* [misc]progress:  [Phase 1 of 3] Setting up.
* * * [misc]progress:  [1/2] Preparing points
* * * * [misc]points:  Sampling 256 additional inputs, on iter 0 have 0 / 256
* * * * [misc]points:  Computing exacts on every 16 of 256 points to ramp up precision
* * * * [misc]points:  Setting MPFR precision to 64
* * * * [misc]points:  Setting MPFR precision to 320
* * * * [misc]points:  Setting MPFR precision to 576
* * * * [misc]points:  Setting MPFR precision to 832
* * * * [misc]points:  Setting MPFR precision to 1088
* * * * [misc]points:  Computing exacts on every 8 of 256 points to ramp up precision
* * * * [misc]points:  Setting MPFR precision to 832
* * * * [misc]points:  Setting MPFR precision to 1088
* * * * [misc]points:  Computing exacts on every 4 of 256 points to ramp up precision
* * * * [misc]points:  Setting MPFR precision to 832
* * * * [misc]points:  Setting MPFR precision to 1088
* * * * [misc]points:  Computing exacts on every 2 of 256 points to ramp up precision
* * * * [misc]points:  Setting MPFR precision to 832
* * * * [misc]points:  Setting MPFR precision to 1088
* * * * [misc]points:  Computing exacts for 256 points
* * * * [misc]points:  Setting MPFR precision to 832
* * * * [misc]points:  Setting MPFR precision to 1088
* * * * [misc]points:  Filtering points with unrepresentable outputs
* * * * [exit]points:  Sampled 256 points with exact outputs
* * * [misc]progress:  [2/2] Setting up program.
* [misc]progress:  [Phase 2 of 3] Improving.
* [enter]simplify:  Simplifying (im (+.c (+.c (+.c (+.c (*.c (*.c (*.c (complex (/ (- 1) 2) (/ (sqrt 3) 2)) (complex (/ (- 1) 2) (/ (sqrt 3) 2))) (complex (/ (- 1) 2) (/ (sqrt 3) 2))) (complex (/ (- 1) 2) (/ (sqrt 3) 2))) (*.c (*.c (*.c (complex (- 2) 0) (complex (/ (- 1) 2) (/ (sqrt 3) 2))) (complex (/ (- 1) 2) (/ (sqrt 3) 2))) (complex (/ (- 1) 2) (/ (sqrt 3) 2)))) (*.c (*.c (complex 5 0) (complex (/ (- 1) 2) (/ (sqrt 3) 2))) (complex (/ (- 1) 2) (/ (sqrt 3) 2)))) (*.c (complex 4 0) (complex (/ (- 1) 2) (/ (sqrt 3) 2)))) (complex 7 0)))
* * [misc]simplify:  iters left: 6 (31 enodes)
* * [misc]simplify:  iters left: 5 (85 enodes)
* * [misc]simplify:  iters left: 4 (309 enodes)
* [exit]simplify:  Simplified to (im (+.c (complex 5 (/ (* 4 (sqrt 3)) 2)) (*.c (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))) (+.c (complex 6 (/ (* (sqrt 3) -2) 2)) (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2)))))))
* * [misc]progress:  iteration 1 / 4
* * * [misc]progress:  picking best candidate
* * * * [misc]pick:  Picked  #<alt (λ () (im (+.c (complex 5 (/ (* 4 (sqrt 3)) 2)) (*.c (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))) (+.c (complex 6 (/ (* (sqrt 3) -2) 2)) (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))))))))>
* * * [misc]progress:  localizing error
* * * [misc]progress:  generating rewritten candidates
* * * * [misc]progress:  [ 1 / 2 ] rewriting at (2 1 2 2 2)
* * * * [misc]progress:  [ 2 / 2 ] rewriting at (2 1 2 1)
* * * [misc]progress:  generating series expansions
* * * * [misc]progress:  [ 1 / 2 ] generating series at (2 1 2 2 2)
* * * * [misc]progress:  [ 2 / 2 ] generating series at (2 1 2 1)
* * * [misc]progress:  simplifying candidates
* * * * [misc]progress:  [ 1 / 6 ] simplifiying candidate #<alt (λ () (im (+.c (complex 5 (/ (* 4 (sqrt 3)) 2)) (*.c (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))) (+.c (complex 6 (/ (* (sqrt 3) -2) 2)) (complex (- (* -1/2 -1/2) (* (/ (sqrt 3) 2) (/ (sqrt 3) 2))) (+ (* -1/2 (/ (sqrt 3) 2)) (* (/ (sqrt 3) 2) -1/2))))))))>
* [enter]simplify:  Simplifying (- (* -1/2 -1/2) (* (/ (sqrt 3) 2) (/ (sqrt 3) 2)))
* * [misc]simplify:  iters left: 6 (8 enodes)
* * [misc]simplify:  iters left: 5 (19 enodes)
* * [misc]simplify:  iters left: 4 (35 enodes)
* * [misc]simplify:  iters left: 3 (66 enodes)
* * [misc]simplify:  iters left: 2 (133 enodes)
* * [misc]simplify:  iters left: 1 (181 enodes)
* [exit]simplify:  Simplified to -1/2
* [misc]simplify:  Simplified (2 1 2 2 2 1) to (λ () (im (+.c (complex 5 (/ (* 4 (sqrt 3)) 2)) (*.c (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))) (+.c (complex 6 (/ (* (sqrt 3) -2) 2)) (complex -1/2 (+ (* -1/2 (/ (sqrt 3) 2)) (* (/ (sqrt 3) 2) -1/2))))))))
* [enter]simplify:  Simplifying (+ (* -1/2 (/ (sqrt 3) 2)) (* (/ (sqrt 3) 2) -1/2))
* * [misc]simplify:  iters left: 6 (8 enodes)
* * [misc]simplify:  iters left: 5 (14 enodes)
* * [misc]simplify:  iters left: 4 (27 enodes)
* * [misc]simplify:  iters left: 3 (31 enodes)
* * [misc]simplify:  iters left: 2 (38 enodes)
* * [misc]simplify:  iters left: 1 (49 enodes)
* [exit]simplify:  Simplified to (* -1/2 (sqrt 3))
* [misc]simplify:  Simplified (2 1 2 2 2 2) to (λ () (im (+.c (complex 5 (/ (* 4 (sqrt 3)) 2)) (*.c (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))) (+.c (complex 6 (/ (* (sqrt 3) -2) 2)) (complex -1/2 (* -1/2 (sqrt 3))))))))
* * * * [misc]progress:  [ 2 / 6 ] simplifiying candidate #<alt (λ () (im (+.c (complex 5 (/ (* 4 (sqrt 3)) 2)) (*.c (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))) (+.c (complex 6 (/ (* (sqrt 3) -2) 2)) (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))))))))>
* * * * [misc]progress:  [ 3 / 6 ] simplifiying candidate #<alt (λ () (im (+.c (complex 5 (/ (* 4 (sqrt 3)) 2)) (*.c (complex (- (* -1/2 -1/2) (* (/ (sqrt 3) 2) (/ (sqrt 3) 2))) (+ (* -1/2 (/ (sqrt 3) 2)) (* (/ (sqrt 3) 2) -1/2))) (+.c (complex 6 (/ (* (sqrt 3) -2) 2)) (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))))))))>
* [enter]simplify:  Simplifying (- (* -1/2 -1/2) (* (/ (sqrt 3) 2) (/ (sqrt 3) 2)))
* * [misc]simplify:  iters left: 6 (8 enodes)
* * [misc]simplify:  iters left: 5 (19 enodes)
* * [misc]simplify:  iters left: 4 (35 enodes)
* * [misc]simplify:  iters left: 3 (66 enodes)
* * [misc]simplify:  iters left: 2 (133 enodes)
* * [misc]simplify:  iters left: 1 (181 enodes)
* [exit]simplify:  Simplified to -1/2
* [misc]simplify:  Simplified (2 1 2 1 1) to (λ () (im (+.c (complex 5 (/ (* 4 (sqrt 3)) 2)) (*.c (complex -1/2 (+ (* -1/2 (/ (sqrt 3) 2)) (* (/ (sqrt 3) 2) -1/2))) (+.c (complex 6 (/ (* (sqrt 3) -2) 2)) (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))))))))
* [enter]simplify:  Simplifying (+ (* -1/2 (/ (sqrt 3) 2)) (* (/ (sqrt 3) 2) -1/2))
* * [misc]simplify:  iters left: 6 (8 enodes)
* * [misc]simplify:  iters left: 5 (14 enodes)
* * [misc]simplify:  iters left: 4 (27 enodes)
* * [misc]simplify:  iters left: 3 (31 enodes)
* * [misc]simplify:  iters left: 2 (38 enodes)
* * [misc]simplify:  iters left: 1 (49 enodes)
* [exit]simplify:  Simplified to (* -1/2 (sqrt 3))
* [misc]simplify:  Simplified (2 1 2 1 2) to (λ () (im (+.c (complex 5 (/ (* 4 (sqrt 3)) 2)) (*.c (complex -1/2 (* -1/2 (sqrt 3))) (+.c (complex 6 (/ (* (sqrt 3) -2) 2)) (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))))))))
* * * * [misc]progress:  [ 4 / 6 ] simplifiying candidate #<alt (λ () (im (+.c (complex 5 (/ (* 4 (sqrt 3)) 2)) (*.c (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))) (+.c (complex 6 (/ (* (sqrt 3) -2) 2)) (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))))))))>
* * * * [misc]progress:  [ 5 / 6 ] simplifiying candidate #<alt (λ () (im (+.c (complex 5 (/ (* 4 (sqrt 3)) 2)) (*.c (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))) (+.c (complex 6 (/ (* (sqrt 3) -2) 2)) (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))))))))>
* [enter]simplify:  Simplifying (im (+.c (complex 5 (/ (* 4 (sqrt 3)) 2)) (*.c (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))) (+.c (complex 6 (/ (* (sqrt 3) -2) 2)) (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2)))))))
* * [misc]simplify:  iters left: 6 (21 enodes)
* * [misc]simplify:  iters left: 5 (46 enodes)
* * [misc]simplify:  iters left: 4 (110 enodes)
* * [misc]simplify:  iters left: 3 (331 enodes)
* [exit]simplify:  Simplified to (im (+.c (*.c (complex (+ (/ -3/2 2) 1/4) (+ (* -1/4 (sqrt 3)) (* -1/4 (sqrt 3)))) (complex (+ 25/4 (/ -3/2 2)) (+ (* -1/4 (sqrt 3)) (+ (* -1/4 (sqrt 3)) (/ (sqrt 3) -1))))) (complex 5 (* 2 (sqrt 3)))))
* [misc]simplify:  Simplified (2) to (λ () (im (+.c (*.c (complex (+ (/ -3/2 2) 1/4) (+ (* -1/4 (sqrt 3)) (* -1/4 (sqrt 3)))) (complex (+ 25/4 (/ -3/2 2)) (+ (* -1/4 (sqrt 3)) (+ (* -1/4 (sqrt 3)) (/ (sqrt 3) -1))))) (complex 5 (* 2 (sqrt 3))))))
* * * * [misc]progress:  [ 6 / 6 ] simplifiying candidate #<alt (λ () (im (+.c (complex 5 (/ (* 4 (sqrt 3)) 2)) (*.c (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))) (+.c (complex 6 (/ (* (sqrt 3) -2) 2)) (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))))))))>
* [enter]simplify:  Simplifying (im (+.c (complex 5 (/ (* 4 (sqrt 3)) 2)) (*.c (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))) (+.c (complex 6 (/ (* (sqrt 3) -2) 2)) (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2)))))))
* * [misc]simplify:  iters left: 6 (21 enodes)
* * [misc]simplify:  iters left: 5 (46 enodes)
* * [misc]simplify:  iters left: 4 (110 enodes)
* * [misc]simplify:  iters left: 3 (331 enodes)
* [exit]simplify:  Simplified to (im (+.c (*.c (complex (+ (/ -3/2 2) 1/4) (+ (* -1/4 (sqrt 3)) (* -1/4 (sqrt 3)))) (complex (+ 25/4 (/ -3/2 2)) (+ (* -1/4 (sqrt 3)) (+ (* -1/4 (sqrt 3)) (/ (sqrt 3) -1))))) (complex 5 (* 2 (sqrt 3)))))
* [misc]simplify:  Simplified (2) to (λ () (im (+.c (*.c (complex (+ (/ -3/2 2) 1/4) (+ (* -1/4 (sqrt 3)) (* -1/4 (sqrt 3)))) (complex (+ 25/4 (/ -3/2 2)) (+ (* -1/4 (sqrt 3)) (+ (* -1/4 (sqrt 3)) (/ (sqrt 3) -1))))) (complex 5 (* 2 (sqrt 3))))))
* * * [misc]progress:  adding candidates to table
* [misc]progress:  [Phase 3 of 3] Extracting.
* [enter]simplify:  Simplifying (im (+.c (complex 5 (/ (* 4 (sqrt 3)) 2)) (*.c (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))) (+.c (complex 6 (/ (* (sqrt 3) -2) 2)) (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2)))))))
* * [misc]simplify:  iters left: 6 (21 enodes)
* * [misc]simplify:  iters left: 5 (26 enodes)
* [exit]simplify:  Simplified to (im (+.c (*.c (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))) (+.c (*.c (complex -1/2 (/ (sqrt 3) 2)) (complex -1/2 (/ (sqrt 3) 2))) (complex 6 (/ (* (sqrt 3) -2) 2)))) (complex 5 (/ (* (sqrt 3) 4) 2))))
* * * * [misc]points:  Sampling 8000 additional inputs, on iter 0 have 0 / 8000
* * * * [misc]points:  Computing exacts on every 500 of 8000 points to ramp up precision
* * * * [misc]points:  Setting MPFR precision to 832
* * * * [misc]points:  Setting MPFR precision to 1088
* * * * [misc]points:  Computing exacts on every 250 of 8000 points to ramp up precision
* * * * [misc]points:  Setting MPFR precision to 832
* * * * [misc]points:  Setting MPFR precision to 1088
* * * * [misc]points:  Computing exacts on every 125 of 8000 points to ramp up precision
* * * * [misc]points:  Setting MPFR precision to 832
* * * * [misc]points:  Setting MPFR precision to 1088
* * * * [misc]points:  Computing exacts on every 62 of 8000 points to ramp up precision
* * * * [misc]points:  Setting MPFR precision to 832
* * * * [misc]points:  Setting MPFR precision to 1088
* * * * [misc]points:  Computing exacts on every 31 of 8000 points to ramp up precision
* * * * [misc]points:  Setting MPFR precision to 832
* * * * [misc]points:  Setting MPFR precision to 1088
* * * * [misc]points:  Computing exacts on every 15 of 8000 points to ramp up precision
* * * * [misc]points:  Setting MPFR precision to 832
* * * * [misc]points:  Setting MPFR precision to 1088
* * * * [misc]points:  Computing exacts on every 7 of 8000 points to ramp up precision
* * * * [misc]points:  Setting MPFR precision to 832
* * * * [misc]points:  Setting MPFR precision to 1088
* * * * [misc]points:  Computing exacts on every 3 of 8000 points to ramp up precision
* * * * [misc]points:  Setting MPFR precision to 832
* * * * [misc]points:  Setting MPFR precision to 1088
* * * * [misc]points:  Computing exacts for 8000 points
* * * * [misc]points:  Setting MPFR precision to 832
* * * * [misc]points:  Setting MPFR precision to 1088
* * * * [misc]points:  Filtering points with unrepresentable outputs
* * * * [exit]points:  Sampled 8000 points with exact outputs