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5c7ce4475e
- Change INIT_FUNCTION and INIT_SECTION to CODE_SEG("INIT") and DATA_SEG("INIT") respectively - Remove INIT_FUNCTION from function prototypes - Remove alloc_text pragma calls as they are not needed anymore
318 lines
6.8 KiB
C
318 lines
6.8 KiB
C
/*
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* PROJECT: NEC PC-98 series HAL
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* LICENSE: GPL-2.0-or-later (https://spdx.org/licenses/GPL-2.0-or-later)
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* PURPOSE: RTC and NVRAM access routines
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* COPYRIGHT: Copyright 2020 Dmitry Borisov (di.sean@protonmail.com)
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*/
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/* INCLUDES ******************************************************************/
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#include <hal.h>
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#define NDEBUG
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#include <debug.h>
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/* GLOBALS *******************************************************************/
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/*
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* The PC-98 hardware maps data from the NVRAM directly into the text video
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* memory address space. Every fourth byte is a "writable data".
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*
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* |0x2FE2|0x2FE3|0x2FE4|0x2FE5|0x2FE6|0x2FE7| .... |0x2FFD|0x2FFE|
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* | D | | | | D | | .... | | D |
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*
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* Most of these bits of the NVRAM are already used. There are some reserved
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* bits in the 0x3FE6 and 0x3FFE that we can use.
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*/
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#define NVRAM_START 0x3FE2
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#define NVRAM_SIZE 0x1C
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#define NVRAM_UNUSED_REG 0x14
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#define NVRAM_UNUSED_BIT 0x80
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static ULONG_PTR MappedNvram;
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/* PRIVATE FUNCTIONS *********************************************************/
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/* Avoid double calls */
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#undef BCD_INT
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static UCHAR
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BCD_INT(
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_In_ UCHAR Bcd)
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{
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return ((Bcd & 0xF0) >> 4) * 10 + (Bcd & 0x0F);
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}
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static UCHAR
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NTAPI
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HalpReadNvram(
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_In_ UCHAR Register)
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{
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return READ_REGISTER_UCHAR((PUCHAR)(MappedNvram + Register));
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}
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_Requires_lock_held_(HalpSystemHardwareLock)
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static VOID
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NTAPI
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HalpWriteNvram(
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_In_ UCHAR Register,
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_In_ UCHAR Value)
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{
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__outbyte(GDC1_IO_o_MODE_FLIPFLOP1, GDC1_NVRAM_UNPROTECT);
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WRITE_REGISTER_UCHAR((PUCHAR)(MappedNvram + Register), Value);
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__outbyte(GDC1_IO_o_MODE_FLIPFLOP1, GDC1_NVRAM_PROTECT);
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}
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_Requires_lock_held_(HalpSystemHardwareLock)
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static UCHAR
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NTAPI
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HalpRtcReadByte(VOID)
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{
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UCHAR i;
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UCHAR Byte = 0;
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/* Read byte from single wire bus */
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for (i = 0; i < 8; i++)
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{
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Byte |= (__inbyte(PPI_IO_i_PORT_B) & 1) << i;
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__outbyte(RTC_IO_o_DATA, RTC_CLOCK | RTC_CMD_SERIAL_TRANSFER_MODE);
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KeStallExecutionProcessor(1);
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__outbyte(RTC_IO_o_DATA, RTC_CMD_SERIAL_TRANSFER_MODE);
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KeStallExecutionProcessor(1);
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}
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return Byte;
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}
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_Requires_lock_held_(HalpSystemHardwareLock)
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static VOID
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NTAPI
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HalpRtcWriteBit(
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_In_ UCHAR Bit)
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{
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Bit = (Bit & 1) << 5;
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__outbyte(RTC_IO_o_DATA, Bit | RTC_CMD_SERIAL_TRANSFER_MODE);
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KeStallExecutionProcessor(1);
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__outbyte(RTC_IO_o_DATA, Bit | RTC_CLOCK | RTC_CMD_SERIAL_TRANSFER_MODE);
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KeStallExecutionProcessor(1);
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}
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_Requires_lock_held_(HalpSystemHardwareLock)
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static VOID
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NTAPI
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HalpRtcWriteCommand(
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_In_ UCHAR Command)
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{
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UCHAR i;
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for (i = 0; i < 4; i++)
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HalpRtcWriteBit(Command >> i);
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__outbyte(RTC_IO_o_DATA, RTC_STROBE | RTC_CMD_SERIAL_TRANSFER_MODE);
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KeStallExecutionProcessor(1);
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__outbyte(RTC_IO_o_DATA, RTC_CMD_SERIAL_TRANSFER_MODE);
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KeStallExecutionProcessor(1);
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}
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UCHAR
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NTAPI
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HalpReadCmos(
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_In_ UCHAR Reg)
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{
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/* Not supported by hardware */
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return 0;
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}
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VOID
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NTAPI
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HalpWriteCmos(
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_In_ UCHAR Reg,
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_In_ UCHAR Value)
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{
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/* Not supported by hardware */
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NOTHING;
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}
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ULONG
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NTAPI
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HalpGetCmosData(
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_In_ ULONG BusNumber,
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_In_ ULONG SlotNumber,
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_Out_writes_bytes_(Length) PVOID Buffer,
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_In_ ULONG Length)
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{
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/* Not supported by hardware */
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return 0;
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}
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ULONG
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NTAPI
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HalpSetCmosData(
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_In_ ULONG BusNumber,
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_In_ ULONG SlotNumber,
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_In_reads_bytes_(Length) PVOID Buffer,
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_In_ ULONG Length)
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{
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/* Not supported by hardware */
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return 0;
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}
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CODE_SEG("INIT")
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VOID
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NTAPI
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HalpInitializeCmos(VOID)
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{
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PHYSICAL_ADDRESS PhysicalAddress;
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/* TODO: Detect TVRAM address */
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if (TRUE)
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PhysicalAddress.QuadPart = VRAM_NORMAL_TEXT + NVRAM_START;
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else
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PhysicalAddress.QuadPart = VRAM_HI_RESO_TEXT + NVRAM_START;
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MappedNvram = (ULONG_PTR)HalpMapPhysicalMemory64(PhysicalAddress, BYTES_TO_PAGES(NVRAM_SIZE));
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}
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/* PUBLIC FUNCTIONS **********************************************************/
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ARC_STATUS
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NTAPI
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HalGetEnvironmentVariable(
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_In_ PCH Name,
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_In_ USHORT ValueLength,
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_Out_writes_z_(ValueLength) PCH Value)
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{
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UCHAR Val;
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/* Only variable supported on x86 */
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if (_stricmp(Name, "LastKnownGood"))
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return ENOENT;
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if (!MappedNvram)
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return ENOENT;
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HalpAcquireCmosSpinLock();
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Val = HalpReadNvram(NVRAM_UNUSED_REG) & NVRAM_UNUSED_BIT;
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HalpReleaseCmosSpinLock();
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/* Check the flag */
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if (Val)
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strncpy(Value, "FALSE", ValueLength);
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else
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strncpy(Value, "TRUE", ValueLength);
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return ESUCCESS;
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}
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ARC_STATUS
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NTAPI
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HalSetEnvironmentVariable(
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_In_ PCH Name,
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_In_ PCH Value)
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{
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UCHAR Val;
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/* Only variable supported on x86 */
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if (_stricmp(Name, "LastKnownGood"))
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return ENOMEM;
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if (!MappedNvram)
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return ENOMEM;
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/* Check if this is true or false */
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if (!_stricmp(Value, "TRUE"))
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{
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HalpAcquireCmosSpinLock();
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Val = HalpReadNvram(NVRAM_UNUSED_REG) | NVRAM_UNUSED_BIT;
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}
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else if (!_stricmp(Value, "FALSE"))
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{
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HalpAcquireCmosSpinLock();
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Val = HalpReadNvram(NVRAM_UNUSED_REG) & ~NVRAM_UNUSED_BIT;
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}
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else
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{
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/* Fail */
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return ENOMEM;
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}
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HalpWriteNvram(NVRAM_UNUSED_REG, Val);
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HalpReleaseCmosSpinLock();
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return ESUCCESS;
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}
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BOOLEAN
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NTAPI
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HalQueryRealTimeClock(
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_Out_ PTIME_FIELDS Time)
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{
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UCHAR Temp;
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HalpAcquireCmosSpinLock();
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HalpRtcWriteCommand(RTC_CMD_TIME_READ);
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HalpRtcWriteCommand(RTC_CMD_REGISTER_SHIFT);
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KeStallExecutionProcessor(19);
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/* Set the time data */
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Time->Second = BCD_INT(HalpRtcReadByte());
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Time->Minute = BCD_INT(HalpRtcReadByte());
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Time->Hour = BCD_INT(HalpRtcReadByte());
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Time->Day = BCD_INT(HalpRtcReadByte());
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Temp = HalpRtcReadByte();
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Time->Weekday = Temp & 0x0F;
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Time->Month = Temp >> 4;
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Time->Year = BCD_INT(HalpRtcReadByte());
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Time->Milliseconds = 0;
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Time->Year += (Time->Year >= 80) ? 1900 : 2000;
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HalpRtcWriteCommand(RTC_CMD_REGISTER_HOLD);
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HalpReleaseCmosSpinLock();
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return TRUE;
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}
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BOOLEAN
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NTAPI
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HalSetRealTimeClock(
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_In_ PTIME_FIELDS Time)
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{
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UCHAR i, j;
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UCHAR SysTime[6];
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HalpAcquireCmosSpinLock();
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HalpRtcWriteCommand(RTC_CMD_REGISTER_SHIFT);
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SysTime[0] = INT_BCD(Time->Second);
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SysTime[1] = INT_BCD(Time->Minute);
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SysTime[2] = INT_BCD(Time->Hour);
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SysTime[3] = INT_BCD(Time->Day);
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SysTime[4] = (Time->Month << 4) | (Time->Weekday & 0x0F);
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SysTime[5] = INT_BCD(Time->Year % 100);
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/* Write time fields to RTC */
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for (i = 0; i < 6; i++)
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{
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for (j = 0; j < 8; j++)
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HalpRtcWriteBit(SysTime[i] >> j);
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}
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HalpRtcWriteCommand(RTC_CMD_TIME_SET_COUNTER_HOLD);
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HalpRtcWriteCommand(RTC_CMD_REGISTER_HOLD);
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HalpReleaseCmosSpinLock();
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return TRUE;
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}
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