binutils-gdb/sim/testsuite/bfin/se_excpt_dagprotviol.S
Mike Frysinger 1368b914e9 sim: testsuite: flatten tree
Now that all port tests live under testsuite/sim/*/, and none live
in testsuite/ directly, flatten the structure by moving all of the
dirs under testsuite/sim/ to testsuite/ directly.

We need to stop passing --tool to dejagnu so that it searches all
dirs and not just ones that start with "sim".  Since we have no
other dirs in this tree, and no plans to add any, should be fine.
2021-01-15 19:18:34 -05:00

282 lines
5.6 KiB
ArmAsm

//Original:/proj/frio/dv/testcases/seq/se_excpt_dagprotviol/se_excpt_dagprotviol.dsp
// Description: EXCPT instruction combined with DAG Misaligned Access
# mach: bfin
# sim: --environment operating
#include "test.h"
.include "testutils.inc"
start
include(gen_int.inc)
include(selfcheck.inc)
include(std.inc)
include(mmrs.inc)
include(symtable.inc)
#ifndef STACKSIZE
#define STACKSIZE 0x100 // change for how much stack you need
#endif
#ifndef ITABLE
#define ITABLE 0xF0000000
#endif
GEN_INT_INIT(ITABLE) // set location for interrupt table
//
// Reset/Bootstrap Code
// (Here we should set the processor operating modes, initialize registers,
// etc.)
//
BOOT:
INIT_R_REGS(0); // initialize general purpose regs
INIT_P_REGS(0); // initialize the pointers
INIT_I_REGS(0); // initialize the dsp address regs
INIT_M_REGS(0);
INIT_L_REGS(0);
INIT_B_REGS(0);
CLI R1; // inhibit events during MMR writes
LD32_LABEL(sp, USTACK); // setup the user stack pointer
USP = SP;
LD32_LABEL(sp, KSTACK); // setup the kernel stack pointer
FP = SP; // and frame pointer
LD32(p0, EVT0); // Setup Event Vectors and Handlers
P0 += 4; // EVT0 not used (Emulation)
P0 += 4; // EVT1 not used (Reset)
LD32_LABEL(r0, NHANDLE); // NMI Handler (Int2)
[ P0 ++ ] = R0;
LD32_LABEL(r0, XHANDLE); // Exception Handler (Int3)
[ P0 ++ ] = R0;
P0 += 4; // EVT4 not used (Global Interrupt Enable)
LD32_LABEL(r0, HWHANDLE); // HW Error Handler (Int5)
[ P0 ++ ] = R0;
LD32_LABEL(r0, THANDLE); // Timer Handler (Int6)
[ P0 ++ ] = R0;
LD32_LABEL(r0, I7HANDLE); // IVG7 Handler
[ P0 ++ ] = R0;
LD32_LABEL(r0, I8HANDLE); // IVG8 Handler
[ P0 ++ ] = R0;
LD32_LABEL(r0, I9HANDLE); // IVG9 Handler
[ P0 ++ ] = R0;
LD32_LABEL(r0, I10HANDLE);// IVG10 Handler
[ P0 ++ ] = R0;
LD32_LABEL(r0, I11HANDLE);// IVG11 Handler
[ P0 ++ ] = R0;
LD32_LABEL(r0, I12HANDLE);// IVG12 Handler
[ P0 ++ ] = R0;
LD32_LABEL(r0, I13HANDLE);// IVG13 Handler
[ P0 ++ ] = R0;
LD32_LABEL(r0, I14HANDLE);// IVG14 Handler
[ P0 ++ ] = R0;
LD32_LABEL(r0, I15HANDLE);// IVG15 Handler
[ P0 ++ ] = R0;
LD32(p0, EVT_OVERRIDE);
R0 = 0;
[ P0 ++ ] = R0;
R1 = -1; // Change this to mask interrupts (*)
CSYNC; // wait for MMR writes to finish
STI R1; // sync and reenable events (implicit write to IMASK)
DUMMY:
R0 = 0 (Z);
LT0 = r0; // set loop counters to something deterministic
LB0 = r0;
LC0 = r0;
LT1 = r0;
LB1 = r0;
LC1 = r0;
ASTAT = r0; // reset other internal regs
SYSCFG = r0;
RETS = r0; // prevent X's breaking LINK instruction
RETI = r0; // prevent Xs later on
RETX = r0;
RETN = r0;
RETE = r0;
// The following code sets up the test for running in USER mode
LD32_LABEL(r0, STARTUSER);// One gets to user mode by doing a
// ReturnFromInterrupt (RTI)
RETI = r0; // We need to load the return address
// Comment the following line for a USER Mode test
// JUMP STARTSUP; // jump to code start for SUPERVISOR mode
RTI;
STARTSUP:
LD32_LABEL(p1, BEGIN);
LD32(p0, EVT15);
CLI R1; // inhibit events during write to MMR
[ P0 ] = P1; // IVG15 (General) handler (Int 15) load with start
CSYNC; // wait for it
STI R1; // reenable events with proper imask
RAISE 15; // after we RTI, INT 15 should be taken
RTI;
//
// The Main Program
//
STARTUSER:
LD32_LABEL(sp, USTACK); // setup the user stack pointer
FP = SP;
LINK 0; // change for how much stack frame space you need.
JUMP BEGIN;
//*********************************************************************
BEGIN:
// COMMENT the following line for USER MODE tests
// [--sp] = RETI; // enable interrupts in supervisor mode
R0 = 0;
R1 = -1;
LD32_LABEL(p1, USTACK);
P1 += 1; // misalign it
EXCPT 2; // the RAISE should not prevent the EXCPT from being taken
R2 = [ P1 ];
CHECK_INIT_DEF(p0); //CHECK_INIT(p0, 0xFF7FFFFC);
CHECKREG(r5, 2); // check the flag
END:
dbg_pass; // End the test
//*********************************************************************
//
// Handlers for Events
//
NHANDLE: // NMI Handler 2
RTN;
XHANDLE: // Exception Handler 3
[ -- SP ] = ASTAT; // save what we damage
[ -- SP ] = ( R7:6 );
R7 = SEQSTAT;
R7 <<= 26;
R7 >>= 26; // only want EXCAUSE
R6 = 0x02; // EXCAUSE 0x02 means EXCPT 2 instruction
CC = r7 == r6;
IF CC JUMP EXCPT2;
R6 = 0x24; // EXCAUSE 0x24 means DAG misalign
CC = r7 == r6;
IF CC JUMP DGPROTVIOL;
JUMP.S OUT; // if the EXCAUSE is wrong the test will infinite loop
EXCPT2:
R5 = 1; // Set a Flag
JUMP.S OUT;
DGPROTVIOL:
R7 = RETX; // Fix up return address
R7 += 2; // skip offending 16 bit instruction
RETX = r7; // and put back in RETX
R5 <<= 1; // Alter Global Flag
OUT:
( R7:6 ) = [ SP ++ ];
ASTAT = [sp++];
RTX;
HWHANDLE: // HW Error Handler 5
RTI;
THANDLE: // Timer Handler 6
RTI;
I7HANDLE: // IVG 7 Handler
RTI;
I8HANDLE: // IVG 8 Handler
RTI;
I9HANDLE: // IVG 9 Handler
RTI;
I10HANDLE: // IVG 10 Handler
RTI;
I11HANDLE: // IVG 11 Handler
RTI;
I12HANDLE: // IVG 12 Handler
RTI;
I13HANDLE: // IVG 13 Handler
RTI;
I14HANDLE: // IVG 14 Handler
RTI;
I15HANDLE: // IVG 15 Handler
RTI;
// padding for the icache
EXCPT 0; EXCPT 0; EXCPT 0; EXCPT 0; EXCPT 0; EXCPT 0; EXCPT 0;
//
// Data Segment
//
.data
DATA:
.space (0x10);
// Stack Segments (Both Kernel and User)
.space (STACKSIZE);
KSTACK:
.space (STACKSIZE);
USTACK: