^(1/2))^(1+2*_Z1)+(1/2)*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1))}, {x = -2*(1+2^(1/2))^(1+2*_Z1)-2*(1-2^(1/2))^(1+2*_Z1)+(5/4)*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)), y = (3/2)*(1+2^(1/2))^(1+2*_Z1)+(3/2)*(1-2^(1/2))^(1+2*_Z1)-(1/2)*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1))}, {x = -(1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)-(1/4)*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)), y = (3/2)*(1+2^(1/2))^(1+2*_Z1)+(3/2)*(1-2^(1/2))^(1+2*_Z1)-(1/2)*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1))}, {x = -(1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)+(1/4)*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)), y = (3/2)*(1+2^(1/2))^(1+2*_Z1)+(3/2)*(1-2^(1/2))^(1+2*_Z1)+(1/2)*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1))}, {x = (1+2^(1/2))^(1+2*_Z1)+(1-2^(1/2))^(1+2*_Z1)-(1/4)*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)), y = -(3/2)*(1+2^(1/2))^(1+2*_Z1)-(3/2)*(1-2^(1/2))^(1+2*_Z1)-(1/2)*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1))}, {x = (1+2^(1/2))^(1+2*_Z1)+(1-2^(1/2))^(1+2*_Z1)+(1/4)*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)), y = -(3/2)*(1+2^(1/2))^(1+2*_Z1)-(3/2)*(1-2^(1/2))^(1+2*_Z1)+(1/2)*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1))}, {x = 2*(1+2^(1/2))^(1+2*_Z1)+2*(1-2^(1/2))^(1+2*_Z1)-(5/4)*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)), y = -(3/2)*(1+2^(1/2))^(1+2*_Z1)-(3/2)*(1-2^(1/2))^(1+2*_Z1)+(1/2)*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1))}, {x = 2*(1+2^(1/2))^(1+2*_Z1)+2*(1-2^(1/2))^(1+2*_Z1)+(5/4)*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1)), y = -(3/2)*(1+2^(1/2))^(1+2*_Z1)-(3/2)*(1-2^(1/2))^(1+2*_Z1)-(1/2)*2^(1/2)*((1+2^(1/2))^(1+2*_Z1)-(1-2^(1/2))^(1+2*_Z1))}}$

Evaluate for some _Z1 values, say _Z1=0 and _Z1=5.
It is evident from above that integer solutions in may transform to non-integer solutions in but that doesn't occur for these two cases

>

sol__h0 := evala(eval(sol__h, _Z1 = 0)); sol__h5 := evala(eval(sol__h, _Z1 = 5))

Check they are solutions to

>

For negative discriminant and negative , the equation has no solutions. In the classification scheme for the conics, the "imaginary ellipse" case (no real solutions) occurs when . For negative discriminant, we must have and the same sign, and this is the case of negative .

>

. In this case Maple returns NULL for both the untransformed and transformed case, which can mean no solutions or just that isolve couldn't find any.

>	$ie_params := {a = 3, b = 0, c = 5, d = 0, e = 0, f = 8}; P__ie := eval(P, ie_params); {isolve(P__ie)}; Q__ie := eval(Q, ie_params); {isolve(Q__ie)}$

For negative discriminant and positive or , the ellipse is real, and there are a finite number of solutions. Maple solves the untransformed and transformed equations.
Here we need to filter out non-integer solutions

>	$P__e; {isolve(P__e)}; Q__e := eval(Q, e_params); solXY__e := {isolve(Q__e)}; {seq(eval(eval(tr, e_params), solXY), `in`(solXY, solXY__e))}; sol__e := select(proc (q) options operator, arrow; eval(x::integer, q) and eval(y::integer, q) end proc, %)$

Transformation for zero discriminant
For the case of zero discriminant (parabola), we need a different transformation.

>

The transformed equation is of the form

>

We consider the parabolic example above, for which Maple finds no solutions without transformation.

>	$P__p; {isolve(P__p)}$

For the transformed problem, Maple finds an infinite number of solutions

>	$Q__p := eval(Q0, p_params); solXY__p := {isolve(Q__p)}; sol__p := {seq(eval(eval(tr0, p_params), solXY), `in`(solXY, solXY__p))}$

${{X = 1+8*_Z1, Y = -8*_Z1^2-2*_Z1-7}, {X = 3+8*_Z1, Y = -8*_Z1^2-6*_Z1-8}, {X = 5+8*_Z1, Y = -8*_Z1^2-10*_Z1-10}, {X = 7+8*_Z1, Y = -8*_Z1^2-14*_Z1-13}}$

${{x = 17/2+8*_Z1+8*_Z1^2, y = -8*_Z1^2-6*_Z1-8}, {x = 29/2+16*_Z1+8*_Z1^2, y = -8*_Z1^2-14*_Z1-13}, {x = 8*_Z1^2+4*_Z1+7, y = -8*_Z1^2-2*_Z1-7}, {x = 8*_Z1^2+12*_Z1+11, y = -8*_Z1^2-10*_Z1-10}}$

Two of the general solutions will not give integer solutions, so could be filtered out, but it is easier to filter after choosing some specific _Z1 values.

>

eval(sol__p, _Z1 = 0); sol__p0 := select(proc (q) options operator, arrow; eval(x::integer, q) and eval(y::integer, q) end proc, %); eval(sol__p, _Z1 = 5); sol__p5 := select(proc (q) options operator, arrow; eval(x::integer, q) and eval(y::integer, q) end proc, %)

Check they are solutions to

>

Download DiophantineConics2.mw

Maple Conference 2025: It's almost here!

by: KaskaKowalska 165 Products: Maple , Maple Learn

8 hours ago

1 1

There is still time to register for Maple Conference 2025, which takes place November 5-7, 2025.

The free registration includes access to three full days of presentations from Maplesoft product directors and developers, two distinguished keynote speakers, contributed talks by Maple users, and opportunities to network with fellow users, researchers, and Maplesoft staff.

The final day of the conference will feature three in-depth workshops presented by the R&D team. You'll get hands-on experience with creating professional documents in Maple, learn how to solve various differential equations more effectively using Maple's numerical solvers, and explore the power of the Maple programming language while solving interesting puzzles.

Access to the workshops is included with the free conference registration.

We hope to see you there!

Kaska Kowalska
Contributed Program Co-chair

if statement inside a do-loop...

Asked by: Andiguys 85

16 hours ago

0 2

How can I use an if statement inside a do - loop in maple and then plot a figure based on the conditional results? I need help with the correct syntax for combining the do-loop, `if` condition, and plotting command.

Sheet attached below:
Algorithmm.mw

How can I add color bar to these 2- and 3-D plots?...

Asked by: raj2018 55

Yesterday at 6:19 AM

0 1

Hi,
I want to have a colorbar aside the curve, but I can't. (My Maple version is 2018).

restart:
with(plots):

# --- constants ---
qc := 0.4:
qh := 0.64:
alpha := 0.8:

# --- parameter ranges ---
deltac_min := 0.01: deltac_max := 0.99:
Tch_min := 0.1: Tch_max := 1.1:

# --- numerical safety ---
epsDen := 1e-12:
Mcap := 3.0: # cap to avoid infinity

# --- denominator ---
Den := (deltac, Tch) ->
-2*Tch*deltac*qh - 2*Tch*deltac + 2*Tch*qh
+ 2*deltac*qc + 2*Tch + 2*deltac:

# --- safe functions ---
M1safe := (deltac, Tch) ->
piecewise(Den(deltac,Tch) > epsDen,
min(2/sqrt(Den(deltac,Tch)), Mcap),
Mcap):

M0safe := (deltac, Tch) ->
piecewise(Den(deltac,Tch) > epsDen,
min(2*alpha/sqrt(Den(deltac,Tch)), Mcap),
Mcap):

# --- density plots ---
p1 := densityplot(
M1safe(deltac,Tch),
deltac = deltac_min .. deltac_max,
Tch = Tch_min .. Tch_max,
grid = [200,200],
style = patchnogrid,
colorstyle = HUE,
axes = boxed,
labels = ["δ_c", "T_ch"],
title = sprintf("M1(δ_c, T_ch) (capped at %.2f)", Mcap)
):

p2 := densityplot(
M0safe(deltac,Tch),
deltac = deltac_min .. deltac_max,
Tch = Tch_min .. Tch_max,
grid = [200,200],
style = patchnogrid,
colorstyle = HUE,
axes = boxed,
labels = ["δ_c", "T_ch"],
title = sprintf("M0(δ_c, T_ch) (capped at %.2f)", Mcap)
):

# --- Contour Den = 0 (to mark physical boundary) ---
cont := contourplot(
Den(deltac,Tch),
deltac = deltac_min .. deltac_max,
Tch = Tch_min .. Tch_max,
contours = [0],
color = black,
thickness = 2
):

# --- Overlay contour ---
p1_final := display(p1, cont):
p2_final := display(p2, cont):

# --- Display side by side ---
display(array([p1_final, p2_final]), scaling = constrained);

@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@

restart;
with(plots):

# === Constants ===
qc := 0.4:
qh := 0.64:
alpha := 0.8:

# === Denominator ===
Den := (deltac, Tch) ->
-2*Tch*deltac*qh - 2*Tch*deltac + 2*Tch*qh
+ 2*deltac*qc + 2*Tch + 2*deltac:

# === M1 and M0 ===
M1 := (deltac, Tch) -> piecewise(Den(deltac,Tch)>0, 2/sqrt(Den(deltac,Tch)), undefined):
M0 := (deltac, Tch) -> piecewise(Den(deltac,Tch)>0, 2*alpha/sqrt(Den(deltac,Tch)), undefined):

# === Domain ===
deltac_min := 0.05: deltac_max := 0.95:
Tch_min := 0.01: Tch_max := 1.10: # Physically realistic range

# === 3D Plots ===
p1 := plot3d(M1(deltac,Tch),
deltac=deltac_min..deltac_max,
Tch=Tch_min..Tch_max,
grid=[80,80],
axes=boxed,
orientation=[-130,45],
scaling=constrained,
style=surfacecontour,
color=green,
labels=["δ_c", "T_ch", "M1"],
labelfont=[TIMES,12],
title="M1(δ_c, T_ch) for qc=0.4, qh=0.64"):

p2 := plot3d(M0(deltac,Tch),
deltac=deltac_min..deltac_max,
Tch=Tch_min..Tch_max,
grid=[80,80],
axes=boxed,
orientation=[-130,45],
scaling=constrained,
style=surfacecontour,
color=blue,
labels=["δ_c", "T_ch", "M0"],
labelfont=[TIMES,12],
title="M0(δ_c, T_ch) for α=0.8, qc=0.4, qh=0.64"):

# === Display vertically (M1 above M0) ===
display(Array(1..2, [p1, p2]), insequence=true, scaling=constrained);
display(Array([[p1], [p2]]));

Where is wrong in this code when I use sort a list...

Asked by: minhthien2016 390

Yesterday at 3:32 AM

1 4

I am using S := sort([sqrt(x2), sqrt(y2), sqrt(z2)]);

restart;
n := 0:
L := []:

for a from 3 to 100 do
for b from 3 to a do
c2 := a^2 - a*b + b^2;
c := isqrt(c2);
if c^2 = c2 then
if c < a + b and a < b + c and b < c + a then
if igcd(a, b, c) = 1 then
x2 := (-a^2 + b^2 + c^2)/2;
y2 := (a^2 - b^2 + c^2)/2;
z2 := (a^2 + b^2 - c^2)/2;
if 0 < x2 and 0 < y2 and 0 < z2 then
S := sort([sqrt(x2), sqrt(y2), sqrt(z2)]);
x := S[1];
y := S[2];
z := S[3];
n := n + 1;
L := [op(L), [x, y, z, sqrt(x^2 + y^2), sqrt(y^2 + z^2), sqrt(x^2 + z^2)]];
end if;
end if;
end if;
end if;
end do;
end do;

n;
L;

But I get the result. How can I get the correct result of sort?

What is the mserver for that runs after start-up...

Asked by: C_R 3487

October 29 2025

1 0

After Maple 2025 start-up (with disabled start-up page) and closing the blank worksheet (note the dark grey workspace) there is still one mserver running (highlighted in yellow).

I have not seen a difference when I kill this process and open a new worksheet which starts a new mserver.exe task (and run Maple code).

The task seems to be inactive (no processor load and memory allocation visible).

Is it a task only used by the interface task (javaw.exe)?
What might be the purpose of this mserver.exe?

Update: The task is inactive in a sense that it does not show immetiate activity when annother mserver.exe task runs (i.e. exceuting a worksheet). However, after a day memory allocation shows changes. When exactly these changes happend is unclear.

is there difference between running code in worksh...

Asked by: nm 11523

October 28 2025

1 1

I am able to reproduce a case where same exact code, which is in .mla library, when called from worksheet produces Maple internal errors when calling odetest, which happens at random places

Error, (in depends) too many levels of recursion

Error, (in anonymous procedure called from depends) too many levels of recursion

But when calling same exact proc in the mla from the command line using

/home/me/maple2025/bin/maple  -q BUILD_ALL.mpl

Where BUILD_ALL.mpl has same command used in worksheet, which is say my_command() where my_command() is proc in my .mla library, the code runs with no erros.

Both worksheet and command use the same exact initialization code before running the command, which is read from this file

dsolve(diff(y(x),x$20)=0,arbitraryconstants=traditional):

interface(warnlevel=0):
kernelopts('assertlevel'=2):

kernelopts(numcpus=1);
kernelopts(gcmaxthreads=1);
interface(rtablesize=100);

latex:-Settings(useimaginaryunit=i,
      usecolor = false,
      powersoftrigonometricfunctions= mixed, ## computernotation,
      leavespaceafterfunctionname = true,
      cacheresults = false,
      spaceaftersqrt = true,
      usetypesettingcurrentsettings=true,
      linelength=1000000
):

plots[setoptions](font=[TIMES,12], labelfont=[TIMES,16]);
plots[setoptions3d](font=[TIMES,12], labelfont=[TIMES,24]);

_EnvUseHeavisideAsUnitStep:=true;
local gamma;

libname := "/home/me/my.mla", libname:

I see from the print messages I have, that both codes run exactly the same steps as ofcourse should be the case as it is the same function. But when running from worksheet, I keep getting these internal Maple errors when calling odetest in the function called after running for sometime. But no errors from command line.

In the worksheet I have it setup so that each worksheet uses its own math engine.

This also happens when starting from clean worksheet with restart.

So there must be something different in running code in .mla from worksheet vs. command to cause this.

Some sort of memory or stack issue or something like this?. But I have no idea what it can be as I expected same code to run the same way.

I am not able to make MWE so far since it uses the whole .mla and code is very large also code uses SQL database. I tried to make small MWE, but the error from worksheet do not show up then. Only when running the whole program it shows up.

But why does odetest behave different when running code from worksheet vs. command line Maple?

This always happens when calling odetest inside timelimit in the function in question. I also use

`assuming/restore_previous_state`;

In all my try/catch calls. I wonder if this has anything to do with this difference in behavior. I will try next to remove all calls to the above and see if this is what causing the problem. But stil the question is, why behaves different when called from worksheet vs. command line?

I am asking general question here: Should there be difference in how proc() in .mla behaves when called from command line vs. worksheet? Any one had similar experience in Maple?

Any ideas or guesses what can cause this, Or anything I can try to help find the cause? I will try them as I gave up figuring this one.

Does Maple math engine internally makes any checks if it called from worksheet vs. command line? Or does the worksheet itself changes some settings that can cause some math engine function such as odetest to behave different? I do not see how this is can be the case.

Any additional information needed, will be happy to provide it,

(#5654 for my reference)

Update

Good news. I am able to make a MWE which reproduces this bug.

It happens when running many many such calls.

Here is the worksheet. It is large, because the Maple bug only happens when running this sequence of calling odetest. And it happens in worksheet. I will now make version for command line which should not give error. But for now, this is the worksheet version. For me, it gives this error each time. But if you do not see the error, try again from the top of the worksheet.

Note. I am adding the same initialization code I used in both worksheet and command line. Which is

kernelopts(numcpus=1);
kernelopts(gcmaxthreads=1);
interface(rtablesize=100);

to the top of the worksheet. But the Maple error shows up with or without using the above 3 lines of code.

>

restart;

>	interface(version);

>	Physics:-Version();

>	SupportTools:-Version();

>

restart;

>	kernelopts(numcpus=1); kernelopts(gcmaxthreads=1); interface(rtablesize=100);

>

verify_it:=proc(sol,ode,func)
  local the_status;
  try
   the_status:=timelimit(30,odetest(sol,ode,func)):
   if the_statu<>0 then
      the_status:=timelimit(30, (odetest(sol,ode,func) assuming integer));
   fi;

   if the_status<>0 then
      the_status:=timelimit(30, (odetest(sol,ode,func) assuming integer,positive));
   fi;

   if the_status<>0 then
       the_status:= timelimit(30, (odetest(sol,ode,func) assuming positive));
   fi;

   if the_status<>0 then
      the_status:=timelimit(30, (odetest(sol,ode,func) assuming x<1));
   fi;

   if the_status<>0 then
      timelimit(30, (odetest(sol,ode,func) assuming x>1));
   fi;
  catch:
   NULL;
  end try:
end proc:

>	#RUN THE next one large cell. If you do not get internal error, try again from restart

>

sol:=ln(x)-_C1+Intat(1/z/(-1-1/6/(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)*(-6*z*(z
*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)+6^(2/3)*((z^3*(-3*(27*z^2-2*z)^(1/2)*3
^(1/2)+27*z-1))^(1/3)+z))/z),z = x*y(x)) = 0:
ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
*y(x)^3 = 0:
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C2+Intat(1/z/(-1+1/4*((-I*3^(1/6)*2^(2/3)+1/3*6^(2/3))*(z^3*(-3*(27*z^2-\
2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)+1/3*6^(2/3)+4*(z*(27*z^2
-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)/z
),z = x*y(x)) = 0:
ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
*y(x)^3 = 0:
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C3+Intat(1/z/(-1-1/4/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)*((-I*3^(
1/6)*2^(2/3)-1/3*6^(2/3))*(z^3*(-3*(27*z^2-2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*
(I*3^(1/6)*2^(2/3)-1/3*6^(2/3)-4*(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/z
),z = x*y(x)) = 0:
ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
*y(x)^3 = 0:
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C1+Intat(1/z/(-1-1/6/(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)*(-6*z*(z
*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)+6^(2/3)*((z^3*(-3*(27*z^2-2*z)^(1/2)*3
^(1/2)+27*z-1))^(1/3)+z))/z),z = x*y(x)) = 0:
ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
*y(x)^3 = 0:
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C2+Intat(1/z/(-1+1/4*((-I*3^(1/6)*2^(2/3)+1/3*6^(2/3))*(z^3*(-3*(27*z^2-\
2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)+1/3*6^(2/3)+4*(z*(27*z^2
-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)/z
),z = x*y(x)) = 0:
ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
*y(x)^3 = 0:
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C3+Intat(1/z/(-1-1/4/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)*((-I*3^(
1/6)*2^(2/3)-1/3*6^(2/3))*(z^3*(-3*(27*z^2-2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*
(I*3^(1/6)*2^(2/3)-1/3*6^(2/3)-4*(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/z
),z = x*y(x)) = 0:
ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
*y(x)^3 = 0:
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C1+Intat(1/z/(-1-1/6*(-6*z*(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)+6^
(2/3)*((z^3*(-3*(27*z^2-2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z))/(z*3^(1/2)*(27*z^
2-2*z)^(1/2)-9*z^2)^(1/3)/z),z = x*y(x)) = 0:
ode:=diff(y(x),x) = 1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(
x))*x^2)^(1/3)+1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9
*y(x))*x^2)^(1/3)-1/x*y(x):
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C1+Intat(1/z/(-1-1/6*(-6*z*(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)+6^
(2/3)*((z^3*(-3*(27*z^2-2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z))/(z*3^(1/2)*(27*z^
2-2*z)^(1/2)-9*z^2)^(1/3)/z),z = x*y(x)) = 0:
ode:=diff(y(x),x) = 1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(
x))*x^2)^(1/3)+1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9
*y(x))*x^2)^(1/3)-1/x*y(x):
verify_it(sol,ode,y(x)):

sol:=Intat(1/(6^(1/3)*tau+(-3^(1/2)*(3*3^(1/2)*tau-(tau*(27*tau-2))^(1/2))*tau)^(2/3
))*(-3^(1/2)*(3*3^(1/2)*tau-(tau*(27*tau-2))^(1/2))*tau)^(1/3),tau = x*y(x)) =
6^(1/3)*ln(x^(1/6))+_C2:
ode:=diff(y(x),x) = 1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(
x))*x^2)^(1/3)+1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9
*y(x))*x^2)^(1/3)-1/x*y(x):
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C3+Intat(1/z/(-1-1/4*((-I*3^(1/6)*2^(2/3)-1/3*6^(2/3))*(z^3*(-3*3^(1/2)*
(27*z^2-2*z)^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)-1/3*6^(2/3)-4*(z*3^(1/2)
*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)))/(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)/z
),z = x*y(x)) = 0:
ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
)-9*y(x))*x^2)^(1/3)-1/x*y(x)-1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C3+Intat(1/z/(-1-1/4*((-I*3^(1/6)*2^(2/3)-1/3*6^(2/3))*(z^3*(-3*3^(1/2)*
(27*z^2-2*z)^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)-1/3*6^(2/3)-4*(z*3^(1/2)
*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)))/(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)/z
),z = x*y(x)) = 0:
ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
)-9*y(x))*x^2)^(1/3)-1/x*y(x)-1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
verify_it(sol,ode,y(x)):

sol:=-ln(x) = Intat(-(1+I*3^(1/2))*(-(27*_a-2)^(1/2)*3^(1/2)+9*_a^(1/2))^(1/3)*6^(2/
3)/_a^(1/2)/(I*3^(5/6)*2^(1/3)+2*(-(27*_a-2)^(1/2)*3^(1/2)+9*_a^(1/2))^(2/3)-6^
(1/3)),_a = x*y(x))+_C5:
ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
)-9*y(x))*x^2)^(1/3)-1/x*y(x)-1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
verify_it(sol,ode,y(x)):

sol:=ln(y)-_C6+Intat(1/z/(-1-(1-I*3^(1/2))*z*6^(2/3)*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2
)-9))^(1/3)/(-2*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(2/3)+z*(3*I*3^(1/6)*2^(2/
3)-6^(2/3))*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(1/3)+I*3^(5/6)*2^(1/3)*z+6^(1
/3)*z)),z = x(y)*y) = 0:
ode:=diff(x(y),y) = (3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
1/3)*x(y)^2*6^(2/3)*(I*3^(1/2)-1)/(-1/12*6^(2/3)*(I*3^(1/2)-1)*(-I*6^(2/3)*3^(1
/2)+6^(2/3)+12*(3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
1/3))*x(y)*y+2*(3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
2/3)):
verify_it(sol,ode,y(x)):

sol:=ln(y)-_C6+Intat(1/z/(-1-(1-I*3^(1/2))*z*6^(2/3)*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2
)-9))^(1/3)/(-2*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(2/3)+z*(3*I*3^(1/6)*2^(2/
3)-6^(2/3))*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(1/3)+I*3^(5/6)*2^(1/3)*z+6^(1
/3)*z)),z = x(y)*y) = 0:
ode:=diff(x(y),y) = (3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
1/3)*x(y)^2*6^(2/3)*(I*3^(1/2)-1)/(-1/12*6^(2/3)*(I*3^(1/2)-1)*(-I*6^(2/3)*3^(1
/2)+6^(2/3)+12*(3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
1/3))*x(y)*y+2*(3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
2/3)):
verify_it(sol,ode,y(x)):

sol:=ln(y(x))-_C6+Intat(1/z/(-1-(1-I*3^(1/2))*z*6^(2/3)*(z^2*(((27*z-2)/z)^(1/2)*3^(
1/2)-9))^(1/3)/(-2*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(2/3)+z*(3*I*3^(1/6)*2^
(2/3)-6^(2/3))*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(1/3)+I*3^(5/6)*2^(1/3)*z+6
^(1/3)*z)),z = x*y(x)) = 0:
ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
)-9*y(x))*x^2)^(1/3)-1/x*y(x)-1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C7+Intat(1/z/(-1+1/4*((-I*3^(1/6)*2^(2/3)+1/3*6^(2/3))*(z^3*(-3*(27*z^2-\
2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)+1/3*6^(2/3)+4*(z*(27*z^2
-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)/z
),z = x*y(x)) = 0:
ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
)-9*y(x))*x^2)^(1/3)-1/x*y(x)+1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C7+Intat(1/z/(-1+1/4*((-I*3^(1/6)*2^(2/3)+1/3*6^(2/3))*(z^3*(-3*(27*z^2-\
2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)+1/3*6^(2/3)+4*(z*(27*z^2
-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)/z
),z = x*y(x)) = 0:
ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
)-9*y(x))*x^2)^(1/3)-1/x*y(x)+1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
verify_it(sol,ode,y(x)):

sol:=-ln(x) = Intat(-2/_a^(1/2)*((27*_a-2)^(1/2)*3^(1/2)-9*_a^(1/2))^(1/3)/(-I*3^(5/
6)*2^(1/3)+I*3^(1/2)*((27*_a-2)^(1/2)*3^(1/2)-9*_a^(1/2))^(2/3)-((27*_a-2)^(1/2
)*3^(1/2)-9*_a^(1/2))^(2/3)-6^(1/3))*6^(2/3),_a = x*y(x))+_C9:
ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
)-9*y(x))*x^2)^(1/3)-1/x*y(x)+1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
verify_it(sol,ode,y(x)):

Error, (in anonymous procedure called from depends) too many levels of recursion

>

Download error_in_worksheet_but_not_in_command_line_oct_28_2025.mw

Below is same exact code but run in command line Maple. It produces no error

#run this A.mpl file using
#/home/me/maple2025/bin/maple A.mpl

interface(version);
Physics:-Version();
SupportTools:-Version();

kernelopts(numcpus=1);
kernelopts(gcmaxthreads=1);
interface(rtablesize=100);

verify_it:=proc(sol,ode,func)
  local the_status;
  try
   the_status:=timelimit(30,odetest(sol,ode,func)):
   if the_statu<>0 then
      the_status:=timelimit(30, (odetest(sol,ode,func) assuming integer));
   fi;

   if the_status<>0 then
      the_status:=timelimit(30, (odetest(sol,ode,func) assuming integer,positive));
   fi;

   if the_status<>0 then
       the_status:= timelimit(30, (odetest(sol,ode,func) assuming positive));
   fi;

   if the_status<>0 then
      the_status:=timelimit(30, (odetest(sol,ode,func) assuming x<1));
   fi;

   if the_status<>0 then
      timelimit(30, (odetest(sol,ode,func) assuming x>1));
   fi;
  catch:
   NULL;
  end try:
end proc:


sol:=ln(x)-_C1+Intat(1/z/(-1-1/6/(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)*(-6*z*(z
*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)+6^(2/3)*((z^3*(-3*(27*z^2-2*z)^(1/2)*3
^(1/2)+27*z-1))^(1/3)+z))/z),z = x*y(x)) = 0:
ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
*y(x)^3 = 0:
verify_it(sol,ode,y(x)):


sol:=ln(x)-_C2+Intat(1/z/(-1+1/4*((-I*3^(1/6)*2^(2/3)+1/3*6^(2/3))*(z^3*(-3*(27*z^2-\
2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)+1/3*6^(2/3)+4*(z*(27*z^2
-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)/z
),z = x*y(x)) = 0:
ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
*y(x)^3 = 0:
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C3+Intat(1/z/(-1-1/4/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)*((-I*3^(
1/6)*2^(2/3)-1/3*6^(2/3))*(z^3*(-3*(27*z^2-2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*
(I*3^(1/6)*2^(2/3)-1/3*6^(2/3)-4*(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/z
),z = x*y(x)) = 0:
ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
*y(x)^3 = 0:
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C1+Intat(1/z/(-1-1/6/(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)*(-6*z*(z
*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)+6^(2/3)*((z^3*(-3*(27*z^2-2*z)^(1/2)*3
^(1/2)+27*z-1))^(1/3)+z))/z),z = x*y(x)) = 0:
ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
*y(x)^3 = 0:
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C2+Intat(1/z/(-1+1/4*((-I*3^(1/6)*2^(2/3)+1/3*6^(2/3))*(z^3*(-3*(27*z^2-\
2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)+1/3*6^(2/3)+4*(z*(27*z^2
-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)/z
),z = x*y(x)) = 0:
ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
*y(x)^3 = 0:
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C3+Intat(1/z/(-1-1/4/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)*((-I*3^(
1/6)*2^(2/3)-1/3*6^(2/3))*(z^3*(-3*(27*z^2-2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*
(I*3^(1/6)*2^(2/3)-1/3*6^(2/3)-4*(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/z
),z = x*y(x)) = 0:
ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
*y(x)^3 = 0:
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C1+Intat(1/z/(-1-1/6*(-6*z*(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)+6^
(2/3)*((z^3*(-3*(27*z^2-2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z))/(z*3^(1/2)*(27*z^
2-2*z)^(1/2)-9*z^2)^(1/3)/z),z = x*y(x)) = 0:
ode:=diff(y(x),x) = 1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(
x))*x^2)^(1/3)+1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9
*y(x))*x^2)^(1/3)-1/x*y(x):
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C1+Intat(1/z/(-1-1/6*(-6*z*(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)+6^
(2/3)*((z^3*(-3*(27*z^2-2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z))/(z*3^(1/2)*(27*z^
2-2*z)^(1/2)-9*z^2)^(1/3)/z),z = x*y(x)) = 0:
ode:=diff(y(x),x) = 1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(
x))*x^2)^(1/3)+1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9
*y(x))*x^2)^(1/3)-1/x*y(x):
verify_it(sol,ode,y(x)):


sol:=Intat(1/(6^(1/3)*tau+(-3^(1/2)*(3*3^(1/2)*tau-(tau*(27*tau-2))^(1/2))*tau)^(2/3
))*(-3^(1/2)*(3*3^(1/2)*tau-(tau*(27*tau-2))^(1/2))*tau)^(1/3),tau = x*y(x)) =
6^(1/3)*ln(x^(1/6))+_C2:
ode:=diff(y(x),x) = 1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(
x))*x^2)^(1/3)+1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9
*y(x))*x^2)^(1/3)-1/x*y(x):
verify_it(sol,ode,y(x)):


sol:=ln(x)-_C3+Intat(1/z/(-1-1/4*((-I*3^(1/6)*2^(2/3)-1/3*6^(2/3))*(z^3*(-3*3^(1/2)*
(27*z^2-2*z)^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)-1/3*6^(2/3)-4*(z*3^(1/2)
*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)))/(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)/z
),z = x*y(x)) = 0:
ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
)-9*y(x))*x^2)^(1/3)-1/x*y(x)-1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C3+Intat(1/z/(-1-1/4*((-I*3^(1/6)*2^(2/3)-1/3*6^(2/3))*(z^3*(-3*3^(1/2)*
(27*z^2-2*z)^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)-1/3*6^(2/3)-4*(z*3^(1/2)
*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)))/(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)/z
),z = x*y(x)) = 0:
ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
)-9*y(x))*x^2)^(1/3)-1/x*y(x)-1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
verify_it(sol,ode,y(x)):

sol:=-ln(x) = Intat(-(1+I*3^(1/2))*(-(27*_a-2)^(1/2)*3^(1/2)+9*_a^(1/2))^(1/3)*6^(2/
3)/_a^(1/2)/(I*3^(5/6)*2^(1/3)+2*(-(27*_a-2)^(1/2)*3^(1/2)+9*_a^(1/2))^(2/3)-6^
(1/3)),_a = x*y(x))+_C5:
ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
)-9*y(x))*x^2)^(1/3)-1/x*y(x)-1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
verify_it(sol,ode,y(x)):

sol:=ln(y)-_C6+Intat(1/z/(-1-(1-I*3^(1/2))*z*6^(2/3)*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2
)-9))^(1/3)/(-2*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(2/3)+z*(3*I*3^(1/6)*2^(2/
3)-6^(2/3))*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(1/3)+I*3^(5/6)*2^(1/3)*z+6^(1
/3)*z)),z = x(y)*y) = 0:
ode:=diff(x(y),y) = (3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
1/3)*x(y)^2*6^(2/3)*(I*3^(1/2)-1)/(-1/12*6^(2/3)*(I*3^(1/2)-1)*(-I*6^(2/3)*3^(1
/2)+6^(2/3)+12*(3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
1/3))*x(y)*y+2*(3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
2/3)):
verify_it(sol,ode,y(x)):

sol:=ln(y)-_C6+Intat(1/z/(-1-(1-I*3^(1/2))*z*6^(2/3)*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2
)-9))^(1/3)/(-2*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(2/3)+z*(3*I*3^(1/6)*2^(2/
3)-6^(2/3))*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(1/3)+I*3^(5/6)*2^(1/3)*z+6^(1
/3)*z)),z = x(y)*y) = 0:
ode:=diff(x(y),y) = (3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
1/3)*x(y)^2*6^(2/3)*(I*3^(1/2)-1)/(-1/12*6^(2/3)*(I*3^(1/2)-1)*(-I*6^(2/3)*3^(1
/2)+6^(2/3)+12*(3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
1/3))*x(y)*y+2*(3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
2/3)):
verify_it(sol,ode,y(x)):

sol:=ln(y(x))-_C6+Intat(1/z/(-1-(1-I*3^(1/2))*z*6^(2/3)*(z^2*(((27*z-2)/z)^(1/2)*3^(
1/2)-9))^(1/3)/(-2*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(2/3)+z*(3*I*3^(1/6)*2^
(2/3)-6^(2/3))*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(1/3)+I*3^(5/6)*2^(1/3)*z+6
^(1/3)*z)),z = x*y(x)) = 0:
ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
)-9*y(x))*x^2)^(1/3)-1/x*y(x)-1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C7+Intat(1/z/(-1+1/4*((-I*3^(1/6)*2^(2/3)+1/3*6^(2/3))*(z^3*(-3*(27*z^2-\
2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)+1/3*6^(2/3)+4*(z*(27*z^2
-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)/z
),z = x*y(x)) = 0:
ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
)-9*y(x))*x^2)^(1/3)-1/x*y(x)+1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
verify_it(sol,ode,y(x)):

sol:=ln(x)-_C7+Intat(1/z/(-1+1/4*((-I*3^(1/6)*2^(2/3)+1/3*6^(2/3))*(z^3*(-3*(27*z^2-\
2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)+1/3*6^(2/3)+4*(z*(27*z^2
-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)/z
),z = x*y(x)) = 0:
ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
)-9*y(x))*x^2)^(1/3)-1/x*y(x)+1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
verify_it(sol,ode,y(x)):


sol:=-ln(x) = Intat(-2/_a^(1/2)*((27*_a-2)^(1/2)*3^(1/2)-9*_a^(1/2))^(1/3)/(-I*3^(5/
6)*2^(1/3)+I*3^(1/2)*((27*_a-2)^(1/2)*3^(1/2)-9*_a^(1/2))^(2/3)-((27*_a-2)^(1/2
)*3^(1/2)-9*_a^(1/2))^(2/3)-6^(1/3))*6^(2/3),_a = x*y(x))+_C9:
ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
)-9*y(x))*x^2)^(1/3)-1/x*y(x)+1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
verify_it(sol,ode,y(x)):

print("DONE. Did you see any errors?");

exit();

Here is the result

>/home/me/maple2025/bin/maple A.mpl
    |\^/|     Maple 2025 (X86 64 LINUX)
._|\|   |/|_. Copyright (c) Maplesoft, a division of Waterloo Maple Inc. 2025
 \  MAPLE  /  All rights reserved. Maple is a trademark of
 <____ ____>  Waterloo Maple Inc.
      |       Type ? for help.
#run this A.mpl file using
#/home/me/maple2025/bin/maple A.mpl


> interface(version);
                               Command-line Interface, Maple 2025.1, X86 64 LINUX, Jun 12 2025, Build ID 1932578

> Physics:-Version();
The "Physics Updates" version in the MapleCloud is 1881 and is the same as the version installed in this computer, created 2025, October 7, \
    16:4 hours Pacific Time.

> SupportTools:-Version();
The Customer Support Updates version in the MapleCloud is 29 and is the same as the version installed in this computer, created June 23, 202\
    5, 10:25 hours Eastern Time.


> kernelopts(numcpus=1);
                                                                       32

> kernelopts(gcmaxthreads=1);
                                                                    numcpus

> interface(rtablesize=100);
                                                                    [10, 10]


> verify_it:=proc(sol,ode,func)
>   local the_status;
>   try
>    the_status:=timelimit(30,odetest(sol,ode,func)):
>    if the_statu<>0 then
>       the_status:=timelimit(30, (odetest(sol,ode,func) assuming integer));
>    fi;

>    if the_status<>0 then
>       the_status:=timelimit(30, (odetest(sol,ode,func) assuming integer,positive));
>    fi;

>    if the_status<>0 then
>        the_status:= timelimit(30, (odetest(sol,ode,func) assuming positive));
>    fi;

>    if the_status<>0 then
>       the_status:=timelimit(30, (odetest(sol,ode,func) assuming x<1));
>    fi;

>    if the_status<>0 then
>       timelimit(30, (odetest(sol,ode,func) assuming x>1));
>    fi;
>   catch:
>    NULL;
>   end try:
> end proc:


> sol:=ln(x)-_C1+Intat(1/z/(-1-1/6/(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)*(-6*z*(z
> *3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)+6^(2/3)*((z^3*(-3*(27*z^2-2*z)^(1/2)*3
> ^(1/2)+27*z-1))^(1/3)+z))/z),z = x*y(x)) = 0:
> ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
> *y(x)^3 = 0:
> verify_it(sol,ode,y(x)):
memory used=35.6MB, alloc=108.3MB, time=0.19
memory used=121.3MB, alloc=116.3MB, time=0.54
memory used=200.1MB, alloc=144.3MB, time=0.87
memory used=321.1MB, alloc=176.3MB, time=1.35
memory used=384.3MB, alloc=176.3MB, time=1.63
memory used=474.4MB, alloc=176.3MB, time=2.00
memory used=624.5MB, alloc=184.3MB, time=2.57
memory used=759.0MB, alloc=184.3MB, time=3.14
memory used=893.1MB, alloc=184.3MB, time=3.72


> sol:=ln(x)-_C2+Intat(1/z/(-1+1/4*((-I*3^(1/6)*2^(2/3)+1/3*6^(2/3))*(z^3*(-3*(27*z^2-\
> 2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)+1/3*6^(2/3)+4*(z*(27*z^2
> -2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)/z
> ),z = x*y(x)) = 0:
> ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
> *y(x)^3 = 0:
> verify_it(sol,ode,y(x)):
memory used=1035.8MB, alloc=184.3MB, time=4.27
memory used=1169.9MB, alloc=184.3MB, time=4.83
memory used=1302.5MB, alloc=184.3MB, time=5.38
memory used=1423.7MB, alloc=184.3MB, time=5.90
memory used=1552.0MB, alloc=184.3MB, time=6.42
memory used=1667.7MB, alloc=184.3MB, time=6.93
memory used=1795.9MB, alloc=184.3MB, time=7.46
memory used=1921.7MB, alloc=184.3MB, time=7.99
memory used=2035.4MB, alloc=184.3MB, time=8.49

> sol:=ln(x)-_C3+Intat(1/z/(-1-1/4/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)*((-I*3^(
> 1/6)*2^(2/3)-1/3*6^(2/3))*(z^3*(-3*(27*z^2-2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*
> (I*3^(1/6)*2^(2/3)-1/3*6^(2/3)-4*(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/z
> ),z = x*y(x)) = 0:
> ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
> *y(x)^3 = 0:
> verify_it(sol,ode,y(x)):
memory used=2154.0MB, alloc=184.3MB, time=9.00
memory used=2278.5MB, alloc=184.3MB, time=9.53
memory used=2399.9MB, alloc=184.3MB, time=10.04
memory used=2509.9MB, alloc=184.3MB, time=10.52
memory used=2627.5MB, alloc=184.3MB, time=11.02
memory used=2732.8MB, alloc=184.3MB, time=11.48
memory used=2849.4MB, alloc=184.3MB, time=11.97
memory used=2955.4MB, alloc=184.3MB, time=12.45
memory used=3069.4MB, alloc=184.3MB, time=12.93

> sol:=ln(x)-_C1+Intat(1/z/(-1-1/6/(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)*(-6*z*(z
> *3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)+6^(2/3)*((z^3*(-3*(27*z^2-2*z)^(1/2)*3
> ^(1/2)+27*z-1))^(1/3)+z))/z),z = x*y(x)) = 0:
> ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
> *y(x)^3 = 0:
memory used=3173.5MB, alloc=216.3MB, time=13.41
> verify_it(sol,ode,y(x)):
memory used=3322.2MB, alloc=216.3MB, time=14.05
memory used=3466.2MB, alloc=216.3MB, time=14.68
memory used=3605.1MB, alloc=216.3MB, time=15.29
memory used=3743.9MB, alloc=216.3MB, time=15.89
memory used=3882.0MB, alloc=216.3MB, time=16.51

> sol:=ln(x)-_C2+Intat(1/z/(-1+1/4*((-I*3^(1/6)*2^(2/3)+1/3*6^(2/3))*(z^3*(-3*(27*z^2-\
> 2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)+1/3*6^(2/3)+4*(z*(27*z^2
> -2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)/z
> ),z = x*y(x)) = 0:
> ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
> *y(x)^3 = 0:
> verify_it(sol,ode,y(x)):
memory used=4029.8MB, alloc=216.3MB, time=17.11
memory used=4159.8MB, alloc=216.3MB, time=17.70
memory used=4299.4MB, alloc=216.3MB, time=18.29
memory used=4434.6MB, alloc=216.3MB, time=18.86
memory used=4557.8MB, alloc=216.3MB, time=19.42
memory used=4701.2MB, alloc=248.3MB, time=20.00

> sol:=ln(x)-_C3+Intat(1/z/(-1-1/4/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)*((-I*3^(
> 1/6)*2^(2/3)-1/3*6^(2/3))*(z^3*(-3*(27*z^2-2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*
> (I*3^(1/6)*2^(2/3)-1/3*6^(2/3)-4*(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/z
> ),z = x*y(x)) = 0:
> ode:=2*x^3*diff(y(x),x)^3+6*x^2*y(x)*diff(y(x),x)^2-(1-6*x*y(x))*y(x)*diff(y(x),x)+2
> *y(x)^3 = 0:
> verify_it(sol,ode,y(x)):
memory used=4863.9MB, alloc=248.3MB, time=20.70
memory used=5031.5MB, alloc=248.3MB, time=21.41
memory used=5195.2MB, alloc=248.3MB, time=22.11
memory used=5346.8MB, alloc=248.3MB, time=22.76
memory used=5505.1MB, alloc=248.3MB, time=23.42
memory used=5662.7MB, alloc=248.3MB, time=24.09
memory used=5819.2MB, alloc=248.3MB, time=24.76

> sol:=ln(x)-_C1+Intat(1/z/(-1-1/6*(-6*z*(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)+6^
> (2/3)*((z^3*(-3*(27*z^2-2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z))/(z*3^(1/2)*(27*z^
> 2-2*z)^(1/2)-9*z^2)^(1/3)/z),z = x*y(x)) = 0:
> ode:=diff(y(x),x) = 1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(
> x))*x^2)^(1/3)+1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9
> *y(x))*x^2)^(1/3)-1/x*y(x):
> verify_it(sol,ode,y(x)):
memory used=5967.8MB, alloc=248.3MB, time=25.44
memory used=6122.7MB, alloc=248.3MB, time=26.17
memory used=6282.9MB, alloc=280.3MB, time=26.88
memory used=6458.2MB, alloc=280.3MB, time=27.67
memory used=6632.0MB, alloc=280.3MB, time=28.47
memory used=6824.1MB, alloc=280.3MB, time=29.31

> sol:=ln(x)-_C1+Intat(1/z/(-1-1/6*(-6*z*(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)+6^
> (2/3)*((z^3*(-3*(27*z^2-2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z))/(z*3^(1/2)*(27*z^
> 2-2*z)^(1/2)-9*z^2)^(1/3)/z),z = x*y(x)) = 0:
> ode:=diff(y(x),x) = 1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(
> x))*x^2)^(1/3)+1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9
> *y(x))*x^2)^(1/3)-1/x*y(x):
> verify_it(sol,ode,y(x)):
memory used=6997.3MB, alloc=280.3MB, time=30.11
memory used=7185.8MB, alloc=280.3MB, time=30.94
memory used=7352.2MB, alloc=280.3MB, time=31.70
memory used=7511.5MB, alloc=280.3MB, time=32.44
memory used=7691.1MB, alloc=280.3MB, time=33.23


> sol:=Intat(1/(6^(1/3)*tau+(-3^(1/2)*(3*3^(1/2)*tau-(tau*(27*tau-2))^(1/2))*tau)^(2/3
> ))*(-3^(1/2)*(3*3^(1/2)*tau-(tau*(27*tau-2))^(1/2))*tau)^(1/3),tau = x*y(x)) =
> 6^(1/3)*ln(x^(1/6))+_C2:
> ode:=diff(y(x),x) = 1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(
> x))*x^2)^(1/3)+1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9
> *y(x))*x^2)^(1/3)-1/x*y(x):
> verify_it(sol,ode,y(x)):
memory used=7852.5MB, alloc=312.3MB, time=33.99
memory used=8061.4MB, alloc=312.3MB, time=34.94
memory used=8272.3MB, alloc=312.3MB, time=35.84


> sol:=ln(x)-_C3+Intat(1/z/(-1-1/4*((-I*3^(1/6)*2^(2/3)-1/3*6^(2/3))*(z^3*(-3*3^(1/2)*
> (27*z^2-2*z)^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)-1/3*6^(2/3)-4*(z*3^(1/2)
> *(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)))/(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)/z
> ),z = x*y(x)) = 0:
> ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
> y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
> )-9*y(x))*x^2)^(1/3)-1/x*y(x)-1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
> x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
> (y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
> verify_it(sol,ode,y(x)):
memory used=8467.0MB, alloc=312.3MB, time=36.70
memory used=8678.4MB, alloc=312.3MB, time=37.59
memory used=8886.0MB, alloc=344.3MB, time=38.46
memory used=9099.1MB, alloc=344.3MB, time=39.43
memory used=9317.0MB, alloc=344.3MB, time=40.39
memory used=9549.3MB, alloc=344.3MB, time=41.36

> sol:=ln(x)-_C3+Intat(1/z/(-1-1/4*((-I*3^(1/6)*2^(2/3)-1/3*6^(2/3))*(z^3*(-3*3^(1/2)*
> (27*z^2-2*z)^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)-1/3*6^(2/3)-4*(z*3^(1/2)
> *(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)))/(z*3^(1/2)*(27*z^2-2*z)^(1/2)-9*z^2)^(1/3)/z
> ),z = x*y(x)) = 0:
> ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
> y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
> )-9*y(x))*x^2)^(1/3)-1/x*y(x)-1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
> x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
> (y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
> verify_it(sol,ode,y(x)):
memory used=9758.9MB, alloc=344.3MB, time=42.33
memory used=9986.7MB, alloc=344.3MB, time=43.29
memory used=10213.4MB, alloc=376.3MB, time=44.25
memory used=10438.1MB, alloc=376.3MB, time=45.26
memory used=10674.2MB, alloc=376.3MB, time=46.31
memory used=10939.1MB, alloc=376.3MB, time=47.36

> sol:=-ln(x) = Intat(-(1+I*3^(1/2))*(-(27*_a-2)^(1/2)*3^(1/2)+9*_a^(1/2))^(1/3)*6^(2/
> 3)/_a^(1/2)/(I*3^(5/6)*2^(1/3)+2*(-(27*_a-2)^(1/2)*3^(1/2)+9*_a^(1/2))^(2/3)-6^
> (1/3)),_a = x*y(x))+_C5:
> ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
> y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
> )-9*y(x))*x^2)^(1/3)-1/x*y(x)-1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
> x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
> (y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
> verify_it(sol,ode,y(x)):
memory used=11157.9MB, alloc=376.3MB, time=48.37
memory used=11397.1MB, alloc=376.3MB, time=49.36
memory used=11635.9MB, alloc=376.3MB, time=50.33
memory used=11843.8MB, alloc=376.3MB, time=51.27
memory used=12045.3MB, alloc=408.3MB, time=52.21
memory used=12325.2MB, alloc=408.3MB, time=53.28
memory used=12596.4MB, alloc=408.3MB, time=54.33

> sol:=ln(y)-_C6+Intat(1/z/(-1-(1-I*3^(1/2))*z*6^(2/3)*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2
> )-9))^(1/3)/(-2*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(2/3)+z*(3*I*3^(1/6)*2^(2/
> 3)-6^(2/3))*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(1/3)+I*3^(5/6)*2^(1/3)*z+6^(1
> /3)*z)),z = x(y)*y) = 0:
> ode:=diff(x(y),y) = (3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
> 1/3)*x(y)^2*6^(2/3)*(I*3^(1/2)-1)/(-1/12*6^(2/3)*(I*3^(1/2)-1)*(-I*6^(2/3)*3^(1
> /2)+6^(2/3)+12*(3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
> 1/3))*x(y)*y+2*(3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
> 2/3)):
> verify_it(sol,ode,y(x)):

> sol:=ln(y)-_C6+Intat(1/z/(-1-(1-I*3^(1/2))*z*6^(2/3)*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2
> )-9))^(1/3)/(-2*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(2/3)+z*(3*I*3^(1/6)*2^(2/
> 3)-6^(2/3))*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(1/3)+I*3^(5/6)*2^(1/3)*z+6^(1
> /3)*z)),z = x(y)*y) = 0:
> ode:=diff(x(y),y) = (3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
> 1/3)*x(y)^2*6^(2/3)*(I*3^(1/2)-1)/(-1/12*6^(2/3)*(I*3^(1/2)-1)*(-I*6^(2/3)*3^(1
> /2)+6^(2/3)+12*(3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
> 1/3))*x(y)*y+2*(3^(1/2)*(-3*3^(1/2)*y+(y*(27*x(y)*y-2)/x(y))^(1/2))*y*x(y)^2)^(
> 2/3)):
> verify_it(sol,ode,y(x)):

> sol:=ln(y(x))-_C6+Intat(1/z/(-1-(1-I*3^(1/2))*z*6^(2/3)*(z^2*(((27*z-2)/z)^(1/2)*3^(
> 1/2)-9))^(1/3)/(-2*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(2/3)+z*(3*I*3^(1/6)*2^
> (2/3)-6^(2/3))*(z^2*(((27*z-2)/z)^(1/2)*3^(1/2)-9))^(1/3)+I*3^(5/6)*2^(1/3)*z+6
> ^(1/3)*z)),z = x*y(x)) = 0:
> ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
> y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
> )-9*y(x))*x^2)^(1/3)-1/x*y(x)-1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
> x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
> (y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
> verify_it(sol,ode,y(x)):
memory used=12834.3MB, alloc=408.3MB, time=55.38
memory used=13093.0MB, alloc=408.3MB, time=56.51
memory used=13325.7MB, alloc=440.3MB, time=57.54
memory used=13576.1MB, alloc=440.3MB, time=58.67
memory used=13834.9MB, alloc=440.3MB, time=59.79
memory used=14096.1MB, alloc=440.3MB, time=60.95

> sol:=ln(x)-_C7+Intat(1/z/(-1+1/4*((-I*3^(1/6)*2^(2/3)+1/3*6^(2/3))*(z^3*(-3*(27*z^2-\
> 2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)+1/3*6^(2/3)+4*(z*(27*z^2
> -2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)/z
> ),z = x*y(x)) = 0:
> ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
> y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
> )-9*y(x))*x^2)^(1/3)-1/x*y(x)+1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
> x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
> (y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
> verify_it(sol,ode,y(x)):
memory used=14339.1MB, alloc=440.3MB, time=62.07
memory used=14599.6MB, alloc=440.3MB, time=63.21
memory used=14905.7MB, alloc=504.3MB, time=64.42
memory used=15179.6MB, alloc=488.3MB, time=65.73
memory used=15487.1MB, alloc=488.3MB, time=67.03

> sol:=ln(x)-_C7+Intat(1/z/(-1+1/4*((-I*3^(1/6)*2^(2/3)+1/3*6^(2/3))*(z^3*(-3*(27*z^2-\
> 2*z)^(1/2)*3^(1/2)+27*z-1))^(1/3)+z*(I*3^(1/6)*2^(2/3)+1/3*6^(2/3)+4*(z*(27*z^2
> -2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)))/(z*(27*z^2-2*z)^(1/2)*3^(1/2)-9*z^2)^(1/3)/z
> ),z = x*y(x)) = 0:
> ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
> y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
> )-9*y(x))*x^2)^(1/3)-1/x*y(x)+1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
> x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
> (y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
> verify_it(sol,ode,y(x)):
memory used=15758.8MB, alloc=488.3MB, time=68.34
memory used=16065.9MB, alloc=520.3MB, time=69.68
memory used=16378.3MB, alloc=520.3MB, time=71.08
memory used=16680.5MB, alloc=520.3MB, time=72.47


> sol:=-ln(x) = Intat(-2/_a^(1/2)*((27*_a-2)^(1/2)*3^(1/2)-9*_a^(1/2))^(1/3)/(-I*3^(5/
> 6)*2^(1/3)+I*3^(1/2)*((27*_a-2)^(1/2)*3^(1/2)-9*_a^(1/2))^(2/3)-((27*_a-2)^(1/2
> )*3^(1/2)-9*_a^(1/2))^(2/3)-6^(1/3))*6^(2/3),_a = x*y(x))+_C9:
> ode:=diff(y(x),x) = -1/12/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2)-9*
> y(x))*x^2)^(1/3)-1/12*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*(y(x)*(27*x*y(x)-2)/x)^(1/2
> )-9*y(x))*x^2)^(1/3)-1/x*y(x)+1/2*I*3^(1/2)*(1/6/x^2*6^(1/3)*(y(x)*(3^(1/2)*(y(
> x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)-1/6*y(x)/x*6^(2/3)/(y(x)*(3^(1/2)*
> (y(x)*(27*x*y(x)-2)/x)^(1/2)-9*y(x))*x^2)^(1/3)):
> verify_it(sol,ode,y(x)):
memory used=16982.9MB, alloc=520.3MB, time=73.86
memory used=17292.8MB, alloc=520.3MB, time=75.22
memory used=17593.5MB, alloc=520.3MB, time=76.51
memory used=17860.3MB, alloc=552.3MB, time=77.77
memory used=18212.4MB, alloc=552.3MB, time=79.18
memory used=18534.1MB, alloc=552.3MB, time=80.58

> print("DONE. Did you see any errors?");
                                                        "DONE. Did you see any errors?"


> exit();
                                                                     exit()

> quit
memory used=18554.9MB, alloc=552.3MB, time=80.69

You see, no error.

Has anyone turned off scrollable matrices on Mac? ...

Asked by: Hullzie16 393

October 28 2025

1 4

Has anyone had any success in turning off the scrollable matrix feature on Mac? I found the post

https://www.mapleprimes.com/questions/238061-How-To-Disable-The-New-Scrollable-Matrices

and tried to follow the steps outlined by Acer, but I cannot get it to work. Specifically, I greated a preference file at the location:

//Users/$USER/Library/Preferences/Maple/<version>/Maple preferences which has the statement

ScrollableMathTableOutput=false

Any success stories, or tips, will be greatly appreciated.

Thanks.

PDE dchange example...

Asked by: delvin 65

October 28 2025

1 1

I want to ask a question, but I cannot submit it using the link below. I tried several times, but it didn’t work. I wrote it like this, but I didn’t get the desired answer.

http://www.mapleprimes.com/questions/231499-Changing-The-Variables-

Download 963.mw

Problem in differential equation?...

Asked by: delvin 65

October 28 2025

0 2

Hi,

I want to solve the equation shown in the image, along with its given conditions, using Maple and obtain the same results as in the image, but it does not work. Could you please help me?

Download 852.mw

Symbolic calculus w.r.t. ABSTRACT vector, matrix a...

Asked by: sursumCorda 1269

October 28 2025

1 0

Although several similar problems were asked many years ago (see, e.g., the section “Formal linear algebra” here), there appears to be no new progress so far. It is said that such functionalities exists in the Physics package, but I cannot find any corresponding examples.
In short, can Maple at present calculate these examples in terms of symbolic array constructs completely automatically?

How to find the residue at an essential singularit...

Asked by: ssssazxsdfzcas 15

October 28 2025

3 3

residue(z^3*cos(1/(z - 2)), z = 2);

                  3       1
         residue(z  cos(-----), z = 2)
                        z - 2

l notice the help document asks me to increse the n，but the n of essential singularity is infinity

Does the "expand" command have a bug?...

Asked by: Roy Hughes 20

October 28 2025

0 1

I wrote a simple expand command in Maple - expand(cos((u - 2*k)*x))

only to get the result

2*cos(x*u)*cos(x*k)^2 + 2*sin(x*u)*sin(x*k)*cos(x*k) - cos(x*u)

The presence of a squared term seems to indicate a bug??

complicated numerical integral...

Asked by: Marfranz 0

October 27 2025

0 1

I need to compute complicated numerical integral, and my Maple integration does not produce very stable results. Is the a way to do that on line?

Can simplify be improved on this expression with s...

Asked by: C_R 3487

October 26 2025

2 11

In the below I had to add the assumption x>=0 to get simplifications. Am I wrong with my interpretation that the other assumptions should have been sufficient?

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