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[/] [openrisc/] [trunk/] [rtos/] [rtems/] [c/] [src/] [lib/] [libbsp/] [powerpc/] [ppcn_60x/] [nvram/] [nvram.c] - Rev 389
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/* * This file contains the NvRAM driver for the PPCn_60x * * COPYRIGHT (c) 1998 by Radstone Technology * * * THIS FILE IS PROVIDED TO YOU, THE USER, "AS IS", WITHOUT WARRANTY OF ANY * KIND, EITHER EXPRESSED OR IMPLIED, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTY OF FITNESS FOR A PARTICULAR PURPOSE. THE ENTIRE RISK * AS TO THE QUALITY AND PERFORMANCE OF ALL CODE IN THIS FILE IS WITH YOU. * * You are hereby granted permission to use, copy, modify, and distribute * this file, provided that this notice, plus the above copyright notice * and disclaimer, appears in all copies. Radstone Technology will provide * no support for this code. * */ #include <bsp.h> #include "ds1385.h" #include "mk48t18.h" #include "stk11c68.h" /* * Private types */ typedef void (*PNVRAMWRITE) ( unsigned32 ulOffset, unsigned8 ucByte ); typedef unsigned8 (*PNVRAMREAD) ( unsigned32 ulOffset ); typedef void (*PNVRAMCOMMIT) ( ); typedef struct _NVRAM_ENTRY_TABLE { PNVRAMWRITE nvramWrite; PNVRAMREAD nvramRead; PNVRAMCOMMIT nvramCommit; unsigned32 nvramSize; } NVRAM_ENTRY_TABLE, *PNVRAM_ENTRY_TABLE; /* * Private routines */ /* * This routine provides a stub for NvRAM devices which * do not require a commit operation */ static void nvramCommitStub(); /* * DS1385 specific routines */ static void nvramDsWrite(unsigned32 ulOffset, unsigned8 ucByte); static unsigned8 nvramDsRead(unsigned32 ulOffset); /* * MK48T18 specific routines */ static void nvramMkWrite(unsigned32 ulOffset, unsigned8 ucByte); static unsigned8 nvramMkRead(unsigned32 ulOffset); /* * STK11C68 specific routines */ static void nvramStk11C68Commit(); /* * STK11C88 specific routines */ static void nvramStk11C88Commit(); /* * NvRAM hook tables */ NVRAM_ENTRY_TABLE nvramDsTable = { nvramDsWrite, nvramDsRead, nvramCommitStub, DS1385_NVSIZE }; NVRAM_ENTRY_TABLE nvramMkTable = { nvramMkWrite, nvramMkRead, nvramCommitStub, MK48T18_NVSIZE }; /* * As the STK devicxe is at the same address as the MK device, * the MK read/write routines may be used */ NVRAM_ENTRY_TABLE nvramStkTable = { nvramMkWrite, nvramMkRead, nvramStk11C68Commit, STK11C68_NVSIZE }; NVRAM_ENTRY_TABLE nvramStk88Table = { nvramMkWrite, nvramMkRead, nvramStk11C88Commit, STK11C88_NVSIZE }; /* * Private variables */ static PNVRAM_ENTRY_TABLE pNvRAMFunc; static boolean bNvRAMChanged=FALSE; static unsigned32 ulPRePOSAreaLength; static unsigned32 ulPRePOSAreaOffset; /* * Mutual-exclusion semaphore */ static rtems_id semNvRAM; /* * These routines support the ds1385 */ static unsigned8 nvramDsRead(unsigned32 ulOffset) { unsigned8 ucTemp; ucTemp = ulOffset & 0xff; outport_byte(DS1385_PORT_BASE, ucTemp); ucTemp = (ulOffset >> 8) & 0xf; outport_byte((DS1385_PORT_BASE + 1) , ucTemp); inport_byte(DS1385_PORT_BASE+3, ucTemp); return(ucTemp); } static void nvramDsWrite(unsigned32 ulOffset, unsigned8 ucData) { unsigned8 ucTemp; ucTemp = (unsigned8)(ulOffset & 0xff); outport_byte(DS1385_PORT_BASE, (unsigned8) ucTemp); ucTemp = (unsigned8)((ulOffset >> 8) & 0xf); outport_byte((DS1385_PORT_BASE + 1) , (unsigned8)ucTemp); outport_byte((DS1385_PORT_BASE+3), ucData); } /* * These routines support the MK48T18 and STK11C68 */ static unsigned8 nvramMkRead(unsigned32 ulOffset) { unsigned8 *pNvRAM = (unsigned8 *)MK48T18_BASE; return(pNvRAM[ulOffset]); } static void nvramMkWrite(unsigned32 ulOffset, unsigned8 ucData) { unsigned8 *pNvRAM = (unsigned8 *)MK48T18_BASE; pNvRAM[ulOffset]=ucData; } /* * This routine provides a stub for NvRAM devices which * do not require a commit operation */ static void nvramCommitStub() { } /* * This routine triggers a transfer from the NvRAM to the * EE array in the STK11C68 device */ static void nvramStk11C68Commit() { #if 0 rtems_interval ticks_per_second; rtems_status_code status; #endif rtems_semaphore_obtain(semNvRAM, RTEMS_WAIT, RTEMS_NO_TIMEOUT); /* * Issue Store command */ EIEIO; (void)pNvRAMFunc->nvramRead(0x0000); EIEIO; (void)pNvRAMFunc->nvramRead(0x1555); EIEIO; (void)pNvRAMFunc->nvramRead(0x0aaa); EIEIO; (void)pNvRAMFunc->nvramRead(0x1fff); EIEIO; (void)pNvRAMFunc->nvramRead(0x10f0); EIEIO; (void)pNvRAMFunc->nvramRead(0x0f0f); EIEIO; /* * Delay for 10mS to allow store to * complete */ #if 0 status = rtems_clock_get( RTEMS_CLOCK_GET_TICKS_PER_SECOND, &ticks_per_second ); status = rtems_task_wake_after(ticks_per_second/100); #endif bNvRAMChanged=FALSE; rtems_semaphore_release(semNvRAM); } /* * This routine triggers a transfer from the NvRAM to the * EE array in the STK11C88 device */ static void nvramStk11C88Commit() { #if 0 rtems_interval ticks_per_second; rtems_status_code status; #endif rtems_semaphore_obtain(semNvRAM, RTEMS_WAIT, RTEMS_NO_TIMEOUT); /* * Issue Store command */ EIEIO; (void)pNvRAMFunc->nvramRead(0x0e38); EIEIO; (void)pNvRAMFunc->nvramRead(0x31c7); EIEIO; (void)pNvRAMFunc->nvramRead(0x03e0); EIEIO; (void)pNvRAMFunc->nvramRead(0x3c1f); EIEIO; (void)pNvRAMFunc->nvramRead(0x303f); EIEIO; (void)pNvRAMFunc->nvramRead(0x0fc0); EIEIO; /* * Delay for 10mS to allow store to * complete */ #if 0 status = rtems_clock_get( RTEMS_CLOCK_GET_TICKS_PER_SECOND, &ticks_per_second ); status = rtems_task_wake_after(ticks_per_second/100); #endif bNvRAMChanged=FALSE; rtems_semaphore_release(semNvRAM); } /* * These are the publically accessable routines */ /* * This routine returns the size of the NvRAM */ unsigned32 SizeNvRAM() { return(ulPRePOSAreaLength); } /* * This routine commits changes to the NvRAM */ void CommitNvRAM() { if(bNvRAMChanged) { (pNvRAMFunc->nvramCommit)(); } } /* * This routine reads a byte from the NvRAM */ rtems_status_code ReadNvRAM8(unsigned32 ulOffset, unsigned8 *pucData) { if(ulOffset>ulPRePOSAreaLength) { return RTEMS_INVALID_ADDRESS; } rtems_semaphore_obtain(semNvRAM, RTEMS_WAIT, RTEMS_NO_TIMEOUT); *pucData=pNvRAMFunc->nvramRead(ulPRePOSAreaOffset+ulOffset); rtems_semaphore_release(semNvRAM); return(RTEMS_SUCCESSFUL); } /* * This routine writes a byte to the NvRAM */ rtems_status_code WriteNvRAM8(unsigned32 ulOffset, unsigned8 ucValue) { if(ulOffset>ulPRePOSAreaLength) { return RTEMS_INVALID_ADDRESS; } rtems_semaphore_obtain(semNvRAM, RTEMS_WAIT, RTEMS_NO_TIMEOUT); pNvRAMFunc->nvramWrite(ulPRePOSAreaOffset+ulOffset, ucValue); bNvRAMChanged=TRUE; rtems_semaphore_release(semNvRAM); return(RTEMS_SUCCESSFUL); } /* * This routine reads a block of bytes from the NvRAM */ rtems_status_code ReadNvRAMBlock( unsigned32 ulOffset, unsigned8 *pucData, unsigned32 length) { unsigned32 i; if((ulOffset + length) > ulPRePOSAreaLength) { return RTEMS_INVALID_ADDRESS; } rtems_semaphore_obtain(semNvRAM, RTEMS_WAIT, RTEMS_NO_TIMEOUT); for ( i=0 ; i<length ; i++ ) pucData[i] = pNvRAMFunc->nvramRead(ulPRePOSAreaOffset+ulOffset+i); rtems_semaphore_release(semNvRAM); return(RTEMS_SUCCESSFUL); } /* * This routine writes a block of bytes to the NvRAM */ rtems_status_code WriteNvRAMBlock( unsigned32 ulOffset, unsigned8 *ucValue, unsigned32 length) { unsigned32 i; if((ulOffset + length) > ulPRePOSAreaLength) { return RTEMS_INVALID_ADDRESS; } rtems_semaphore_obtain(semNvRAM, RTEMS_WAIT, RTEMS_NO_TIMEOUT); for ( i=0 ; i<length ; i++ ) pNvRAMFunc->nvramWrite( ulPRePOSAreaOffset+ulOffset+i, ucValue[i]); bNvRAMChanged=TRUE; rtems_semaphore_release(semNvRAM); return(RTEMS_SUCCESSFUL); } /* * The NVRAM holds data in Big-Endian format */ rtems_status_code ReadNvRAM16 (unsigned32 ulOffset, unsigned16 *pusData) { unsigned32 ulTrueOffset=ulPRePOSAreaOffset+ulOffset; if(ulOffset>ulPRePOSAreaLength) { return RTEMS_INVALID_ADDRESS; } rtems_semaphore_obtain(semNvRAM, RTEMS_WAIT, RTEMS_NO_TIMEOUT); *pusData=(pNvRAMFunc->nvramRead(ulTrueOffset) << 8) + (pNvRAMFunc->nvramRead(ulTrueOffset + 1)); rtems_semaphore_release(semNvRAM); return(RTEMS_SUCCESSFUL); } rtems_status_code WriteNvRAM16 (unsigned32 ulOffset, unsigned16 usValue) { unsigned32 ulTrueOffset=ulPRePOSAreaOffset+ulOffset; if(ulOffset>ulPRePOSAreaLength) { return RTEMS_INVALID_ADDRESS; } rtems_semaphore_obtain(semNvRAM, RTEMS_WAIT, RTEMS_NO_TIMEOUT); pNvRAMFunc->nvramWrite(ulTrueOffset, (unsigned8) (usValue >> 8)); pNvRAMFunc->nvramWrite(ulTrueOffset + 1, (unsigned8) usValue); bNvRAMChanged=TRUE; rtems_semaphore_release(semNvRAM); return(RTEMS_SUCCESSFUL); } rtems_status_code ReadNvRAM32 (unsigned32 ulOffset, unsigned32 *pulData) { unsigned32 ulTrueOffset=ulPRePOSAreaOffset+ulOffset; if(ulOffset>ulPRePOSAreaLength) { return RTEMS_INVALID_ADDRESS; } rtems_semaphore_obtain(semNvRAM, RTEMS_WAIT, RTEMS_NO_TIMEOUT); *pulData=(pNvRAMFunc->nvramRead(ulTrueOffset) << 24) + (pNvRAMFunc->nvramRead(ulTrueOffset + 1) << 16) + (pNvRAMFunc->nvramRead(ulTrueOffset + 2) << 8) + (pNvRAMFunc->nvramRead(ulTrueOffset + 3)); rtems_semaphore_release(semNvRAM); return(RTEMS_SUCCESSFUL); } rtems_status_code WriteNvRAM32 (unsigned32 ulOffset, unsigned32 ulValue) { unsigned32 ulTrueOffset=ulPRePOSAreaOffset+ulOffset; if(ulOffset>ulPRePOSAreaLength) { return RTEMS_INVALID_ADDRESS; } rtems_semaphore_obtain(semNvRAM, RTEMS_WAIT, RTEMS_NO_TIMEOUT); pNvRAMFunc->nvramWrite(ulTrueOffset, (unsigned8) (ulValue >> 24)); pNvRAMFunc->nvramWrite(ulTrueOffset + 1, (unsigned8) (ulValue >> 16)); pNvRAMFunc->nvramWrite(ulTrueOffset + 2, (unsigned8) (ulValue >> 8)); pNvRAMFunc->nvramWrite(ulTrueOffset + 3, (unsigned8) ulValue); bNvRAMChanged=TRUE; rtems_semaphore_release(semNvRAM); return(RTEMS_SUCCESSFUL); } void InitializeNvRAM(void) { PHEADER pNvHeader = (PHEADER)0; rtems_status_code sc; unsigned32 ulLength, ulOffset; if(ucSystemType==SYS_TYPE_PPC1) { if(ucBoardRevMaj<5) { pNvRAMFunc=&nvramDsTable; } else { pNvRAMFunc=&nvramMkTable; } } else if(ucSystemType==SYS_TYPE_PPC1a) { pNvRAMFunc=&nvramMkTable; } else if(ucSystemType==SYS_TYPE_PPC4) { pNvRAMFunc=&nvramStk88Table; } else { pNvRAMFunc=&nvramStkTable; } /* * Set up mutex semaphore */ sc = rtems_semaphore_create ( rtems_build_name ('N', 'V', 'R', 's'), 1, RTEMS_BINARY_SEMAPHORE | RTEMS_INHERIT_PRIORITY | RTEMS_PRIORITY, RTEMS_NO_PRIORITY, &semNvRAM); if (sc != RTEMS_SUCCESSFUL) { rtems_fatal_error_occurred (sc); } /* * Initially access the whole of NvRAM until we determine where the * OS Area is located. */ ulPRePOSAreaLength=0xffffffff; ulPRePOSAreaOffset=0; /* * Access the header at the start of NvRAM */ ReadNvRAM32((unsigned32)(&pNvHeader->OSAreaLength), &ulLength); ReadNvRAM32((unsigned32)(&pNvHeader->OSAreaAddress), &ulOffset); /* * Now set limits for future accesses */ ulPRePOSAreaLength=ulLength; ulPRePOSAreaOffset=ulOffset; }
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