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[/] [openrisc/] [trunk/] [orpsocv2/] [sw/] [tests/] [or1200/] [sim/] [or1200-ov.S] - Rev 628
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/*
OR1200 overflow bit checking
Very basic, testing
TODO: Check range exception handling in delay slots
Julius Baxter, ORSoC AB, julius.baxter@orsoc.se
*/
//////////////////////////////////////////////////////////////////////
//// ////
//// Copyright (C) 2011 Authors and OPENCORES.ORG ////
//// ////
//// This source file may be used and distributed without ////
//// restriction provided that this copyright statement is not ////
//// removed from the file and that any derivative work contains ////
//// the original copyright notice and the associated disclaimer. ////
//// ////
//// This source file is free software; you can redistribute it ////
//// and/or modify it under the terms of the GNU Lesser General ////
//// Public License as published by the Free Software Foundation; ////
//// either version 2.1 of the License, or (at your option) any ////
//// later version. ////
//// ////
//// This source is distributed in the hope that it will be ////
//// useful, but WITHOUT ANY WARRANTY; without even the implied ////
//// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR ////
//// PURPOSE. See the GNU Lesser General Public License for more ////
//// details. ////
//// ////
//// You should have received a copy of the GNU Lesser General ////
//// Public License along with this source; if not, download it ////
//// from http://www.opencores.org/lgpl.shtml ////
//// ////
//////////////////////////////////////////////////////////////////////
#include "spr-defs.h"
#include "board.h"
#include "or1200-defines.h"
/* =================================================== [ exceptions ] === */
.section .vectors, "ax"
/* ---[ 0x100: RESET exception ]----------------------------------------- */
.org 0x100
l.movhi r0, 0
/* Clear status register */
l.ori r1, r0, SPR_SR_SM
l.mtspr r0, r1, SPR_SR
/* Clear timer */
l.mtspr r0, r0, SPR_TTMR
/* Jump to program initialisation code */
.global _start
l.movhi r4, hi(_start)
l.ori r4, r4, lo(_start)
l.jr r4
l.nop
.org 0x600
l.nop 0x1
/* ---[ 0x700: Illegal instruction exception ]-------------------------- */
.org 0x700
#ifndef OR1200_IMPL_ADDC
// No problem - instruction not supported
l.movhi r3, hi(0x8000000d)
l.ori r3, r3, lo(0x8000000d)
l.nop 0x2
l.ori r3, r0, 0
#else
l.ori r3, r0, 1
#endif
l.nop 0x1
#define INCREMENT_EXCEPTION_COUNTER l.addi r11, r11, 0x1
#define CHECK_EXCEPTION_COUNTER \
l.sfne r11, r12 ; \
l.bf _fail ; \
l.nop ;
#define EXPECT_RANGE_EXCEPT \
l.addi r12, r12, 1 ; \
CHECK_EXCEPTION_COUNTER
/* ---[ 0xb00: Range exception ]---------------------------------------- */
.org 0xb00
l.sw 0(r0), r3 ;// Save r3 - don't disrupt it during exceptions
l.ori r3, r0, 0xaaee
l.nop 0x2
// TODO - get instruction and decode to ensure it was an instruction
// which is capable of causing a range exception. Remember delay slot!
INCREMENT_EXCEPTION_COUNTER
// Clear OV in ESR
l.mfspr r3,r0,SPR_ESR_BASE ;// Get ESR
l.nop 2
l.xori r3, r3,SPR_SR_OV ;// Clear OV bit
l.mtspr r0,r3,SPR_ESR_BASE ;// Get EPC
l.mfspr r3,r0,SPR_EPCR_BASE ;// Get EPC
l.nop 2
l.addi r3, r3, 0x4 ;// Increment
l.mtspr r0,r3,SPR_EPCR_BASE ;// Get EPC
// For now, increment EPCR so we step over instruction and continue
l.lwz r3, 0(r0)
l.rfe
/* =================================================== [ text ] === */
.section .text
/* =================================================== [ start ] === */
.global _start
_start:
// Clear all regs
l.movhi r1, 0
l.movhi r2, 0
l.movhi r3, 0
l.movhi r4, 0
l.movhi r5, 0
l.movhi r6, 0
l.movhi r7, 0
l.movhi r8, 0
l.movhi r9, 0
l.movhi r10, 0
l.movhi r11, 0
l.movhi r12, 0
l.movhi r13, 0
l.movhi r14, 0
l.movhi r15, 0
l.movhi r16, 0
l.movhi r17, 0
l.movhi r18, 0
l.movhi r19, 0
l.movhi r20, 0
l.movhi r21, 0
l.movhi r22, 0
l.movhi r23, 0
l.movhi r24, 0
l.movhi r25, 0
l.movhi r26, 0
l.movhi r27, 0
l.movhi r28, 0
l.movhi r29, 0
l.movhi r30, 0
l.movhi r31, 0
#ifdef OR1200_IMPL_OV
// Kick off test
l.jal _main
#else
// Not supported, exit test
l.j _finish
#endif
l.nop
/* =================================================== [ main ] === */
#define CHECK_OV_CLEAR \
l.mfspr r20, r0, SPR_SR ; \
l.andi r21, r20, SPR_SR_OV ; \
l.sfne r21, r0 ; \
l.bf _fail ; \
l.nop
#define CHECK_OV_SET \
l.mfspr r20, r0, SPR_SR ; \
l.andi r21, r20, SPR_SR_OV ; \
l.sfnei r21, SPR_SR_OV ; \
l.bf _fail ; \
l.addi r12, r12, 0x1 ; // Increment expected counter
.global _main
_main:
// Set up some values, check the OV bit is cleared
CHECK_OV_CLEAR
l.movhi r4, 0x7fff
l.ori r4, r4, 0xefff
l.ori r5, r0, 0xffff
l.add r3, r5, r4 ;// Should set overflow
l.nop 0x2
CHECK_OV_SET
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_OV_CLEAR
l.addi r3, r4, 0x7fff ;// Should set overflow
l.nop 0x2
CHECK_OV_SET
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_OV_CLEAR
// Now test negative numbers
l.movhi r4, 0x8000
l.ori r4, r4, 0x0000
l.movhi r5, 0xffff
l.ori r5, r5, 0xffff
l.add r3, r4, r5 // Biggest and smallest negative number
l.nop 0x2
CHECK_OV_SET
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_OV_CLEAR
l.addi r3, r4, 0xffff // Biggest and smallest negative number
l.nop 0x2
CHECK_OV_SET
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_OV_CLEAR
l.add r3, r4, r0 // Biggest negative number, and zero
l.nop 0x2
CHECK_OV_CLEAR
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_OV_CLEAR
l.movhi r5, 0xffff
l.ori r5, r5, 0xfffe
l.add r3, r4, r5 // Biggest and second smallest negative number
l.nop 0x2
CHECK_OV_SET
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_OV_CLEAR
#ifdef OR1200_IMPL_SUB
// report indicator that we're at l.sub section 0x55555555
l.movhi r3, 0x5555
l.ori r3, r3, 0x5555
l.nop 0x2
// Quick subtract check
// Check largest negative number -1 tripping overflow
l.ori r5, r0, 1 ; // +1
l.sub r3, r4, r5 ; // -2147483647 - 1
l.nop 0x2
CHECK_OV_SET
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_OV_CLEAR
#endif
l.movhi r4, 0x8000
l.ori r4, r4, 0x0437
l.movhi r5, 0xffff
l.ori r5, r5, 0xfbc7
l.add r3, r4, r5 // Very big negative number, another one big
// enough to cause overflow hopefully
l.nop 0x2
CHECK_OV_SET
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_OV_CLEAR
l.movhi r5, 0xffff
l.ori r5, r5, 0xfff7
l.add r3, r4, r5 // Two negative numbers but shouldn't overflow
l.nop 0x2
CHECK_OV_CLEAR
#ifdef OR1200_DIV_IMPLEMENTED
// report indicator that we're at l.div section 0xdddddddd
l.movhi r3, 0xdddd
l.ori r3, r3, 0xdddd
l.nop 0x2
// Test divide by zero
l.div r3, r5, r0
l.nop 0x2
l.sfne r3, r0 ;// Check result was 0
l.bf _fail
CHECK_OV_SET
l.add r3, r5, r0 ;// Should clear overflow
l.nop 0x2
CHECK_OV_CLEAR
// Test divide by zero
l.divu r3, r0, r0
l.nop 0x2
CHECK_OV_SET
l.sfne r3, r0 ;// Check result was 0
l.bf _fail
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_OV_CLEAR
#endif
#ifdef OR1200_MULT_IMPLEMENTED
// report indicator that we're at l.multiply section 0x11111111
l.movhi r3, 0x1111
l.ori r3, r3, 0x1111
l.nop 0x2
// Check multiplying two large numbers, which will cause overflow,
// trigger the flag appropriately
// First signed multiply.
l.movhi r4, 0xd555 ;//-(((2^32)-1)/3 + 2)
l.ori r4, r4, 0x5552
l.ori r5, r0, 2
l.ori r6, r0, 3
// First multiply big negative number by 2 - shouldn't overflow
l.mul r3, r4, r5
l.nop 0x2
CHECK_OV_CLEAR
// Now multiply by 3 - should just overflow negative
l.mul r3, r4, r6
l.nop 0x2
CHECK_OV_SET
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_OV_CLEAR
// Now some big positive values
l.movhi r4, 0x2aaa ;//((2^32)-1)/3 + 2
l.ori r4, r4, 0xaaae
l.ori r5, r0, 2
l.ori r6, r0, 3
// First multiply big number by 2 - shouldn't overflow
l.mul r3, r4, r5
l.nop 0x2
CHECK_OV_CLEAR
// Now multiply by 3 - should only just overflow
l.mul r3, r4, r6
l.nop 0x2
CHECK_OV_SET
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_OV_CLEAR
// First multiply big number by 2 - shouldn't overflow
l.muli r3, r4, 0x2
l.nop 0x2
CHECK_OV_CLEAR
// Now multiply by 3 - should just overflow negative
l.muli r3, r4, 0x3
l.nop 0x2
CHECK_OV_SET
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_OV_CLEAR
// Now check overflow on unsigned multiply
// Some stimulus to make a 32-bit multiply overflow
l.movhi r4, 0x5555 ;//((2^32))/3 + 2
l.ori r4, r4, 0x5557
l.ori r5, r0, 2
l.ori r6, r0, 3
// First multiply big negative number by 2 - shouldn't overflow
l.mulu r3, r4, r5
l.nop 0x2
CHECK_OV_CLEAR
// Now multiply by 3 - should just overflow negative
l.mulu r3, r4, r6
l.nop 0x2
CHECK_OV_SET
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_OV_CLEAR
#endif
/////////////////////////////////////////////////////////////
// //
// Range Exception Tests //
// //
/////////////////////////////////////////////////////////////
#ifdef OR1200_IMPL_OVE
// report indicator that we're at exception section 0xeeeeeeee
l.movhi r3, 0xeeee
l.ori r3, r3, 0xeeee
l.nop 0x2
// First enable OV exception in SR
l.mfspr r20, r0, SPR_SR
l.ori r21, r20, SPR_SR_OVE
l.mtspr r0, r21, SPR_SR
// Check it's set
l.mfspr r20, r0, SPR_SR
l.andi r21, r20, SPR_SR_OVE
l.sfnei r21, SPR_SR_OVE
l.bf _fail
l.nop
// now set r11 to r12 to know how many tests we've done so far
l.or r11, r12, r12
l.movhi r4, 0x7fff
l.ori r4, r4, 0xefff
l.ori r5, r0, 0xffff
l.add r3, r5, r4 ;// Should set overflow
l.nop 0x2
EXPECT_RANGE_EXCEPT
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_EXCEPTION_COUNTER
l.addi r3, r4, 0x7fff ;// Should set overflow
l.nop 0x2
EXPECT_RANGE_EXCEPT
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_EXCEPTION_COUNTER
// Now test negative numbers
l.movhi r4, 0x8000
l.ori r4, r4, 0x0000
l.movhi r5, 0xffff
l.ori r5, r5, 0xffff
l.add r3, r4, r5 // Biggest and smallest negative number
l.nop 0x2
EXPECT_RANGE_EXCEPT
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_EXCEPTION_COUNTER
l.addi r3, r4, 0xffff // Biggest and smallest negative number
l.nop 0x2
EXPECT_RANGE_EXCEPT
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_EXCEPTION_COUNTER
l.add r3, r4, r0 // Biggest negative number, and zero
l.nop 0x2
CHECK_EXCEPTION_COUNTER
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_EXCEPTION_COUNTER
l.movhi r5, 0xffff
l.ori r5, r5, 0xfffe
l.add r3, r4, r5 // Biggest and second smallest negative number
l.nop 0x2
EXPECT_RANGE_EXCEPT
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_EXCEPTION_COUNTER
#ifdef OR1200_IMPL_SUB
// report indicator that we're at l.sub section 0x55555555
l.movhi r3, 0x5555
l.ori r3, r3, 0x5555
l.nop 0x2
// Quick subtract check
// Check largest negative number -1 tripping overflow
l.ori r5, r0, 1 ; // +1
l.sub r3, r4, r5 ; // -2147483647 - 1
l.nop 0x2
EXPECT_RANGE_EXCEPT
l.sub r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_EXCEPTION_COUNTER
#endif
l.movhi r4, 0x8000
l.ori r4, r4, 0x0437
l.movhi r5, 0xffff
l.ori r5, r5, 0xfbc7
l.add r3, r4, r5 // Very big negative number, another one big
// enough to cause overflow hopefully
l.nop 0x2
EXPECT_RANGE_EXCEPT
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_EXCEPTION_COUNTER
l.movhi r5, 0xffff
l.ori r5, r5, 0xfff7
l.add r3, r4, r5 // Two negative numbers but shouldn't overflow
l.nop 0x2
CHECK_EXCEPTION_COUNTER
#ifdef OR1200_DIV_IMPLEMENTED
// report indicator that we're at l.div section 0xdddddddd
l.movhi r3, 0xdddd
l.ori r3, r3, 0xdddd
l.nop 0x2
// Test divide by zero
l.div r3, r5, r0
l.nop 0x2
l.sfne r3, r0 ;// Check result was 0
l.bf _fail
EXPECT_RANGE_EXCEPT
l.add r3, r5, r0 ;// Should clear overflow
l.nop 0x2
CHECK_EXCEPTION_COUNTER
// Test divide by zero
l.divu r3, r0, r0
l.nop 0x2
EXPECT_RANGE_EXCEPT
l.sfne r3, r0 ;// Check result was 0
l.bf _fail
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_EXCEPTION_COUNTER
#endif
#ifdef OR1200_MULT_IMPLEMENTED
// report indicator that we're at l.multiply section 0x11111111
l.movhi r3, 0x1111
l.ori r3, r3, 0x1111
l.nop 0x2
// Check multiplying two large numbers, which will cause overflow,
// trigger the flag appropriately
// First signed multiply.
l.movhi r4, 0xd555 ;//-(((2^32)-1)/3 + 2)
l.ori r4, r4, 0x5552
l.ori r5, r0, 2
l.ori r6, r0, 3
// First multiply big negative number by 2 - shouldn't overflow
l.mul r3, r4, r5
l.nop 0x2
CHECK_EXCEPTION_COUNTER
// Now multiply by 3 - should just overflow negative
l.mul r3, r4, r6
l.nop 0x2
EXPECT_RANGE_EXCEPT
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_EXCEPTION_COUNTER
// Now some big positive values
l.movhi r4, 0x2aaa ;//((2^32)-1)/3 + 2
l.ori r4, r4, 0xaaae
l.ori r5, r0, 2
l.ori r6, r0, 3
// First multiply big number by 2 - shouldn't overflow
l.mul r3, r4, r5
l.nop 0x2
CHECK_EXCEPTION_COUNTER
// Now multiply by 3 - should only just overflow
l.mul r3, r4, r6
l.nop 0x2
EXPECT_RANGE_EXCEPT
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_EXCEPTION_COUNTER
// First multiply big number by 2 - shouldn't overflow
l.muli r3, r4, 0x2
l.nop 0x2
CHECK_EXCEPTION_COUNTER
// Now multiply by 3 - should just overflow negative
l.muli r3, r4, 0x3
l.nop 0x2
EXPECT_RANGE_EXCEPT
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_EXCEPTION_COUNTER
// Now check overflow on unsigned multiply
// Some stimulus to make a 32-bit multiply overflow
l.movhi r4, 0x5555 ;//((2^32))/3 + 2
l.ori r4, r4, 0x5557
l.ori r5, r0, 2
l.ori r6, r0, 3
// First multiply big negative number by 2 - shouldn't overflow
l.mulu r3, r4, r5
l.nop 0x2
CHECK_EXCEPTION_COUNTER
// Now multiply by 3 - should just overflow negative
l.mulu r3, r4, r6
l.nop 0x2
EXPECT_RANGE_EXCEPT
l.add r3, r0, r0 ;// Should clear overflow
l.nop 0x2
CHECK_EXCEPTION_COUNTER
#endif
#endif
_finish:
l.movhi r3, hi(0x8000000d)
l.ori r3, r3, lo(0x8000000d)
l.nop 0x2
l.ori r3, r0, 0
l.nop 0x1
_fail:
l.or r3, r12, r0 ;// Fail and report test number we were up to
l.nop 0x1
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