I'm working on optimizing a 4D (128 Bit) matrix-vector multiplication using ARM NEON Assembler.

If I load the matrix, and the vector into the NEON Registers and transform it, I won't get a great performance boost, because the switch to the NEON Registers cost 20 cycles. Furthermore I reload the matrix for each multiplication, despite it has not changed.

There is enough register-space to perform the transformation on more vectors a time. This IS increasing performance.

But..

I'm wondering how fast this operation would be if I do the loop over all vertices (increasing pointers) within the assembler. But I am at the very beginning of Neon assembler and though don't know how to do this. Can someone give me an hand on that?

What I want to achieve:

- load matrix and first vector
- store loop count "count" and..
- -- LOOP_START --
- perform multiply-adds (do the Transformation)
- write q0 to vOut
- increase pointers vIn and vOut by 4 (128 Bit)
- LOAD vIn to q5.
- -- LOOP_END --

existing C-Version of loop:

```
void TransformVertices(ESMatrix* m, GLfloat* vertices, GLfloat* normals, int count)
{
GLfloat* pVertex = vertices;
int i;
// iterate trough vertices only one at a time
for (i = 0; i < count ; i ++)
{
Matrix4Vector4Mul( (float *)m, (float *)pVertex, (float *)pVertex);
pVertex += 4;
}
//LoadMatrix( (const float*) m);
//// two at a time
//for (i = 0; i < count ; i += 2)
//{
// Matrix4Vector4Mul2( (float *)m, (float *)pVertex, (float *)(pVertex + 4));
// pVertex += 8;
//}
}
```

Following code for NEON-Version on doing only one transformation:

```
void Matrix4Vector4Mul (const float* m, const float* vIn, float* vOut)
{
asm volatile
(
"vldmia %1, {q1-q4 } \n\t"
"vldmia %2, {q5} \n\t"
"vmul.f32 q0, q1, d10[0] \n\t"
"vmla.f32 q0, q2, d10[1] \n\t"
"vmla.f32 q0, q3, d11[0] \n\t"
"vmla.f32 q0, q4, d11[1] \n\t"
"vstmia %0, {q0}"
: // no output
: "r" (vOut), "r" (m), "r" (vIn)
: "memory", "q0", "q1", "q2", "q3", "q4", "q5"
);
}
```

C-Version of transformation:

```
void Matrix4Vector4Mul (const float* m, const float* vIn, float* vOut)
{
Vertex4D* v1 = (Vertex4D*)vIn;
Vertex4D vOut1;
Vertex4D* l0;
Vertex4D* l1;
Vertex4D* l2;
Vertex4D* l3;
// 4x4 Matrix with members m00 - m33
ESMatrix* m1 = (ESMatrix*)m;
l0 = (Vertex4D*)&m1->m00;
vOut1.x = l0->x * v1->x;
vOut1.y = l0->y * v1->x;
vOut1.z = l0->z * v1->x;
vOut1.w = l0->w * v1->x;
l1 = (Vertex4D*)&m1->m10;
vOut1.x += l1->x * v1->y;
vOut1.y += l1->y * v1->y;
vOut1.z += l1->z * v1->y;
vOut1.w += l1->w * v1->y;
l2 = (Vertex4D*)&m1->m20;
vOut1.x += l2->x * v1->z;
vOut1.y += l2->y * v1->z;
vOut1.z += l2->z * v1->z;
vOut1.w += l2->w * v1->z;
l3 = (Vertex4D*)&m1->m30;
vOut1.x += l3->x * v1->w;
vOut1.y += l3->y * v1->w;
vOut1.z += l3->z * v1->w;
vOut1.w += l3->w * v1->w;
*(vOut) = vOut1.x;
*(vOut + 1) = vOut1.y;
*(vOut + 2) = vOut1.z;
*(vOut + 3) = vOut1.w;
}
```

Performance: (Transform > 90 000 Vertices | Android 4.0.4 SGS II)

```
C-Version: 190 FPS
NEON-Version: 162 FPS ( .. slower -.- )
--- LOAD Matrix only ONCE (seperate ASM) and then perform two V's at a time ---
NEON-Version: 217 FPS ( + 33 % NEON | + 14 % C-Code )
```