mirror of
https://git.code.sf.net/p/quake/quakeforge
synced 2024-11-30 08:00:51 +00:00
80c5e2c3f6
It seems gcc-11 does a pretty good job of emulating the instructions (it no longer requires avx2 for 256-bit wide vectors).
685 lines
23 KiB
C
685 lines
23 KiB
C
#ifdef HAVE_CONFIG_H
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# include "config.h"
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#endif
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#include <stdio.h>
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#include <stdio.h>
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#include <string.h>
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#include <unistd.h>
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#include "QF/mathlib.h"
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#include "QF/simd/vec4d.h"
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#include "QF/simd/vec4f.h"
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#include "QF/simd/mat4f.h"
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#define right { 1, 0, 0 }
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#define forward { 0, 1, 0 }
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#define up { 0, 0, 1 }
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#define one { 1, 1, 1, 1 }
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#define half { 0.5, 0.5, 0.5, 0.5 }
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#define zero { 0, 0, 0, 0 }
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#define qident { 0, 0, 0, 1 }
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#define qtest { 0.64, 0.48, 0, 0.6 }
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#define nright { -1, 0, 0 }
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#define nforward { 0, -1, 0 }
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#define nup { 0, 0, -1 }
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#define none { -1, -1, -1, -1 }
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#define nqident { 0, 0, 0, -1 }
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#define pi { M_PI, M_PI, M_PI, M_PI } // lots of bits
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#define pmpi { -M_PI, M_PI, -M_PI, M_PI } // lots of bits
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#define identity \
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{ { 1, 0, 0, 0 }, \
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{ 0, 1, 0, 0 }, \
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{ 0, 0, 1, 0 }, \
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{ 0, 0, 0, 1 } }
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#define rotate120 \
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{ { 0, 1, 0, 0 }, \
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{ 0, 0, 1, 0 }, \
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{ 1, 0, 0, 0 }, \
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{ 0, 0, 0, 1 } }
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#define rotate240 \
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{ { 0, 0, 1, 0 }, \
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{ 1, 0, 0, 0 }, \
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{ 0, 1, 0, 0 }, \
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{ 0, 0, 0, 1 } }
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#define s05 0.70710678118654757
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typedef struct {
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int line;
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vec4d_t (*op) (vec4d_t a, vec4d_t b);
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vec4d_t a;
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vec4d_t b;
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vec4d_t expect;
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vec4d_t ulp_errors;
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} vec4d_test_t;
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typedef struct {
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int line;
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vec4f_t (*op) (vec4f_t a, vec4f_t b);
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vec4f_t a;
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vec4f_t b;
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vec4f_t expect;
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vec4f_t ulp_errors;
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} vec4f_test_t;
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typedef struct {
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int line;
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void (*op) (mat4f_t c, const mat4f_t a, const mat4f_t b);
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mat4f_t a;
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mat4f_t b;
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mat4f_t expect;
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mat4f_t ulp_errors;
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} mat4f_test_t;
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typedef struct {
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int line;
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vec4f_t (*op) (const mat4f_t a, vec4f_t b);
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mat4f_t a;
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vec4f_t b;
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vec4f_t expect;
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vec4f_t ulp_errors;
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} mv4f_test_t;
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typedef struct {
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int line;
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void (*op) (mat4f_t m, vec4f_t q);
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vec4f_t q;
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mat4f_t expect;
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mat4f_t ulp_errors;
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} mq4f_test_t;
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static vec4d_t tvtruncd (vec4d_t v, vec4d_t ignore)
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{
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return vtrunc4d (v);
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}
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static vec4d_t tvceild (vec4d_t v, vec4d_t ignore)
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{
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return vceil4d (v);
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}
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static vec4d_t tvfloord (vec4d_t v, vec4d_t ignore)
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{
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return vfloor4d (v);
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}
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static vec4d_t tqconjd (vec4d_t v, vec4d_t ignore)
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{
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return qconjd (v);
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}
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static vec4f_t tvtruncf (vec4f_t v, vec4f_t ignore)
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{
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return vtrunc4f (v);
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}
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static vec4f_t tvceilf (vec4f_t v, vec4f_t ignore)
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{
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return vceil4f (v);
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}
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static vec4f_t tvfloorf (vec4f_t v, vec4f_t ignore)
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{
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return vfloor4f (v);
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}
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static vec4f_t tqconjf (vec4f_t v, vec4f_t ignore)
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{
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return qconjf (v);
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}
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static vec4f_t tvabsf (vec4f_t v, vec4f_t ignore)
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{
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return vabs4f (v);
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}
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static vec4f_t tvsqrtf (vec4f_t v, vec4f_t ignore)
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{
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return vsqrt4f (v);
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}
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static vec4f_t tmagnitudef (vec4f_t v, vec4f_t ignore)
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{
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return magnitudef (v);
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}
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static vec4f_t tmagnitude3f (vec4f_t v, vec4f_t ignore)
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{
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return magnitude3f (v);
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}
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#define T(t...) { __LINE__, t }
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static vec4d_test_t vec4d_tests[] = {
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// 3D dot products
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T(dotd, right, right, one ),
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T(dotd, right, forward, zero ),
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T(dotd, right, up, zero ),
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T(dotd, forward, right, zero ),
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T(dotd, forward, forward, one ),
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T(dotd, forward, up, zero ),
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T(dotd, up, right, zero ),
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T(dotd, up, forward, zero ),
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T(dotd, up, up, one ),
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// one is 4D, so its self dot product is 4
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T(dotd, one, one, { 4, 4, 4, 4} ),
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T(dotd, one, none, {-4, -4, -4, -4} ),
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// 3D cross products
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T(crossd, right, right, zero ),
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T(crossd, right, forward, up ),
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T(crossd, right, up, nforward ),
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T(crossd, forward, right, nup ),
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T(crossd, forward, forward, zero ),
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T(crossd, forward, up, right ),
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T(crossd, up, right, forward ),
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T(crossd, up, forward, nright ),
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T(crossd, up, up, zero ),
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// double whammy tests: cross product with an angled vector and
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// ensuring that a 4d vector (non-zero w component) does not affect
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// the result, including the result's w component remaining zero.
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T(crossd, right, one, { 0, -1, 1} ),
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T(crossd, forward, one, { 1, 0, -1} ),
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T(crossd, up, one, {-1, 1, 0} ),
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T(crossd, one, right, { 0, 1, -1} ),
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T(crossd, one, forward, {-1, 0, 1} ),
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T(crossd, one, up, { 1, -1, 0} ),
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// This one fails when optimizing with -mfma (which is why fma is not
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// used): ulp errors in z and w
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T(crossd, qtest, qtest, {0, 0, 0, 0} ),
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T(qmuld, qident, qident, qident ),
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T(qmuld, qident, right, right ),
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T(qmuld, qident, forward, forward ),
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T(qmuld, qident, up, up ),
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T(qmuld, right, qident, right ),
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T(qmuld, forward, qident, forward ),
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T(qmuld, up, qident, up ),
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T(qmuld, right, right, nqident ),
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T(qmuld, right, forward, up ),
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T(qmuld, right, up, nforward ),
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T(qmuld, forward, right, nup ),
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T(qmuld, forward, forward, nqident ),
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T(qmuld, forward, up, right ),
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T(qmuld, up, right, forward ),
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T(qmuld, up, forward, nright ),
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T(qmuld, up, up, nqident ),
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T(qmuld, one, one, { 2, 2, 2, -2 } ),
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T(qmuld, one, { 2, 2, 2, -2 }, { 0, 0, 0, -8 } ),
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// This one fails when optimizing with -mfma (which is why fma is not
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// used): ulp error in z
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T(qmuld, qtest, qtest, {0.768, 0.576, 0, -0.28} ),
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// The one vector is not unit (magnitude 2), so using it as a rotation
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// quaternion results in scaling by 4. However, it still has the effect
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// of rotating 120 degrees around the axis equidistant from the three
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// orthogonal axes such that x->y->z->x
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T(qvmuld, one, right, { 0, 4, 0, 0 } ),
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T(qvmuld, one, forward, { 0, 0, 4, 0 } ),
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T(qvmuld, one, up, { 4, 0, 0, 0 } ),
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T(qvmuld, one, {1,1,1,0}, { 4, 4, 4, 0 } ),
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T(qvmuld, one, one, { 4, 4, 4, -2 } ),
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// inverse rotation, so x->z->y->x
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T(vqmuld, right, one, { 0, 0, 4, 0 } ),
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T(vqmuld, forward, one, { 4, 0, 0, 0 } ),
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T(vqmuld, up, one, { 0, 4, 0, 0 } ),
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T(vqmuld, {1,1,1,0}, one, { 4, 4, 4, 0 } ),
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T(vqmuld, one, one, { 4, 4, 4, -2 } ),
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// The half vector is unit.
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T(qvmuld, half, right, forward ),
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T(qvmuld, half, forward, up ),
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T(qvmuld, half, up, right ),
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T(qvmuld, half, {1,1,1,0}, { 1, 1, 1, 0 } ),
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// inverse
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T(vqmuld, right, half, up ),
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T(vqmuld, forward, half, right ),
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T(vqmuld, up, half, forward ),
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T(vqmuld, {1,1,1,0}, half, { 1, 1, 1, 0 } ),
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// one is a 4D vector and qvmuld is meant for 3D vectors. However, it
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// seems that the vector's w has no effect on the 3d portion of the
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// result, but the result's w is cosine of the full rotation angle
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// scaled by quaternion magnitude and vector w
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T(qvmuld, half, one, { 1, 1, 1, -0.5 } ),
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T(qvmuld, half, {2,2,2,2}, { 2, 2, 2, -1 } ),
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T(qvmuld, qtest, right, {0.5392, 0.6144, -0.576, 0} ),
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T(qvmuld, qtest, forward, {0.6144, 0.1808, 0.768, 0},
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{0, -2.7e-17, 0, 0} ),
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T(qvmuld, qtest, up, {0.576, -0.768, -0.28, 0} ),
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// inverse
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T(vqmuld, one, half, { 1, 1, 1, -0.5 } ),
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T(vqmuld, {2,2,2,2}, half, { 2, 2, 2, -1 } ),
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T(vqmuld, right, qtest, {0.5392, 0.6144, 0.576, 0} ),
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T(vqmuld, forward, qtest, {0.6144, 0.1808, -0.768, 0},
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{0, -2.7e-17, 0, 0} ),
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T(vqmuld, up, qtest, {-0.576, 0.768, -0.28, 0} ),
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T(qrotd, right, right, qident ),
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T(qrotd, right, forward, { 0, 0, s05, s05 },
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{0, 0, -1.1e-16, 0} ),
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T(qrotd, right, up, { 0, -s05, 0, s05 },
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{0, 1.1e-16, 0, 0} ),
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T(qrotd, forward, right, { 0, 0, -s05, s05 },
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{0, 0, 1.1e-16, 0} ),
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T(qrotd, forward, forward, qident ),
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T(qrotd, forward, up, { s05, 0, 0, s05 },
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{-1.1e-16, 0, 0, 0} ),
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T(qrotd, up, right, { 0, s05, 0, s05 },
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{0, -1.1e-16, 0, 0} ),
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T(qrotd, up, forward, { -s05, 0, 0, s05 },
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{ 1.1e-16, 0, 0, 0} ),
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T(qrotd, up, up, qident ),
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T(tvtruncd, { 1.1, 2.9, -1.1, -2.9 }, {}, { 1, 2, -1, -2 } ),
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T(tvceild, { 1.1, 2.9, -1.1, -2.9 }, {}, { 2, 3, -1, -2 } ),
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T(tvfloord, { 1.1, 2.9, -1.1, -2.9 }, {}, { 1, 2, -2, -3 } ),
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T(tqconjd, one, {}, { -1, -1, -1, 1 } ),
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};
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#define num_vec4d_tests (sizeof (vec4d_tests) / (sizeof (vec4d_tests[0])))
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static vec4f_test_t vec4f_tests[] = {
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// 3D dot products
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T(dotf, right, right, one ),
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T(dotf, right, forward, zero ),
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T(dotf, right, up, zero ),
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T(dotf, forward, right, zero ),
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T(dotf, forward, forward, one ),
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T(dotf, forward, up, zero ),
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T(dotf, up, right, zero ),
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T(dotf, up, forward, zero ),
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T(dotf, up, up, one ),
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// one is 4D, so its self dot product is 4
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T(dotf, one, one, { 4, 4, 4, 4} ),
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T(dotf, one, none, {-4, -4, -4, -4} ),
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// 3D cross products
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T(crossf, right, right, zero ),
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T(crossf, right, forward, up ),
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T(crossf, right, up, nforward ),
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T(crossf, forward, right, nup ),
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T(crossf, forward, forward, zero ),
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T(crossf, forward, up, right ),
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T(crossf, up, right, forward ),
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T(crossf, up, forward, nright ),
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T(crossf, up, up, zero ),
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// double whammy tests: cross product with an angled vector and
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// ensuring that a 4d vector (non-zero w component) does not affect
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// the result, including the result's w component remaining zero.
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T(crossf, right, one, { 0, -1, 1} ),
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T(crossf, forward, one, { 1, 0, -1} ),
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T(crossf, up, one, {-1, 1, 0} ),
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T(crossf, one, right, { 0, 1, -1} ),
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T(crossf, one, forward, {-1, 0, 1} ),
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T(crossf, one, up, { 1, -1, 0} ),
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#if !defined(__SSE__) && !defined(__OPTIMIZE__)
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// when not optimizing and SSE is not available (but ok when
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// optimizing)
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T(crossf, qtest, qtest, {0, 0, -1.47819534e-09, 0} ),
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#else
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T(crossf, qtest, qtest, {0, 0, 0, 0} ),
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#endif
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T(qmulf, qident, qident, qident ),
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T(qmulf, qident, right, right ),
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T(qmulf, qident, forward, forward ),
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T(qmulf, qident, up, up ),
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T(qmulf, right, qident, right ),
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T(qmulf, forward, qident, forward ),
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T(qmulf, up, qident, up ),
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T(qmulf, right, right, nqident ),
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T(qmulf, right, forward, up ),
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T(qmulf, right, up, nforward ),
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T(qmulf, forward, right, nup ),
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T(qmulf, forward, forward, nqident ),
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T(qmulf, forward, up, right ),
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T(qmulf, up, right, forward ),
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T(qmulf, up, forward, nright ),
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T(qmulf, up, up, nqident ),
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T(qmulf, one, one, { 2, 2, 2, -2 } ),
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T(qmulf, one, { 2, 2, 2, -2 }, { 0, 0, 0, -8 } ),
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T(qmulf, qtest, qtest, {0.768, 0.576, 0, -0.28},
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#if !defined(__SSE__) && !defined(__OPTIMIZE__)
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// when not optimizing and SSE is not available (but ok when
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// optimizing)
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{0, 6e-8, -1.47819534e-09, 3e-8}
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#elif !defined( __SSE__)
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{0, 6e-8, 0, 6e-8}
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#else
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{0, 6e-8, 0, 3e-8}
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#endif
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),
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// The one vector is not unit (magnitude 2), so using it as a rotation
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// quaternion results in scaling by 4. However, it still has the effect
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// of rotating 120 degrees around the axis equidistant from the three
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// orthogonal axes such that x->y->z->x
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T(qvmulf, one, right, { 0, 4, 0, 0 } ),
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T(qvmulf, one, forward, { 0, 0, 4, 0 } ),
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T(qvmulf, one, up, { 4, 0, 0, 0 } ),
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T(qvmulf, one, {1,1,1,0}, { 4, 4, 4, 0 } ),
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T(qvmulf, one, one, { 4, 4, 4, -2 } ),
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// inverse rotation, so x->z->y->x
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T(vqmulf, right, one, { 0, 0, 4, 0 } ),
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T(vqmulf, forward, one, { 4, 0, 0, 0 } ),
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T(vqmulf, up, one, { 0, 4, 0, 0 } ),
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T(vqmulf, {1,1,1,0}, one, { 4, 4, 4, 0 } ),
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T(vqmulf, one, one, { 4, 4, 4, -2 } ),
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//
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T(qvmulf, qtest, right, {0.5392, 0.6144, -0.576, 0},
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{0, -5.9e-8, -6e-8, 0} ),
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T(qvmulf, qtest, forward, {0.6144, 0.1808, 0.768, 0},
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#if !defined(__SSE__) && !defined(__OPTIMIZE__)
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{-5.9e-8, 0, 0, 0}
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#elif !defined(__SSE__)
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{-5.9e-8, 3e-8, 0, 0}
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#else
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{-5.9e-8, 1.5e-8, 0, 0}
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#endif
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),
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T(qvmulf, qtest, up, {0.576, -0.768, -0.28, 0},
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#if !defined(__SSE__) && !defined(__OPTIMIZE__)
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{6e-8, 0, 3e-8, 0}
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#elif !defined(__SSE__)
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{6e-8, 0, 6e-8, 0}
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#else
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{6e-8, 0, 3e-8, 0}
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#endif
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),
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T(vqmulf, right, qtest, {0.5392, 0.6144, 0.576, 0},
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{0, -5.9e-8, 5.9e-8, 0} ),
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T(vqmulf, forward, qtest, {0.6144, 0.1808, -0.768, 0},
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#if !defined(__SSE__) && !defined(__OPTIMIZE__)
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{-5.9e-8, 0, 0, 0}
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#elif !defined(__SSE__)
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{-5.9e-8, 3e-8, 0, 0}
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#else
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{-5.9e-8, 1.5e-8, 0, 0}
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#endif
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),
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T(vqmulf, up, qtest, {-0.576, 0.768, -0.28, 0},
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#if !defined(__SSE__) && !defined(__OPTIMIZE__)
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{-5.9e-8, 0, 3e-8, 0}
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#elif !defined(__SSE__)
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{-5.9e-8, 0, 6e-8, 0}
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#else
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{-5.9e-8, 0, 3e-8, 0}
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#endif
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),
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T(qrotf, right, right, qident ),
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T(qrotf, right, forward, { 0, 0, s05, s05 } ),
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T(qrotf, right, up, { 0, -s05, 0, s05 } ),
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T(qrotf, forward, right, { 0, 0, -s05, s05 } ),
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T(qrotf, forward, forward, qident ),
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T(qrotf, forward, up, { s05, 0, 0, s05 } ),
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T(qrotf, up, right, { 0, s05, 0, s05 } ),
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T(qrotf, up, forward, { -s05, 0, 0, s05 } ),
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T(qrotf, up, up, qident ),
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T(tvabsf, pmpi, {}, pi ),
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T(tvsqrtf, { 1, 4, 9, 16}, {}, {1, 2, 3, 4} ),
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T(tvtruncf, { 1.1, 2.9, -1.1, -2.9 }, {}, { 1, 2, -1, -2 } ),
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T(tvceilf, { 1.1, 2.9, -1.1, -2.9 }, {}, { 2, 3, -1, -2 } ),
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T(tvfloorf, { 1.1, 2.9, -1.1, -2.9 }, {}, { 1, 2, -2, -3 } ),
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T(tqconjf, one, {}, { -1, -1, -1, 1 } ),
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T(tmagnitudef, { 3, 4, 12, 84}, {}, {85, 85, 85, 85} ),
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T(tmagnitudef, { 3, 4, 12, -84}, {}, {85, 85, 85, 85} ),
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T(tmagnitudef, { 3, 4, -12, 84}, {}, {85, 85, 85, 85} ),
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T(tmagnitudef, { 3, 4, -12, -84}, {}, {85, 85, 85, 85} ),
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T(tmagnitudef, { 3, -4, 12, 84}, {}, {85, 85, 85, 85} ),
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T(tmagnitudef, { 3, -4, 12, -84}, {}, {85, 85, 85, 85} ),
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T(tmagnitudef, { 3, -4, -12, 84}, {}, {85, 85, 85, 85} ),
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T(tmagnitudef, { 3, -4, -12, -84}, {}, {85, 85, 85, 85} ),
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T(tmagnitudef, { -3, 4, 12, 84}, {}, {85, 85, 85, 85} ),
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T(tmagnitudef, { -3, 4, 12, -84}, {}, {85, 85, 85, 85} ),
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T(tmagnitudef, { -3, 4, -12, 84}, {}, {85, 85, 85, 85} ),
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T(tmagnitudef, { -3, 4, -12, -84}, {}, {85, 85, 85, 85} ),
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T(tmagnitudef, { -3, -4, 12, 84}, {}, {85, 85, 85, 85} ),
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T(tmagnitudef, { -3, -4, 12, -84}, {}, {85, 85, 85, 85} ),
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T(tmagnitudef, { -3, -4, -12, 84}, {}, {85, 85, 85, 85} ),
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T(tmagnitudef, { -3, -4, -12, -84}, {}, {85, 85, 85, 85} ),
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T(tmagnitude3f, { -3, -4, -12, -84}, {}, {13, 13, 13, 13} ),
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};
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#define num_vec4f_tests (sizeof (vec4f_tests) / (sizeof (vec4f_tests[0])))
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static mat4f_test_t mat4f_tests[] = {
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T(mmulf, identity, identity, identity ),
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T(mmulf, rotate120, identity, rotate120 ),
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T(mmulf, identity, rotate120, rotate120 ),
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T(mmulf, rotate120, rotate120, rotate240 ),
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T(mmulf, rotate120, rotate240, identity ),
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T(mmulf, rotate240, rotate120, identity ),
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};
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#define num_mat4f_tests (sizeof (mat4f_tests) / (sizeof (mat4f_tests[0])))
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static mv4f_test_t mv4f_tests[] = {
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T(mvmulf, identity, { 1, 0, 0, 0 }, { 1, 0, 0, 0 } ),
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T(mvmulf, identity, { 0, 1, 0, 0 }, { 0, 1, 0, 0 } ),
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T(mvmulf, identity, { 0, 0, 1, 0 }, { 0, 0, 1, 0 } ),
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T(mvmulf, identity, { 0, 0, 0, 1 }, { 0, 0, 0, 1 } ),
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T(mvmulf, rotate120, { 1, 2, 3, 4 }, { 3, 1, 2, 4 } ),
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T(mvmulf, rotate240, { 1, 2, 3, 4 }, { 2, 3, 1, 4 } ),
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};
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#define num_mv4f_tests (sizeof (mv4f_tests) / (sizeof (mv4f_tests[0])))
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// expect filled in using non-simd QuatToMatrix (has its own tests)
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static mq4f_test_t mq4f_tests[] = {
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T(mat4fquat, { 0, 0, 0, 1 } ),
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T(mat4fquat, { 0.5, 0.5, 0.5, 0.5 } ),
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T(mat4fquat, { 0.5, 0.5, -0.5, 0.5 } ),
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T(mat4fquat, { 0.5, -0.5, 0.5, 0.5 } ),
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T(mat4fquat, { 0.5, -0.5, -0.5, 0.5 } ),
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T(mat4fquat, { -0.5, 0.5, 0.5, 0.5 } ),
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T(mat4fquat, { -0.5, 0.5, -0.5, 0.5 } ),
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T(mat4fquat, { -0.5, -0.5, 0.5, 0.5 } ),
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T(mat4fquat, { -0.5, -0.5, -0.5, 0.5 } ),
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};
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#define num_mq4f_tests (sizeof (mq4f_tests) / (sizeof (mq4f_tests[0])))
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static int
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run_vec4d_tests (void)
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{
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int ret = 0;
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for (size_t i = 0; i < num_vec4d_tests; i++) {
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__auto_type test = &vec4d_tests[i];
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vec4d_t result = test->op (test->a, test->b);
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vec4d_t expect = test->expect + test->ulp_errors;
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vec4l_t res = result != expect;
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if (res[0] || res[1] || res[2] || res[3]) {
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ret |= 1;
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printf ("\nrun_vec4d_tests %zd, line %d\n", i, test->line);
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printf ("a: " VEC4D_FMT "\n", VEC4_EXP(test->a));
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printf ("b: " VEC4D_FMT "\n", VEC4_EXP(test->b));
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printf ("r: " VEC4D_FMT "\n", VEC4_EXP(result));
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printf ("t: " VEC4L_FMT "\n", VEC4_EXP(res));
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printf ("E: " VEC4D_FMT "\n", VEC4_EXP(expect));
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printf ("e: " VEC4D_FMT "\n", VEC4_EXP(test->expect));
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printf ("u: " VEC4D_FMT "\n", VEC4_EXP(test->ulp_errors));
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}
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}
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return ret;
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}
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static int
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run_vec4f_tests (void)
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{
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int ret = 0;
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for (size_t i = 0; i < num_vec4f_tests; i++) {
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__auto_type test = &vec4f_tests[i];
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vec4f_t result = test->op (test->a, test->b);
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vec4f_t expect = test->expect + test->ulp_errors;
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vec4i_t res = (vec4i_t) result != (vec4i_t) expect;
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if (res[0] || res[1] || res[2] || res[3]) {
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ret |= 1;
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printf ("\nrun_vec4f_tests %zd, line %d\n", i, test->line);
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printf ("a: " VEC4F_FMT "\n", VEC4_EXP(test->a));
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printf ("b: " VEC4F_FMT "\n", VEC4_EXP(test->b));
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printf ("r: " VEC4F_FMT "\n", VEC4_EXP(result));
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printf ("t: " VEC4I_FMT "\n", VEC4_EXP(res));
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printf ("E: " VEC4F_FMT "\n", VEC4_EXP(expect));
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printf ("e: " VEC4F_FMT "\n", VEC4_EXP(test->expect));
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printf ("u: " VEC4F_FMT "\n", VEC4_EXP(test->ulp_errors));
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}
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}
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return ret;
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}
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static int
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run_mat4f_tests (void)
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{
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int ret = 0;
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for (size_t i = 0; i < num_mat4f_tests; i++) {
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__auto_type test = &mat4f_tests[i];
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mat4f_t result;
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mat4f_t expect;
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mat4i_t res = {};
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test->op (result, test->a, test->b);
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maddf (expect, test->expect, test->ulp_errors);
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int fail = 0;
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for (int j = 0; j < 4; j++) {
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res[j] = result[j] != expect[j];
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fail |= res[j][0] || res[j][1] || res[j][2] || res[j][3];
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}
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if (fail) {
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ret |= 1;
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printf ("\nrun_mat4f_tests %zd, line %d\n", i, test->line);
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printf ("a: " VEC4F_FMT "\n", MAT4_ROW(test->a, 0));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->a, 1));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->a, 2));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->a, 3));
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printf ("b: " VEC4F_FMT "\n", MAT4_ROW(test->b, 0));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->b, 1));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->b, 2));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->b, 3));
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printf ("r: " VEC4F_FMT "\n", MAT4_ROW(result, 0));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(result, 1));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(result, 2));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(result, 3));
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printf ("t: " VEC4I_FMT "\n", MAT4_ROW(res, 0));
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printf (" " VEC4I_FMT "\n", MAT4_ROW(res, 1));
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printf (" " VEC4I_FMT "\n", MAT4_ROW(res, 2));
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printf (" " VEC4I_FMT "\n", MAT4_ROW(res, 3));
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printf ("E: " VEC4F_FMT "\n", MAT4_ROW(expect, 0));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(expect, 1));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(expect, 2));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(expect, 3));
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printf ("e: " VEC4F_FMT "\n", MAT4_ROW(test->expect, 0));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->expect, 1));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->expect, 2));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->expect, 3));
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printf ("u: " VEC4F_FMT "\n", MAT4_ROW(test->ulp_errors, 0));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->ulp_errors, 1));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->ulp_errors, 2));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->ulp_errors, 3));
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}
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}
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return ret;
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}
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static int
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run_mv4f_tests (void)
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{
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int ret = 0;
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for (size_t i = 0; i < num_mv4f_tests; i++) {
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__auto_type test = &mv4f_tests[i];
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vec4f_t result = test->op (test->a, test->b);
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vec4f_t expect = test->expect + test->ulp_errors;
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vec4i_t res = result != expect;
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if (res[0] || res[1] || res[2] || res[3]) {
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ret |= 1;
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printf ("\nrun_mv4f_tests %zd, line %d\n", i, test->line);
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printf ("a: " VEC4F_FMT "\n", MAT4_ROW(test->a, 0));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->a, 1));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->a, 2));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->a, 3));
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printf ("b: " VEC4F_FMT "\n", VEC4_EXP(test->b));
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printf ("r: " VEC4F_FMT "\n", VEC4_EXP(result));
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printf ("t: " VEC4I_FMT "\n", VEC4_EXP(res));
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printf ("E: " VEC4F_FMT "\n", VEC4_EXP(expect));
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printf ("e: " VEC4F_FMT "\n", VEC4_EXP(test->expect));
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printf ("u: " VEC4F_FMT "\n", VEC4_EXP(test->ulp_errors));
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}
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}
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return ret;
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}
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static int
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run_mq4f_tests (void)
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{
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int ret = 0;
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for (size_t i = 0; i < num_mq4f_tests; i++) {
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__auto_type test = &mq4f_tests[i];
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quat_t q;
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vec_t m[16];
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memcpy (q, &test->q, sizeof (quat_t));
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QuatToMatrix (q, m, 1, 1);
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memcpy (&test->expect, m, sizeof (mat4f_t));
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}
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for (size_t i = 0; i < num_mq4f_tests; i++) {
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__auto_type test = &mq4f_tests[i];
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mat4f_t result;
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mat4f_t expect;
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mat4i_t res = {};
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test->op (result, test->q);
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maddf (expect, test->expect, test->ulp_errors);
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memcpy (expect, (void *) &test->expect, sizeof (mat4f_t));
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int fail = 0;
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for (int j = 0; j < 4; j++) {
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res[j] = result[j] != expect[j];
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fail |= res[j][0] || res[j][1] || res[j][2] || res[j][3];
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}
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if (fail) {
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ret |= 1;
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printf ("\nrun_mq4f_tests %zd, line %d\n", i, test->line);
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printf ("q: " VEC4F_FMT "\n", VEC4_EXP(test->q));
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printf ("r: " VEC4F_FMT "\n", MAT4_ROW(result, 0));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(result, 1));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(result, 2));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(result, 3));
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printf ("t: " VEC4I_FMT "\n", MAT4_ROW(res, 0));
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printf (" " VEC4I_FMT "\n", MAT4_ROW(res, 1));
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printf (" " VEC4I_FMT "\n", MAT4_ROW(res, 2));
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printf (" " VEC4I_FMT "\n", MAT4_ROW(res, 3));
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printf ("E: " VEC4F_FMT "\n", MAT4_ROW(expect, 0));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(expect, 1));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(expect, 2));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(expect, 3));
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printf ("e: " VEC4F_FMT "\n", MAT4_ROW(test->expect, 0));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->expect, 1));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->expect, 2));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->expect, 3));
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printf ("u: " VEC4F_FMT "\n", MAT4_ROW(test->ulp_errors, 0));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->ulp_errors, 1));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->ulp_errors, 2));
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printf (" " VEC4F_FMT "\n", MAT4_ROW(test->ulp_errors, 3));
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}
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}
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return ret;
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}
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int
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main (void)
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{
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int ret = 0;
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ret |= run_vec4d_tests ();
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ret |= run_vec4f_tests ();
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ret |= run_mat4f_tests ();
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ret |= run_mv4f_tests ();
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ret |= run_mq4f_tests ();
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return ret;
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}
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