sim/testsuite/bfin/fir.s - binutils-gdb - Git at Google

 # mach: bfin

 // FIR FILTER COMPTUED DIRECTLY ON INPUT WITH NO
 //   INTERNAL STATE
 //   TWO OUTPUTS PER ITERATION
 // This program computes a FIR filter without maintaining a buffer of internal
 // state.
 // This example computes two output samples per inner loop. The following
 // diagram shows the alignment required for signal x and coefficients c:
 // x0 x1 x2 x3 x4 x5
 // c0 c1 c2 c3 c4      -> output z(0)=x0*c0 + x1*c1 + ...
 //    c0 c1 c2 c3 c4   ->        z(1)=x1*c0 + x2*c1 + ...
 //	       L-1
 //               ---
 //      Z(k) =   \   c(n) * x(n+k)
 //               /
 //	         ---
 //       	       n=0
 // Naive, first stab at spliting this for dual MACS.
 //	       L/2-1                     L/2-1
 //               --- 		           ---
 //      R(k) =   \   (x(2n) * y(2n+k))  +  \   (x(2n-1) * y(2n-1+k))
 //               /  		           /
 //	         --- 		           ---
 //       	       n=0		         n=0
 // Alternate, better partitioning for the machine.
 //	       L-1
 //               ---
 //      R(0) =   \   x(n) * y(n)
 //               /
 //	         ---
 //       	 n=0
 //	       L-1
 //               ---
 //      R(1) =   \   x(n) * y(n+1)
 //               /
 //	         ---
 //              n=0
 //	       L-1
 //               ---
 //      R(2) =   \   x(n) * y(n+2)
 //               /
 //	         ---
 //              n=0
 //	       L-1
 //               ---
 //      R(3) =   \   x(n) * y(n+3)
 //               /
 //	         ---
 //               n=0
 //		.
 //		.
 //		.
 //		.
 // Okay in this verion the inner loop will compute R(2k) and R(2k+1) in parallel
 //	       L-1
 //               ---
 //     R(2k) =   \   x(n) * y(n+2k)
 //               /
 //	         ---
 //              n=0
 //	       L-1
 //               ---
 //   R(2k+1) =   \   x(n) * y(n+2k+1)
 //               /
 //	         ---
 //              n=0
 // Implementation
 // --------------
 // Sample pair x1 x0 is loaded into register R0, and coefficients c1 c0
 // is loaded into register R1:
 // +-------+ R0
 // | x1 x0 |
 // +-------+
 // +-------+ R1
 // | c1 c0 |  compute two MACs: z(0)+=x0*c0, and z(1)+=x1*c0
 // +-------+
 // Now load x2 into lo half of R0, and compute the next two MACs:
 // +-------+ R0
 // | x1 x2 |
 // +-------+
 // +-------+ R1
 // | c1 c0 |    compute z(0)+=x1*c1 and z(1)+=x2*c1 (c0 not used)
 // +-------+
 // Meanwhile, load coefficient pair c3 c2 into R2, and x3 into hi half of R0:
 // +-------+ R0
 // | x3 x2 |
 // +-------+
 // +-------+ R2
 // | c3 c2 |    compute z(0)+=x2*c2 and z(1)+=x3*c2 (c3 not used)
 // +-------+
 // Load x4 into low half of R0:
 // +-------+ R0
 // | x3 x4 |
 // +-------+
 // +-------+ R1
 // | c3 c2 |    compute z(0)+=x3*c3 and z(1)+=x4*c3 (c2 not used)
 // +-------+
 // //This is a reference FIR function used to test: */
 //void firf (float input[], float  output[], float coeffs[],
 //           long input_size, long coeffs_size)
 //{
 //  long i, k;
 //  for(i=0;	i< input_size; i++){
 //    output[i] = 0;
 //    for(k=0;	k < coeffs_size; k++)
 //	output[i] += input[k+i] * coeffs[k];
 // }
 //}

 .include "testutils.inc"
 	start


 	R0 = 0;	R1 = 0; R2 = 0;
 	P1 = 128 (X);	// Load loop bounds in R5, R6, and divide by 2
 	P2 = 64 (X);

 	// P0 holds pointer to input data in one memory
 	// bank. Increments by 2 after each inner-loop iter
 	loadsym P0, input;

 	// Pointer to coeffs in alternate memory bank.
 	loadsym I1, coef;

 	// Pointer to outputs in any memory bank.
 	loadsym I2, output;

 	// Setup outer do-loop for M/2 iterations
 	// (2 outputs are computed per pass)

 	LSETUP ( L$0 , L$0end ) LC0 = P1 >> 1;

 L$0:
 	loadsym I1, coef;
 	I0 = P0;
 		// Set-up inner do-loop for L/2 iterations
 		// (2 MACs are computed per pass)

 	LSETUP ( L$1 , L$1end ) LC1 = P2 >> 1;

 		// Load first two data elements in r0,
 		// and two coeffs into r1:

 	R0.L = W [ I0 ++ ];
 	A1 = A0 = 0 || R0.H = W [ I0 ++ ] || R1 = [ I1 ++ ];

 L$1:
 	A1 += R0.H * R1.L, A0 += R0.L * R1.L || R0.L = W [ I0 ++ ] || NOP;
 L$1end:
 	A1 += R0.L * R1.H, A0 += R0.H * R1.H || R0.H = W [ I0 ++ ] || R1 = [ I1 ++ ];

 	// Line 1: do 2 MACs and load next data element into RL0.
 	// Line 2: do 2 MACs, load next data element into RH0,
 	// and load next 2 coeffs

 	R0.H = A1, R0.L = A0;

 		// advance data pointer by 2 16b elements
 	P0 += 4;

 L$0end:
 	[ I2 ++ ] = R0;	// store 2 outputs

 	// Check results
 	loadsym I2, output;

 	R0.L = W [ I2 ++ ];	DBGA ( R0.L , 0x0800 );
 	R0.L = W [ I2 ++ ];	DBGA ( R0.L , 0x1000 );
 	R0.L = W [ I2 ++ ];	DBGA ( R0.L , 0x2000 );
 	R0.L = W [ I2 ++ ];	DBGA ( R0.L , 0x1000 );
 	R0.L = W [ I2 ++ ];	DBGA ( R0.L , 0x0800 );
 	pass

 	.data
 input:
 	.dw 0x0000
 	.dw 0x0000
 	.dw 0x0000
 	.dw 0x0000
 	.dw 0x4000
 	.dw 0x0000
 	.dw 0x0000
 	.dw 0x0000
 	.dw 0x0000
 	.dw 0x0000
 	.space ((128-10)*2);	// must pad with zeros or uninitialized values.

 	.data
 coef:
 	.dw 0x1000
 	.dw 0x2000
 	.dw 0x4000
 	.dw 0x2000
 	.dw 0x1000
 	.dw 0x0000
 	.space ((64-6)*2);	// must pad with zeros or uninitialized values.

 	.data
 output:
 	.space (128*4)
	# mach: bfin

	// FIR FILTER COMPTUED DIRECTLY ON INPUT WITH NO
	// INTERNAL STATE
	// TWO OUTPUTS PER ITERATION
	// This program computes a FIR filter without maintaining a buffer of internal
	// state.
	// This example computes two output samples per inner loop. The following
	// diagram shows the alignment required for signal x and coefficients c:
	// x0 x1 x2 x3 x4 x5
	// c0 c1 c2 c3 c4 -> output z(0)=x0c0 + x1c1 + ...
	// c0 c1 c2 c3 c4 -> z(1)=x1c0 + x2c1 + ...
	// L-1
	// ---
	// Z(k) = \ c(n) * x(n+k)
	// /
	// ---
	// n=0
	// Naive, first stab at spliting this for dual MACS.
	// L/2-1 L/2-1
	// --- ---
	// R(k) = \ (x(2n) * y(2n+k)) + \ (x(2n-1) * y(2n-1+k))
	// / /
	// --- ---
	// n=0 n=0
	// Alternate, better partitioning for the machine.
	// L-1
	// ---
	// R(0) = \ x(n) * y(n)
	// /
	// ---
	// n=0
	// L-1
	// ---
	// R(1) = \ x(n) * y(n+1)
	// /
	// ---
	// n=0
	// L-1
	// ---
	// R(2) = \ x(n) * y(n+2)
	// /
	// ---
	// n=0
	// L-1
	// ---
	// R(3) = \ x(n) * y(n+3)
	// /
	// ---
	// n=0
	// .
	// .
	// .
	// .
	// Okay in this verion the inner loop will compute R(2k) and R(2k+1) in parallel
	// L-1
	// ---
	// R(2k) = \ x(n) * y(n+2k)
	// /
	// ---
	// n=0
	// L-1
	// ---
	// R(2k+1) = \ x(n) * y(n+2k+1)
	// /
	// ---
	// n=0
	// Implementation
	// --------------
	// Sample pair x1 x0 is loaded into register R0, and coefficients c1 c0
	// is loaded into register R1:
	// +-------+ R0
	// \| x1 x0 \|
	// +-------+
	// +-------+ R1
	// \| c1 c0 \| compute two MACs: z(0)+=x0c0, and z(1)+=x1c0
	// +-------+
	// Now load x2 into lo half of R0, and compute the next two MACs:
	// +-------+ R0
	// \| x1 x2 \|
	// +-------+
	// +-------+ R1
	// \| c1 c0 \| compute z(0)+=x1c1 and z(1)+=x2c1 (c0 not used)
	// +-------+
	// Meanwhile, load coefficient pair c3 c2 into R2, and x3 into hi half of R0:
	// +-------+ R0
	// \| x3 x2 \|
	// +-------+
	// +-------+ R2
	// \| c3 c2 \| compute z(0)+=x2c2 and z(1)+=x3c2 (c3 not used)
	// +-------+
	// Load x4 into low half of R0:
	// +-------+ R0
	// \| x3 x4 \|
	// +-------+
	// +-------+ R1
	// \| c3 c2 \| compute z(0)+=x3c3 and z(1)+=x4c3 (c2 not used)
	// +-------+
	// //This is a reference FIR function used to test: */
	//void firf (float input[], float output[], float coeffs[],
	// long input_size, long coeffs_size)
	//{
	// long i, k;
	// for(i=0; i< input_size; i++){
	// output[i] = 0;
	// for(k=0; k < coeffs_size; k++)
	// output[i] += input[k+i] * coeffs[k];
	// }
	//}

	.include "testutils.inc"
	start


	R0 = 0; R1 = 0; R2 = 0;
	P1 = 128 (X); // Load loop bounds in R5, R6, and divide by 2
	P2 = 64 (X);

	// P0 holds pointer to input data in one memory
	// bank. Increments by 2 after each inner-loop iter
	loadsym P0, input;

	// Pointer to coeffs in alternate memory bank.
	loadsym I1, coef;

	// Pointer to outputs in any memory bank.
	loadsym I2, output;

	// Setup outer do-loop for M/2 iterations
	// (2 outputs are computed per pass)

	LSETUP ( L$0 , L$0end ) LC0 = P1 >> 1;

	L$0:
	loadsym I1, coef;
	I0 = P0;
	// Set-up inner do-loop for L/2 iterations
	// (2 MACs are computed per pass)

	LSETUP ( L$1 , L$1end ) LC1 = P2 >> 1;

	// Load first two data elements in r0,
	// and two coeffs into r1:

	R0.L = W [ I0 ++ ];
	A1 = A0 = 0 \|\| R0.H = W [ I0 ++ ] \|\| R1 = [ I1 ++ ];

	L$1:
	A1 += R0.H * R1.L, A0 += R0.L * R1.L \|\| R0.L = W [ I0 ++ ] \|\| NOP;
	L$1end:
	A1 += R0.L * R1.H, A0 += R0.H * R1.H \|\| R0.H = W [ I0 ++ ] \|\| R1 = [ I1 ++ ];

	// Line 1: do 2 MACs and load next data element into RL0.
	// Line 2: do 2 MACs, load next data element into RH0,
	// and load next 2 coeffs

	R0.H = A1, R0.L = A0;

	// advance data pointer by 2 16b elements
	P0 += 4;

	L$0end:
	[ I2 ++ ] = R0; // store 2 outputs

	// Check results
	loadsym I2, output;

	R0.L = W [ I2 ++ ]; DBGA ( R0.L , 0x0800 );
	R0.L = W [ I2 ++ ]; DBGA ( R0.L , 0x1000 );
	R0.L = W [ I2 ++ ]; DBGA ( R0.L , 0x2000 );
	R0.L = W [ I2 ++ ]; DBGA ( R0.L , 0x1000 );
	R0.L = W [ I2 ++ ]; DBGA ( R0.L , 0x0800 );
	pass

	.data
	input:
	.dw 0x0000
	.dw 0x0000
	.dw 0x0000
	.dw 0x0000
	.dw 0x4000
	.dw 0x0000
	.dw 0x0000
	.dw 0x0000
	.dw 0x0000
	.dw 0x0000
	.space ((128-10)*2); // must pad with zeros or uninitialized values.

	.data
	coef:
	.dw 0x1000
	.dw 0x2000
	.dw 0x4000
	.dw 0x2000
	.dw 0x1000
	.dw 0x0000
	.space ((64-6)*2); // must pad with zeros or uninitialized values.

	.data
	output:
	.space (128*4)