Isotropic LOD (LOD)
(FPCore (w h d dX.u dX.v dX.w dY.u dY.v dY.w)
:precision binary32
(let* ((t_0 (* (floor w) dY.u))
(t_1 (* (floor h) dY.v))
(t_2 (* (floor h) dX.v))
(t_3 (* (floor d) dY.w))
(t_4 (* (floor d) dX.w))
(t_5 (* (floor w) dX.u)))
(log2
(sqrt
(fmax
(+ (+ (* t_5 t_5) (* t_2 t_2)) (* t_4 t_4))
(+ (+ (* t_0 t_0) (* t_1 t_1)) (* t_3 t_3)))))))
float code(float w, float h, float d, float dX_46_u, float dX_46_v, float dX_46_w, float dY_46_u, float dY_46_v, float dY_46_w) {
float t_0 = floorf(w) * dY_46_u;
float t_1 = floorf(h) * dY_46_v;
float t_2 = floorf(h) * dX_46_v;
float t_3 = floorf(d) * dY_46_w;
float t_4 = floorf(d) * dX_46_w;
float t_5 = floorf(w) * dX_46_u;
return log2f(sqrtf(fmaxf((((t_5 * t_5) + (t_2 * t_2)) + (t_4 * t_4)), (((t_0 * t_0) + (t_1 * t_1)) + (t_3 * t_3)))));
}
function code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = Float32(floor(w) * dY_46_u) t_1 = Float32(floor(h) * dY_46_v) t_2 = Float32(floor(h) * dX_46_v) t_3 = Float32(floor(d) * dY_46_w) t_4 = Float32(floor(d) * dX_46_w) t_5 = Float32(floor(w) * dX_46_u) return log2(sqrt(((Float32(Float32(Float32(t_5 * t_5) + Float32(t_2 * t_2)) + Float32(t_4 * t_4)) != Float32(Float32(Float32(t_5 * t_5) + Float32(t_2 * t_2)) + Float32(t_4 * t_4))) ? Float32(Float32(Float32(t_0 * t_0) + Float32(t_1 * t_1)) + Float32(t_3 * t_3)) : ((Float32(Float32(Float32(t_0 * t_0) + Float32(t_1 * t_1)) + Float32(t_3 * t_3)) != Float32(Float32(Float32(t_0 * t_0) + Float32(t_1 * t_1)) + Float32(t_3 * t_3))) ? Float32(Float32(Float32(t_5 * t_5) + Float32(t_2 * t_2)) + Float32(t_4 * t_4)) : max(Float32(Float32(Float32(t_5 * t_5) + Float32(t_2 * t_2)) + Float32(t_4 * t_4)), Float32(Float32(Float32(t_0 * t_0) + Float32(t_1 * t_1)) + Float32(t_3 * t_3))))))) end
function tmp = code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = floor(w) * dY_46_u; t_1 = floor(h) * dY_46_v; t_2 = floor(h) * dX_46_v; t_3 = floor(d) * dY_46_w; t_4 = floor(d) * dX_46_w; t_5 = floor(w) * dX_46_u; tmp = log2(sqrt(max((((t_5 * t_5) + (t_2 * t_2)) + (t_4 * t_4)), (((t_0 * t_0) + (t_1 * t_1)) + (t_3 * t_3))))); end
\begin{array}{l}
\\
\begin{array}{l}
t_0 := \left\lfloorw\right\rfloor \cdot dY.u\\
t_1 := \left\lfloorh\right\rfloor \cdot dY.v\\
t_2 := \left\lfloorh\right\rfloor \cdot dX.v\\
t_3 := \left\lfloord\right\rfloor \cdot dY.w\\
t_4 := \left\lfloord\right\rfloor \cdot dX.w\\
t_5 := \left\lfloorw\right\rfloor \cdot dX.u\\
\log_{2} \left(\sqrt{\mathsf{max}\left(\left(t_5 \cdot t_5 + t_2 \cdot t_2\right) + t_4 \cdot t_4, \left(t_0 \cdot t_0 + t_1 \cdot t_1\right) + t_3 \cdot t_3\right)}\right)
\end{array}
\end{array}
Sampling outcomes in binary32 precision:
Herbie found 13 alternatives:
| Alternative | Accuracy | Speedup |
|---|
(FPCore (w h d dX.u dX.v dX.w dY.u dY.v dY.w)
:precision binary32
(let* ((t_0 (* (floor w) dY.u))
(t_1 (* (floor h) dY.v))
(t_2 (* (floor h) dX.v))
(t_3 (* (floor d) dY.w))
(t_4 (* (floor d) dX.w))
(t_5 (* (floor w) dX.u)))
(log2
(sqrt
(fmax
(+ (+ (* t_5 t_5) (* t_2 t_2)) (* t_4 t_4))
(+ (+ (* t_0 t_0) (* t_1 t_1)) (* t_3 t_3)))))))
float code(float w, float h, float d, float dX_46_u, float dX_46_v, float dX_46_w, float dY_46_u, float dY_46_v, float dY_46_w) {
float t_0 = floorf(w) * dY_46_u;
float t_1 = floorf(h) * dY_46_v;
float t_2 = floorf(h) * dX_46_v;
float t_3 = floorf(d) * dY_46_w;
float t_4 = floorf(d) * dX_46_w;
float t_5 = floorf(w) * dX_46_u;
return log2f(sqrtf(fmaxf((((t_5 * t_5) + (t_2 * t_2)) + (t_4 * t_4)), (((t_0 * t_0) + (t_1 * t_1)) + (t_3 * t_3)))));
}
function code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = Float32(floor(w) * dY_46_u) t_1 = Float32(floor(h) * dY_46_v) t_2 = Float32(floor(h) * dX_46_v) t_3 = Float32(floor(d) * dY_46_w) t_4 = Float32(floor(d) * dX_46_w) t_5 = Float32(floor(w) * dX_46_u) return log2(sqrt(((Float32(Float32(Float32(t_5 * t_5) + Float32(t_2 * t_2)) + Float32(t_4 * t_4)) != Float32(Float32(Float32(t_5 * t_5) + Float32(t_2 * t_2)) + Float32(t_4 * t_4))) ? Float32(Float32(Float32(t_0 * t_0) + Float32(t_1 * t_1)) + Float32(t_3 * t_3)) : ((Float32(Float32(Float32(t_0 * t_0) + Float32(t_1 * t_1)) + Float32(t_3 * t_3)) != Float32(Float32(Float32(t_0 * t_0) + Float32(t_1 * t_1)) + Float32(t_3 * t_3))) ? Float32(Float32(Float32(t_5 * t_5) + Float32(t_2 * t_2)) + Float32(t_4 * t_4)) : max(Float32(Float32(Float32(t_5 * t_5) + Float32(t_2 * t_2)) + Float32(t_4 * t_4)), Float32(Float32(Float32(t_0 * t_0) + Float32(t_1 * t_1)) + Float32(t_3 * t_3))))))) end
function tmp = code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = floor(w) * dY_46_u; t_1 = floor(h) * dY_46_v; t_2 = floor(h) * dX_46_v; t_3 = floor(d) * dY_46_w; t_4 = floor(d) * dX_46_w; t_5 = floor(w) * dX_46_u; tmp = log2(sqrt(max((((t_5 * t_5) + (t_2 * t_2)) + (t_4 * t_4)), (((t_0 * t_0) + (t_1 * t_1)) + (t_3 * t_3))))); end
\begin{array}{l}
\\
\begin{array}{l}
t_0 := \left\lfloorw\right\rfloor \cdot dY.u\\
t_1 := \left\lfloorh\right\rfloor \cdot dY.v\\
t_2 := \left\lfloorh\right\rfloor \cdot dX.v\\
t_3 := \left\lfloord\right\rfloor \cdot dY.w\\
t_4 := \left\lfloord\right\rfloor \cdot dX.w\\
t_5 := \left\lfloorw\right\rfloor \cdot dX.u\\
\log_{2} \left(\sqrt{\mathsf{max}\left(\left(t_5 \cdot t_5 + t_2 \cdot t_2\right) + t_4 \cdot t_4, \left(t_0 \cdot t_0 + t_1 \cdot t_1\right) + t_3 \cdot t_3\right)}\right)
\end{array}
\end{array}
NOTE: dX.u should be positive before calling this function
(FPCore (w h d dX.u dX.v dX.w dY.u dY.v dY.w)
:precision binary32
(let* ((t_0 (* (floor d) dX.w))
(t_1 (* (floor h) dX.v))
(t_2 (* (floor d) dY.w)))
(if (<= dX.u 1.899999976158142)
(log2
(sqrt
(fmax
(pow (hypot t_0 t_1) 2.0)
(pow (hypot t_2 (hypot (* (floor w) dY.u) (* (floor h) dY.v))) 2.0))))
(log2
(sqrt
(fmax
(pow (hypot t_0 (hypot (* (floor w) dX.u) t_1)) 2.0)
(fma (pow (floor h) 2.0) (* dY.v dY.v) (pow t_2 2.0))))))))dX.u = abs(dX.u);
float code(float w, float h, float d, float dX_46_u, float dX_46_v, float dX_46_w, float dY_46_u, float dY_46_v, float dY_46_w) {
float t_0 = floorf(d) * dX_46_w;
float t_1 = floorf(h) * dX_46_v;
float t_2 = floorf(d) * dY_46_w;
float tmp;
if (dX_46_u <= 1.899999976158142f) {
tmp = log2f(sqrtf(fmaxf(powf(hypotf(t_0, t_1), 2.0f), powf(hypotf(t_2, hypotf((floorf(w) * dY_46_u), (floorf(h) * dY_46_v))), 2.0f))));
} else {
tmp = log2f(sqrtf(fmaxf(powf(hypotf(t_0, hypotf((floorf(w) * dX_46_u), t_1)), 2.0f), fmaf(powf(floorf(h), 2.0f), (dY_46_v * dY_46_v), powf(t_2, 2.0f)))));
}
return tmp;
}
dX.u = abs(dX.u) function code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = Float32(floor(d) * dX_46_w) t_1 = Float32(floor(h) * dX_46_v) t_2 = Float32(floor(d) * dY_46_w) tmp = Float32(0.0) if (dX_46_u <= Float32(1.899999976158142)) tmp = log2(sqrt((((hypot(t_0, t_1) ^ Float32(2.0)) != (hypot(t_0, t_1) ^ Float32(2.0))) ? (hypot(t_2, hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0)) : (((hypot(t_2, hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0)) != (hypot(t_2, hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0))) ? (hypot(t_0, t_1) ^ Float32(2.0)) : max((hypot(t_0, t_1) ^ Float32(2.0)), (hypot(t_2, hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0))))))); else tmp = log2(sqrt((((hypot(t_0, hypot(Float32(floor(w) * dX_46_u), t_1)) ^ Float32(2.0)) != (hypot(t_0, hypot(Float32(floor(w) * dX_46_u), t_1)) ^ Float32(2.0))) ? fma((floor(h) ^ Float32(2.0)), Float32(dY_46_v * dY_46_v), (t_2 ^ Float32(2.0))) : ((fma((floor(h) ^ Float32(2.0)), Float32(dY_46_v * dY_46_v), (t_2 ^ Float32(2.0))) != fma((floor(h) ^ Float32(2.0)), Float32(dY_46_v * dY_46_v), (t_2 ^ Float32(2.0)))) ? (hypot(t_0, hypot(Float32(floor(w) * dX_46_u), t_1)) ^ Float32(2.0)) : max((hypot(t_0, hypot(Float32(floor(w) * dX_46_u), t_1)) ^ Float32(2.0)), fma((floor(h) ^ Float32(2.0)), Float32(dY_46_v * dY_46_v), (t_2 ^ Float32(2.0)))))))); end return tmp end
\begin{array}{l}
dX.u = |dX.u|\\
\\
\begin{array}{l}
t_0 := \left\lfloord\right\rfloor \cdot dX.w\\
t_1 := \left\lfloorh\right\rfloor \cdot dX.v\\
t_2 := \left\lfloord\right\rfloor \cdot dY.w\\
\mathbf{if}\;dX.u \leq 1.899999976158142:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({\left(\mathsf{hypot}\left(t_0, t_1\right)\right)}^{2}, {\left(\mathsf{hypot}\left(t_2, \mathsf{hypot}\left(\left\lfloorw\right\rfloor \cdot dY.u, \left\lfloorh\right\rfloor \cdot dY.v\right)\right)\right)}^{2}\right)}\right)\\
\mathbf{else}:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({\left(\mathsf{hypot}\left(t_0, \mathsf{hypot}\left(\left\lfloorw\right\rfloor \cdot dX.u, t_1\right)\right)\right)}^{2}, \mathsf{fma}\left({\left(\left\lfloorh\right\rfloor\right)}^{2}, dY.v \cdot dY.v, {t_2}^{2}\right)\right)}\right)\\
\end{array}
\end{array}
if dX.u < 1.89999998Initial program 66.8%
expm1-log1p-u66.1%
expm1-udef66.1%
Applied egg-rr66.1%
expm1-def66.1%
expm1-log1p66.8%
*-commutative66.8%
*-commutative66.8%
*-commutative66.8%
Simplified66.8%
Taylor expanded in dX.u around 0 62.5%
if 1.89999998 < dX.u Initial program 58.1%
expm1-log1p-u57.5%
expm1-udef57.5%
Applied egg-rr57.5%
expm1-def57.5%
expm1-log1p58.1%
*-commutative58.1%
*-commutative58.1%
*-commutative58.1%
Simplified58.1%
Taylor expanded in dY.u around 0 58.0%
*-commutative58.0%
fma-def58.0%
unpow258.0%
*-commutative58.0%
unpow258.0%
unpow258.0%
swap-sqr58.0%
unpow258.0%
Simplified58.0%
Final simplification61.3%
NOTE: dX.u should be positive before calling this function
(FPCore (w h d dX.u dX.v dX.w dY.u dY.v dY.w)
:precision binary32
(let* ((t_0 (* (floor w) dY.u))
(t_1 (* (floor h) dY.v))
(t_2 (* (floor h) dX.v))
(t_3 (* (floor d) dY.w))
(t_4 (* (floor d) dX.w))
(t_5 (* (floor w) dX.u)))
(if (<=
(fmax
(+ (+ (* t_5 t_5) (* t_2 t_2)) (* t_4 t_4))
(+ (+ (* t_0 t_0) (* t_1 t_1)) (* t_3 t_3)))
INFINITY)
(log2
(sqrt
(fmax
(pow (hypot t_4 (hypot t_5 t_2)) 2.0)
(pow (hypot t_3 (hypot t_0 t_1)) 2.0))))
(log2
(sqrt (fmax (pow t_4 2.0) (* (pow (floor h) 2.0) (* dY.v dY.v))))))))dX.u = abs(dX.u);
float code(float w, float h, float d, float dX_46_u, float dX_46_v, float dX_46_w, float dY_46_u, float dY_46_v, float dY_46_w) {
float t_0 = floorf(w) * dY_46_u;
float t_1 = floorf(h) * dY_46_v;
float t_2 = floorf(h) * dX_46_v;
float t_3 = floorf(d) * dY_46_w;
float t_4 = floorf(d) * dX_46_w;
float t_5 = floorf(w) * dX_46_u;
float tmp;
if (fmaxf((((t_5 * t_5) + (t_2 * t_2)) + (t_4 * t_4)), (((t_0 * t_0) + (t_1 * t_1)) + (t_3 * t_3))) <= ((float) INFINITY)) {
tmp = log2f(sqrtf(fmaxf(powf(hypotf(t_4, hypotf(t_5, t_2)), 2.0f), powf(hypotf(t_3, hypotf(t_0, t_1)), 2.0f))));
} else {
tmp = log2f(sqrtf(fmaxf(powf(t_4, 2.0f), (powf(floorf(h), 2.0f) * (dY_46_v * dY_46_v)))));
}
return tmp;
}
dX.u = abs(dX.u) function code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = Float32(floor(w) * dY_46_u) t_1 = Float32(floor(h) * dY_46_v) t_2 = Float32(floor(h) * dX_46_v) t_3 = Float32(floor(d) * dY_46_w) t_4 = Float32(floor(d) * dX_46_w) t_5 = Float32(floor(w) * dX_46_u) tmp = Float32(0.0) if (((Float32(Float32(Float32(t_5 * t_5) + Float32(t_2 * t_2)) + Float32(t_4 * t_4)) != Float32(Float32(Float32(t_5 * t_5) + Float32(t_2 * t_2)) + Float32(t_4 * t_4))) ? Float32(Float32(Float32(t_0 * t_0) + Float32(t_1 * t_1)) + Float32(t_3 * t_3)) : ((Float32(Float32(Float32(t_0 * t_0) + Float32(t_1 * t_1)) + Float32(t_3 * t_3)) != Float32(Float32(Float32(t_0 * t_0) + Float32(t_1 * t_1)) + Float32(t_3 * t_3))) ? Float32(Float32(Float32(t_5 * t_5) + Float32(t_2 * t_2)) + Float32(t_4 * t_4)) : max(Float32(Float32(Float32(t_5 * t_5) + Float32(t_2 * t_2)) + Float32(t_4 * t_4)), Float32(Float32(Float32(t_0 * t_0) + Float32(t_1 * t_1)) + Float32(t_3 * t_3))))) <= Float32(Inf)) tmp = log2(sqrt((((hypot(t_4, hypot(t_5, t_2)) ^ Float32(2.0)) != (hypot(t_4, hypot(t_5, t_2)) ^ Float32(2.0))) ? (hypot(t_3, hypot(t_0, t_1)) ^ Float32(2.0)) : (((hypot(t_3, hypot(t_0, t_1)) ^ Float32(2.0)) != (hypot(t_3, hypot(t_0, t_1)) ^ Float32(2.0))) ? (hypot(t_4, hypot(t_5, t_2)) ^ Float32(2.0)) : max((hypot(t_4, hypot(t_5, t_2)) ^ Float32(2.0)), (hypot(t_3, hypot(t_0, t_1)) ^ Float32(2.0))))))); else tmp = log2(sqrt((((t_4 ^ Float32(2.0)) != (t_4 ^ Float32(2.0))) ? Float32((floor(h) ^ Float32(2.0)) * Float32(dY_46_v * dY_46_v)) : ((Float32((floor(h) ^ Float32(2.0)) * Float32(dY_46_v * dY_46_v)) != Float32((floor(h) ^ Float32(2.0)) * Float32(dY_46_v * dY_46_v))) ? (t_4 ^ Float32(2.0)) : max((t_4 ^ Float32(2.0)), Float32((floor(h) ^ Float32(2.0)) * Float32(dY_46_v * dY_46_v))))))); end return tmp end
dX.u = abs(dX.u) function tmp_2 = code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = floor(w) * dY_46_u; t_1 = floor(h) * dY_46_v; t_2 = floor(h) * dX_46_v; t_3 = floor(d) * dY_46_w; t_4 = floor(d) * dX_46_w; t_5 = floor(w) * dX_46_u; tmp = single(0.0); if (max((((t_5 * t_5) + (t_2 * t_2)) + (t_4 * t_4)), (((t_0 * t_0) + (t_1 * t_1)) + (t_3 * t_3))) <= single(Inf)) tmp = log2(sqrt(max((hypot(t_4, hypot(t_5, t_2)) ^ single(2.0)), (hypot(t_3, hypot(t_0, t_1)) ^ single(2.0))))); else tmp = log2(sqrt(max((t_4 ^ single(2.0)), ((floor(h) ^ single(2.0)) * (dY_46_v * dY_46_v))))); end tmp_2 = tmp; end
\begin{array}{l}
dX.u = |dX.u|\\
\\
\begin{array}{l}
t_0 := \left\lfloorw\right\rfloor \cdot dY.u\\
t_1 := \left\lfloorh\right\rfloor \cdot dY.v\\
t_2 := \left\lfloorh\right\rfloor \cdot dX.v\\
t_3 := \left\lfloord\right\rfloor \cdot dY.w\\
t_4 := \left\lfloord\right\rfloor \cdot dX.w\\
t_5 := \left\lfloorw\right\rfloor \cdot dX.u\\
\mathbf{if}\;\mathsf{max}\left(\left(t_5 \cdot t_5 + t_2 \cdot t_2\right) + t_4 \cdot t_4, \left(t_0 \cdot t_0 + t_1 \cdot t_1\right) + t_3 \cdot t_3\right) \leq \infty:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({\left(\mathsf{hypot}\left(t_4, \mathsf{hypot}\left(t_5, t_2\right)\right)\right)}^{2}, {\left(\mathsf{hypot}\left(t_3, \mathsf{hypot}\left(t_0, t_1\right)\right)\right)}^{2}\right)}\right)\\
\mathbf{else}:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({t_4}^{2}, {\left(\left\lfloorh\right\rfloor\right)}^{2} \cdot \left(dY.v \cdot dY.v\right)\right)}\right)\\
\end{array}
\end{array}
if (fmax.f32 (+.f32 (+.f32 (*.f32 (*.f32 (floor.f32 w) dX.u) (*.f32 (floor.f32 w) dX.u)) (*.f32 (*.f32 (floor.f32 h) dX.v) (*.f32 (floor.f32 h) dX.v))) (*.f32 (*.f32 (floor.f32 d) dX.w) (*.f32 (floor.f32 d) dX.w))) (+.f32 (+.f32 (*.f32 (*.f32 (floor.f32 w) dY.u) (*.f32 (floor.f32 w) dY.u)) (*.f32 (*.f32 (floor.f32 h) dY.v) (*.f32 (floor.f32 h) dY.v))) (*.f32 (*.f32 (floor.f32 d) dY.w) (*.f32 (floor.f32 d) dY.w)))) < +inf.0Initial program 64.5%
expm1-log1p-u63.8%
expm1-udef63.8%
Applied egg-rr63.8%
expm1-def63.8%
expm1-log1p64.5%
*-commutative64.5%
*-commutative64.5%
*-commutative64.5%
Simplified64.5%
if +inf.0 < (fmax.f32 (+.f32 (+.f32 (*.f32 (*.f32 (floor.f32 w) dX.u) (*.f32 (floor.f32 w) dX.u)) (*.f32 (*.f32 (floor.f32 h) dX.v) (*.f32 (floor.f32 h) dX.v))) (*.f32 (*.f32 (floor.f32 d) dX.w) (*.f32 (floor.f32 d) dX.w))) (+.f32 (+.f32 (*.f32 (*.f32 (floor.f32 w) dY.u) (*.f32 (floor.f32 w) dY.u)) (*.f32 (*.f32 (floor.f32 h) dY.v) (*.f32 (floor.f32 h) dY.v))) (*.f32 (*.f32 (floor.f32 d) dY.w) (*.f32 (floor.f32 d) dY.w)))) Initial program 64.5%
expm1-log1p-u63.8%
expm1-udef63.8%
Applied egg-rr63.8%
expm1-def63.8%
expm1-log1p64.5%
*-commutative64.5%
*-commutative64.5%
*-commutative64.5%
Simplified64.5%
Taylor expanded in dY.v around inf 53.4%
*-commutative53.4%
unpow253.4%
Simplified53.4%
Taylor expanded in dX.w around inf 38.0%
unpow252.5%
unpow252.5%
swap-sqr52.5%
unpow252.5%
Simplified38.0%
Final simplification64.5%
NOTE: dX.u should be positive before calling this function
(FPCore (w h d dX.u dX.v dX.w dY.u dY.v dY.w)
:precision binary32
(let* ((t_0 (* (floor d) dX.w))
(t_1 (* (floor h) dX.v))
(t_2 (* (floor d) dY.w)))
(if (<= dX.u 200000000.0)
(log2
(sqrt
(fmax
(pow (hypot t_0 t_1) 2.0)
(pow (hypot t_2 (hypot (* (floor w) dY.u) (* (floor h) dY.v))) 2.0))))
(log2
(pow
(sqrt
(sqrt
(fmax
(pow (hypot t_0 (hypot (* (floor w) dX.u) t_1)) 2.0)
(pow t_2 2.0))))
2.0)))))dX.u = abs(dX.u);
float code(float w, float h, float d, float dX_46_u, float dX_46_v, float dX_46_w, float dY_46_u, float dY_46_v, float dY_46_w) {
float t_0 = floorf(d) * dX_46_w;
float t_1 = floorf(h) * dX_46_v;
float t_2 = floorf(d) * dY_46_w;
float tmp;
if (dX_46_u <= 200000000.0f) {
tmp = log2f(sqrtf(fmaxf(powf(hypotf(t_0, t_1), 2.0f), powf(hypotf(t_2, hypotf((floorf(w) * dY_46_u), (floorf(h) * dY_46_v))), 2.0f))));
} else {
tmp = log2f(powf(sqrtf(sqrtf(fmaxf(powf(hypotf(t_0, hypotf((floorf(w) * dX_46_u), t_1)), 2.0f), powf(t_2, 2.0f)))), 2.0f));
}
return tmp;
}
dX.u = abs(dX.u) function code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = Float32(floor(d) * dX_46_w) t_1 = Float32(floor(h) * dX_46_v) t_2 = Float32(floor(d) * dY_46_w) tmp = Float32(0.0) if (dX_46_u <= Float32(200000000.0)) tmp = log2(sqrt((((hypot(t_0, t_1) ^ Float32(2.0)) != (hypot(t_0, t_1) ^ Float32(2.0))) ? (hypot(t_2, hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0)) : (((hypot(t_2, hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0)) != (hypot(t_2, hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0))) ? (hypot(t_0, t_1) ^ Float32(2.0)) : max((hypot(t_0, t_1) ^ Float32(2.0)), (hypot(t_2, hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0))))))); else tmp = log2((sqrt(sqrt((((hypot(t_0, hypot(Float32(floor(w) * dX_46_u), t_1)) ^ Float32(2.0)) != (hypot(t_0, hypot(Float32(floor(w) * dX_46_u), t_1)) ^ Float32(2.0))) ? (t_2 ^ Float32(2.0)) : (((t_2 ^ Float32(2.0)) != (t_2 ^ Float32(2.0))) ? (hypot(t_0, hypot(Float32(floor(w) * dX_46_u), t_1)) ^ Float32(2.0)) : max((hypot(t_0, hypot(Float32(floor(w) * dX_46_u), t_1)) ^ Float32(2.0)), (t_2 ^ Float32(2.0))))))) ^ Float32(2.0))); end return tmp end
dX.u = abs(dX.u) function tmp_2 = code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = floor(d) * dX_46_w; t_1 = floor(h) * dX_46_v; t_2 = floor(d) * dY_46_w; tmp = single(0.0); if (dX_46_u <= single(200000000.0)) tmp = log2(sqrt(max((hypot(t_0, t_1) ^ single(2.0)), (hypot(t_2, hypot((floor(w) * dY_46_u), (floor(h) * dY_46_v))) ^ single(2.0))))); else tmp = log2((sqrt(sqrt(max((hypot(t_0, hypot((floor(w) * dX_46_u), t_1)) ^ single(2.0)), (t_2 ^ single(2.0))))) ^ single(2.0))); end tmp_2 = tmp; end
\begin{array}{l}
dX.u = |dX.u|\\
\\
\begin{array}{l}
t_0 := \left\lfloord\right\rfloor \cdot dX.w\\
t_1 := \left\lfloorh\right\rfloor \cdot dX.v\\
t_2 := \left\lfloord\right\rfloor \cdot dY.w\\
\mathbf{if}\;dX.u \leq 200000000:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({\left(\mathsf{hypot}\left(t_0, t_1\right)\right)}^{2}, {\left(\mathsf{hypot}\left(t_2, \mathsf{hypot}\left(\left\lfloorw\right\rfloor \cdot dY.u, \left\lfloorh\right\rfloor \cdot dY.v\right)\right)\right)}^{2}\right)}\right)\\
\mathbf{else}:\\
\;\;\;\;\log_{2} \left({\left(\sqrt{\sqrt{\mathsf{max}\left({\left(\mathsf{hypot}\left(t_0, \mathsf{hypot}\left(\left\lfloorw\right\rfloor \cdot dX.u, t_1\right)\right)\right)}^{2}, {t_2}^{2}\right)}}\right)}^{2}\right)\\
\end{array}
\end{array}
if dX.u < 2e8Initial program 69.1%
expm1-log1p-u68.3%
expm1-udef68.3%
Applied egg-rr68.3%
expm1-def68.3%
expm1-log1p69.1%
*-commutative69.1%
*-commutative69.1%
*-commutative69.1%
Simplified69.1%
Taylor expanded in dX.u around 0 65.0%
if 2e8 < dX.u Initial program 47.1%
add-sqr-sqrt47.1%
pow247.1%
Applied egg-rr47.1%
Taylor expanded in dY.w around inf 48.0%
*-commutative47.9%
unpow247.9%
unpow247.9%
swap-sqr47.9%
unpow247.9%
Simplified48.0%
Final simplification61.5%
NOTE: dX.u should be positive before calling this function
(FPCore (w h d dX.u dX.v dX.w dY.u dY.v dY.w)
:precision binary32
(let* ((t_0 (* (floor d) dX.w)))
(if (<= dX.u 20.0)
(log2
(sqrt
(fmax
(pow t_0 2.0)
(pow
(hypot
(* (floor d) dY.w)
(hypot (* (floor w) dY.u) (* (floor h) dY.v)))
2.0))))
(log2
(sqrt
(fmax
(pow (hypot t_0 (hypot (* (floor w) dX.u) (* (floor h) dX.v))) 2.0)
(* (pow (floor h) 2.0) (* dY.v dY.v))))))))dX.u = abs(dX.u);
float code(float w, float h, float d, float dX_46_u, float dX_46_v, float dX_46_w, float dY_46_u, float dY_46_v, float dY_46_w) {
float t_0 = floorf(d) * dX_46_w;
float tmp;
if (dX_46_u <= 20.0f) {
tmp = log2f(sqrtf(fmaxf(powf(t_0, 2.0f), powf(hypotf((floorf(d) * dY_46_w), hypotf((floorf(w) * dY_46_u), (floorf(h) * dY_46_v))), 2.0f))));
} else {
tmp = log2f(sqrtf(fmaxf(powf(hypotf(t_0, hypotf((floorf(w) * dX_46_u), (floorf(h) * dX_46_v))), 2.0f), (powf(floorf(h), 2.0f) * (dY_46_v * dY_46_v)))));
}
return tmp;
}
dX.u = abs(dX.u) function code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = Float32(floor(d) * dX_46_w) tmp = Float32(0.0) if (dX_46_u <= Float32(20.0)) tmp = log2(sqrt((((t_0 ^ Float32(2.0)) != (t_0 ^ Float32(2.0))) ? (hypot(Float32(floor(d) * dY_46_w), hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0)) : (((hypot(Float32(floor(d) * dY_46_w), hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0)) != (hypot(Float32(floor(d) * dY_46_w), hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0))) ? (t_0 ^ Float32(2.0)) : max((t_0 ^ Float32(2.0)), (hypot(Float32(floor(d) * dY_46_w), hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0))))))); else tmp = log2(sqrt((((hypot(t_0, hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v))) ^ Float32(2.0)) != (hypot(t_0, hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v))) ^ Float32(2.0))) ? Float32((floor(h) ^ Float32(2.0)) * Float32(dY_46_v * dY_46_v)) : ((Float32((floor(h) ^ Float32(2.0)) * Float32(dY_46_v * dY_46_v)) != Float32((floor(h) ^ Float32(2.0)) * Float32(dY_46_v * dY_46_v))) ? (hypot(t_0, hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v))) ^ Float32(2.0)) : max((hypot(t_0, hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v))) ^ Float32(2.0)), Float32((floor(h) ^ Float32(2.0)) * Float32(dY_46_v * dY_46_v))))))); end return tmp end
dX.u = abs(dX.u) function tmp_2 = code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = floor(d) * dX_46_w; tmp = single(0.0); if (dX_46_u <= single(20.0)) tmp = log2(sqrt(max((t_0 ^ single(2.0)), (hypot((floor(d) * dY_46_w), hypot((floor(w) * dY_46_u), (floor(h) * dY_46_v))) ^ single(2.0))))); else tmp = log2(sqrt(max((hypot(t_0, hypot((floor(w) * dX_46_u), (floor(h) * dX_46_v))) ^ single(2.0)), ((floor(h) ^ single(2.0)) * (dY_46_v * dY_46_v))))); end tmp_2 = tmp; end
\begin{array}{l}
dX.u = |dX.u|\\
\\
\begin{array}{l}
t_0 := \left\lfloord\right\rfloor \cdot dX.w\\
\mathbf{if}\;dX.u \leq 20:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({t_0}^{2}, {\left(\mathsf{hypot}\left(\left\lfloord\right\rfloor \cdot dY.w, \mathsf{hypot}\left(\left\lfloorw\right\rfloor \cdot dY.u, \left\lfloorh\right\rfloor \cdot dY.v\right)\right)\right)}^{2}\right)}\right)\\
\mathbf{else}:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({\left(\mathsf{hypot}\left(t_0, \mathsf{hypot}\left(\left\lfloorw\right\rfloor \cdot dX.u, \left\lfloorh\right\rfloor \cdot dX.v\right)\right)\right)}^{2}, {\left(\left\lfloorh\right\rfloor\right)}^{2} \cdot \left(dY.v \cdot dY.v\right)\right)}\right)\\
\end{array}
\end{array}
if dX.u < 20Initial program 67.3%
expm1-log1p-u66.6%
expm1-udef66.6%
Applied egg-rr66.6%
expm1-def66.6%
expm1-log1p67.3%
*-commutative67.3%
*-commutative67.3%
*-commutative67.3%
Simplified67.3%
Taylor expanded in dX.w around inf 57.1%
unpow257.1%
unpow257.1%
swap-sqr57.1%
unpow257.1%
Simplified57.1%
if 20 < dX.u Initial program 56.2%
expm1-log1p-u55.5%
expm1-udef55.5%
Applied egg-rr55.5%
expm1-def55.5%
expm1-log1p56.2%
*-commutative56.2%
*-commutative56.2%
*-commutative56.2%
Simplified56.2%
Taylor expanded in dY.v around inf 54.1%
*-commutative54.1%
unpow254.1%
Simplified54.1%
Final simplification56.4%
NOTE: dX.u should be positive before calling this function
(FPCore (w h d dX.u dX.v dX.w dY.u dY.v dY.w)
:precision binary32
(if (<= dX.u 20.0)
(log2
(sqrt
(fmax
(pow (* (floor d) dX.w) 2.0)
(pow
(hypot (* (floor d) dY.w) (hypot (* (floor w) dY.u) (* (floor h) dY.v)))
2.0))))
(log2
(sqrt
(fmax
(pow (hypot (* (floor w) dX.u) (* (floor h) dX.v)) 2.0)
(* (pow (floor h) 2.0) (* dY.v dY.v)))))))dX.u = abs(dX.u);
float code(float w, float h, float d, float dX_46_u, float dX_46_v, float dX_46_w, float dY_46_u, float dY_46_v, float dY_46_w) {
float tmp;
if (dX_46_u <= 20.0f) {
tmp = log2f(sqrtf(fmaxf(powf((floorf(d) * dX_46_w), 2.0f), powf(hypotf((floorf(d) * dY_46_w), hypotf((floorf(w) * dY_46_u), (floorf(h) * dY_46_v))), 2.0f))));
} else {
tmp = log2f(sqrtf(fmaxf(powf(hypotf((floorf(w) * dX_46_u), (floorf(h) * dX_46_v)), 2.0f), (powf(floorf(h), 2.0f) * (dY_46_v * dY_46_v)))));
}
return tmp;
}
dX.u = abs(dX.u) function code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) tmp = Float32(0.0) if (dX_46_u <= Float32(20.0)) tmp = log2(sqrt((((Float32(floor(d) * dX_46_w) ^ Float32(2.0)) != (Float32(floor(d) * dX_46_w) ^ Float32(2.0))) ? (hypot(Float32(floor(d) * dY_46_w), hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0)) : (((hypot(Float32(floor(d) * dY_46_w), hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0)) != (hypot(Float32(floor(d) * dY_46_w), hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0))) ? (Float32(floor(d) * dX_46_w) ^ Float32(2.0)) : max((Float32(floor(d) * dX_46_w) ^ Float32(2.0)), (hypot(Float32(floor(d) * dY_46_w), hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0))))))); else tmp = log2(sqrt((((hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v)) ^ Float32(2.0)) != (hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v)) ^ Float32(2.0))) ? Float32((floor(h) ^ Float32(2.0)) * Float32(dY_46_v * dY_46_v)) : ((Float32((floor(h) ^ Float32(2.0)) * Float32(dY_46_v * dY_46_v)) != Float32((floor(h) ^ Float32(2.0)) * Float32(dY_46_v * dY_46_v))) ? (hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v)) ^ Float32(2.0)) : max((hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v)) ^ Float32(2.0)), Float32((floor(h) ^ Float32(2.0)) * Float32(dY_46_v * dY_46_v))))))); end return tmp end
dX.u = abs(dX.u) function tmp_2 = code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) tmp = single(0.0); if (dX_46_u <= single(20.0)) tmp = log2(sqrt(max(((floor(d) * dX_46_w) ^ single(2.0)), (hypot((floor(d) * dY_46_w), hypot((floor(w) * dY_46_u), (floor(h) * dY_46_v))) ^ single(2.0))))); else tmp = log2(sqrt(max((hypot((floor(w) * dX_46_u), (floor(h) * dX_46_v)) ^ single(2.0)), ((floor(h) ^ single(2.0)) * (dY_46_v * dY_46_v))))); end tmp_2 = tmp; end
\begin{array}{l}
dX.u = |dX.u|\\
\\
\begin{array}{l}
\mathbf{if}\;dX.u \leq 20:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({\left(\left\lfloord\right\rfloor \cdot dX.w\right)}^{2}, {\left(\mathsf{hypot}\left(\left\lfloord\right\rfloor \cdot dY.w, \mathsf{hypot}\left(\left\lfloorw\right\rfloor \cdot dY.u, \left\lfloorh\right\rfloor \cdot dY.v\right)\right)\right)}^{2}\right)}\right)\\
\mathbf{else}:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({\left(\mathsf{hypot}\left(\left\lfloorw\right\rfloor \cdot dX.u, \left\lfloorh\right\rfloor \cdot dX.v\right)\right)}^{2}, {\left(\left\lfloorh\right\rfloor\right)}^{2} \cdot \left(dY.v \cdot dY.v\right)\right)}\right)\\
\end{array}
\end{array}
if dX.u < 20Initial program 67.3%
expm1-log1p-u66.6%
expm1-udef66.6%
Applied egg-rr66.6%
expm1-def66.6%
expm1-log1p67.3%
*-commutative67.3%
*-commutative67.3%
*-commutative67.3%
Simplified67.3%
Taylor expanded in dX.w around inf 57.1%
unpow257.1%
unpow257.1%
swap-sqr57.1%
unpow257.1%
Simplified57.1%
if 20 < dX.u Initial program 56.2%
expm1-log1p-u55.5%
expm1-udef55.5%
Applied egg-rr55.5%
expm1-def55.5%
expm1-log1p56.2%
*-commutative56.2%
*-commutative56.2%
*-commutative56.2%
Simplified56.2%
Taylor expanded in dY.v around inf 54.1%
*-commutative54.1%
unpow254.1%
Simplified54.1%
Taylor expanded in dX.w around 0 52.1%
unpow147.7%
sqr-pow47.6%
metadata-eval47.6%
unpow1/247.6%
unpow247.6%
unpow247.6%
unswap-sqr47.6%
unpow247.6%
unpow247.6%
unswap-sqr47.6%
hypot-def47.6%
metadata-eval47.6%
Simplified52.1%
Final simplification55.9%
NOTE: dX.u should be positive before calling this function
(FPCore (w h d dX.u dX.v dX.w dY.u dY.v dY.w)
:precision binary32
(let* ((t_0 (* (floor d) dX.w)) (t_1 (* (floor d) dY.w)))
(if (<= dX.u 200000.0)
(log2
(sqrt
(fmax
(pow t_0 2.0)
(pow (hypot t_1 (hypot (* (floor w) dY.u) (* (floor h) dY.v))) 2.0))))
(log2
(sqrt
(fmax
(pow (hypot t_0 (hypot (* (floor w) dX.u) (* (floor h) dX.v))) 2.0)
(pow t_1 2.0)))))))dX.u = abs(dX.u);
float code(float w, float h, float d, float dX_46_u, float dX_46_v, float dX_46_w, float dY_46_u, float dY_46_v, float dY_46_w) {
float t_0 = floorf(d) * dX_46_w;
float t_1 = floorf(d) * dY_46_w;
float tmp;
if (dX_46_u <= 200000.0f) {
tmp = log2f(sqrtf(fmaxf(powf(t_0, 2.0f), powf(hypotf(t_1, hypotf((floorf(w) * dY_46_u), (floorf(h) * dY_46_v))), 2.0f))));
} else {
tmp = log2f(sqrtf(fmaxf(powf(hypotf(t_0, hypotf((floorf(w) * dX_46_u), (floorf(h) * dX_46_v))), 2.0f), powf(t_1, 2.0f))));
}
return tmp;
}
dX.u = abs(dX.u) function code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = Float32(floor(d) * dX_46_w) t_1 = Float32(floor(d) * dY_46_w) tmp = Float32(0.0) if (dX_46_u <= Float32(200000.0)) tmp = log2(sqrt((((t_0 ^ Float32(2.0)) != (t_0 ^ Float32(2.0))) ? (hypot(t_1, hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0)) : (((hypot(t_1, hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0)) != (hypot(t_1, hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0))) ? (t_0 ^ Float32(2.0)) : max((t_0 ^ Float32(2.0)), (hypot(t_1, hypot(Float32(floor(w) * dY_46_u), Float32(floor(h) * dY_46_v))) ^ Float32(2.0))))))); else tmp = log2(sqrt((((hypot(t_0, hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v))) ^ Float32(2.0)) != (hypot(t_0, hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v))) ^ Float32(2.0))) ? (t_1 ^ Float32(2.0)) : (((t_1 ^ Float32(2.0)) != (t_1 ^ Float32(2.0))) ? (hypot(t_0, hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v))) ^ Float32(2.0)) : max((hypot(t_0, hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v))) ^ Float32(2.0)), (t_1 ^ Float32(2.0))))))); end return tmp end
dX.u = abs(dX.u) function tmp_2 = code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = floor(d) * dX_46_w; t_1 = floor(d) * dY_46_w; tmp = single(0.0); if (dX_46_u <= single(200000.0)) tmp = log2(sqrt(max((t_0 ^ single(2.0)), (hypot(t_1, hypot((floor(w) * dY_46_u), (floor(h) * dY_46_v))) ^ single(2.0))))); else tmp = log2(sqrt(max((hypot(t_0, hypot((floor(w) * dX_46_u), (floor(h) * dX_46_v))) ^ single(2.0)), (t_1 ^ single(2.0))))); end tmp_2 = tmp; end
\begin{array}{l}
dX.u = |dX.u|\\
\\
\begin{array}{l}
t_0 := \left\lfloord\right\rfloor \cdot dX.w\\
t_1 := \left\lfloord\right\rfloor \cdot dY.w\\
\mathbf{if}\;dX.u \leq 200000:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({t_0}^{2}, {\left(\mathsf{hypot}\left(t_1, \mathsf{hypot}\left(\left\lfloorw\right\rfloor \cdot dY.u, \left\lfloorh\right\rfloor \cdot dY.v\right)\right)\right)}^{2}\right)}\right)\\
\mathbf{else}:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({\left(\mathsf{hypot}\left(t_0, \mathsf{hypot}\left(\left\lfloorw\right\rfloor \cdot dX.u, \left\lfloorh\right\rfloor \cdot dX.v\right)\right)\right)}^{2}, {t_1}^{2}\right)}\right)\\
\end{array}
\end{array}
if dX.u < 2e5Initial program 68.6%
expm1-log1p-u67.9%
expm1-udef67.9%
Applied egg-rr67.9%
expm1-def67.9%
expm1-log1p68.6%
*-commutative68.6%
*-commutative68.6%
*-commutative68.6%
Simplified68.6%
Taylor expanded in dX.w around inf 58.2%
unpow258.2%
unpow258.2%
swap-sqr58.2%
unpow258.2%
Simplified58.2%
if 2e5 < dX.u Initial program 49.9%
expm1-log1p-u49.3%
expm1-udef49.3%
Applied egg-rr49.3%
expm1-def49.3%
expm1-log1p49.9%
*-commutative49.9%
*-commutative49.9%
*-commutative49.9%
Simplified49.9%
Taylor expanded in dY.w around inf 49.5%
*-commutative49.4%
unpow249.4%
unpow249.4%
swap-sqr49.4%
unpow249.4%
Simplified49.5%
Final simplification56.3%
NOTE: dX.u should be positive before calling this function
(FPCore (w h d dX.u dX.v dX.w dY.u dY.v dY.w)
:precision binary32
(if (<= dX.u 20.0)
(log2
(sqrt
(fmax
(pow (* (floor d) dX.w) 2.0)
(pow (hypot (* (floor d) dY.w) (* (floor h) dY.v)) 2.0))))
(log2
(sqrt
(fmax
(pow (hypot (* (floor w) dX.u) (* (floor h) dX.v)) 2.0)
(* (pow (floor h) 2.0) (* dY.v dY.v)))))))dX.u = abs(dX.u);
float code(float w, float h, float d, float dX_46_u, float dX_46_v, float dX_46_w, float dY_46_u, float dY_46_v, float dY_46_w) {
float tmp;
if (dX_46_u <= 20.0f) {
tmp = log2f(sqrtf(fmaxf(powf((floorf(d) * dX_46_w), 2.0f), powf(hypotf((floorf(d) * dY_46_w), (floorf(h) * dY_46_v)), 2.0f))));
} else {
tmp = log2f(sqrtf(fmaxf(powf(hypotf((floorf(w) * dX_46_u), (floorf(h) * dX_46_v)), 2.0f), (powf(floorf(h), 2.0f) * (dY_46_v * dY_46_v)))));
}
return tmp;
}
dX.u = abs(dX.u) function code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) tmp = Float32(0.0) if (dX_46_u <= Float32(20.0)) tmp = log2(sqrt((((Float32(floor(d) * dX_46_w) ^ Float32(2.0)) != (Float32(floor(d) * dX_46_w) ^ Float32(2.0))) ? (hypot(Float32(floor(d) * dY_46_w), Float32(floor(h) * dY_46_v)) ^ Float32(2.0)) : (((hypot(Float32(floor(d) * dY_46_w), Float32(floor(h) * dY_46_v)) ^ Float32(2.0)) != (hypot(Float32(floor(d) * dY_46_w), Float32(floor(h) * dY_46_v)) ^ Float32(2.0))) ? (Float32(floor(d) * dX_46_w) ^ Float32(2.0)) : max((Float32(floor(d) * dX_46_w) ^ Float32(2.0)), (hypot(Float32(floor(d) * dY_46_w), Float32(floor(h) * dY_46_v)) ^ Float32(2.0))))))); else tmp = log2(sqrt((((hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v)) ^ Float32(2.0)) != (hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v)) ^ Float32(2.0))) ? Float32((floor(h) ^ Float32(2.0)) * Float32(dY_46_v * dY_46_v)) : ((Float32((floor(h) ^ Float32(2.0)) * Float32(dY_46_v * dY_46_v)) != Float32((floor(h) ^ Float32(2.0)) * Float32(dY_46_v * dY_46_v))) ? (hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v)) ^ Float32(2.0)) : max((hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v)) ^ Float32(2.0)), Float32((floor(h) ^ Float32(2.0)) * Float32(dY_46_v * dY_46_v))))))); end return tmp end
dX.u = abs(dX.u) function tmp_2 = code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) tmp = single(0.0); if (dX_46_u <= single(20.0)) tmp = log2(sqrt(max(((floor(d) * dX_46_w) ^ single(2.0)), (hypot((floor(d) * dY_46_w), (floor(h) * dY_46_v)) ^ single(2.0))))); else tmp = log2(sqrt(max((hypot((floor(w) * dX_46_u), (floor(h) * dX_46_v)) ^ single(2.0)), ((floor(h) ^ single(2.0)) * (dY_46_v * dY_46_v))))); end tmp_2 = tmp; end
\begin{array}{l}
dX.u = |dX.u|\\
\\
\begin{array}{l}
\mathbf{if}\;dX.u \leq 20:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({\left(\left\lfloord\right\rfloor \cdot dX.w\right)}^{2}, {\left(\mathsf{hypot}\left(\left\lfloord\right\rfloor \cdot dY.w, \left\lfloorh\right\rfloor \cdot dY.v\right)\right)}^{2}\right)}\right)\\
\mathbf{else}:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({\left(\mathsf{hypot}\left(\left\lfloorw\right\rfloor \cdot dX.u, \left\lfloorh\right\rfloor \cdot dX.v\right)\right)}^{2}, {\left(\left\lfloorh\right\rfloor\right)}^{2} \cdot \left(dY.v \cdot dY.v\right)\right)}\right)\\
\end{array}
\end{array}
if dX.u < 20Initial program 67.3%
expm1-log1p-u66.6%
expm1-udef66.6%
Applied egg-rr66.6%
expm1-def66.6%
expm1-log1p67.3%
*-commutative67.3%
*-commutative67.3%
*-commutative67.3%
Simplified67.3%
Taylor expanded in dX.w around inf 57.1%
unpow257.1%
unpow257.1%
swap-sqr57.1%
unpow257.1%
Simplified57.1%
Taylor expanded in dY.u around 0 51.0%
+-commutative51.0%
*-commutative51.0%
*-commutative51.0%
unpow251.0%
unpow251.0%
swap-sqr51.0%
unpow251.0%
unpow251.0%
unswap-sqr51.0%
hypot-def51.0%
*-commutative51.0%
*-commutative51.0%
Simplified51.0%
if 20 < dX.u Initial program 56.2%
expm1-log1p-u55.5%
expm1-udef55.5%
Applied egg-rr55.5%
expm1-def55.5%
expm1-log1p56.2%
*-commutative56.2%
*-commutative56.2%
*-commutative56.2%
Simplified56.2%
Taylor expanded in dY.v around inf 54.1%
*-commutative54.1%
unpow254.1%
Simplified54.1%
Taylor expanded in dX.w around 0 52.1%
unpow147.7%
sqr-pow47.6%
metadata-eval47.6%
unpow1/247.6%
unpow247.6%
unpow247.6%
unswap-sqr47.6%
unpow247.6%
unpow247.6%
unswap-sqr47.6%
hypot-def47.6%
metadata-eval47.6%
Simplified52.1%
Final simplification51.2%
NOTE: dX.u should be positive before calling this function
(FPCore (w h d dX.u dX.v dX.w dY.u dY.v dY.w)
:precision binary32
(let* ((t_0 (* (floor d) dY.w)))
(if (<= dX.u 200000.0)
(log2
(sqrt
(fmax
(pow (* (floor d) dX.w) 2.0)
(pow (hypot t_0 (* (floor h) dY.v)) 2.0))))
(log2
(sqrt (fmax (* (* dX.u dX.u) (pow (floor w) 2.0)) (pow t_0 2.0)))))))dX.u = abs(dX.u);
float code(float w, float h, float d, float dX_46_u, float dX_46_v, float dX_46_w, float dY_46_u, float dY_46_v, float dY_46_w) {
float t_0 = floorf(d) * dY_46_w;
float tmp;
if (dX_46_u <= 200000.0f) {
tmp = log2f(sqrtf(fmaxf(powf((floorf(d) * dX_46_w), 2.0f), powf(hypotf(t_0, (floorf(h) * dY_46_v)), 2.0f))));
} else {
tmp = log2f(sqrtf(fmaxf(((dX_46_u * dX_46_u) * powf(floorf(w), 2.0f)), powf(t_0, 2.0f))));
}
return tmp;
}
dX.u = abs(dX.u) function code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = Float32(floor(d) * dY_46_w) tmp = Float32(0.0) if (dX_46_u <= Float32(200000.0)) tmp = log2(sqrt((((Float32(floor(d) * dX_46_w) ^ Float32(2.0)) != (Float32(floor(d) * dX_46_w) ^ Float32(2.0))) ? (hypot(t_0, Float32(floor(h) * dY_46_v)) ^ Float32(2.0)) : (((hypot(t_0, Float32(floor(h) * dY_46_v)) ^ Float32(2.0)) != (hypot(t_0, Float32(floor(h) * dY_46_v)) ^ Float32(2.0))) ? (Float32(floor(d) * dX_46_w) ^ Float32(2.0)) : max((Float32(floor(d) * dX_46_w) ^ Float32(2.0)), (hypot(t_0, Float32(floor(h) * dY_46_v)) ^ Float32(2.0))))))); else tmp = log2(sqrt(((Float32(Float32(dX_46_u * dX_46_u) * (floor(w) ^ Float32(2.0))) != Float32(Float32(dX_46_u * dX_46_u) * (floor(w) ^ Float32(2.0)))) ? (t_0 ^ Float32(2.0)) : (((t_0 ^ Float32(2.0)) != (t_0 ^ Float32(2.0))) ? Float32(Float32(dX_46_u * dX_46_u) * (floor(w) ^ Float32(2.0))) : max(Float32(Float32(dX_46_u * dX_46_u) * (floor(w) ^ Float32(2.0))), (t_0 ^ Float32(2.0))))))); end return tmp end
dX.u = abs(dX.u) function tmp_2 = code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = floor(d) * dY_46_w; tmp = single(0.0); if (dX_46_u <= single(200000.0)) tmp = log2(sqrt(max(((floor(d) * dX_46_w) ^ single(2.0)), (hypot(t_0, (floor(h) * dY_46_v)) ^ single(2.0))))); else tmp = log2(sqrt(max(((dX_46_u * dX_46_u) * (floor(w) ^ single(2.0))), (t_0 ^ single(2.0))))); end tmp_2 = tmp; end
\begin{array}{l}
dX.u = |dX.u|\\
\\
\begin{array}{l}
t_0 := \left\lfloord\right\rfloor \cdot dY.w\\
\mathbf{if}\;dX.u \leq 200000:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({\left(\left\lfloord\right\rfloor \cdot dX.w\right)}^{2}, {\left(\mathsf{hypot}\left(t_0, \left\lfloorh\right\rfloor \cdot dY.v\right)\right)}^{2}\right)}\right)\\
\mathbf{else}:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left(\left(dX.u \cdot dX.u\right) \cdot {\left(\left\lfloorw\right\rfloor\right)}^{2}, {t_0}^{2}\right)}\right)\\
\end{array}
\end{array}
if dX.u < 2e5Initial program 68.6%
expm1-log1p-u67.9%
expm1-udef67.9%
Applied egg-rr67.9%
expm1-def67.9%
expm1-log1p68.6%
*-commutative68.6%
*-commutative68.6%
*-commutative68.6%
Simplified68.6%
Taylor expanded in dX.w around inf 58.2%
unpow258.2%
unpow258.2%
swap-sqr58.2%
unpow258.2%
Simplified58.2%
Taylor expanded in dY.u around 0 51.6%
+-commutative51.6%
*-commutative51.6%
*-commutative51.6%
unpow251.6%
unpow251.6%
swap-sqr51.6%
unpow251.6%
unpow251.6%
unswap-sqr51.6%
hypot-def51.6%
*-commutative51.6%
*-commutative51.6%
Simplified51.6%
if 2e5 < dX.u Initial program 49.9%
expm1-log1p-u49.3%
expm1-udef49.3%
Applied egg-rr49.3%
expm1-def49.3%
expm1-log1p49.9%
*-commutative49.9%
*-commutative49.9%
*-commutative49.9%
Simplified49.9%
Taylor expanded in dX.u around inf 45.7%
unpow245.7%
Simplified45.7%
Taylor expanded in dY.w around inf 45.1%
*-commutative25.7%
Simplified45.1%
Final simplification50.2%
NOTE: dX.u should be positive before calling this function
(FPCore (w h d dX.u dX.v dX.w dY.u dY.v dY.w)
:precision binary32
(let* ((t_0 (* (floor d) dY.w)))
(if (<= dX.u 12.5)
(log2
(sqrt
(fmax
(pow (* (floor d) dX.w) 2.0)
(pow (hypot t_0 (* (floor h) dY.v)) 2.0))))
(log2
(sqrt
(fmax
(pow (hypot (* (floor w) dX.u) (* (floor h) dX.v)) 2.0)
(pow t_0 2.0)))))))dX.u = abs(dX.u);
float code(float w, float h, float d, float dX_46_u, float dX_46_v, float dX_46_w, float dY_46_u, float dY_46_v, float dY_46_w) {
float t_0 = floorf(d) * dY_46_w;
float tmp;
if (dX_46_u <= 12.5f) {
tmp = log2f(sqrtf(fmaxf(powf((floorf(d) * dX_46_w), 2.0f), powf(hypotf(t_0, (floorf(h) * dY_46_v)), 2.0f))));
} else {
tmp = log2f(sqrtf(fmaxf(powf(hypotf((floorf(w) * dX_46_u), (floorf(h) * dX_46_v)), 2.0f), powf(t_0, 2.0f))));
}
return tmp;
}
dX.u = abs(dX.u) function code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = Float32(floor(d) * dY_46_w) tmp = Float32(0.0) if (dX_46_u <= Float32(12.5)) tmp = log2(sqrt((((Float32(floor(d) * dX_46_w) ^ Float32(2.0)) != (Float32(floor(d) * dX_46_w) ^ Float32(2.0))) ? (hypot(t_0, Float32(floor(h) * dY_46_v)) ^ Float32(2.0)) : (((hypot(t_0, Float32(floor(h) * dY_46_v)) ^ Float32(2.0)) != (hypot(t_0, Float32(floor(h) * dY_46_v)) ^ Float32(2.0))) ? (Float32(floor(d) * dX_46_w) ^ Float32(2.0)) : max((Float32(floor(d) * dX_46_w) ^ Float32(2.0)), (hypot(t_0, Float32(floor(h) * dY_46_v)) ^ Float32(2.0))))))); else tmp = log2(sqrt((((hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v)) ^ Float32(2.0)) != (hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v)) ^ Float32(2.0))) ? (t_0 ^ Float32(2.0)) : (((t_0 ^ Float32(2.0)) != (t_0 ^ Float32(2.0))) ? (hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v)) ^ Float32(2.0)) : max((hypot(Float32(floor(w) * dX_46_u), Float32(floor(h) * dX_46_v)) ^ Float32(2.0)), (t_0 ^ Float32(2.0))))))); end return tmp end
dX.u = abs(dX.u) function tmp_2 = code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = floor(d) * dY_46_w; tmp = single(0.0); if (dX_46_u <= single(12.5)) tmp = log2(sqrt(max(((floor(d) * dX_46_w) ^ single(2.0)), (hypot(t_0, (floor(h) * dY_46_v)) ^ single(2.0))))); else tmp = log2(sqrt(max((hypot((floor(w) * dX_46_u), (floor(h) * dX_46_v)) ^ single(2.0)), (t_0 ^ single(2.0))))); end tmp_2 = tmp; end
\begin{array}{l}
dX.u = |dX.u|\\
\\
\begin{array}{l}
t_0 := \left\lfloord\right\rfloor \cdot dY.w\\
\mathbf{if}\;dX.u \leq 12.5:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({\left(\left\lfloord\right\rfloor \cdot dX.w\right)}^{2}, {\left(\mathsf{hypot}\left(t_0, \left\lfloorh\right\rfloor \cdot dY.v\right)\right)}^{2}\right)}\right)\\
\mathbf{else}:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({\left(\mathsf{hypot}\left(\left\lfloorw\right\rfloor \cdot dX.u, \left\lfloorh\right\rfloor \cdot dX.v\right)\right)}^{2}, {t_0}^{2}\right)}\right)\\
\end{array}
\end{array}
if dX.u < 12.5Initial program 67.1%
expm1-log1p-u66.5%
expm1-udef66.5%
Applied egg-rr66.5%
expm1-def66.5%
expm1-log1p67.1%
*-commutative67.1%
*-commutative67.1%
*-commutative67.1%
Simplified67.1%
Taylor expanded in dX.w around inf 56.9%
unpow256.9%
unpow256.9%
swap-sqr56.9%
unpow256.9%
Simplified56.9%
Taylor expanded in dY.u around 0 50.7%
+-commutative50.7%
*-commutative50.7%
*-commutative50.7%
unpow250.7%
unpow250.7%
swap-sqr50.7%
unpow250.7%
unpow250.7%
unswap-sqr50.7%
hypot-def50.7%
*-commutative50.7%
*-commutative50.7%
Simplified50.7%
if 12.5 < dX.u Initial program 56.8%
pow1/256.8%
Applied egg-rr56.8%
Simplified56.8%
Taylor expanded in dY.w around inf 50.2%
*-commutative50.2%
unpow250.2%
unpow250.2%
swap-sqr50.2%
unpow250.2%
Simplified50.2%
Taylor expanded in dX.w around 0 48.5%
unpow148.5%
sqr-pow48.4%
metadata-eval48.4%
unpow1/248.4%
unpow248.4%
unpow248.4%
unswap-sqr48.4%
unpow248.4%
unpow248.4%
unswap-sqr48.4%
hypot-def48.4%
metadata-eval48.4%
Simplified48.4%
Taylor expanded in dX.u around 0 48.5%
*-commutative48.5%
Simplified48.5%
Final simplification50.1%
NOTE: dX.u should be positive before calling this function
(FPCore (w h d dX.u dX.v dX.w dY.u dY.v dY.w)
:precision binary32
(let* ((t_0 (* (* dX.u dX.u) (pow (floor w) 2.0)))
(t_1 (pow (* (floor h) dY.v) 2.0)))
(if (<= dY.w 3.2000000427245823e-9)
(log2 (sqrt (fmax (pow (* (floor d) dX.w) 2.0) t_1)))
(if (<= dY.w 200.0)
(log2 (sqrt (fmax t_0 t_1)))
(log2 (sqrt (fmax t_0 (pow (* (floor d) dY.w) 2.0))))))))dX.u = abs(dX.u);
float code(float w, float h, float d, float dX_46_u, float dX_46_v, float dX_46_w, float dY_46_u, float dY_46_v, float dY_46_w) {
float t_0 = (dX_46_u * dX_46_u) * powf(floorf(w), 2.0f);
float t_1 = powf((floorf(h) * dY_46_v), 2.0f);
float tmp;
if (dY_46_w <= 3.2000000427245823e-9f) {
tmp = log2f(sqrtf(fmaxf(powf((floorf(d) * dX_46_w), 2.0f), t_1)));
} else if (dY_46_w <= 200.0f) {
tmp = log2f(sqrtf(fmaxf(t_0, t_1)));
} else {
tmp = log2f(sqrtf(fmaxf(t_0, powf((floorf(d) * dY_46_w), 2.0f))));
}
return tmp;
}
dX.u = abs(dX.u) function code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = Float32(Float32(dX_46_u * dX_46_u) * (floor(w) ^ Float32(2.0))) t_1 = Float32(floor(h) * dY_46_v) ^ Float32(2.0) tmp = Float32(0.0) if (dY_46_w <= Float32(3.2000000427245823e-9)) tmp = log2(sqrt((((Float32(floor(d) * dX_46_w) ^ Float32(2.0)) != (Float32(floor(d) * dX_46_w) ^ Float32(2.0))) ? t_1 : ((t_1 != t_1) ? (Float32(floor(d) * dX_46_w) ^ Float32(2.0)) : max((Float32(floor(d) * dX_46_w) ^ Float32(2.0)), t_1))))); elseif (dY_46_w <= Float32(200.0)) tmp = log2(sqrt(((t_0 != t_0) ? t_1 : ((t_1 != t_1) ? t_0 : max(t_0, t_1))))); else tmp = log2(sqrt(((t_0 != t_0) ? (Float32(floor(d) * dY_46_w) ^ Float32(2.0)) : (((Float32(floor(d) * dY_46_w) ^ Float32(2.0)) != (Float32(floor(d) * dY_46_w) ^ Float32(2.0))) ? t_0 : max(t_0, (Float32(floor(d) * dY_46_w) ^ Float32(2.0))))))); end return tmp end
dX.u = abs(dX.u) function tmp_2 = code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = (dX_46_u * dX_46_u) * (floor(w) ^ single(2.0)); t_1 = (floor(h) * dY_46_v) ^ single(2.0); tmp = single(0.0); if (dY_46_w <= single(3.2000000427245823e-9)) tmp = log2(sqrt(max(((floor(d) * dX_46_w) ^ single(2.0)), t_1))); elseif (dY_46_w <= single(200.0)) tmp = log2(sqrt(max(t_0, t_1))); else tmp = log2(sqrt(max(t_0, ((floor(d) * dY_46_w) ^ single(2.0))))); end tmp_2 = tmp; end
\begin{array}{l}
dX.u = |dX.u|\\
\\
\begin{array}{l}
t_0 := \left(dX.u \cdot dX.u\right) \cdot {\left(\left\lfloorw\right\rfloor\right)}^{2}\\
t_1 := {\left(\left\lfloorh\right\rfloor \cdot dY.v\right)}^{2}\\
\mathbf{if}\;dY.w \leq 3.2000000427245823 \cdot 10^{-9}:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({\left(\left\lfloord\right\rfloor \cdot dX.w\right)}^{2}, t_1\right)}\right)\\
\mathbf{elif}\;dY.w \leq 200:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left(t_0, t_1\right)}\right)\\
\mathbf{else}:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left(t_0, {\left(\left\lfloord\right\rfloor \cdot dY.w\right)}^{2}\right)}\right)\\
\end{array}
\end{array}
if dY.w < 3.20000004e-9Initial program 64.4%
expm1-log1p-u63.6%
expm1-udef63.6%
Applied egg-rr63.6%
expm1-def63.6%
expm1-log1p64.4%
*-commutative64.4%
*-commutative64.4%
*-commutative64.4%
Simplified64.4%
Taylor expanded in dX.w around inf 54.2%
unpow254.2%
unpow254.2%
swap-sqr54.2%
unpow254.2%
Simplified54.2%
Taylor expanded in dY.v around inf 41.0%
*-commutative41.0%
Simplified41.0%
if 3.20000004e-9 < dY.w < 200Initial program 77.4%
expm1-log1p-u76.8%
expm1-udef76.8%
Applied egg-rr76.8%
expm1-def76.8%
expm1-log1p77.4%
*-commutative77.4%
*-commutative77.4%
*-commutative77.4%
Simplified77.4%
Taylor expanded in dX.u around inf 63.3%
unpow263.3%
Simplified63.3%
Taylor expanded in dY.v around inf 57.2%
*-commutative34.2%
Simplified57.2%
if 200 < dY.w Initial program 57.8%
expm1-log1p-u57.1%
expm1-udef57.1%
Applied egg-rr57.1%
expm1-def57.1%
expm1-log1p57.8%
*-commutative57.8%
*-commutative57.8%
*-commutative57.8%
Simplified57.8%
Taylor expanded in dX.u around inf 51.7%
unpow251.7%
Simplified51.7%
Taylor expanded in dY.w around inf 45.3%
*-commutative44.6%
Simplified45.3%
Final simplification43.7%
NOTE: dX.u should be positive before calling this function
(FPCore (w h d dX.u dX.v dX.w dY.u dY.v dY.w)
:precision binary32
(if (<= dY.w 0.8500000238418579)
(log2
(sqrt (fmax (pow (* (floor d) dX.w) 2.0) (pow (* (floor h) dY.v) 2.0))))
(log2
(sqrt
(fmax
(* (* dX.u dX.u) (pow (floor w) 2.0))
(pow (* (floor d) dY.w) 2.0))))))dX.u = abs(dX.u);
float code(float w, float h, float d, float dX_46_u, float dX_46_v, float dX_46_w, float dY_46_u, float dY_46_v, float dY_46_w) {
float tmp;
if (dY_46_w <= 0.8500000238418579f) {
tmp = log2f(sqrtf(fmaxf(powf((floorf(d) * dX_46_w), 2.0f), powf((floorf(h) * dY_46_v), 2.0f))));
} else {
tmp = log2f(sqrtf(fmaxf(((dX_46_u * dX_46_u) * powf(floorf(w), 2.0f)), powf((floorf(d) * dY_46_w), 2.0f))));
}
return tmp;
}
dX.u = abs(dX.u) function code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) tmp = Float32(0.0) if (dY_46_w <= Float32(0.8500000238418579)) tmp = log2(sqrt((((Float32(floor(d) * dX_46_w) ^ Float32(2.0)) != (Float32(floor(d) * dX_46_w) ^ Float32(2.0))) ? (Float32(floor(h) * dY_46_v) ^ Float32(2.0)) : (((Float32(floor(h) * dY_46_v) ^ Float32(2.0)) != (Float32(floor(h) * dY_46_v) ^ Float32(2.0))) ? (Float32(floor(d) * dX_46_w) ^ Float32(2.0)) : max((Float32(floor(d) * dX_46_w) ^ Float32(2.0)), (Float32(floor(h) * dY_46_v) ^ Float32(2.0))))))); else tmp = log2(sqrt(((Float32(Float32(dX_46_u * dX_46_u) * (floor(w) ^ Float32(2.0))) != Float32(Float32(dX_46_u * dX_46_u) * (floor(w) ^ Float32(2.0)))) ? (Float32(floor(d) * dY_46_w) ^ Float32(2.0)) : (((Float32(floor(d) * dY_46_w) ^ Float32(2.0)) != (Float32(floor(d) * dY_46_w) ^ Float32(2.0))) ? Float32(Float32(dX_46_u * dX_46_u) * (floor(w) ^ Float32(2.0))) : max(Float32(Float32(dX_46_u * dX_46_u) * (floor(w) ^ Float32(2.0))), (Float32(floor(d) * dY_46_w) ^ Float32(2.0))))))); end return tmp end
dX.u = abs(dX.u) function tmp_2 = code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) tmp = single(0.0); if (dY_46_w <= single(0.8500000238418579)) tmp = log2(sqrt(max(((floor(d) * dX_46_w) ^ single(2.0)), ((floor(h) * dY_46_v) ^ single(2.0))))); else tmp = log2(sqrt(max(((dX_46_u * dX_46_u) * (floor(w) ^ single(2.0))), ((floor(d) * dY_46_w) ^ single(2.0))))); end tmp_2 = tmp; end
\begin{array}{l}
dX.u = |dX.u|\\
\\
\begin{array}{l}
\mathbf{if}\;dY.w \leq 0.8500000238418579:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left({\left(\left\lfloord\right\rfloor \cdot dX.w\right)}^{2}, {\left(\left\lfloorh\right\rfloor \cdot dY.v\right)}^{2}\right)}\right)\\
\mathbf{else}:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left(\left(dX.u \cdot dX.u\right) \cdot {\left(\left\lfloorw\right\rfloor\right)}^{2}, {\left(\left\lfloord\right\rfloor \cdot dY.w\right)}^{2}\right)}\right)\\
\end{array}
\end{array}
if dY.w < 0.850000024Initial program 65.8%
expm1-log1p-u65.1%
expm1-udef65.1%
Applied egg-rr65.1%
expm1-def65.1%
expm1-log1p65.8%
*-commutative65.8%
*-commutative65.8%
*-commutative65.8%
Simplified65.8%
Taylor expanded in dX.w around inf 52.5%
unpow252.5%
unpow252.5%
swap-sqr52.5%
unpow252.5%
Simplified52.5%
Taylor expanded in dY.v around inf 39.9%
*-commutative39.9%
Simplified39.9%
if 0.850000024 < dY.w Initial program 59.9%
expm1-log1p-u59.2%
expm1-udef59.2%
Applied egg-rr59.2%
expm1-def59.2%
expm1-log1p59.9%
*-commutative59.9%
*-commutative59.9%
*-commutative59.9%
Simplified59.9%
Taylor expanded in dX.u around inf 54.3%
unpow254.3%
Simplified54.3%
Taylor expanded in dY.w around inf 45.1%
*-commutative43.1%
Simplified45.1%
Final simplification41.0%
NOTE: dX.u should be positive before calling this function
(FPCore (w h d dX.u dX.v dX.w dY.u dY.v dY.w)
:precision binary32
(let* ((t_0 (pow (* (floor d) dX.w) 2.0)))
(if (<= dY.w 300.0)
(log2 (sqrt (fmax t_0 (pow (* (floor h) dY.v) 2.0))))
(log2 (sqrt (fmax t_0 (pow (* (floor d) dY.w) 2.0)))))))dX.u = abs(dX.u);
float code(float w, float h, float d, float dX_46_u, float dX_46_v, float dX_46_w, float dY_46_u, float dY_46_v, float dY_46_w) {
float t_0 = powf((floorf(d) * dX_46_w), 2.0f);
float tmp;
if (dY_46_w <= 300.0f) {
tmp = log2f(sqrtf(fmaxf(t_0, powf((floorf(h) * dY_46_v), 2.0f))));
} else {
tmp = log2f(sqrtf(fmaxf(t_0, powf((floorf(d) * dY_46_w), 2.0f))));
}
return tmp;
}
dX.u = abs(dX.u) function code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = Float32(floor(d) * dX_46_w) ^ Float32(2.0) tmp = Float32(0.0) if (dY_46_w <= Float32(300.0)) tmp = log2(sqrt(((t_0 != t_0) ? (Float32(floor(h) * dY_46_v) ^ Float32(2.0)) : (((Float32(floor(h) * dY_46_v) ^ Float32(2.0)) != (Float32(floor(h) * dY_46_v) ^ Float32(2.0))) ? t_0 : max(t_0, (Float32(floor(h) * dY_46_v) ^ Float32(2.0))))))); else tmp = log2(sqrt(((t_0 != t_0) ? (Float32(floor(d) * dY_46_w) ^ Float32(2.0)) : (((Float32(floor(d) * dY_46_w) ^ Float32(2.0)) != (Float32(floor(d) * dY_46_w) ^ Float32(2.0))) ? t_0 : max(t_0, (Float32(floor(d) * dY_46_w) ^ Float32(2.0))))))); end return tmp end
dX.u = abs(dX.u) function tmp_2 = code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) t_0 = (floor(d) * dX_46_w) ^ single(2.0); tmp = single(0.0); if (dY_46_w <= single(300.0)) tmp = log2(sqrt(max(t_0, ((floor(h) * dY_46_v) ^ single(2.0))))); else tmp = log2(sqrt(max(t_0, ((floor(d) * dY_46_w) ^ single(2.0))))); end tmp_2 = tmp; end
\begin{array}{l}
dX.u = |dX.u|\\
\\
\begin{array}{l}
t_0 := {\left(\left\lfloord\right\rfloor \cdot dX.w\right)}^{2}\\
\mathbf{if}\;dY.w \leq 300:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left(t_0, {\left(\left\lfloorh\right\rfloor \cdot dY.v\right)}^{2}\right)}\right)\\
\mathbf{else}:\\
\;\;\;\;\log_{2} \left(\sqrt{\mathsf{max}\left(t_0, {\left(\left\lfloord\right\rfloor \cdot dY.w\right)}^{2}\right)}\right)\\
\end{array}
\end{array}
if dY.w < 300Initial program 66.2%
expm1-log1p-u65.5%
expm1-udef65.5%
Applied egg-rr65.5%
expm1-def65.5%
expm1-log1p66.2%
*-commutative66.2%
*-commutative66.2%
*-commutative66.2%
Simplified66.2%
Taylor expanded in dX.w around inf 52.8%
unpow252.8%
unpow252.8%
swap-sqr52.8%
unpow252.8%
Simplified52.8%
Taylor expanded in dY.v around inf 40.0%
*-commutative40.0%
Simplified40.0%
if 300 < dY.w Initial program 57.8%
expm1-log1p-u57.1%
expm1-udef57.1%
Applied egg-rr57.1%
expm1-def57.1%
expm1-log1p57.8%
*-commutative57.8%
*-commutative57.8%
*-commutative57.8%
Simplified57.8%
Taylor expanded in dX.w around inf 51.2%
unpow251.2%
unpow251.2%
swap-sqr51.2%
unpow251.2%
Simplified51.2%
Taylor expanded in dY.w around inf 44.6%
*-commutative44.6%
Simplified44.6%
Final simplification40.9%
NOTE: dX.u should be positive before calling this function (FPCore (w h d dX.u dX.v dX.w dY.u dY.v dY.w) :precision binary32 (log2 (sqrt (fmax (pow (* (floor d) dX.w) 2.0) (pow (* (floor d) dY.w) 2.0)))))
dX.u = abs(dX.u);
float code(float w, float h, float d, float dX_46_u, float dX_46_v, float dX_46_w, float dY_46_u, float dY_46_v, float dY_46_w) {
return log2f(sqrtf(fmaxf(powf((floorf(d) * dX_46_w), 2.0f), powf((floorf(d) * dY_46_w), 2.0f))));
}
dX.u = abs(dX.u) function code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) return log2(sqrt((((Float32(floor(d) * dX_46_w) ^ Float32(2.0)) != (Float32(floor(d) * dX_46_w) ^ Float32(2.0))) ? (Float32(floor(d) * dY_46_w) ^ Float32(2.0)) : (((Float32(floor(d) * dY_46_w) ^ Float32(2.0)) != (Float32(floor(d) * dY_46_w) ^ Float32(2.0))) ? (Float32(floor(d) * dX_46_w) ^ Float32(2.0)) : max((Float32(floor(d) * dX_46_w) ^ Float32(2.0)), (Float32(floor(d) * dY_46_w) ^ Float32(2.0))))))) end
dX.u = abs(dX.u) function tmp = code(w, h, d, dX_46_u, dX_46_v, dX_46_w, dY_46_u, dY_46_v, dY_46_w) tmp = log2(sqrt(max(((floor(d) * dX_46_w) ^ single(2.0)), ((floor(d) * dY_46_w) ^ single(2.0))))); end
\begin{array}{l}
dX.u = |dX.u|\\
\\
\log_{2} \left(\sqrt{\mathsf{max}\left({\left(\left\lfloord\right\rfloor \cdot dX.w\right)}^{2}, {\left(\left\lfloord\right\rfloor \cdot dY.w\right)}^{2}\right)}\right)
\end{array}
Initial program 64.5%
expm1-log1p-u63.8%
expm1-udef63.8%
Applied egg-rr63.8%
expm1-def63.8%
expm1-log1p64.5%
*-commutative64.5%
*-commutative64.5%
*-commutative64.5%
Simplified64.5%
Taylor expanded in dX.w around inf 52.5%
unpow252.5%
unpow252.5%
swap-sqr52.5%
unpow252.5%
Simplified52.5%
Taylor expanded in dY.w around inf 34.6%
*-commutative34.6%
Simplified34.6%
Final simplification34.6%
herbie shell --seed 2023287
(FPCore (w h d dX.u dX.v dX.w dY.u dY.v dY.w)
:name "Isotropic LOD (LOD)"
:precision binary32
:pre (and (and (and (and (and (and (and (and (and (<= 1.0 w) (<= w 16384.0)) (and (<= 1.0 h) (<= h 16384.0))) (and (<= 1.0 d) (<= d 4096.0))) (and (<= 1e-20 (fabs dX.u)) (<= (fabs dX.u) 1e+20))) (and (<= 1e-20 (fabs dX.v)) (<= (fabs dX.v) 1e+20))) (and (<= 1e-20 (fabs dX.w)) (<= (fabs dX.w) 1e+20))) (and (<= 1e-20 (fabs dY.u)) (<= (fabs dY.u) 1e+20))) (and (<= 1e-20 (fabs dY.v)) (<= (fabs dY.v) 1e+20))) (and (<= 1e-20 (fabs dY.w)) (<= (fabs dY.w) 1e+20)))
(log2 (sqrt (fmax (+ (+ (* (* (floor w) dX.u) (* (floor w) dX.u)) (* (* (floor h) dX.v) (* (floor h) dX.v))) (* (* (floor d) dX.w) (* (floor d) dX.w))) (+ (+ (* (* (floor w) dY.u) (* (floor w) dY.u)) (* (* (floor h) dY.v) (* (floor h) dY.v))) (* (* (floor d) dY.w) (* (floor d) dY.w)))))))