uiotest.c
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/*************************************************************************
*
* File: randtest.c
*
* This file contains the main routine for the I/O random test.
*
* $Header: /root/leakn64/depot/rf/sw/bbplayer/iosim/src/uiotest.c,v 1.2 2002/05/30 05:52:50 whs Exp $
*
*/
#include <sys/types.h>
#include <sys/cachectl.h>
#include <sys/sysmp.h>
#include <sys/mman.h>
#include <ctype.h>
#include <errno.h>
#include <limits.h>
#include <fcntl.h>
#include <getopt.h>
#include <libelf.h>
#include <stdio.h>
#include <stdlib.h>
#include <stdarg.h>
#include <string.h>
#include <unistd.h>
#include <sys/time.h> /* Needed for select */
#include <math.h> /* Needed for random */
#include <sys/prctl.h> /* Needed for sproc */
#include <signal.h> /* Needed for signal */
#include <task.h>
#include "trace.h"
#include "sim.h"
#include "simipc.h"
#include "os.h"
#include "rcp.h"
#include "iotest.h"
#include "sync.h"
#include "verify.h"
#include "viint.h"
/***************************************************************************
* Definitions
*/
#define DEFAULT_LOOP_COUNT 500
#define DEFAULT_RUN_COUNT 1 /* Minimum run count for each thread */
#define DEFAULT_TEST_SEED 1
#define DEFAULT_FREQ_SEED 1
/*
* DP List ring buffer size (in number of 32-bit words)
*/
#define DPL_RING_SIZE 124 /* 124 32-bit words == 62 64-bit longs */
#define FROM_RDRAM 0
#define FROM_DMEM1 1
#define FROM_DMEM2 2
#define MAX_RINGBUFFERS 3
/*
* Default address ranges for testing
*
RDRAM
0 +---------------------+ 04000000 +----------------+
| | | DMEM |
| | | |
| | | |
| | +----------------+
| | | 128 Bytes |
01e7000 +---------------------+ 04000fff +----------------+
| MI (10 KB) | 04001000 | IMEM |
+---------------------+ | |
| PI | | |
+---------------------+ +----------------+
| SI | | 128 Bytes |
+---------------------+ 04001fff +----------------+
| AI |
+---------------------+
| SP |
+---------------------+
| |
01fffff +---------------------+
*/
#define RDRAM_RAND_BASE (RDRAM_0_END+1-(60*1024)) /* 100 KB from end */
#define RDRAM_TEST_SIZE (3*1024) /* 3 KB each */
#define RDRAM_VI_START (RDRAM_RAND_BASE)
#define RDRAM_VI_END (RDRAM_VI_START+(30*1024)-1)
#define RDRAM_MI_START (RDRAM_VI_END+1)
#define RDRAM_MI_END (RDRAM_MI_START+RDRAM_TEST_SIZE-1)
#define RDRAM_PI_START (RDRAM_MI_END+1)
#define RDRAM_PI_END (RDRAM_PI_START+RDRAM_TEST_SIZE-1)
#define RDRAM_SI_START (RDRAM_PI_END+1)
#define RDRAM_SI_END (RDRAM_SI_START+RDRAM_TEST_SIZE-1)
#define RDRAM_AI_START (RDRAM_SI_END+1)
#define RDRAM_AI_END (RDRAM_AI_START+RDRAM_TEST_SIZE-1)
#define RDRAM_SP_START (RDRAM_AI_END+1)
#define RDRAM_SP_END (RDRAM_SP_START+RDRAM_TEST_SIZE-1)
#define RDRAM_DP_START ((RDRAM_SP_END+1) + 0x3e0) /* +992 */
#define RDRAM_DP_END (RDRAM_DP_START+RDRAM_TEST_SIZE-1)
#define DP_DMEM_TEST_SIZE (DPL_RING_SIZE*4) /* 62 64-bit words */
#define DMEM_TEST_SIZE (128) /* 128 bytes */
#define IMEM_TEST_SIZE (128) /* 128 bytes */
#define DMEM_START (SP_DMEM_END+1-128)
#define DMEM_END (DMEM_START+DMEM_TEST_SIZE-1)
#define DP_DMEM_START (SP_DMEM_END+1-(DMEM_TEST_SIZE+DP_DMEM_TEST_SIZE))
#define DP_DMEM_END (DP_DMEM_START+DP_DMEM_TEST_SIZE-1)
#define DP2_DMEM_START 0x04000800 /* Evan's ring buffer */
#define DP2_DMEM_END 0x040008FF
#define IMEM_START (SP_IMEM_END+1-128)
#define IMEM_END (IMEM_START+IMEM_TEST_SIZE-1)
#define PI_ROM1_START 0x08000000 /* 4 MB each */
#define PI_ROM1_END 0x08400000
#define PI_ROM2_START 0x10000000 /* 4 MB each */
#define PI_ROM2_END 0x10400000
#define PI_WROM_START1 0x09000000 /* 2 MB each */
#define PI_WROM_END1 0x09200000
#define PI_WROM_START2 0x09200000 /* 2 MB each */
#define PI_WROM_END2 0x09400000
#define SI_ROM_START 0x1fc00000 /* 1984 bytes (4-byte status) */
#define SI_ROM_END 0x1fc007bc
#define SI_RAM_START 0x1fc007c0 /* 64 bytes */
#define SI_RAM_END 0x1fc007ff
#define RDRAM_IMEM_TEST_ID 0x00137000
/*
* IO/DMA states
*/
#define IO_STATE_INIT 1 /* One-time-only init steps */
#define IO_STATE_START 2 /* Start IO transaction */
#define IO_STATE_CHECK_STATUS 3 /* Check for IO (i.e. DMA) completion */
#define IO_STATE_COMPARE 4 /* Compare data */
/*
* Extra IO/DMA states for doing multi-frame video tests
*/
#define IO_STATE_CHECK_F0 10
#define IO_STATE_CHECK_MID 11
#define IO_STATE_CHECK_F1 12
#define IO_STATE_CHECK_END 13
/*
* Messages
*/
/* test id, description, expected val, actual val, passed/failed */
#define RTST_MSG_RES_STR "Test %3d (%15s: %08x %08x %08x %08x)\n"
#define RTST_MSG_RES2_STR "Test %3d (%15s: %08x %08x %08x %08x) -> %s\n"
#define RTST_ERROR_STR "\t****ERROR: src=%08x:%08x, dst=%08x:%08x\t\t -> %s\n"
#define THREAD_PRINT_MSG \
"T: id=%2d, pid=%4d, entry=0x%08x, R=%3d, B=%1d, S=%1d, I=%1d, name=%s\n"
#define BUSY_STR "Busy"
#define DONE_STR "Done"
/*
* Macros
*/
#define INSERT_RESULT(ret) (ret == -1 ? FAIL_STR : PASS_STR)
#define PRINT_RESULT(ret) { \
if (ret == -1) fprintf(LogFp, "-> %s\n", FAIL_STR); \
else fprintf(LogFp, "-> %s\n", PASS_STR); } \
#define RANDLOG_ERROR(src,w1,dst,w2) \
fprintf(LogFp, RTST_ERROR_STR, src, w1, dst, w2, FAIL_STR)
/***************************************************************************
* External variables
*/
extern unsigned long Dflags;
extern FILE *LogFp, *CmdFp;
extern char *LogFile;
/***************************************************************************
* Data structures
*/
typedef struct _ThreadCmd {
int pid; /* Thread process id */
void (*entry)(struct _ThreadCmd *); /* Thread entry point */
int runCount; /* Total number of run
(Parent) */
int busy; /* Busy running (Child) */
int state; /* IO internal state */
int inProgress; /* IO transaction is still
in progress */
char *name;
} ThreadCmd;
typedef void (*SPROC_T)(void *);
/***************************************************************************
* Global variables
*/
/* How many times we need to run */
unsigned int LoopCount = DEFAULT_LOOP_COUNT;
unsigned int MinRunCount= DEFAULT_RUN_COUNT;
/* Random seed for selecting a test */
unsigned int TestSeed = DEFAULT_TEST_SEED;
/* Random seed for frequency of run for a test */
unsigned int FreqSeed = DEFAULT_FREQ_SEED;
/* Size of memory reserved for each IO subsystem for testing */
unsigned int RdramTestSize = RDRAM_TEST_SIZE;
/* Define RDRAM address range for MI testing */
unsigned int MiRdramStart = RDRAM_MI_START;
unsigned int MiRdramEnd = RDRAM_MI_END;
/* Define RDRAM address range for PI testing */
unsigned int PiRdramStart = RDRAM_PI_START;
unsigned int PiRdramEnd = RDRAM_PI_END;
unsigned int PiRomStart[2] = {{PI_ROM1_START}, {PI_ROM2_START}};
unsigned int PiRomEnd[2] = {{PI_ROM1_END}, {PI_ROM2_END}};
unsigned int PiWRomStart1 = PI_WROM_START1;
unsigned int PiWRomEnd1 = PI_WROM_END1;
unsigned int PiWRomStart2 = PI_WROM_START2;
unsigned int PiWRomEnd2 = PI_WROM_END2;
/* Define RDRAM address range for SI testing */
unsigned int SiRdramStart = RDRAM_SI_START;
unsigned int SiRdramEnd = RDRAM_SI_END;
unsigned int SiRomStart = SI_ROM_START;
unsigned int SiRomEnd = SI_ROM_END;
unsigned int SiRamStart = SI_RAM_START;
unsigned int SiRamEnd = SI_RAM_END;
/* Define RDRAM address range for AI testing */
unsigned int AiRdramStart = RDRAM_AI_START;
unsigned int AiRdramEnd = RDRAM_AI_END;
/* Define RDRAM address range for SP testing */
unsigned int SpRdramStart = RDRAM_SP_START;
unsigned int SpRdramEnd = RDRAM_SP_END;
unsigned int SpImemStart = IMEM_START;
unsigned int SpImemEnd = IMEM_END;
unsigned int SpDmemStart = DMEM_START;
unsigned int SpDmemEnd = DMEM_END;
/* Define RDRAM address range for DP testing */
unsigned int DpRdramStart = RDRAM_DP_START;
unsigned int DpRdramEnd = RDRAM_DP_END;
unsigned int DpDmemStart = DP_DMEM_START;
unsigned int DpDmemEnd = DP_DMEM_END;
unsigned int Dp2DmemStart = DP2_DMEM_START;
unsigned int Dp2DmemEnd = DP2_DMEM_END;
/* Define RDRAM address range for VI testing */
unsigned int ViRdramStart = RDRAM_VI_START;
unsigned int ViRdramEnd = RDRAM_VI_END;
/* To turn on 2nd RDRAM */
unsigned int Rdram1Enabled = 1;
/* To kill the iorand environment - can be set in any test */
unsigned int QuickDeath = 0;
/* To enable DMA compare and disable round-robin scheduing */
unsigned int CompareEnabled = 1;
unsigned int RoundRobinEnabled = 0;
/* Flag to tell if IMEM dma80 test is enabled or not */
unsigned int dma80Enabled = 1;
/* Flag to tell if AI is running at 44.1 KHz */
unsigned int Ai441Enabled = 0;
/* Only for standalone */
#ifdef STANDALONE
int errorTotal = 0;
int errorCount = 0;
#endif
/* Round robin randomizing array */
int *ProcessOrder;
/***************************************************************************
* Static declarations
*/
unsigned int spLocDmaActive = 0;
unsigned int dpcRandDmaActive = 0;
/* Display list parameters */
unsigned int dplStartAddr = 0;
unsigned int dplEndAddr = 0;
unsigned int dplCurrAddr = 0;
/* Display list ring buffer parameters */
unsigned int dplRingSize = 0;
unsigned int dplRingSource = 0;
unsigned int dplRingStartp = 0;
unsigned int dplRingEndp = 0;
unsigned int __osRomType = 0;
/***************************************************************************
* Extern declarations
*/
extern int __osDpDeviceBusy(void);
extern int __osSiDeviceBusy(void);
extern int __osPiDeviceBusy(void);
/***************************************************************************
* Forward declarations
*/
static void setupRingBuffer(void);
void KillAllThreads(void);
int CheckInterrupt(unsigned int, unsigned int *);
void FlushVerifyInfo(void);
void PrintActiveTable(void);
int MemSmplCompare(int , int , int , int );
void rangeExpand(char *);
void initRoundRobin(void);
ThreadCmd * findActiveThread(void *entry);
void MiRandIoRd(ThreadCmd *);
void MiRandIoWrRd(ThreadCmd *);
void PiRandIoRd(ThreadCmd *);
void PiRandIoWrRd(ThreadCmd *);
void PiRandDma(ThreadCmd *);
void SiRandIoRd(ThreadCmd *);
void SiRandIoWrRd(ThreadCmd *);
void SiRandDma(ThreadCmd *);
void AiRandDma(ThreadCmd *);
void SpRandIoRd(ThreadCmd *);
void SpRandIoWrRd(ThreadCmd *);
void SpRandDma(ThreadCmd *);
void SpLocDma(ThreadCmd *);
void DpcRandDma(ThreadCmd *);
void SpDummyDma(ThreadCmd *);
/* New test procedures for vi, added by kluster */
void ViMLF2Dma(ThreadCmd *);
void ViLAN1Dma(ThreadCmd *);
void ViLAN2Dma(ThreadCmd *);
void ViLPN1Dma(ThreadCmd *);
void ViHAN1Dma(ThreadCmd *);
void ViHPF2Dma(ThreadCmd *);
void ViModeTest(ThreadCmd *);
/*
* IDs for different test threads
*/
#define MI_RAND_BASE 0
#define MI_IOR_ID (MI_RAND_BASE+0)
#define MI_IOWR_ID (MI_RAND_BASE+1)
#define PI_RAND_BASE (MI_IOWR_ID+1)
#define PI_IOR_ID (PI_RAND_BASE+0)
#define PI_IOWR_ID (PI_RAND_BASE+1)
#define PI_DMA_ID (PI_RAND_BASE+2)
#define SI_RAND_BASE (PI_DMA_ID+1)
#define SI_IOR_ID (SI_RAND_BASE+0)
#define SI_IOWR_ID (SI_RAND_BASE+1)
#define SI_DMA_ID (SI_RAND_BASE+2)
#define AI_RAND_BASE (SI_DMA_ID+1)
#define AI_DMA_ID (AI_RAND_BASE+0)
#define VI_RAND_BASE (AI_DMA_ID+1)
#define VI_DMA_ID (VI_RAND_BASE+0)
#define SP_RAND_BASE (VI_DMA_ID+1)
#define SP_IOR_ID (SP_RAND_BASE+0)
#define SP_IOWR_ID (SP_RAND_BASE+1)
#define SP_DMA_ID (SP_RAND_BASE+2)
#define SP_LOC_ID (SP_RAND_BASE+3)
#define DPC_RAND_BASE (SP_LOC_ID+1)
#define DPC_DMA_ID (DPC_RAND_BASE+0)
/***************************************************************************
* Test Thread Table
*/
ThreadCmd RandThreadTable[] = {
/*
* ID PID Entry R B S I EntryName
* ====================================================================
*/
{ /* 0 */ 0, MiRandIoRd, 0, 0, 1, 0, "MiRandIoRd" },
{ /* 1 */ 0, MiRandIoWrRd, 0, 0, 1, 0, "MiRandIoWrRd"},
{ /* 2 */ 0, PiRandIoRd, 0, 0, 1, 0, "PiRandIoRd" },
{ /* 3 */ 0, PiRandIoWrRd, 0, 0, 1, 0, "PiRandIoWrRd"},
{ /* 4 */ 0, PiRandDma, 0, 0, 1, 0, "PiRandDma" },
{ /* 5 */ 0, SiRandIoRd, 0, 0, 1, 0, "SiRandIoRd" },
{ /* 6 */ 0, SiRandIoWrRd, 0, 0, 1, 0, "SiRandIoWrRd"},
{ /* 7 */ 0, SiRandDma, 0, 0, 1, 0, "SiRandDma" },
{ /* 8 */ 0, AiRandDma, 0, 0, 1, 0, "AiRandDma" },
{ /* 9 */ 0, ViMLF2Dma, 0, 0, 1, 0, "ViMLF2Dma" },
{ /* 10 */ 0, SpRandIoRd, 0, 0, 1, 0, "SpRandIoRd" },
{ /* 11 */ 0, SpRandIoWrRd, 0, 0, 1, 0, "SpRandIoWrRd"},
{ /* 12 */ 0, SpRandDma, 0, 0, 1, 0, "SpRandDma" },
{ /* 13 */ 0, SpLocDma, 0, 0, 1, 0, "SpLocDma" },
{ /* 14 */ 0, DpcRandDma, 0, 0, 1, 0, "DpcRandDma" },
/* New tests for vi testing */
{ /* 15 */ 0, SpDummyDma, 0, 0, 1, 0, "SpDummyDma" },
{ /* 16 */ 0, ViLAN1Dma, 0, 0, 1, 0, "ViLAN1Dma" },
{ /* 17 */ 0, ViLAN2Dma, 0, 0, 1, 0, "ViLAN2Dma" },
{ /* 18 */ 0, ViLPN1Dma, 0, 0, 1, 0, "ViLPN1Dma" },
{ /* 19 */ 0, ViHAN1Dma, 0, 0, 1, 0, "ViHAN1Dma" },
{ /* 20 */ 0, ViHPF2Dma, 0, 0, 1, 0, "ViHPF2Dma" },
/* NTSC_LAN1 */
{ /* 21 */ 0, ViModeTest, 0, 0, 0x1002, 0, "ViModeTest" },
/* NTSC_LAN2 */
{ /* 22 */ 0, ViModeTest, 0, 0, 0x2106, 0, "ViModeTest" },
/* NTSC_LPN1 */
{ /* 23 */ 0, ViModeTest, 0, 0, 0x2000, 0, "ViModeTest" },
/* NTSC_HAN1 */
{ /* 24 */ 0, ViModeTest, 0, 0, 0x200A, 0, "ViModeTest" },
/* NTSC_HPF2 */
{ /* 25 */ 0, ViModeTest, 0, 0, 0x210D, 0, "ViModeTest" },
/* NTSC_LAN1 */
{ /* 26 */ 0, ViModeTest, 0, 0, 0x2002, 0, "ViModeTest" },
};
int RandTableSize = sizeof(RandThreadTable)/sizeof(RandThreadTable[0]);
ThreadCmd **ActiveThreadTable;
int ActiveTableSize;
/***************************************************************************
* Main random IO test loop
*
* The idea is to have a table containing of various test routines that can
* be spawned off as a thread (via sproc). The parent scheduler randomly
* selects (based on UNIX random() function) which test thread to run.
* Each thread contains a main loop where it processes the IO transaction and
* then blocks itself, waiting to be unblocked by the parent scheduler upon the
* next invocation. The thread exits only when it receives a SIGINT signal from
* the parent; this occurs at the end of the all testing. Parent and child
* communicate over global data structures. Once started, the child thread
* sets a busy flag, telling the parent to not invoke this thread again. And
* once the child finishes its task, it resets the busy flag and blocks itself.
* Based on the random number generated, the parent will most likely select this
* thread again, especially when the busy flag is cleared.
*
* In general, there 3 types of test thread: one to perform only IO read-compare
* from a memory address range that has been initialized with pattern data,
* one to perform IO write-read-compare, and one to perform DMA transaction
* between an IO subsytem and RDRAM. The DMA thread needs to have its own
* internal state machine to minimize the time it spends hogging CPU and
* RCP. For example, in state 1, the thread will start a DMA transaction,
* records the transaction and returns. In its next invocation, it will enter
* state 2 where it checks for DMA completion and returns. The thread will
* stay in state 2 (after numerous invocation) until the DMA busy bit is off.
* Once the busy bit is off, the next invocation will put the thread into
* its last state 3 to compare the data for correctness. Once again, the thread
* need to distribute its time spent in this state over numerous invocations.
*
* Ideally, there should be 2 random seeds: one for selecting a test to run, and
* the other for choosing the number of times (or frequency) that this test
* should run. For simplicity, we'll simply use 1 seed to generate random
* numbers which only the low 8 bits are used.
*/
int
IoRandTest(char *testRange)
{
int i, j, ret;
int status, done;
int randomNeeded, stillRunning;
unsigned int count;
unsigned int testRand = 0;
ThreadCmd *thread;
struct timeval timeout;
_TRACE(DLOG, printf("IoRandTest: entered\n"));
rangeExpand(testRange);
_TRACE(DLOG, printf("RandTableSize = %d\n", RandTableSize));
_TRACE(DLOG, printf("ActiveTableSize = %d\n", ActiveTableSize));
/*
* Initialize random seeds
*/
ret =srandom(TestSeed);
initRoundRobin();
randomNeeded = 1;
done = 0;
count = 1;
while (!done && !QuickDeath) {
/*
* First, get the random number to select which thread to run
*/
if (randomNeeded) {
if (RoundRobinEnabled)
testRand = (testRand+1) % ActiveTableSize;
else
testRand = random() % ActiveTableSize;
}
else {
/*
* Here, we have finished the testing but there are still
* transactions in progress (most likely DMAs). So, we need
* to keep activate the in-progress thread to run until
* it's finished. We sequentially search the table for each
* unfinished thread and sticks with it.
*/
for (i=0; i < ActiveTableSize; i++) {
if (ActiveThreadTable[i]->inProgress == 1) {
testRand = i;
break;
} /* if */
} /* for */
} /* if */
thread = ActiveThreadTable[ProcessOrder[testRand]];
_TRACE(DLOG, printf(
"Count #%4d: thread id=%2d, name=%s\n",
count, testRand, thread->name));
thread->entry(thread);
thread->runCount++;
_TRACE(DLOG, printf(THREAD_PRINT_MSG,
thread - RandThreadTable,
thread->pid, thread->entry,
thread->runCount, thread->busy,
thread->state, thread->inProgress,
thread->name));
count++;
/*
* Check to see if we're done:
* 1) LoopCount is reached
* 2) Every thread has been run at least MinRunCount
* 3) No outstanding DMA test
*/
if (count > LoopCount) {
stillRunning = 0;
for (i=0; i < ActiveTableSize; i++) {
if (ActiveThreadTable[i]->runCount <
MinRunCount)
break;
if (ActiveThreadTable[i]->inProgress == 1)
stillRunning = 1;
} /* for */
if (i >= ActiveTableSize) {
if (stillRunning)
randomNeeded = 0;
else
done = 1;
} /* if */
} /* if */
} /* while */
PrintActiveTable();
return(0);
} /* IoRandTest */
/***************************************************************************
* Thread entry routines
*/
void
MiRandIoRd(ThreadCmd *thread)
{
unsigned int data;
int ret;
static unsigned int address = 0;
/* Assume that RDRAM has been initialized with data = address */
if ((address == 0) ||
(address > (MiRdramStart+(RdramTestSize/2))))
address = MiRdramStart - 4;
address = (address + 4) & 0xfffffffc;
ret = MemReadCompare(address, address, 0, 0);
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, thread->name,
address, address, 0, 0,
INSERT_RESULT(ret));
} /* MiRandIoRd */
void
MiRandIoWrRd(ThreadCmd *thread)
{
int ret = 0;
static unsigned int address = 0;
/* If 2nd RDRAM is enabled, we use this thread to test it */
if (Rdram1Enabled) {
if ((address == 0) ||
(address > (RDRAM_1_START+0x80000+RdramTestSize)))
address = RDRAM_1_START+0x80000 - 4;
}
else {
if ((address == 0) || (address > MiRdramEnd))
address = MiRdramStart+(RdramTestSize/2) - 4;
}
address = (address + 4) & 0xfffffffc;
ret = MemWriteRead(address, address, address, 0);
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, thread->name,
address, address, 0, 0,
INSERT_RESULT(ret));
} /* MiRandIoWrRd */
/***************************************************************************
* PI thread routines
*/
void
PiRandIoRd(ThreadCmd *thread)
{
unsigned int data, stat;
static unsigned int rom = 1;
static unsigned int address = 0;
/*
* For PI, we need to check for both DMA/IO busy bits before
* perform IO read/write - If they're busy, we simply exit and
* try again later
*/
/* Assume that ROM 1 & 2 have been initialized with
* data = address
*/
if ((address == 0) || (address > (PiRomStart[rom]+100))) {
rom = 1 - rom;
address = PiRomStart[rom] - 4;
}
address = (address + 4) & 0xfffffffc;
stat = osPiGetStatus();
if (osPiRawReadIo((u32)address, &data) == 0) {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, thread->name,
address, data, 0, 0, DONE_STR);
}
else {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, thread->name,
address, stat, 0, 0, BUSY_STR);
}
} /* PiRandIoRd */
void
PiRandIoWrRd(ThreadCmd *thread)
{
int ret;
unsigned int stat, data;
static unsigned int address = 0;
/*
* For PI, we need to check for both DMA/IO busy bits before
* perform IO read/write - If they're busy, we simply exit and
* try again later
*/
if ((address == 0) || (address > PiWRomEnd1))
address = PiWRomStart1 - 4;
address = (address + 4) & 0xfffffffc;
stat = osPiGetStatus();
ret = osPiRawWriteIo(address, address);
if (ret == 0) {
while (__osPiDeviceBusy()) ;
if (osPiRawReadIo(address, &data) == 0) {
ret = (data == address) ? 0 : -1;
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, thread->name,
address, data, 0, 0, INSERT_RESULT(ret));
return;
}
}
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, thread->name,
address, stat, 0, 0, BUSY_STR);
} /* PiRandIoWrRd */
void
PiRandDma(ThreadCmd *thread)
{
int ret;
unsigned int stat;
static unsigned int dir = OS_WRITE;
static unsigned int piAddr = 0;
static unsigned int ramAddr = 0;
static unsigned int nbytes = 0;
static unsigned int lastStat= 0;
static unsigned int rom = 1;
switch (thread->state) {
case IO_STATE_INIT:
case IO_STATE_START: {
thread->inProgress = 1;
/* Toggle direction */
dir = (dir==OS_WRITE) ? OS_READ:OS_WRITE;
/* If DMA to RDRAM, then we use the 2 ROM models
*/
if (dir == OS_READ) {
rom = 1 - rom;
piAddr = PiRomStart[rom];
}
else { /* we use the WROM model */
piAddr = PiWRomStart2;
}
/*
* We randomly pick nbytes to be between
* 128 and 2044 (0x7fc) bytes
*/
nbytes = (128 + random()) & 0x7fc;
/* Set RDRAM address */
if ((ramAddr == 0) ||
(ramAddr > (PiRdramEnd - (nbytes+4))))
ramAddr = PiRdramStart - 128;
ramAddr += 128;
ret = osPiRawStartDma(dir, piAddr, ramAddr, nbytes);
if (ret != -1) {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "PiTestDma",
dir, piAddr, ramAddr, nbytes,
INSERT_RESULT(ret));
thread->state = IO_STATE_CHECK_STATUS;
} else {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "PiTestDma",
dir, piAddr, ramAddr, stat, BUSY_STR);
}
break;
}
case IO_STATE_CHECK_STATUS: {
stat = osPiGetStatus();
if (stat != lastStat)
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "PiDmaStatus",
PI_STATUS_REG, PI_STATUS_DMA_BUSY,
1, stat, DONE_STR);
lastStat = stat;
if (!(stat & PI_STATUS_DMA_BUSY)) {
if (CheckInterrupt(MI_INTR_PI, &stat)) {
IO_WRITE(PI_STATUS_REG, PI_CLR_INTR);
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable,
"PiCheckIntr",
MI_INTR_REG, MI_INTR_PI,
0, stat, PASS_STR);
}
else {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable,
"PiCheckIntr",
MI_INTR_REG, MI_INTR_PI,
0, stat, FAIL_STR);
errorTotal++;
}
if (CompareEnabled)
thread->state = IO_STATE_COMPARE;
else {
thread->state = IO_STATE_START;
thread->inProgress = 0;
}
}
break;
}
case IO_STATE_COMPARE: {
/* Here we compare the 1st word, last word */
ret = MemSmplCompare(piAddr, ramAddr, nbytes/4, 0);
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable,
"PiDmaCompare",
piAddr,
ramAddr, nbytes/4, 0, INSERT_RESULT(ret));
thread->state = IO_STATE_START;
thread->inProgress = 0;
break;
}
default: {
_TRACE(DERROR,
fprintf(LogFp,
"\tERROR: Illegal IO state encountered!\n"));
}
} /* switch */
} /* PiRandDma */
/***************************************************************************
* SI thread routines
*/
void
SiRandIoRd(ThreadCmd *thread)
{
int ret;
unsigned int data, stat;
static unsigned int address = 0;
/* Assume that ROM has been initialized with data = address */
if ((address == 0) || (address > SiRomEnd)) {
address = SiRomStart - 4;
}
address = (address + 4) & 0xfffffffc;
data = (address >> 2) & 0x0000ffff;
stat = osSiGetStatus();
#if 0
if (RandThreadTable[SI_DMA_ID].inProgress == 0) {
#endif
if (osSiRawReadIo(address, &ret) == 0) {
if (ret == data) ret = 0;
else ret = -1;
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, thread->name,
address, data, stat, 0, INSERT_RESULT(ret));
return;
}
#if 0
}
#endif
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, thread->name,
address, data, stat, 0, BUSY_STR);
} /* SiRandIoRd */
void
SiRandIoWrRd(ThreadCmd *thread)
{
int ret;
unsigned int stat, data;
static unsigned int address = 0;
/*
* For SI, we need to check for both DMA/IO busy bits before
* perform IO write - If they're busy, we simply exit and try
* again later
*/
if ((address == 0) || (address > SiRamEnd))
address = SiRamStart - 4;
address = (address + 4) & 0xfffffffc;
/*
* Need to check for busy bits AND no outstanding DMA
* in progress; otherwise, this routine will overwrite
* one 32-bit word in the 64 bytes SI RAM and cause DMA
* compare to fail.
*/
stat = osSiGetStatus();
#if 0
if (RandThreadTable[SI_DMA_ID].inProgress == 0) {
#endif
ret = osSiRawWriteIo(address, address);
if (ret == 0) {
while (__osSiDeviceBusy()) ;
if (osSiRawReadIo(address, &data) == 0) {
ret = (data == address) ? 0 : -1;
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, thread->name,
address,data,stat,0,INSERT_RESULT(ret));
return;
}
}
#if 0
}
#endif
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, thread->name,
address, address, stat, 0, BUSY_STR);
} /* SiRandIoWrRd */
void
SiRandDma(ThreadCmd *thread)
{
int ret;
unsigned int stat;
static unsigned int dir = OS_WRITE;
static unsigned int siAddr = 0;
static unsigned int ramAddr = 0;
static unsigned int nbytes = 64;
static unsigned int lastStat= 0;
switch (thread->state) {
case IO_STATE_INIT:
case IO_STATE_START: {
thread->inProgress = 1;
dir = (dir==OS_WRITE) ? OS_READ : OS_WRITE;
if ((ramAddr == 0) ||
(ramAddr > (SiRdramEnd - (nbytes+4))))
ramAddr = SiRdramStart - 8;
ramAddr += 8;
siAddr = SiRamStart;
siAddr &= 0xfffffff8;
ramAddr &= 0xfffffff8;
ret = osSiRawStartDma(dir, siAddr, ramAddr, nbytes);
if (ret != -1) {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "SiTestDma",
dir, siAddr, ramAddr, nbytes,
INSERT_RESULT(ret));
thread->state = IO_STATE_CHECK_STATUS;
} else {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "SiTestDma",
dir, siAddr, ramAddr, stat, BUSY_STR);
}
break;
}
case IO_STATE_CHECK_STATUS: {
/*
* Here, we need to combine 2 states into 1 to
* protect against an SI IO WR/RD test to come in
* between state 2 & 3 and clobber the data (since
* SI RAM only contains 64-bytes
*/
stat = osSiGetStatus();
if (stat != lastStat)
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "SiDmaStatus",
SI_STATUS_REG, SI_STATUS_DMA_BUSY,
1, stat, DONE_STR);
lastStat = stat;
if (!(stat & SI_STATUS_DMA_BUSY)) {
if (CheckInterrupt(MI_INTR_SI, &stat)) {
/* Any write clears interrupt */
IO_WRITE(SI_STATUS_REG, 0);
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable,
"SiCheckIntr",
MI_INTR_REG, MI_INTR_SI,
0, stat, PASS_STR);
}
else {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable,
"SiCheckIntr",
MI_INTR_REG, MI_INTR_SI,
0, stat, FAIL_STR);
errorTotal++;
}
/* Here we compare the 1st word, last word */
ret = MemSmplCompare(siAddr,ramAddr,nbytes/4,0);
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable,
"SiDmaCompare", siAddr,
ramAddr, nbytes/4, 0,
INSERT_RESULT(ret));
thread->state = IO_STATE_START;
thread->inProgress = 0;
}
break;
}
default: {
_TRACE(DERROR,
fprintf(LogFp,
"\tERROR: Illegal IO state encountered!\n"));
}
} /* switch */
} /* SiRandDma */
/***************************************************************************
* AI thread routines
*/
void
AiRandDma(ThreadCmd *thread)
{
int ret;
unsigned int stat;
static unsigned int ramAddr = 0;
static unsigned int nbytes = 400;
static unsigned int dmaCount = 0;
static unsigned int waitCount = 0;
static unsigned int lastStat = 0;
switch (thread->state) {
case IO_STATE_INIT:
case IO_STATE_START: {
thread->inProgress = 1;
ramAddr = AiRdramStart;
ret = osAiSetNextBuffer(ramAddr, nbytes);
dmaCount++;
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "AiTestDma",
ramAddr, nbytes, 0, 0, INSERT_RESULT(ret));
stat = osAiGetStatus();
/* If not full, we start another DMA */
if (!(stat & AI_STATUS_FIFO_FULL) &&
(dmaCount < MinRunCount)) {
ret = osAiSetNextBuffer(ramAddr,nbytes);
dmaCount++;
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "AiTestDma",
ramAddr, nbytes, 0, stat,
INSERT_RESULT(ret));
}
thread->state = IO_STATE_CHECK_STATUS;
break;
}
case IO_STATE_CHECK_STATUS: {
stat = osAiGetStatus();
if (stat != lastStat)
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable,
"AiDmaStatus",
AI_STATUS_REG, AI_STATUS_DMA_BUSY,
1, stat, DONE_STR);
lastStat = stat;
/* If not full, we start another DMA */
if (!(stat & AI_STATUS_FIFO_FULL) &&
(dmaCount < MinRunCount)) {
ret = osAiSetNextBuffer(ramAddr,nbytes);
dmaCount++;
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable,
"AiTestDma", ramAddr,
nbytes, 0, 0, INSERT_RESULT(ret));
}
stat = osAiGetStatus();
_TRACE(DSTATUS,
fprintf(LogFp, "\n\tStatus = 0x%08x\n",stat));
if (!(stat & (AI_STATUS_DMA_BUSY|AI_STATUS_FIFO_FULL))){
if (CheckInterrupt(MI_INTR_AI, &stat)) {
/* Any write clears interrupt */
IO_WRITE(AI_STATUS_REG, 0);
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable,
"AiCheckIntr",
MI_INTR_REG, MI_INTR_AI,
0, stat, PASS_STR);
}
else {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable,
"AiCheckIntr",
MI_INTR_REG, MI_INTR_AI,
0, stat, FAIL_STR);
errorTotal++;
}
thread->state = IO_STATE_START;
thread->inProgress = 0;
}
break;
}
default: {
_TRACE(DERROR,
fprintf(LogFp,
"\tERROR: Illegal IO state encountered!\n"));
}
} /* switch */
} /* AiRandDma */
/***************************************************************************
* VI thread routines
*/
static void
dumpViRegs(void)
{
fprintf(LogFp, "VI Regs:\n");
fprintf(LogFp, "\tcurrent=0x%08x\n", IO_READ(VI_CURRENT_REG));
fprintf(LogFp, "\torigin=0x%08x\n", IO_READ(VI_ORIGIN_REG));
fprintf(LogFp, "\twidth =0x%08x\n", IO_READ(VI_WIDTH_REG));
fprintf(LogFp, "\tvIntr =0x%08x\n", IO_READ(VI_V_INTR_REG));
fprintf(LogFp, "\tburst =0x%08x\n", IO_READ(VI_BURST_REG));
fprintf(LogFp, "\tvSync =0x%08x\n", IO_READ(VI_V_SYNC_REG));
fprintf(LogFp, "\thSync =0x%08x\n", IO_READ(VI_H_SYNC_REG));
fprintf(LogFp, "\tleap =0x%08x\n", IO_READ(VI_LEAP_REG));
fprintf(LogFp, "\thStart=0x%08x\n", IO_READ(VI_H_START_REG));
fprintf(LogFp, "\tvStart=0x%08x\n", IO_READ(VI_V_START_REG));
fprintf(LogFp, "\tvBurst=0x%08x\n", IO_READ(VI_V_BURST_REG));
fprintf(LogFp, "\txScale=0x%08x\n", IO_READ(VI_X_SCALE_REG));
fprintf(LogFp, "\tyScale=0x%08x\n", IO_READ(VI_Y_SCALE_REG));
fprintf(LogFp, "\tctrl =0x%08x\n", IO_READ(VI_CONTROL_REG));
}
static void
dumpViContext(__OSViContext *vc)
{
fprintf(LogFp, "VI Context\t= 0x%08x\n", vc);
fprintf(LogFp, "\tstate\t= 0x%08x\n", vc->state);
fprintf(LogFp, "\tcontrol\t= 0x%08x\n", vc->control);
fprintf(LogFp, "\tframep\t= 0x%08x\n", vc->framep);
fprintf(LogFp, "\tmodep\t= 0x%08x\n", vc->modep);
fprintf(LogFp, "\tmsgq\t= 0x%08x\n", vc->msgq);
fprintf(LogFp, "\tmsg\t= 0x%08x\n", vc->msg);
fprintf(LogFp, "\tCommon Regs:\n");
fprintf(LogFp, "\tctrl\t= 0x%08x\n", vc->modep->comRegs.ctrl);
fprintf(LogFp, "\twidth\t= 0x%08x\n", vc->modep->comRegs.width);
fprintf(LogFp, "\tvCurrent\t= 0x%08x\n", vc->modep->comRegs.vCurrent);
fprintf(LogFp, "\tburst\t= 0x%08x\n", vc->modep->comRegs.burst);
fprintf(LogFp, "\tvSync\t= 0x%08x\n", vc->modep->comRegs.vSync);
fprintf(LogFp, "\thSync\t= 0x%08x\n", vc->modep->comRegs.hSync);
fprintf(LogFp, "\tleap\t= 0x%08x\n", vc->modep->comRegs.leap);
fprintf(LogFp, "\thStart\t= 0x%08x\n", vc->modep->comRegs.hStart);
fprintf(LogFp, "\txScale\t= 0x%08x\n", vc->modep->comRegs.xScale);
fprintf(LogFp, "\tField #1 Regs:\n");
fprintf(LogFp, "\torigin\t= 0x%08x\n", vc->modep->fldRegs[0].origin);
fprintf(LogFp, "\tyScale\t= 0x%08x\n", vc->modep->fldRegs[0].yScale);
fprintf(LogFp, "\tvStart\t= 0x%08x\n", vc->modep->fldRegs[0].vStart);
fprintf(LogFp, "\tvBurst\t= 0x%08x\n", vc->modep->fldRegs[0].vBurst);
fprintf(LogFp, "\tvIntr\t= 0x%08x\n", vc->modep->fldRegs[0].vIntr);
fprintf(LogFp, "\tField #2 Regs:\n");
fprintf(LogFp, "\torigin\t= 0x%08x\n", vc->modep->fldRegs[1].origin);
fprintf(LogFp, "\tyScale\t= 0x%08x\n", vc->modep->fldRegs[1].yScale);
fprintf(LogFp, "\tvStart\t= 0x%08x\n", vc->modep->fldRegs[1].vStart);
fprintf(LogFp, "\tvBurst\t= 0x%08x\n", vc->modep->fldRegs[1].vBurst);
fprintf(LogFp, "\tvIntr\t= 0x%08x\n", vc->modep->fldRegs[1].vIntr);
fprintf(LogFp, "\tX-scale:\n");
fprintf(LogFp, "\tfactor\t= %d\n", vc->x.factor);
fprintf(LogFp, "\toffset\t= 0x%04x\n", vc->x.offset);
fprintf(LogFp, "\tscale\t= 0x%08x\n", vc->x.scale);
fprintf(LogFp, "\tY-scale:\n");
fprintf(LogFp, "\tfactor\t= %d\n", vc->y.factor);
fprintf(LogFp, "\toffset\t= 0x%04x\n", vc->y.offset);
fprintf(LogFp, "\tscale\t= 0x%08x\n", vc->y.scale);
}
void ViModeTest(ThreadCmd *thread)
{
/*
* We use thread->state field to tell us which VI mode to run
* and the frame buffer size (16-bit or 32-bit)
*/
int ret;
unsigned int stat, line, oldline;
unsigned short field, pixel, mode, scale;
float xscale, yscale;
static unsigned int frameBufPtr = 0;
static int done;
__OSViContext *vc;
thread->inProgress = 1;
mode = thread->state & 0x00FF;
pixel = thread->state & 0x0100;
scale = (thread->state & 0xF000) >> 12;
fprintf(LogFp,
"---- ViModeTest: starting with mode=%d, pixel=%d, line=%d, scale=%d\n",
mode, pixel, osViGetCurrentLine(), scale);
/* We want RDRAM address to be near 2KB boundary */
/* Advance address by 128 bytes to skip the first field */
#if 0
frameBufPtr = RDRAM_VI_START + 0x400 + 128; /* 0x001fd7e0 */
if (pixel) {
/* frameBufPtr = RDRAM_VI_START + 0x4000; */
frameBufPtr = 0x1000; /* Use tri-small32.rdram */
}
else {
/* frameBufPtr = RDRAM_VI_START + 0x4000; */
frameBufPtr = 0x1000; /* Use tri-small16.rdram */
}
#else
frameBufPtr = 0x1000;
#endif
xscale = (float) 1 / scale;
yscale = (float) 1 / scale;
fprintf(LogFp,
"---- ViModeTest: using x_scale=%2.1f, y_scale=%2.1f\n",
xscale, yscale);
osViSetMode(&osViModeTable[mode]);
osViSetXScale(xscale);
osViSetYScale(yscale);
osViSwapBuffer((void *)frameBufPtr);
dumpViRegs();
fprintf(LogFp, "---- ViModeTest: current field=%d\n",
osViGetCurrentField());
fprintf(LogFp, "---- ViModeTest: calling __osViSwapContext\n");
field = osViGetCurrentField();
__osViSwapContext(field);
dumpViRegs();
fprintf(LogFp, "---- ViModeTest: dumping CURRENT context\n");
dumpViContext(__osViGetCurrentContext());
fprintf(LogFp, "---- ViModeTest: dumping NEXT context\n");
dumpViContext(__osViGetNextContext());
fprintf(LogFp, "---- ViModeTest: finished swapping first context!\n");
vc = __osViGetCurrentContext();
/* Loop until we hit line number */
fprintf(LogFp,
"---- ViModeTest: in field=%d, current=%d, looping until line %d\n",
field, osViGetCurrentLine(), vc->modep->fldRegs[field].vIntr);
oldline = osViGetCurrentLine();
while (1) {
line = osViGetCurrentLine();
if (line >= vc->modep->fldRegs[field].vIntr)
break;
if (line != oldline)
fprintf(LogFp, "---- ViModeTest: in line=%d\n", line);
oldline = line;
}
/* Check for interrupt */
if (CheckInterrupt(MI_INTR_VI, &stat)) {
/* Write to VI_CURRENT_REG to clear interrupt */
IO_WRITE(VI_CURRENT_REG, 0);
fprintf(LogFp, "---- ViModeTest: interrupt #1 passed, stat=%d !\n",
stat);
}
else {
fprintf(LogFp, "---- ViModeTest: interrupt #1 failed, stat=%d !\n",
stat);
}
/* Wait until V_SYNC occurs and wraps around */
oldline = osViGetCurrentLine();
while (1) {
line = osViGetCurrentLine();
if (line < vc->modep->fldRegs[field].vIntr)
break;
if (line != oldline)
fprintf(LogFp, "---- ViModeTest: (v_sync) in line=%d\n", line);
oldline = line;
}
/* Swap context to field #2 */
fprintf(LogFp, "---- ViModeTest: current field=%d\n",
osViGetCurrentField());
fprintf(LogFp, "---- ViModeTest: calling __osViSwapContext\n");
field = osViGetCurrentField();
__osViSwapContext(field);
dumpViRegs();
fprintf(LogFp, "---- ViModeTest: dumping CURRENT context\n");
dumpViContext(__osViGetCurrentContext());
fprintf(LogFp, "---- ViModeTest: dumping NEXT context\n");
dumpViContext(__osViGetNextContext());
vc = __osViGetCurrentContext();
/* Loop until we hit line number */
fprintf(LogFp,
"---- ViModeTest: in field=%d, current=%d, looping until line %d\n",
field, osViGetCurrentLine(), vc->modep->fldRegs[field].vIntr);
oldline = osViGetCurrentLine();
while (1) {
line = osViGetCurrentLine();
if (line >= vc->modep->fldRegs[field].vIntr)
break;
if (line != oldline)
fprintf(LogFp, "---- ViModeTest: in line=%d\n", line);
oldline = line;
}
/* Check for interrupt */
if (CheckInterrupt(MI_INTR_VI, &stat)) {
/* Write to VI_CURRENT_REG to clear interrupt */
IO_WRITE(VI_CURRENT_REG, 0);
fprintf(LogFp, "---- ViModeTest: interrupt #2 passed, stat=%d !\n",
stat);
}
else {
fprintf(LogFp, "---- ViModeTest: interrupt #2 failed, stat=%d !\n",
stat);
}
fprintf(LogFp, "---- ViModeTest: completed at line=%d (0x%08x)\n",
osViGetCurrentLine(), osViGetCurrentLine());
QuickDeath = 1;
} /* ViModeTest */
void ViMLF2Dma(ThreadCmd *thread)
{
int ret;
unsigned int stat, data;
int dmaCount;
static unsigned int ramAddr = 0;
static int done;
fprintf(stdout, "In ViMLF2Dma procedure \n");
switch (thread->state) {
case IO_STATE_INIT:
case IO_STATE_START:
{
fprintf(stdout, "In IO_STATE_START \n");
thread->inProgress = 1;
/****************************************************************/
/* We want RDRAM address to be near 2KB boundary */
/* Advance address by 128 bytes to skip the first field */
ramAddr = RDRAM_VI_START + 0x400 + 128; /* 0x001fd7e0 */
osViSetMode(&osViModeTable[OS_VI_NTSC_LAF2]);
osViSwapBuffer((void *)(RDRAM_VI_START + 0x400));
dumpViRegs();
__osViSwapContext(0);
dumpViRegs();
dumpViContext(__osViGetCurrentContext());
dumpViContext(__osViGetNextContext());
dmaCount++;
fprintf(LogFp, RTST_MSG_RES2_STR, thread - RandThreadTable,
"ViMLF2Dma", ramAddr, 0x28, 0x3ff, 0,
INSERT_RESULT(ret));
thread->state = IO_STATE_CHECK_F0;
fprintf(stdout, "Leaving IO_STATE_START \n");
break;
}
case IO_STATE_CHECK_F0:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_F0: 0x%.2x \n", data);
if (data >= 0x00000028)
thread->state = IO_STATE_CHECK_MID;
break;
}
case IO_STATE_CHECK_MID:
{
/* Wait until DMA counter is back at beginning */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_MID: 0x%.2x \n", data);
dumpViRegs();
dumpViContext(__osViGetCurrentContext());
dumpViContext(__osViGetNextContext());
__osViSwapContext(1);
dumpViRegs();
dumpViContext(__osViGetCurrentContext());
dumpViContext(__osViGetNextContext());
if (data < 0x00000028)
thread->state = IO_STATE_CHECK_F1;
break;
}
case IO_STATE_CHECK_F1:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_F1: 0x%.2x \n", data);
if (data >= 0x00000029)
thread->state = IO_STATE_CHECK_END;
break;
}
case IO_STATE_CHECK_END:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_END: 0x%.2x \n", data);
if (data < 0x00000029)
{
thread->state = IO_STATE_START;
thread->inProgress = 0;
done++;
fprintf(stdout, "Done = %d \n", done);
QuickDeath = 1;
if (done == 6)
{
QuickDeath = 1;
fprintf(stdout, "Finished test \n");
}
}
break;
}
default:
{
_TRACE(DERROR,
fprintf(LogFp,
"\tERROR: Illegal IO state encountered!\n"));
}
} /* switch */
} /* ViMLF2Dma */
/* 5 new vi tests */
/* void ViMLN1Dma(ThreadCmd *thread) */
void ViLAN1Dma(ThreadCmd *thread)
{
int ret;
unsigned int stat, data;
int dmacount;
static int done;
static unsigned int ramAddr = 0;
switch (thread->state)
{
case IO_STATE_INIT:
case IO_STATE_START:
{
fprintf(stdout, "In IO_STATE_START \n");
fflush(stdout);
ret = 0;
thread->inProgress = 1;
ramAddr = RDRAM_VI_START + 0x400;
osViSetMode(&osViModeTable[OS_VI_NTSC_LAN1]);
osViSwapBuffer((void *)ramAddr);
__osViSwapContext(0);
dumpViRegs();
dumpViContext(__osViGetCurrentContext());
dumpViContext(__osViGetNextContext());
dmacount++;
fprintf(LogFp, RTST_MSG_RES2_STR, thread - RandThreadTable,
"ViMLN1Dma", 0x1f5820, 0x28, 0x3ff, 0,
INSERT_RESULT(ret));
thread->state = IO_STATE_CHECK_F0;
fprintf(stdout, "Leaving IO_STATE_START \n");
fflush(stdout);
break;
}
case IO_STATE_CHECK_F0:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_F0: 0x%.2x \n", data);
fflush(stdout);
if (data >= 0x00000028)
thread->state = IO_STATE_CHECK_MID;
break;
}
case IO_STATE_CHECK_MID:
{
/* Wait until DMA counter is back at beginning */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_MID: 0x%.2x \n", data);
fflush(stdout);
if (data < 0x00000028)
thread->state = IO_STATE_CHECK_F1;
break;
}
case IO_STATE_CHECK_F1:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_F1: 0x%.2x \n", data);
fflush(stdout);
if (data >= 0x00000028)
thread->state = IO_STATE_CHECK_END;
break;
}
case IO_STATE_CHECK_END:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_END: 0x%.2x \n", data);
fflush(stdout);
if (data < 0x00000028)
{
thread->state = IO_STATE_CHECK_F0;
thread->inProgress = 0;
done++;
printf("Done = %d \n", done);
if (done == 5)
{
QuickDeath = 1;
printf("Finished test \n");
}
}
break;
}
default:
{
_TRACE(DERROR,
fprintf(LogFp,
"\tERROR: Illegal IO state encountered!\n"));
}
} /* switch */
} /* ViLAN1Dma */
void ViLAN2Dma(ThreadCmd *thread)
{
int ret;
unsigned int stat, data;
int dmacount;
static int done;
static unsigned int ramAddr = 0;
switch (thread->state)
{
case IO_STATE_INIT:
case IO_STATE_START:
{
fprintf(stdout, "In IO_STATE_START \n");
fflush(stdout);
thread->inProgress = 1;
ramAddr = RDRAM_VI_START + 0xd00;
osViSetMode(&osViModeTable[OS_VI_NTSC_LAN2]);
osViSwapBuffer((void *)ramAddr);
__osViSwapContext(0);
dmacount++;
fprintf(LogFp, RTST_MSG_RES2_STR, thread - RandThreadTable,
"ViLAN2Dma", 0x1f6160, 0x28, 0x3ff, 0,
INSERT_RESULT(ret));
thread->state = IO_STATE_CHECK_F0;
fprintf(stdout, "Leaving IO_STATE_START \n");
fflush(stdout);
break;
}
case IO_STATE_CHECK_F0:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_F0: 0x%.2x \n", data);
fflush(stdout);
if (data >= 0x00000028)
thread->state = IO_STATE_CHECK_MID;
break;
}
case IO_STATE_CHECK_MID:
{
/* Wait until DMA counter is back at beginning */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_MID: 0x%.2x \n", data);
fflush(stdout);
if (data < 0x00000028)
thread->state = IO_STATE_CHECK_F1;
break;
}
case IO_STATE_CHECK_F1:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_F1: 0x%.2x \n", data);
fflush(stdout);
if (data >= 0x00000028)
thread->state = IO_STATE_CHECK_END;
break;
}
case IO_STATE_CHECK_END:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_END: 0x%.2x \n", data);
fflush(stdout);
if (data < 0x00000028)
{
thread->state = IO_STATE_CHECK_F0;
thread->inProgress = 0;
done++;
printf("Done = %d \n", done);
if (done == 5)
{
QuickDeath = 1;
printf("Finished test \n");
}
}
break;
}
default:
{
_TRACE(DERROR,
fprintf(LogFp,
"\tERROR: Illegal IO state encountered!\n"));
}
} /* switch */
} /* ViLAN2Dma */
void ViLPN1Dma(ThreadCmd *thread)
{
int ret;
unsigned int stat, data;
int dmacount;
static int done;
static unsigned int ramAddr = 0;
switch (thread->state)
{
case IO_STATE_INIT:
case IO_STATE_START:
{
fprintf(stdout, "In IO_STATE_START \n");
fflush(stdout);
thread->inProgress = 1;
ramAddr = RDRAM_VI_START + 0x1d00;
osViSetMode(&osViModeTable[OS_VI_NTSC_LPN1]);
osViSwapBuffer((void *)ramAddr);
__osViSwapContext(0);
dmacount++;
fprintf(LogFp, RTST_MSG_RES2_STR, thread - RandThreadTable,
"ViLPN1Dma", 0x1f7120, 0x28, 0x3ff, 0,
INSERT_RESULT(ret));
thread->state = IO_STATE_CHECK_F0;
fprintf(stdout, "Leaving IO_STATE_START \n");
fflush(stdout);
break;
}
case IO_STATE_CHECK_F0:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_F0: 0x%.2x \n", data);
fflush(stdout);
if (data >= 0x00000028)
thread->state = IO_STATE_CHECK_MID;
break;
}
case IO_STATE_CHECK_MID:
{
/* Wait until DMA counter is back at beginning */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_MID: 0x%.2x \n", data);
fflush(stdout);
if (data < 0x00000028)
thread->state = IO_STATE_CHECK_F1;
break;
}
case IO_STATE_CHECK_F1:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_F1: 0x%.2x \n", data);
fflush(stdout);
if (data >= 0x00000028)
thread->state = IO_STATE_CHECK_END;
break;
}
case IO_STATE_CHECK_END:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_END: 0x%.2x \n", data);
fflush(stdout);
if (data < 0x00000028)
{
thread->state = IO_STATE_CHECK_F0;
thread->inProgress = 0;
done++;
printf("Done = %d \n", done);
if (done == 5)
{
QuickDeath = 1;
printf("Finished test \n");
}
}
break;
}
default:
{
_TRACE(DERROR,
fprintf(LogFp,
"\tERROR: Illegal IO state encountered!\n"));
}
} /* switch */
} /* ViLPN1Dma */
void ViHAN1Dma(ThreadCmd *thread)
{
int ret;
unsigned int stat, data;
int dmacount;
static int done;
static unsigned int ramAddr = 0;
switch (thread->state)
{
case IO_STATE_INIT:
case IO_STATE_START:
{
fprintf(stdout, "In IO_STATE_START \n");
fflush(stdout);
thread->inProgress = 1;
ramAddr = RDRAM_VI_START + 0x27d0;
osViSetMode(&osViModeTable[OS_VI_NTSC_HAN1]);
osViSwapBuffer((void *)ramAddr);
__osViSwapContext(0);
dmacount++;
fprintf(LogFp, RTST_MSG_RES2_STR, thread - RandThreadTable,
"ViHAN1Dma", 0x1f7c30, 0x28, 0x3ff, 0,
INSERT_RESULT(ret));
thread->state = IO_STATE_CHECK_F0;
fprintf(stdout, "Leaving IO_STATE_START \n");
fflush(stdout);
break;
}
case IO_STATE_CHECK_F0:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_F0: 0x%.2x \n", data);
fflush(stdout);
if (data >= 0x00000028)
thread->state = IO_STATE_CHECK_MID;
break;
}
case IO_STATE_CHECK_MID:
{
/* Wait until DMA counter is back at beginning */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_MID: 0x%.2x \n", data);
fflush(stdout);
if (data < 0x00000028)
thread->state = IO_STATE_CHECK_F1;
break;
}
case IO_STATE_CHECK_F1:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_F1: 0x%.2x \n", data);
fflush(stdout);
if (data >= 0x00000028)
thread->state = IO_STATE_CHECK_END;
break;
}
case IO_STATE_CHECK_END:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_END: 0x%.2x \n", data);
fflush(stdout);
if (data < 0x00000028)
{
thread->state = IO_STATE_CHECK_F0;
thread->inProgress = 0;
done++;
printf("Done = %d \n", done);
if (done == 5)
{
QuickDeath = 1;
printf("Finished test \n");
}
}
break;
}
default:
{
_TRACE(DERROR,
fprintf(LogFp,
"\tERROR: Illegal IO state encountered!\n"));
}
} /* switch */
} /* ViHAN1Dma */
void ViHPF2Dma(ThreadCmd *thread)
{
int ret;
unsigned int stat, data;
int dmacount;
static int done;
static unsigned int ramAddr = 0;
switch (thread->state)
{
case IO_STATE_INIT:
case IO_STATE_START:
{
fprintf(stdout, "In IO_STATE_START \n");
fflush(stdout);
thread->inProgress = 1;
ramAddr = RDRAM_VI_START + 0x3120;
osViSetMode(&osViModeTable[OS_VI_NTSC_HPF2]);
osViSwapBuffer((void *)ramAddr);
__osViSwapContext(0);
dmacount++;
fprintf(LogFp, RTST_MSG_RES2_STR, thread - RandThreadTable,
"ViHPF2Dma", 0x1f5820, 0x28, 0x3ff, 0,
INSERT_RESULT(ret));
thread->state = IO_STATE_CHECK_F0;
fprintf(stdout, "Leaving IO_STATE_START \n");
fflush(stdout);
break;
}
case IO_STATE_CHECK_F0:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_F0: 0x%.2x \n", data);
fflush(stdout);
if (data >= 0x00000028)
thread->state = IO_STATE_CHECK_MID;
break;
}
case IO_STATE_CHECK_MID:
{
/* Wait until DMA counter is back at beginning */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_MID: 0x%.2x \n", data);
fflush(stdout);
if (data < 0x00000028)
thread->state = IO_STATE_CHECK_F1;
break;
}
case IO_STATE_CHECK_F1:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_F1: 0x%.2x \n", data);
fflush(stdout);
if (data >= 0x00000028)
thread->state = IO_STATE_CHECK_END;
break;
}
case IO_STATE_CHECK_END:
{
/* Wait until DMA counter is at end */
data = osViGetCurrentLine();
fprintf(stdout, "In IO_STATE_CHECK_END: 0x%.2x \n", data);
fflush(stdout);
if (data < 0x00000028)
{
thread->state = IO_STATE_CHECK_F0;
thread->inProgress = 0;
done++;
printf("Done = %d \n", done);
if (done == 5)
{
QuickDeath = 1;
printf("Finished test \n");
}
}
break;
}
default:
{
_TRACE(DERROR,
fprintf(LogFp,
"\tERROR: Illegal IO state encountered!\n"));
}
} /* switch */
} /* ViHPF2Dma */
/***************************************************************************
* SP thread routines
*/
static int
getSpSemaphore(void)
{
unsigned int sem;
sem = IO_READ(SP_SEMAPHORE_REG);
/* If sem is 0, it means that we have the semaphore */
return((sem == 0) ? 1 : 0);
}
static void
releaseSpSemaphore(void)
{
IO_WRITE(SP_SEMAPHORE_REG, 0);
}
void
SpRandIoRd(ThreadCmd *thread)
{
unsigned int data;
unsigned int stat;
char s1[20];
static unsigned int address = 0;
/* Assume that ROM has been initialized with data = address */
if ((address == 0) || (address == SpImemStart)) {
address = SpDmemStart;
}
else if (address == SpDmemStart) {
address = SpImemStart;
}
address = address & 0xfffffffc;
/*
* For SP, we need to check for IO full bit before perform
* IO read - If they're busy, we simply exit and try again
* later
*/
stat = osSpGetStatus();
if (((address == SpImemStart) && !(stat & SP_STATUS_HALT))) {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, thread->name,
address, data, 0, stat, BUSY_STR);
return;
}
if (osSpRawReadIo(address, &data) == -1) {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, thread->name,
address, data, 0, stat, BUSY_STR);
}
else {
sprintf(s1, "0x%08x", data);
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, thread->name,
address, data, 0, stat, s1);
}
} /* SpRandIoRd */
void
SpRandIoWrRd(ThreadCmd *thread)
{
int ret;
unsigned int stat, data;
static unsigned int address = 0;
/*
* For SP, we need to check for DMA/IO busy bits before perform
* IO write - If they're busy, we simply exit and try again
* later
*/
/* Reserve the 1st 32-bit for IO read */
if ((address == 0) || (address == SpImemStart+8)) {
address = SpDmemStart+8;
}
else if (address == SpDmemStart+8) {
address = SpImemStart+8;
}
address = address & 0xfffffffc;
stat = osSpGetStatus();
if (((address == SpImemStart+8) && !(stat & SP_STATUS_HALT))) {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, thread->name,
address, address, 0, 0, BUSY_STR);
return;
}
ret = osSpRawWriteIo(address, address);
if (ret == 0) {
if (osSpRawReadIo(address, &data) == 0) {
if (data != address)
ret = -1;
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, thread->name,
address, address, 0, stat, INSERT_RESULT(ret));
return;
}
}
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, thread->name,
address, address, 0, 0, BUSY_STR);
} /* SpRandIoWrRd */
void
SpRandDma(ThreadCmd *thread)
{
int i, ret;
unsigned int stat;
static unsigned int skip, count, nbytes;
static unsigned int dir = OS_READ;
static unsigned int spAddr = 0;
static unsigned int ramAddr = 0;
static unsigned int length = IMEM_TEST_SIZE - 16;
static unsigned int lastStat = 0;
switch (thread->state) {
case IO_STATE_INIT:
case IO_STATE_START: {
thread->inProgress = 1;
/* Toggle
dir = (dir==OS_READ) ? OS_WRITE : OS_READ;
/* Toggle between I/DMEM address
* Reserve the first 2 words (64-bit) for IO W/R
*/
if (spAddr == SpImemStart+16)
spAddr = SpDmemStart+16;
else {
spAddr = SpImemStart+16;
/* For IMEM, we only DMA RDRAM -> IMEM */
dir = OS_WRITE;
}
ramAddr = (dir == OS_WRITE) ? SpRdramStart :
(SpRdramStart + IMEM_TEST_SIZE);
ramAddr &= 0xfffffff8;
spAddr &= 0xfffffff8;
/*
* Now, we configure the length to be
* (skip[12], count[8], len[12])
*/
/* skip = 8, count = 1 (actually 2), nbytes = 48 */
skip = 8;
count = 1;
nbytes = 48;
length = (skip << 20) | (count << 12) | nbytes;
/* If DMA is full, we simply return */
stat = osSpGetStatus();
if (stat & SP_STATUS_DMA_FULL) {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "SpTestDma",
dir, spAddr, ramAddr, stat, BUSY_STR);
} else {
/* else start DMA and go to next state */
if (!getSpSemaphore()) {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "SpTestDma",
dir, spAddr, ramAddr, length, BUSY_STR);
break;
}
ret = osSpRawStartDma(dir, spAddr,
ramAddr, length);
releaseSpSemaphore();
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "SpTestDma",
dir, spAddr, ramAddr, length,
INSERT_RESULT(ret));
thread->state = IO_STATE_CHECK_STATUS;
}
break;
}
case IO_STATE_CHECK_STATUS: {
stat = osSpGetStatus();
if (stat != lastStat)
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "SpDmaStatus",
SP_STATUS_REG, SP_STATUS_DMA_BUSY,
1, stat, DONE_STR);
lastStat = stat;
if (!(stat & SP_STATUS_DMA_BUSY)) {
if (CompareEnabled)
thread->state = IO_STATE_COMPARE;
else {
thread->state = IO_STATE_START;
thread->inProgress = 0;
}
}
break;
}
case IO_STATE_COMPARE: {
/* Here we compare the 1st word, last word */
/* nbytes = 48; skip = 8; count = 2
* length = skip | count | nbytes;
*/
for (i = 0; i < (count+1); i++) {
ret = MemSmplCompare(spAddr+(i*nbytes),
ramAddr+(i*nbytes)+(i*skip),
nbytes/4, 0);
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable,
"SpDmaCompare",
spAddr+(i*nbytes),
ramAddr+(i*nbytes)+(i*skip),
nbytes/4, 0, INSERT_RESULT(ret));
}
thread->state = IO_STATE_INIT;
thread->inProgress = 0;
break;
}
default: {
_TRACE(DERROR,
fprintf(LogFp,
"\tERROR: Illegal IO state encountered!\n"));
}
} /* switch */
} /* SpRandDma */
/* Dummy sp test used in vi testing */
void
SpDummyDma(ThreadCmd *thread)
{
int i, ret;
unsigned int stat;
static unsigned int skip, count, nbytes;
static unsigned int dir = OS_READ;
static unsigned int spAddr = 0;
static unsigned int ramAddr = 0;
static unsigned int length = IMEM_TEST_SIZE - 16;
static unsigned int lastStat = 0;
switch (thread->state) {
case IO_STATE_INIT:
case IO_STATE_START: {
thread->inProgress = 1;
/* Toggle */
dir = OS_READ;
spAddr = SP_DMEM_START;
ramAddr = SpRdramStart + IMEM_TEST_SIZE;
ramAddr &= 0xfffffff8;
spAddr &= 0xfffffff8;
/*
* Now, we configure the length to be
* (skip[12], count[8], len[12])
*/
skip = 0;
count = 15;
nbytes = 256;
length = (skip << 20) | (count << 12) | nbytes;
/* If DMA is full, we simply return */
stat = osSpGetStatus();
if (stat & SP_STATUS_DMA_FULL) {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "SpTestDma",
dir, spAddr, ramAddr, stat, BUSY_STR);
} else {
/* else start DMA and go to next state */
if (!getSpSemaphore()) {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "SpTestDma",
dir, spAddr, ramAddr, length, BUSY_STR);
break;
}
ret = osSpRawStartDma(dir, spAddr,
ramAddr, length);
releaseSpSemaphore();
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "SpTestDma",
dir, spAddr, ramAddr, length,
INSERT_RESULT(ret));
thread->state = IO_STATE_CHECK_STATUS;
}
break;
}
case IO_STATE_CHECK_STATUS: {
stat = osSpGetStatus();
if (stat != lastStat)
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "SpDmaStatus",
SP_STATUS_REG, SP_STATUS_DMA_BUSY,
1, stat, DONE_STR);
lastStat = stat;
if (!(stat & SP_STATUS_DMA_BUSY)) {
thread->state = IO_STATE_INIT;
thread->inProgress = 0;
releaseSpSemaphore();
}
break;
}
default: {
_TRACE(DERROR,
fprintf(LogFp,
"\tERROR: Illegal IO state encountered!\n"));
}
} /* switch */
} /* SpDummyDma */
/*
* Use Evan's test to exercise DMA transfers to/from RDRAM from/to D/IMEM
* Use semaphore to guarantee that only one processor (either SP or CPU)
* can DMA in/out of D/IMEM. Load Evan's test to D/IMEM and DMA RDRAM data
* from ROM cartrdige (to 0x0012000 - 0x0012700).
*
* Test uses SP signal 0 : 0 - test not done
* 1 - test done
* signal [3-1] : test that fails (if all passes, should be 0)
*
* Should poll for either the SP halt bit and signal 0 bit to be set
*
* Test only uses the upper 2KB in both D/IMEM
*/
void
SpLocDma(ThreadCmd *thread)
{
unsigned int stat, data;
ThreadCmd *dpThread;
unsigned int testFile = 0;
unsigned int testNum = 0;
static unsigned int testCount = 1;
static unsigned int lastStat = 0;
static unsigned int done = 0;
static unsigned int init = 0;
spLocDmaActive = 1;
switch (thread->state) {
case IO_STATE_INIT:
case IO_STATE_START: {
thread->inProgress = 1;
/*
* Assume that D/Imem and Rdram has been pre-loaded
* with test data
*/
stat = osSpGetStatus();
/* Make sure that SP is halted before setting PC */
if (stat & SP_STATUS_HALT) {
if (!init) {
/* Set the SP PC to 0 */
if (dma80Enabled) {
osSpSetPc(0);
/* This is a hack to fix the problem
* with exception handler executing
* the else case
*/
init = 1;
}
else {
osSpSetPc(0xb24);
}
init = 1;
}
/* Clear halt bit to kick off SP test */
osSpSetStatus(SP_CLR_HALT);
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable,
"SpLocStart",
SP_STATUS_REG, 0, testCount,
stat, DONE_STR);
thread->state = IO_STATE_CHECK_STATUS;
}
else {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable,
"SpLocStart",
SP_STATUS_REG, 0, testCount,
stat, BUSY_STR);
}
break;
}
case IO_STATE_CHECK_STATUS: {
stat = osSpGetStatus();
if (stat != lastStat)
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "SpLocStatus",
SP_STATUS_REG, SP_STATUS_HALT,
testCount, stat, DONE_STR);
lastStat = stat;
/* Check for halt bit set */
if (stat & (SP_STATUS_HALT | SP_STATUS_BROKE)) {
if (dma80Enabled) {
/* Check for failed test */
if (stat & (SP_STATUS_SIG1 | SP_STATUS_SIG2 |
SP_STATUS_SIG3)) {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "SpLocCheck",
SP_STATUS_REG, testCount,
(SP_STATUS_SIG1 | SP_STATUS_SIG2 |
SP_STATUS_SIG3), stat, FAIL_STR);
errorTotal++;
} else
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "SpLocCheck",
SP_STATUS_REG, testCount,
(SP_STATUS_SIG1 | SP_STATUS_SIG2 |
SP_STATUS_SIG3), stat, PASS_STR);
/* Clear broke and signal bits [1-3] */
osSpSetStatus(
(SP_CLR_BROKE | SP_CLR_SIG1 |
SP_CLR_SIG2 | SP_CLR_SIG3));
}
else {
/* Check for failed test */
if (stat & SP_STATUS_SIG1) {
/* Get test file from RDRAM_IMEM_TEST_ID */
testFile = IO_READ(RDRAM_IMEM_TEST_ID);
testFile = (testFile & 0x000000ff) >> 3;
/* Get test number from DMEM address 0 */
osSpRawReadIo( SP_DMEM_START, &testNum);
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "SpLocCheck",
SP_STATUS_REG, testFile, testNum,
stat, FAIL_STR);
errorTotal++;
}
else {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "SpLocCheck",
SP_STATUS_REG, testCount,
SP_STATUS_SIG1, stat, PASS_STR);
}
/* Clear broke and signal 1 */
osSpSetStatus(SP_CLR_BROKE | SP_CLR_SIG1);
} /* not dma80 test */
thread->state = IO_STATE_START;
thread->inProgress = 0;
testCount++;
}
break;
}
default: {
_TRACE(DERROR,
fprintf(LogFp,
"\tERROR: Illegal IO state encountered!\n"));
}
} /* switch */
} /* SpLocDma */
/***************************************************************************
* DP thread routines
*/
static void
initDpXbusChannel(unsigned int dmemActive)
{
/* Setup dmem/rdram-xbus channel */
if (dmemActive == 0) {
IO_WRITE(DPC_STATUS_REG, DPC_CLR_XBUS_DMEM_DMA);
/* This is a hack: without the next statement, program ignores
* the else condition and executes the other memory write:
* could the bug be in the exception handler or compiler?
*/
dmemActive = 0;
} else {
IO_WRITE(DPC_STATUS_REG, DPC_SET_XBUS_DMEM_DMA);
dmemActive = 1;
}
/* Wait for xbus_dmem_dma set/cleared */
MemPollStatus(DPC_STATUS_REG,
DPC_STATUS_XBUS_DMEM_DMA, (dmemActive != 0) ? 0 : 1, 0);
} /* initDpXbusChannel */
static void
parseVerifyInfo(void)
{
VerifyInfo *verifp;
int count;
/* Get DP list starting address and length count
* count is a multiple of 8 (64-bit)
*/
#ifdef __sgi__
verifp=(VerifyInfo *)PHYS_TO_K1(VERIFY_INFO_PHYSADDR);
dplStartAddr = verifp->rdpListAddr;
/*
* The rdpListSize is 64 bit written back by the SP. The count resides in
* the lower 32 bit. Since iosim only traps 32 bit mbus reads, we must
* read the lower 32 bit.
*/
count = *(((unsigned int *)&verifp->rdpListSize)+1);
#else
{
VerifyInfo tmp;
int offset = ((void*) tmp->rdpListAddr) - ((void *)tmp);
dplStartAddr = IO_READ(VERIFY_INFO_PHYSADDR+offset);
offset = ((void*) tmp->rdpListSize) - ((void *)tmp);
count = IO_READ(VERIFY_INFO_PHYSADDR+offset+offset+4) ;
}
#endif
fprintf(LogFp, "VerifyInfo: start=0x%x, count=%d\n",
dplStartAddr, count);
/*
* Calculate DP list ending address and set current address
*/
dplEndAddr = dplStartAddr + count;
dplCurrAddr = dplStartAddr;
} /* parseVerifyInfo */
static void
setupRingBuffer(void)
{
unsigned int i, data;
dplRingStartp &= 0xfffffff8;
#ifdef _NOUIO
initDpXbusChannel(dplRingSource);
#endif
/* Copy from DP list to ring buffer */
i = 0;
while ((i < dplRingSize) &&
(dplCurrAddr < dplEndAddr)) {
data = IO_READ(dplCurrAddr);
if (dplRingSource != FROM_RDRAM) {
osSpRawWriteIo(dplRingStartp+(i*4), data);
}
else
IO_WRITE((dplRingStartp+(i*4)), data);
dplCurrAddr += 4;
i++;
}
if (dplRingSource == FROM_DMEM2) { /* Use Evan's test */
initDpXbusChannel(1);
/* Fill remaining space with 0 (noop) */
while (i < dplRingSize) {
osSpRawWriteIo(dplRingStartp+(i*4), 0);
i++;
}
/* Set sig0 in SP to tell SP that it can perform
* DMA to DPC
*/
osSpSetStatus(SP_SET_SIG0);
dplRingEndp = Dp2DmemEnd & 0xfffffff8;
}
else {
/* Since ring size is an even number of 32-bit words and
* start/end addresses are 8-byte aligned, we assume
* that "i" (after while loop) is an even number
*/
dplRingEndp = (dplRingStartp+(i*4)) & 0xfffffff8;
#ifdef _NOUIO
/* Write start & end addresses */
IO_WRITE(DPC_START_REG, dplRingStartp);
/*
* If end is far away from start (at least 10 64-bit
* words, we program 2 end pointers to satisfy the case:
* 3) start -> end (no stalled) -> end
*/
if (((dplRingEndp - dplRingStartp)/8) > 10) {
IO_WRITE(DPC_END_REG, dplRingEndp-8);
}
/* Reset end pointer */
IO_WRITE(DPC_END_REG, dplRingEndp);
#else
osDpSetNextBuffer(dplRingStartp, (i*4));
#endif
} /* else */
} /* setupRingBuffer */
void
DpcRandDma(ThreadCmd *thread)
{
VerifyInfo *verifp;
int i, ret;
unsigned int stat, data, countAddr;
unsigned int spStat;
static ThreadCmd *spThread = NULL;
static unsigned int init = 0;
static unsigned int count = 0;
static unsigned int done = 0;
static unsigned int lastStat = 0;
/*
* For DP testing of the command buffer, we pass it a real display
* list for processing. By programming the fifo in circular manner
* all the different conditions will be exercised.
* 1) idle -> start -> end
* 2) start -> end (stalled) -> end
* 3) start -> end (no stalled) -> end
* 4) start -> end -> wrap
*
* In this test, we have a DP list and a small ring buffer in RDRAM.
* We copy 64-bit words from the DP list to the ring buffer and
* kick off DMA to DP Cmd from the ring buffer. We maintain 2 pointers
* (start and end) in the ring buffer. By wrapping these pointers
* around the buffer, we will exercise all the 4 conditions mentioned
* above.
* RDRAM
* +-----------+
* +-- | DP List |
* | | |
* | | |
* | +-----------+
* | | . |
* | | . |
* | | . |
* | | |
* | +-----------+ <- Start
* +-> | Ring |
* | Buffer |
* +-----------+ <- End
*
* NOTE:
* - Need to enlarge the ring buffer size (to 30 64-bit words)
* so that DMA busy bit can be verified in dmem->xbus direction
* (DP takes around 11 cycles to process CMD FIFO; that is why
* with the current size of 11 64-bit words, we can't see busy
* bit to set)
* - Need to put DpRdramStart at an address such that the RDRAM
* ring buffer spans a 2KB-page boundary.
*/
/* Here, we kick off DP for DMA data from RDRAM into DP for
* processing and writing out results back to RDRAM
* Since RDRAM is mmap with a file, the output can be reviewed
* once the test is completed
*/
/* For now, we only paint the display list ONCE! */
if (done) {
return;
}
dpcRandDmaActive = 1;
switch (thread->state) {
case IO_STATE_INIT:
case IO_STATE_START: {
thread->inProgress = 1;
if (!init) {
init = 1;
/* Get info from VerifyInfo structure */
parseVerifyInfo();
/* Find SpLocDma thread */
spThread = findActiveThread((void *)SpLocDma);
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "DpcDmaInit",
dplStartAddr, dplEndAddr,
dplEndAddr - dplStartAddr,
dplRingSize, DONE_STR);
} /* if */
count++;
/* We alternate between RDRAM and 2 DMEM ring buffers */
dplRingSource = (dplRingSource == FROM_RDRAM) ?
FROM_DMEM1 : FROM_RDRAM;
/* Initialize start pointer and size for ring buffer */
dplRingStartp = (dplRingSource == FROM_RDRAM) ?
DpRdramStart : DpDmemStart;
dplRingStartp &= 0xfffffff8;
/*
* We randomly pick the ring buffer size to be between
* 4 and 124 32-bit words
*/
dplRingSize = 0;
while (dplRingSize == 0) {
dplRingSize = random() & 0x07c;
}
/* HACK to use Sp's code to DMA data to CMD FIFO */
if (dma80Enabled && spThread &&
((count & 0x3) == 0x3)) {
data = osSpGetStatus();
if (!(data & SP_STATUS_SIG0)) {
dplRingSource = FROM_DMEM2;
dplRingStartp = Dp2DmemStart;
dplRingSize = 62; /* 248 bytes */
}
}
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "DpcDmaStart",
dplRingStartp, dplRingEndp, dplCurrAddr,
dplRingSize, "Begin");
setupRingBuffer();
/* Read out status */
stat = osDpGetStatus();
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "DpcDmaStart",
dplRingStartp, dplRingEndp, dplCurrAddr,
stat, PASS_STR);
thread->state = IO_STATE_CHECK_STATUS;
break;
}
case IO_STATE_CHECK_STATUS: {
/* Make sure that Sp's code has acknowledged SIG0 */
if (dplRingSource == FROM_DMEM2) {
spStat = osSpGetStatus();
if (spStat & SP_STATUS_SIG0) {
/* We manually start this thread to
* kick off the DMA from ring buffer to DP
*/
SpLocDma(spThread);
break;
}
}
/* Wait until DMA counter is at end */
data = IO_READ(DPC_CURRENT_REG);
stat = osDpGetStatus();
/* Here, we should check for END_VALID */
if (data == (dplRingEndp & 0x00ffffff)) {
if (dplCurrAddr >= dplEndAddr)
thread->state = IO_STATE_COMPARE;
else
thread->state = IO_STATE_START;
}
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable, "DpcDmaCurrent",
DPC_CURRENT_REG, data, dplRingEndp,
stat, DONE_STR);
break;
}
case IO_STATE_COMPARE: {
stat = osDpGetStatus();
if (stat != lastStat)
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable,
"DpcDmaStatus",
DPC_STATUS_REG, DPC_STATUS_PIPE_BUSY,
1, stat, DONE_STR);
lastStat = stat;
if (!(stat & DPC_STATUS_PIPE_BUSY)) {
if (CheckInterrupt(MI_INTR_DP, &stat)) {
/* Write to bit[11] of MI_INIT_MODE
* to clear interrupt
*/
IO_WRITE(MI_INIT_MODE_REG,
MI_CLR_DP_INTR);
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable,
"DpcCheckIntr",
MI_INTR_REG, MI_INTR_DP,
0, stat, PASS_STR);
}
else {
fprintf(LogFp, RTST_MSG_RES2_STR,
thread - RandThreadTable,
"DpcCheckIntr",
MI_INTR_REG, MI_INTR_DP,
0, stat, FAIL_STR);
errorTotal++;
}
done = 1;
thread->state = IO_STATE_INIT;
thread->inProgress = 0;
}
break;
}
default: {
_TRACE(DERROR,
fprintf(LogFp,
"\tERROR: Illegal IO state encountered!\n"));
}
} /* switch */
} /* DpcRandDma */
/***************************************************************************
* Memory compare by sampling various 32-bit words in the array
*/
int
MemSmplCompare(int src, int dst, int nwords, int failExpected)
{
/* Compare 'nwords' bytes between source 'src' and destination 'dst' */
/* 'nwords' must be even and addresses word-aligned */
int i;
unsigned int w1, w2;
errorCount = 0;
_TRACE(DCOMPARE, fprintf(LogFp,"\tSRC\t\t\t\tDST\n"));
src &= 0xfffffffc; /* Ensure addresses are word-aligned */
dst &= 0xfffffffc;
/* Here, we sample 1st word, then every 5th word, then last word
* So, if there are 16 words (64-bytes), then it's a diagonal-line
* compare
*/
for (i = 0; i < nwords; i += 5) {
w1 = IO_READ(src+(i*4));
w2 = IO_READ(dst+(i*4));
_TRACE(DCOMPARE, fprintf(LogFp,
"\t%08x: %08x\t%08x: %08x\t\n",
src+(i*4), w1, dst+(i*4), w2));
if (w1 != w2) {
errorCount++;
_TRACE(DERROR, RANDLOG_ERROR(src+(i*4), w1,
dst+(i*4), w2));
break;
}
}
/* Test the last word */
if (errorCount == 0) {
w1 = IO_READ(src+((nwords-1)*4));
w2 = IO_READ(dst+((nwords-1)*4));
_TRACE(DCOMPARE, fprintf(LogFp,
"\t%08x: %08x\t%08x: %08x\t\n",
src+((nwords-1)*4), w1, dst+((nwords-1)*4), w2));
if (w1 != w2) {
errorCount++;
_TRACE(DERROR, RANDLOG_ERROR(src+((nwords-1)*4), w1,
dst+((nwords-1)*4), w2));
}
}
errorTotal += errorCount;
return((errorCount == 0) ? 0 : -1);
} /* MemSmplCompare */
/***************************************************************************
* Initialize various IO subsystems (RDRAM, PI, AI)
*/
void
IoRandInit(char *testRange)
{
extern char IpcName[];
unsigned int data = 0;
fprintf(LogFp, "\n******** Parameters ********\n");
fprintf(LogFp, "Ipc name = %s\n", IpcName);
fprintf(LogFp, "Debug flag = 0x%08x\n", Dflags);
fprintf(LogFp, "Log file = %s\n", LogFile);
fprintf(LogFp, "Test range = %s\n",
(testRange == NULL) ? "all" : testRange);
fprintf(LogFp, "Random test seed = %d\n", TestSeed);
fprintf(LogFp, "Minimum run count per thread = %d\n", MinRunCount);
fprintf(LogFp, "Minimum iteration for testing = %d\n", LoopCount);
fprintf(LogFp, "Data comparison = %s\n",
CompareEnabled ? "on" : "off");
fprintf(LogFp, "Scheduling method = %s\n",
RoundRobinEnabled ? "round-robin" : "random");
fprintf(LogFp, "Rdram test size = 0x%08x\n",
RdramTestSize);
fprintf(LogFp, "I/Dmem test size = 0x%08x\n\n",
IMEM_TEST_SIZE);
fprintf(LogFp, "MI:\tStart = 0x%08x\tEnd = 0x%08x\n",
MiRdramStart, MiRdramEnd);
fprintf(LogFp, "PI:\tStart = 0x%08x\tEnd = 0x%08x\n",
PiRdramStart, PiRdramEnd);
fprintf(LogFp, " Rom1:\tStart = 0x%08x\tEnd = 0x%08x\n",
PiRomStart[0], PiRomEnd[0]);
fprintf(LogFp, " Rom2:\tStart = 0x%08x\tEnd = 0x%08x\n",
PiRomStart[1], PiRomEnd[1]);
fprintf(LogFp, " WRom1:\tStart = 0x%08x\tEnd = 0x%08x\n",
PiWRomStart1, PiWRomEnd1);
fprintf(LogFp, " WRom2:\tStart = 0x%08x\tEnd = 0x%08x\n",
PiWRomStart2, PiWRomEnd2);
fprintf(LogFp, "SI:\tStart = 0x%08x\tEnd = 0x%08x\n",
SiRdramStart, SiRdramEnd);
fprintf(LogFp, " Ram:\tStart = 0x%08x\tEnd = 0x%08x\n",
SiRamStart, SiRamEnd);
fprintf(LogFp, " Rom:\tStart = 0x%08x\tEnd = 0x%08x\n",
SiRomStart, SiRomEnd);
fprintf(LogFp, "AI:\tStart = 0x%08x\tEnd = 0x%08x\n",
AiRdramStart, AiRdramEnd);
fprintf(LogFp, "SP:\tStart = 0x%08x\tEnd = 0x%08x\n",
SpRdramStart, SpRdramEnd);
fprintf(LogFp, " Imem:\tStart = 0x%08x\tEnd = 0x%08x\n",
SpImemStart, SpImemEnd);
fprintf(LogFp, " Dmem:\tStart = 0x%08x\tEnd = 0x%08x\n\n",
SpDmemStart, SpDmemEnd);
fprintf(LogFp, "DP:\tStart = 0x%08x\tEnd = 0x%08x\n",
DpRdramStart, DpRdramEnd);
fprintf(LogFp, " Dmem:\tStart = 0x%08x\tEnd = 0x%08x\n\n",
DpDmemStart, DpDmemEnd);
fprintf(LogFp, "VI:\tStart = 0x%08x\tEnd = 0x%08x\n",
ViRdramStart, ViRdramEnd);
fprintf(LogFp, "\n******** Parameters ********\n\n");
fprintf(LogFp, "Initializing random environment...\n");
/* Config RDRAM */
fprintf(LogFp, RTST_MSG_RES2_STR,
0, "RdramInit", Rdram1Enabled, 0, 0, 0, DONE_STR);
RdramInit(Rdram1Enabled);
/* Print out hardware version */
data = IO_READ(MI_VERSION_REG);
fprintf(LogFp, "Hardware version = 0x%08x\n", data);
#if 0
/* Initialize the Peripheral Interface (PI) controller */
/* Initial test cause the IO busy bit to always be set? */
fprintf(LogFp, "Configuring PI Domains...\n");
fprintf(LogFp, RTST_MSG_RES2_STR,
0, "PiConfigDomain1", 0x80, 0x20, 0x02, 0x03, DONE_STR);
PiConfigDomain(PI_DOMAIN1_REG, 0x80, 0x20, 0x02, 0x03);
fprintf(LogFp, RTST_MSG_RES2_STR,
0, "PiConfigDomain2", 0x80, 0x20, 0x02, 0x03, DONE_STR);
PiConfigDomain(PI_DOMAIN2_REG, 0x80, 0x20, 0x02, 0x03);
#endif
/* Init Video Interface (VI) to get proper video clock signal into AI */
/* t 0102 04400000 00000000 00000000 00000000 */
fprintf(LogFp, "Initializing VI clock signal...\n");
IO_WRITE(VI_STATUS_REG, 0);
fprintf(LogFp, "Initializing refresh signal...\n");
IO_WRITE(VI_H_SYNC_REG, 0x130);
/* Init VI internal structures and set default mode */
fprintf(LogFp, "Initializing VI default mode...\n");
__osViInit();
dumpViRegs();
#if 0
/* Config AI: dacRate, bitRate */
fprintf(LogFp, "Initializing AI...\n");
/*
* Based on Rambus clock (243.37 MHz) and video clock (48.67 MHz)
* (using cg.v with RAMBUS_CLOCK_PERIOD=4.10897) to get 44.1 KHz
* for audio: DAC rate = 1103 (0x44f), bit rate = 15 (0xf)
* For faster sample rate: use DAC rate=0x86, bit rate=0x1
*/
if (Ai441Enabled) {
/* AiInit(0x44f, 0x0f); */
data = osAiSetFrequency(44100);
fprintf(LogFp, RTST_MSG_RES2_STR,
0, "osAiSetFrequency", 0x44f,0x0f,44100,data,DONE_STR);
}
else {
/* AiInit(0x86, 0x01); */
data = osAiSetFrequency(5000);
fprintf(LogFp, RTST_MSG_RES2_STR,
0, "osAiSetFrequency", 0x86,0x01,5000,data,DONE_STR);
}
fprintf(LogFp, "Halting SP...\n");
osSpSetStatus(SP_SET_HALT);
/* Init D/Imem test area */
fprintf(LogFp, RTST_MSG_RES2_STR,
0, "osSpRawWriteIo", SpImemStart, 0x3, 0x0, 0x0, DONE_STR);
osSpRawWriteIo(SpImemStart, SpImemStart);
osSpRawWriteIo(SpImemStart+4, SpImemStart+4);
osSpRawWriteIo(SpImemStart+8, SpImemStart+8);
osSpRawWriteIo(SpDmemStart, SpDmemStart);
osSpRawWriteIo(SpDmemStart+4, SpDmemStart+4);
osSpRawWriteIo(SpDmemStart+8, SpDmemStart+8);
/* Detect to see which test is loaded in IMEM */
data = IO_READ(RDRAM_IMEM_TEST_ID);
dma80Enabled = ((data & 0xff000000) == 0) ? 1 : 0;
fprintf(LogFp, "IMEM test dma80 is %s...\n", dma80Enabled ? "on":"off");
#endif
/* Setup all interrupt masks */
fprintf(LogFp, "Setting all interrupt masks...\n");
IO_WRITE(MI_INTR_MASK_REG, (MI_INTR_MASK_SET_SP |
MI_INTR_MASK_SET_SI | MI_INTR_MASK_SET_AI |
MI_INTR_MASK_SET_VI | MI_INTR_MASK_SET_PI |
MI_INTR_MASK_SET_DP));
fprintf(LogFp, "Initializing random environment completed!\n");
} /* IoRandInit */
/***************************************************************************
* Send command to tell verilog server to shutdown
*/
extern int IoCmd(int, int);
void
ShutdownServer(void)
{
IoCmd(REQ_QUIT, 0);
}
/***************************************************************************
* Flush VerifyInfo structure to mmap file
*/
void
FlushVerifyInfo(void)
{
int i;
unsigned int data;
/* Read-out/write-in VerifyInfo structure for mmap_rdram to work
* with pre-loaded RDRAM
*/
for (i=0; i < (sizeof(VerifyInfo)/4) + 2; i++) {
data = IO_READ(VERIFY_INFO_PHYSADDR+(i*4));
IO_WRITE(VERIFY_INFO_PHYSADDR+(i*4), data);
}
} /* FlushVerifyInfo */
/***************************************************************************
* Check to see if interrupt is set in MI interrupt register
* Return 1 if interrupt is set, 0 otherwise.
*/
int
CheckInterrupt(unsigned int intrBit, unsigned int *stat)
{
unsigned int ret;
ret = IO_READ(MI_INTR_REG);
*stat = ret;
return(ret & intrBit);
} /* CheckInterrupt */
/***************************************************************************
* Unblock and kill all children threads
* Assume that all threads are not busy and have no outstanding transactions
*/
void
KillAllThreads(void)
{
int i;
ThreadCmd *thread;
for (i=0; i < ActiveTableSize; i++) {
thread = ActiveThreadTable[i];
_TRACE(DLOG,
printf("Unblocking and killing thread %d with pid=%d\n",
thread - RandThreadTable, thread->pid));
/* Here, we unblock the thread and kill it */
/* Do we really need to unblock it first? */
kill(thread->pid, SIGKILL);
}
} /* KillAllThreads */
/***************************************************************************
* Print all entries in active thread table
*/
void
PrintActiveTable(void)
{
int i, testCount;
ThreadCmd *thread;
_TRACE(DLOG, fprintf(LogFp,
"\n*************************************************\n"));
_TRACE(DLOG, fprintf(LogFp, "Thread Table Status:\n"));
testCount = 0;
for (i=0; i < ActiveTableSize; i++) {
thread = ActiveThreadTable[i];
_TRACE(DLOG, fprintf(LogFp, THREAD_PRINT_MSG,
thread - RandThreadTable, thread->pid, thread->entry,
thread->runCount, thread->busy,
thread->state, thread->inProgress, thread->name));
testCount += thread->runCount;
}
_TRACE(DLOG, fprintf(LogFp,
"\n*************************************************\n"));
fprintf(LogFp, "\n*************************************************\n");
fprintf(LogFp,
"\n\tTotal transactions = %d, total error = %d\n",
testCount, errorTotal);
fprintf(LogFp, "\n*************************************************\n");
} /* PrintRandTable */
/***************************************************************************
* Find and return a specified thread from the active table
*/
ThreadCmd *
findActiveThread(void *entry)
{
int i;
for (i = 0; i < ActiveTableSize; i++) {
if (ActiveThreadTable[i]->entry == entry)
return(ActiveThreadTable[i]);
}
return(NULL);
} /* findActiveThread */
/***************************************************************************
* Add a thread to the active table
*/
void
AddActiveTable(int n)
{
if (n > RandTableSize-1) {
fprintf (stderr, "ERROR: test %d out of range\n", n);
exit(1);
}
ActiveTableSize++;
if (ActiveThreadTable == NULL)
ActiveThreadTable = malloc(ActiveTableSize * sizeof(ThreadCmd *));
else
ActiveThreadTable = realloc(ActiveThreadTable,
ActiveTableSize * sizeof(ThreadCmd *));
ActiveThreadTable[ActiveTableSize-1] = &RandThreadTable[n];
}
/***************************************************************************
/* Create a mapping array of the active table procedure numbers so implement
/* random round robin
*/
void
initRoundRobin()
{
int i, ArraySize, Pick, Temp;
ProcessOrder = (int *) malloc(ActiveTableSize * sizeof(int));
for (i=0; i<ActiveTableSize; i++)
ProcessOrder[i] = i;
if (RoundRobinEnabled)
{
ArraySize = ActiveTableSize;
for (i=0; i<ActiveTableSize-1; i++)
{
Pick = random() % ArraySize;
Temp = ProcessOrder[ArraySize-1];
ProcessOrder[ArraySize-- -1] = ProcessOrder[Pick];
ProcessOrder[Pick] = Temp;
}
}
}
/***************************************************************************
* Expand a range expression into a table of pointers to active tests
*/
void
rangeExpand(char *range)
{
char *exp;
int n, state, next_state, start, stop, cindx;
if (range == NULL) {
for (n = 0; n < RandTableSize; n++)
AddActiveTable(n);
return;
}
state = 0;
start = -1;
stop = -1;
cindx = 0;
for (exp = range; *exp != '\0'; exp++) {
switch (state) {
case 0: {
if (isdigit(*exp)) {
start = *exp - '0';
next_state = 1;
} else {
fprintf (stderr,
"Syntax Error: character #%d (%c), state = %d\n",
cindx, *exp, state);
exit (1);
}
break;
}
case 1: {
if (isdigit(*exp)) {
start = (start * 10) + (*exp - '0');
next_state = 1;
} else if (*exp == ',') {
AddActiveTable(start);
start = -1;
next_state = 0;
} else if (*exp == '-') {
next_state = 2;
} else {
fprintf (stderr,
"Syntax Error: character #%d (%c), state = %d\n",
cindx, *exp, state);
exit (1);
}
break;
}
case 2: {
if (isdigit(*exp)) {
stop = *exp - '0';
next_state = 3;
} else {
fprintf (stderr,
"Syntax Error: character #%d (%c), state = %d\n",
cindx, *exp, state);
exit (1);
}
break;
}
case 3: {
if (isdigit(*exp)) {
stop = (stop * 10) + (*exp - '0');
next_state = 3;
} else if (*exp == ',') {
if (start >= stop) {
fprintf (stderr,
"Syntax Error: in range first number(%d) must be smaller than second(%d)\n",
start, stop);
exit (1);
}
for (n = start; n <= stop; n++)
AddActiveTable(n);
start = stop = -1;
next_state = 0;
} else {
fprintf (stderr,
"Syntax Error: character #%d (%c), state = %d\n",
cindx, *exp, state);
exit (1);
}
break;
}
}
state = next_state;
cindx++;
}
/*
* Cleanup
*/
if (start != -1) {
if (stop == -1) {
AddActiveTable(start);
} else {
if (start >= stop) {
fprintf (stderr,
"Syntax Error: in range first number(%d) must be smaller than second(%d)\n",
start, stop);
exit (1);
}
for (n = start; n <= stop; n++)
AddActiveTable(n);
}
}
} /* rangeExpand */