/*++ Copyright (c) 1992-1996 Microsoft Corporation Module Name: modeset.c Abstract: This is the modeset code for the WD VGA miniport driver. Environment: kernel mode only Notes: Revision History: --*/ #include "dderror.h" #include "devioctl.h" #include "miniport.h" #include "ntddvdeo.h" #include "video.h" #include "wdvga.h" #include "cmdcnst.h" #include "pvgaequ.h" VP_STATUS VgaInterpretCmdStream( PHW_DEVICE_EXTENSION HwDeviceExtension, PUSHORT pusCmdStream ); VP_STATUS VgaSetMode( PHW_DEVICE_EXTENSION HwDeviceExtension, PVIDEO_MODE Mode, ULONG ModeSize ); VP_STATUS VgaQueryAvailableModes( PHW_DEVICE_EXTENSION HwDeviceExtension, PVIDEO_MODE_INFORMATION ModeInformation, ULONG ModeInformationSize, PULONG OutputSize ); VP_STATUS VgaQueryNumberOfAvailableModes( PHW_DEVICE_EXTENSION HwDeviceExtension, PVIDEO_NUM_MODES NumModes, ULONG NumModesSize, PULONG OutputSize ); VP_STATUS VgaQueryCurrentMode( PHW_DEVICE_EXTENSION HwDeviceExtension, PVIDEO_MODE_INFORMATION ModeInformation, ULONG ModeInformationSize, PULONG OutputSize ); VOID VgaZeroVideoMemory( PHW_DEVICE_EXTENSION HwDeviceExtension ); VOID VgaValidateModes( PHW_DEVICE_EXTENSION HwDeviceExtension ); VP_STATUS VgaSetActiveDisplay( PHW_DEVICE_EXTENSION HwDeviceExtension, ULONG ActiveDisplay ); // // Private functions // VOID DisableLCD( PHW_DEVICE_EXTENSION HwDeviceExtension ); VOID EnableLCD( PHW_DEVICE_EXTENSION HwDeviceExtension ); VOID DisableCRT( PHW_DEVICE_EXTENSION HwDeviceExtension ); VOID EnableCRT( PHW_DEVICE_EXTENSION HwDeviceExtension ); VOID UnlockAll( PHW_DEVICE_EXTENSION HwDeviceExtension ); #if defined(ALLOC_PRAGMA) #pragma alloc_text(PAGE,VgaInterpretCmdStream) #pragma alloc_text(PAGE,VgaSetMode) #pragma alloc_text(PAGE,VgaQueryAvailableModes) #pragma alloc_text(PAGE,VgaQueryNumberOfAvailableModes) #pragma alloc_text(PAGE,VgaQueryCurrentMode) #pragma alloc_text(PAGE,VgaZeroVideoMemory) #pragma alloc_text(PAGE,VgaValidateModes) // // This routine is NOT pagable because it is called a high IRQL // //#pragma alloc_text(PAGE,ExternalMonitorPresent) #endif VP_STATUS VgaInterpretCmdStream( PHW_DEVICE_EXTENSION HwDeviceExtension, PUSHORT pusCmdStream ) /*++ Routine Description: Interprets the appropriate command array to set up VGA registers for the requested mode. Typically used to set the VGA into a particular mode by programming all of the registers Arguments: HwDeviceExtension - Pointer to the miniport driver's device extension. pusCmdStream - array of commands to be interpreted. Return Value: The status of the operation (can only fail on a bad command); TRUE for success, FALSE for failure. --*/ { ULONG ulCmd; ULONG ulPort; UCHAR jValue; USHORT usValue; ULONG culCount; ULONG ulIndex; ULONG ulBase; if (pusCmdStream == NULL) { VideoDebugPrint((1, "VgaInterpretCmdStream - Invalid pusCmdStream\n")); return TRUE; } ulBase = (ULONG)HwDeviceExtension->IOAddress; // // Now set the adapter to the desired mode. // while ((ulCmd = *pusCmdStream++) != EOD) { // // Determine major command type // switch (ulCmd & 0xF0) { // // Basic input/output command // case INOUT: // // Determine type of inout instruction // if (!(ulCmd & IO)) { // // Out instruction. Single or multiple outs? // if (!(ulCmd & MULTI)) { // // Single out. Byte or word out? // if (!(ulCmd & BW)) { // // Single byte out // ulPort = *pusCmdStream++; jValue = (UCHAR) *pusCmdStream++; VideoPortWritePortUchar((PUCHAR)(ulBase+ulPort), jValue); } else { // // Single word out // ulPort = *pusCmdStream++; usValue = *pusCmdStream++; VideoPortWritePortUshort((PUSHORT)(ulBase+ulPort), usValue); } } else { // // Output a string of values // Byte or word outs? // if (!(ulCmd & BW)) { // // String byte outs. Do in a loop; can't use // VideoPortWritePortBufferUchar because the data // is in USHORT form // ulPort = ulBase + *pusCmdStream++; culCount = *pusCmdStream++; while (culCount--) { jValue = (UCHAR) *pusCmdStream++; VideoPortWritePortUchar((PUCHAR)ulPort, jValue); } } else { // // String word outs // ulPort = *pusCmdStream++; culCount = *pusCmdStream++; VideoPortWritePortBufferUshort((PUSHORT) (ulBase + ulPort), pusCmdStream, culCount); pusCmdStream += culCount; } } } else { // In instruction // // Currently, string in instructions aren't supported; all // in instructions are handled as single-byte ins // // Byte or word in? // if (!(ulCmd & BW)) { // // Single byte in // ulPort = *pusCmdStream++; jValue = VideoPortReadPortUchar((PUCHAR)ulBase+ulPort); } else { // // Single word in // ulPort = *pusCmdStream++; usValue = VideoPortReadPortUshort((PUSHORT) (ulBase+ulPort)); } } break; // // Higher-level input/output commands // case METAOUT: // // Determine type of metaout command, based on minor // command field // switch (ulCmd & 0x0F) { // // Indexed outs // case INDXOUT: ulPort = ulBase + *pusCmdStream++; culCount = *pusCmdStream++; ulIndex = *pusCmdStream++; while (culCount--) { usValue = (USHORT) (ulIndex + (((ULONG)(*pusCmdStream++)) << 8)); VideoPortWritePortUshort((PUSHORT)ulPort, usValue); ulIndex++; } break; // // Masked out (read, AND, XOR, write) // case MASKOUT: ulPort = *pusCmdStream++; jValue = VideoPortReadPortUchar((PUCHAR)ulBase+ulPort); jValue &= *pusCmdStream++; jValue ^= *pusCmdStream++; VideoPortWritePortUchar((PUCHAR)ulBase + ulPort, jValue); break; // // Attribute Controller out // case ATCOUT: ulPort = ulBase + *pusCmdStream++; culCount = *pusCmdStream++; ulIndex = *pusCmdStream++; while (culCount--) { // Write Attribute Controller index VideoPortWritePortUchar((PUCHAR)ulPort, (UCHAR)ulIndex); // Write Attribute Controller data jValue = (UCHAR) *pusCmdStream++; VideoPortWritePortUchar((PUCHAR)ulPort, jValue); ulIndex++; } break; // // None of the above; error // default: return FALSE; } break; // // NOP // case NCMD: break; // // Unknown command; error // default: return FALSE; } } return TRUE; } // end VgaInterpretCmdStream() VP_STATUS VgaSetMode( PHW_DEVICE_EXTENSION HwDeviceExtension, PVIDEO_MODE Mode, ULONG ModeSize ) /*++ Routine Description: This routine sets the VGA into the requested mode. Arguments: HwDeviceExtension - Pointer to the miniport driver's device extension. Mode - Pointer to the structure containing the information about the font to be set. ModeSize - Length of the input buffer supplied by the user. Return Value: ERROR_INSUFFICIENT_BUFFER if the input buffer was not large enough for the input data. ERROR_INVALID_PARAMETER if the mode number is invalid. NO_ERROR if the operation completed successfully. --*/ { PVIDEOMODE pRequestedMode; VP_STATUS status; UCHAR temp; UCHAR dummy; UCHAR bIsColor; VIDEO_X86_BIOS_ARGUMENTS biosArguments; UCHAR frequencySetting; PUCHAR CrtAddressPort, CrtDataPort; UCHAR bModeFirst = 1; BOOLEAN bMonitorPresent; // // Check if the size of the data in the input buffer is large enough. // if (ModeSize < sizeof(VIDEO_MODE)) { VideoDebugPrint((1, "VgaSetMode: ERROR_INSUFFICIENT_BUFFER\n")); return ERROR_INSUFFICIENT_BUFFER; } // // Extract the clear memory bit. // if (Mode->RequestedMode & VIDEO_MODE_NO_ZERO_MEMORY) { Mode->RequestedMode &= ~VIDEO_MODE_NO_ZERO_MEMORY; } else { VgaZeroVideoMemory(HwDeviceExtension); } // // Check to see if we are requesting a valid mode // if ( (Mode->RequestedMode >= NumVideoModes) || (!ModesVGA[Mode->RequestedMode].ValidMode) ) { VideoDebugPrint((1, "VgaSetMode: ERROR_INVALID_PARAMETER\n")); return ERROR_INVALID_PARAMETER; } pRequestedMode = &ModesVGA[Mode->RequestedMode]; #ifdef INT10_MODE_SET // // Make sure we unlock extended registers since the BIOS on some machines // does not do it properly. // VideoPortWritePortUshort((PUSHORT)(HwDeviceExtension->IOAddress + GRAPH_ADDRESS_PORT), 0x050F); // // Initialize CrtAddressPort, and CrtDataPort // if (VideoPortReadPortUchar(HwDeviceExtension->IOAddress + MISC_OUTPUT_REG_READ_PORT) & 0x01) { bIsColor = TRUE; CrtAddressPort = HwDeviceExtension->IOAddress + CRTC_ADDRESS_PORT_COLOR; CrtDataPort = HwDeviceExtension->IOAddress + CRTC_DATA_PORT_COLOR; } else { bIsColor = FALSE; CrtAddressPort = HwDeviceExtension->IOAddress + CRTC_ADDRESS_PORT_MONO; CrtDataPort = HwDeviceExtension->IOAddress + CRTC_DATA_PORT_MONO; } // // Make sure we unlock extended registers since the BIOS on some machines // does not do it properly. // VideoPortWritePortUchar(HwDeviceExtension->IOAddress + GRAPH_ADDRESS_PORT, 0x0F); VideoPortWritePortUchar(HwDeviceExtension->IOAddress + GRAPH_DATA_PORT, 0x05); VideoPortWritePortUchar(CrtAddressPort, 0x2b); temp = VideoPortReadPortUchar(CrtDataPort); // // Adjust the frequency setting register and write it back out. // Also support Diamond changes to frequency settings // temp &= pRequestedMode->FrequencyMask; frequencySetting = pRequestedMode->FrequencySetting; if ( (HwDeviceExtension->BoardID == SPEEDSTAR31) && (pRequestedMode->hres == 1024) ) { // // Diamond has inversed the refresh rates of interlaced and 72 Hz // on the 1024 modes // if (pRequestedMode->Frequency == 72) { frequencySetting = 0x00; } else { if (pRequestedMode->Frequency == 44) { frequencySetting = 0x30; } } } temp |= frequencySetting; VideoPortWritePortUchar(CrtDataPort, temp); // // Mode set block that can be repeated. // SetAgain: // // Set the mode // VideoPortZeroMemory(&biosArguments, sizeof(VIDEO_X86_BIOS_ARGUMENTS)); if (HwDeviceExtension->IsIBM && (pRequestedMode->Int10ModeNumber & 0xffff0000)) { biosArguments.Eax = 0x4f02; biosArguments.Ebx = pRequestedMode->Int10ModeNumber >> 16; } else { biosArguments.Eax = pRequestedMode->Int10ModeNumber & 0xff; } status = VideoPortInt10(HwDeviceExtension, &biosArguments); if (status != NO_ERROR) { return status; } // // Check to see if the modeset worked. If not, then if we // don't have an SVGA Bios, and do have a modetable, then // set the mode. Else, fail. // if (HwDeviceExtension->BoardID == WD90C24A) { biosArguments.Eax = 0x0f00; VideoPortInt10(HwDeviceExtension, &biosArguments); if ((biosArguments.Eax & 0xff) != (pRequestedMode->Int10ModeNumber & 0xff)) { if ((HwDeviceExtension->SVGABios < FULL_SVGA_BIOS) && (pRequestedMode->ModeTable != NULL)) { BOOLEAN bLCD=FALSE; VideoDebugPrint((1, "\n*** Setting mode with mode table!\n\n")); // // NOTE: Certain models of IBM Thinkpads can switch // between LCD, Monitor, and Simultaneous modes while // the machine is running. Other models cannot. // Currently we have noticed a coralation between // machines which have SVGA Bios's and machines which // can set the mode. // // IF MACHINE HAS SVGA BIOS THEN // MACHINE CAN TURN ON/OFF LCD ON THE FLY // ELSE // MACHINE CANNOT TURN ON/OFF LCD ON THE FLY // // If a user has a machine where the LCD can be turned // on dynamically, then it is possible that the user // will turn on the LCD when we think it is off. Then // we may try to set a mode which does not work with // the LCD off. To avoid this problem, we will try // to determine if the LCD is on/off before setting // the mode. If the LCD is on, and it needs to be // off in order for the modeset to succeed, we'll fail // the modeset. // // Unfortunately, this does not solve all of our // problems. The code which we use to try to detect // whether or not the LCD is on fails on some // machines. The code seems to fail on machines // which do not have SVGA Bios's. As mentioned above // machines which do not have SVGA Bios's can not // switch on their LCD's dynamically. Therefore we // do not need to execute this special code on these // machines because the LCD state wont change on us // anyway. // if (HwDeviceExtension->SVGABios > NO_SVGA_BIOS) { // // If the LCD is enabled we also need to SET bit 0 // of PR2. // // We will check to see if the LCD is enabled by // checking bit 2 of CRTC register 0x31, and bit // 4 of CRTC register 0x32. If either of these // is set, then we'll assume an LCD is enabled. // VideoPortWritePortUchar(HwDeviceExtension->IOAddress + CRTC_ADDRESS_PORT_COLOR, 0x31); if (VideoPortReadPortUchar(HwDeviceExtension->IOAddress + CRTC_DATA_PORT_COLOR) & 0x04) { bLCD = TRUE; } VideoPortWritePortUchar(HwDeviceExtension->IOAddress + CRTC_ADDRESS_PORT_COLOR, 0x32); if (VideoPortReadPortUchar(HwDeviceExtension->IOAddress + CRTC_DATA_PORT_COLOR) & 0x10) { bLCD = TRUE; } // // For some reason, on the 755CDV, if we set a high res mode, // while the LCD is on, then the LCD won't be disabled // properly. Therefore, fail the mode set if the LCD // is on, and we need to turn it off to set this mode. // if (bLCD && !(HwDeviceExtension->DisplayType & pRequestedMode->LCDtype & ~MONITOR)) { return ERROR_INVALID_PARAMETER; } } VgaSetActiveDisplay(HwDeviceExtension, LCD_DISABLE | CRT_ENABLE); VgaInterpretCmdStream(HwDeviceExtension, pRequestedMode->ModeTable); // // if the LCD can do this mode, then turn the LCD // back on. Else, leave it off. // // add the code!! // if (pRequestedMode->LCDtype & HwDeviceExtension->DisplayType & ~MONITOR) { VgaSetActiveDisplay(HwDeviceExtension, LCD_ENABLE | CRT_ENABLE); VideoDebugPrint((1, "LCD Enabled!\n")); } else { VgaSetActiveDisplay(HwDeviceExtension, LCD_DISABLE | CRT_ENABLE); VideoDebugPrint((1, "LCD Disabled!\n")); } } else { return ERROR_INVALID_PARAMETER; } } } if (pRequestedMode->CmdStrings != NULL) { VgaInterpretCmdStream(HwDeviceExtension, pRequestedMode->CmdStrings); } if (!(pRequestedMode->fbType & VIDEO_MODE_GRAPHICS)) { // // Fix to make sure we always set the colors in text mode to be // intensity, and not flashing // For this zero out the Mode Control Regsiter bit 3 (index 0x10 // of the Attribute controller). // if (bIsColor) { dummy = VideoPortReadPortUchar(HwDeviceExtension->IOAddress + INPUT_STATUS_1_COLOR); } else { dummy = VideoPortReadPortUchar(HwDeviceExtension->IOAddress + INPUT_STATUS_1_MONO); } VideoPortWritePortUchar(HwDeviceExtension->IOAddress + ATT_ADDRESS_PORT, (0x10 | VIDEO_ENABLE)); temp = VideoPortReadPortUchar(HwDeviceExtension->IOAddress + ATT_DATA_READ_PORT); temp &= 0xF7; if (bIsColor) { dummy = VideoPortReadPortUchar(HwDeviceExtension->IOAddress + INPUT_STATUS_1_COLOR); } else { dummy = VideoPortReadPortUchar(HwDeviceExtension->IOAddress + INPUT_STATUS_1_MONO); } VideoPortWritePortUchar(HwDeviceExtension->IOAddress + ATT_ADDRESS_PORT, (0x10 | VIDEO_ENABLE)); VideoPortWritePortUchar(HwDeviceExtension->IOAddress + ATT_DATA_WRITE_PORT, temp); } // // A few wd cards do not work properly on the first mode set. You have // to set the mode twice. So lets set it twice! // if (bModeFirst == 1 && HwDeviceExtension->BoardID != WD90C24A) { bModeFirst = 0; goto SetAgain; } #else VgaInterpretCmdStream(HwDeviceExtension, pRequestedMode->CmdStrings); #endif // // Make sure we unlock extended registers since the BIOS on some machines // does not do it properly. // VideoPortWritePortUshort((PUSHORT)(HwDeviceExtension->IOAddress + GRAPH_ADDRESS_PORT), 0x050F); if (HwDeviceExtension->BoardID == WD90C24A) { VideoPortWritePortUchar(HwDeviceExtension->IOAddress + DAC_PIXEL_MASK_PORT, 0xFF); } // // Update the location of the physical frame buffer within video memory. // HwDeviceExtension->PhysicalFrameLength = MemoryMaps[pRequestedMode->MemMap].MaxSize; HwDeviceExtension->PhysicalFrameBase.LowPart = MemoryMaps[pRequestedMode->MemMap].Start; // // Store the new mode value. // HwDeviceExtension->CurrentMode = pRequestedMode; HwDeviceExtension->ModeIndex = Mode->RequestedMode; return NO_ERROR; } //end VgaSetMode() VP_STATUS VgaQueryAvailableModes( PHW_DEVICE_EXTENSION HwDeviceExtension, PVIDEO_MODE_INFORMATION ModeInformation, ULONG ModeInformationSize, PULONG OutputSize ) /*++ Routine Description: This routine returns the list of all available available modes on the card. Arguments: HwDeviceExtension - Pointer to the miniport driver's device extension. ModeInformation - Pointer to the output buffer supplied by the user. This is where the list of all valid modes is stored. ModeInformationSize - Length of the output buffer supplied by the user. OutputSize - Pointer to a buffer in which to return the actual size of the data in the buffer. If the buffer was not large enough, this contains the minimum required buffer size. Return Value: ERROR_INSUFFICIENT_BUFFER if the output buffer was not large enough for the data being returned. NO_ERROR if the operation completed successfully. --*/ { PVIDEO_MODE_INFORMATION videoModes = ModeInformation; ULONG i; // // Find out the size of the data to be put in the buffer and return // that in the status information (whether or not the information is // there). If the buffer passed in is not large enough return an // appropriate error code. // if (ModeInformationSize < (*OutputSize = HwDeviceExtension->NumAvailableModes * sizeof(VIDEO_MODE_INFORMATION)) ) { return ERROR_INSUFFICIENT_BUFFER; } // // For each mode supported by the card, store the mode characteristics // in the output buffer. // for (i = 0; i < NumVideoModes; i++) { if (ModesVGA[i].ValidMode) { videoModes->Length = sizeof(VIDEO_MODE_INFORMATION); videoModes->ModeIndex = i; videoModes->VisScreenWidth = ModesVGA[i].hres; videoModes->ScreenStride = ModesVGA[i].wbytes; videoModes->VisScreenHeight = ModesVGA[i].vres; videoModes->NumberOfPlanes = ModesVGA[i].numPlanes; videoModes->BitsPerPlane = ModesVGA[i].bitsPerPlane; videoModes->Frequency = ModesVGA[i].Frequency; videoModes->XMillimeter = 320; // temporary hardcoded constant videoModes->YMillimeter = 240; // temporary hardcoded constant videoModes->AttributeFlags = ModesVGA[i].fbType; videoModes->AttributeFlags |= ModesVGA[i].Interlaced ? VIDEO_MODE_INTERLACED : 0; videoModes->DriverSpecificAttributeFlags = 0; // // Calculate the VideoMemoryBitmapWidth // { LONG x; x = videoModes->BitsPerPlane; if( x == 15 ) x = 16; videoModes->VideoMemoryBitmapWidth = (videoModes->ScreenStride * 8 ) / x; } videoModes->VideoMemoryBitmapHeight = HwDeviceExtension->AdapterMemorySize / videoModes->ScreenStride; if (ModesVGA[i].bitsPerPlane == 16) { videoModes->NumberRedBits = 5; videoModes->NumberGreenBits = 6; videoModes->NumberBlueBits = 5; videoModes->RedMask = 0xF800; videoModes->GreenMask = 0x07E0; videoModes->BlueMask = 0x001F; } else { videoModes->NumberRedBits = 6; videoModes->NumberGreenBits = 6; videoModes->NumberBlueBits = 6; videoModes->RedMask = 0; videoModes->GreenMask = 0; videoModes->BlueMask = 0; videoModes->AttributeFlags |= VIDEO_MODE_PALETTE_DRIVEN | VIDEO_MODE_MANAGED_PALETTE; } videoModes++; } } return NO_ERROR; } // end VgaGetAvailableModes() VP_STATUS VgaQueryNumberOfAvailableModes( PHW_DEVICE_EXTENSION HwDeviceExtension, PVIDEO_NUM_MODES NumModes, ULONG NumModesSize, PULONG OutputSize ) /*++ Routine Description: This routine returns the number of available modes for this particular video card. Arguments: HwDeviceExtension - Pointer to the miniport driver's device extension. NumModes - Pointer to the output buffer supplied by the user. This is where the number of modes is stored. NumModesSize - Length of the output buffer supplied by the user. OutputSize - Pointer to a buffer in which to return the actual size of the data in the buffer. Return Value: ERROR_INSUFFICIENT_BUFFER if the output buffer was not large enough for the data being returned. NO_ERROR if the operation completed successfully. --*/ { // // Find out the size of the data to be put in the the buffer and return // that in the status information (whether or not the information is // there). If the buffer passed in is not large enough return an // appropriate error code. // if (NumModesSize < (*OutputSize = sizeof(VIDEO_NUM_MODES)) ) { return ERROR_INSUFFICIENT_BUFFER; } // // Validate the modes each time on the portables since an external monitor // can be connected or disconnected dynamically. // VgaValidateModes(HwDeviceExtension); // // Store the number of modes into the buffer. // NumModes->NumModes = HwDeviceExtension->NumAvailableModes; NumModes->ModeInformationLength = sizeof(VIDEO_MODE_INFORMATION); return NO_ERROR; } // end VgaGetNumberOfAvailableModes() VP_STATUS VgaQueryCurrentMode( PHW_DEVICE_EXTENSION HwDeviceExtension, PVIDEO_MODE_INFORMATION ModeInformation, ULONG ModeInformationSize, PULONG OutputSize ) /*++ Routine Description: This routine returns a description of the current video mode. Arguments: HwDeviceExtension - Pointer to the miniport driver's device extension. ModeInformation - Pointer to the output buffer supplied by the user. This is where the current mode information is stored. ModeInformationSize - Length of the output buffer supplied by the user. OutputSize - Pointer to a buffer in which to return the actual size of the data in the buffer. If the buffer was not large enough, this contains the minimum required buffer size. Return Value: ERROR_INSUFFICIENT_BUFFER if the output buffer was not large enough for the data being returned. NO_ERROR if the operation completed successfully. --*/ { // // // check if a mode has been set // if (HwDeviceExtension->CurrentMode == NULL) { return ERROR_INVALID_FUNCTION; } // // Find out the size of the data to be put in the the buffer and return // that in the status information (whether or not the information is // there). If the buffer passed in is not large enough return an // appropriate error code. // if (ModeInformationSize < (*OutputSize = sizeof(VIDEO_MODE_INFORMATION))) { return ERROR_INSUFFICIENT_BUFFER; } // // Store the characteristics of the current mode into the buffer. // ModeInformation->Length = sizeof(VIDEO_MODE_INFORMATION); ModeInformation->ModeIndex = HwDeviceExtension->ModeIndex; ModeInformation->VisScreenWidth = HwDeviceExtension->CurrentMode->hres; ModeInformation->ScreenStride = HwDeviceExtension->CurrentMode->wbytes; ModeInformation->VisScreenHeight = HwDeviceExtension->CurrentMode->vres; ModeInformation->NumberOfPlanes = HwDeviceExtension->CurrentMode->numPlanes; ModeInformation->BitsPerPlane = HwDeviceExtension->CurrentMode->bitsPerPlane; ModeInformation->Frequency = HwDeviceExtension->CurrentMode->Frequency; ModeInformation->XMillimeter = 320; // temporary hardcoded constant ModeInformation->YMillimeter = 240; // temporary hardcoded constant ModeInformation->AttributeFlags = HwDeviceExtension->CurrentMode->fbType | (HwDeviceExtension->CurrentMode->Interlaced ? VIDEO_MODE_INTERLACED : 0); ModeInformation->DriverSpecificAttributeFlags = 0; if (ModeInformation->BitsPerPlane == 16) { ModeInformation->NumberRedBits = 5; ModeInformation->NumberGreenBits = 6; ModeInformation->NumberBlueBits = 5; ModeInformation->RedMask = 0xF800; ModeInformation->GreenMask = 0x07E0; ModeInformation->BlueMask = 0x1F; } else { ModeInformation->NumberRedBits = 6; ModeInformation->NumberGreenBits = 6; ModeInformation->NumberBlueBits = 6; ModeInformation->RedMask = 0; ModeInformation->GreenMask = 0; ModeInformation->BlueMask = 0; ModeInformation->AttributeFlags |= VIDEO_MODE_PALETTE_DRIVEN | VIDEO_MODE_MANAGED_PALETTE; } // // Calculate the VideoMemoryBitmapWidth // { LONG x; x = ModeInformation->BitsPerPlane; if( x == 15 ) x = 16; ModeInformation->VideoMemoryBitmapWidth = (ModeInformation->ScreenStride * 8 ) / x; } ModeInformation->VideoMemoryBitmapHeight = HwDeviceExtension->AdapterMemorySize / ModeInformation->ScreenStride; return NO_ERROR; } // end VgaQueryCurrentMode() VOID VgaZeroVideoMemory( PHW_DEVICE_EXTENSION HwDeviceExtension ) /*++ Routine Description: This routine zeros the first 256K on the VGA. Arguments: HwDeviceExtension - Pointer to the miniport driver's device extension. Return Value: None. --*/ { UCHAR temp; // // Map font buffer at A0000 // VgaInterpretCmdStream(HwDeviceExtension, EnableA000Data); // // Enable all planes. // VideoPortWritePortUchar(HwDeviceExtension->IOAddress + SEQ_ADDRESS_PORT, IND_MAP_MASK); temp = VideoPortReadPortUchar(HwDeviceExtension->IOAddress + SEQ_DATA_PORT) | (UCHAR)0x0F; VideoPortWritePortUchar(HwDeviceExtension->IOAddress + SEQ_DATA_PORT, temp); // // Zero the memory. // VideoPortZeroDeviceMemory(HwDeviceExtension->VideoMemoryAddress, 0xFFFF); VgaInterpretCmdStream(HwDeviceExtension, DisableA000Color); } VOID VgaValidateModes( PHW_DEVICE_EXTENSION HwDeviceExtension ) /*++ Routine Description: Determines which modes are valid and which are not. Arguments: HwDeviceExtension - Pointer to the miniport driver's device extension. Return Value: None. --*/ { ULONG i; HwDeviceExtension->NumAvailableModes = 0; VideoDebugPrint((1, "VgaValidateModes:\n")); VideoDebugPrint((1, "Avail Adapter Mem: 0x%x\n" "Avail Monitor Type: 0x%x\n", HwDeviceExtension->AdapterMemorySize, HwDeviceExtension->DisplayType)); for (i = 0; i < NumVideoModes; i++) { VideoDebugPrint((1, "Mode %d %dx%d at %d bpp\n" "\tAdapterMemoryRequired: 0x%x\n" "\tMonitorType 0x%x\n", i, ModesVGA[i].hres, ModesVGA[i].vres, ModesVGA[i].bitsPerPlane * ModesVGA[i].numPlanes, ModesVGA[i].numPlanes * ModesVGA[i].sbytes, ModesVGA[i].LCDtype)); if ((HwDeviceExtension->AdapterMemorySize >= ModesVGA[i].numPlanes * ModesVGA[i].sbytes) && (HwDeviceExtension->DisplayType & ModesVGA[i].LCDtype)) { ModesVGA[i].ValidMode = TRUE; HwDeviceExtension->NumAvailableModes++; } // // invalidates some modes we may have enabled based on some specific // chip\machine problems // if ( (ModesVGA[i].ValidMode) && (HwDeviceExtension->BoardID == WD90C24A)) { // // get rid of 16 color modes // except on MONO_STN_LCD displays. // if ((ModesVGA[i].numPlanes == 4) && (ModesVGA[i].hres >= 640) && (ModesVGA[i].fbType & VIDEO_MODE_GRAPHICS) && !(HwDeviceExtension->DisplayType & STN_MONO_LCD)) { ModesVGA[i].ValidMode = FALSE; HwDeviceExtension->NumAvailableModes--; } else if (HwDeviceExtension->IsIBM == TRUE) { // // get rid of 256 color modes > 640x480 on // machines with STN displays // if ((ModesVGA[i].bitsPerPlane == 8) && (ModesVGA[i].hres > 640) && (HwDeviceExtension->DisplayType & TOSHIBA_DSTNC)) { ModesVGA[i].ValidMode = FALSE; HwDeviceExtension->NumAvailableModes--; } // // get rid of 64K color support for machines without // SVGABios support // else if ((ModesVGA[i].bitsPerPlane == 16) && (HwDeviceExtension->SVGABios == NO_SVGA_BIOS)) { ModesVGA[i].ValidMode = FALSE; HwDeviceExtension->NumAvailableModes--; } } } // // 16bpp modes only work on the WD90C24A chip sets. // if( (ModesVGA[i].ValidMode) && (HwDeviceExtension->BoardID != WD90C24A) && (ModesVGA[i].bitsPerPlane == 16)) { ModesVGA[i].ValidMode = FALSE; HwDeviceExtension->NumAvailableModes--; } // // Older boards do not support 72HZ in 1024x768 modes. // So disable those. // if ( (ModesVGA[i].ValidMode) && (HwDeviceExtension->BoardID < WD90C31) && (ModesVGA[i].hres == 1024) && (ModesVGA[i].vres == 768) && (ModesVGA[i].Frequency == 72) ) { ModesVGA[i].ValidMode = FALSE; HwDeviceExtension->NumAvailableModes--; } if (ModesVGA[i].ValidMode == FALSE) { VideoDebugPrint((1, "The mode is not valid.\n")); } else { VideoDebugPrint((1, "The mode is valid.\n")); } } } BOOLEAN ExternalMonitorPresent( PHW_DEVICE_EXTENSION HwDeviceExtension ) /*++ Routine Description: Determine whether an external monitor is connected to the machine. This routine should only be called if the BoardID == WD90C24A. Note: This routine expects to be called after the WD extended registers have been unlocked. Arguments: HwDeviceExtension - Pointer to the miniport driver's device extension. Return Value: Updated the DisplayType field in HwDeviceExtension to indicate whether a monitor is connected. The routine always returns TRUE. --*/ { UCHAR dac[3]; UCHAR _pr19, _pr1b; int i,j; int bExternal = 0; // // If we are on an IBM machine, use SMAPI routines // instead of detetecting the monitor ourselves. // if (HwDeviceExtension->IsIBM) { bExternal = LCDIsMonitorPresent(); if (bExternal) { HwDeviceExtension->DisplayType |= MONITOR; } else { HwDeviceExtension->DisplayType &= ~MONITOR; } return TRUE; } // // Only refresh display with value in DAC 0 // VideoPortWritePortUchar(HwDeviceExtension->IOAddress + DAC_PIXEL_MASK_PORT, 0x00); // // lets preserve what's in the DAC // VideoPortWritePortUchar(HwDeviceExtension->IOAddress + DAC_ADDRESS_READ_PORT, (UCHAR) 0); for (j=0; j<3; j++) { dac[j]= VideoPortReadPortUchar(HwDeviceExtension->IOAddress + DAC_DATA_REG_PORT); } // // Fill in DAC 0 with a value for the test // VideoPortWritePortUchar(HwDeviceExtension->IOAddress + DAC_ADDRESS_WRITE_PORT, 0); VideoPortWritePortUchar(HwDeviceExtension->IOAddress + DAC_DATA_REG_PORT, 0x04); // Red VideoPortWritePortUchar(HwDeviceExtension->IOAddress + DAC_DATA_REG_PORT, 0x12); // Green VideoPortWritePortUchar(HwDeviceExtension->IOAddress + DAC_DATA_REG_PORT, 0x04); // Blue // // We need to check bit 4 of 0x3c2. We only want to check // this bit during actual display output. Therefore we will // wait for a vertical refresh, and then try to wait 300 // nanoseconds for the monitor detection circuits to // stabalize, and then read the bit. (I may have to adjust // crtc registers to prevent refresh cycles). // // There are two bits in the Input Status #1 Register which // will help us to detect if we are in a refresh cycle. If // bit 3 is on then we are in a verticle refresh. If bit 0 // is off (0) then we are in a display mode, else we are in // some sort of a refresh. // // Therefore, for our purposes, we will do the following. We // will wait for a verticle refresh (bit 3 = 1) then we will // wait for it to turn off. We are now starting to draw the // screen. Now we will examine the monitor connection bit // (bit 4 of 0x3c2) until the display mode bit (bit 0 of // 0x3da) goes high. Now we will use our last recorded value // for monitor detection. // // // wait for V retrace // while ((VideoPortReadPortUchar(HwDeviceExtension->IOAddress + INPUT_STATUS_1_COLOR) & 0x8) == 0); // // wait for V retrace to end // while ((VideoPortReadPortUchar(HwDeviceExtension->IOAddress + INPUT_STATUS_1_COLOR) & 0x8) != 0); // // wait for display enable to start // while ((VideoPortReadPortUchar(HwDeviceExtension->IOAddress + INPUT_STATUS_1_COLOR) & 0x1) != 0); // // wait for display enable to end. Use last value of // bExternal to determine if an external monitor is // connected. // { int LoopCount=0, OnCount=0; bExternal = FALSE; while ((VideoPortReadPortUchar(HwDeviceExtension->IOAddress + INPUT_STATUS_1_COLOR) & 0x1) == 0) { if ((VideoPortReadPortUchar(HwDeviceExtension->IOAddress + INPUT_STATUS_0_PORT) & 0x10) == 0x10) { OnCount++; } LoopCount++; } if (OnCount > (LoopCount / 2)) // should compile as LoopCount >> 1 { bExternal = TRUE; } } // // restore the DAC // VideoPortWritePortUchar(HwDeviceExtension->IOAddress + DAC_ADDRESS_WRITE_PORT, (UCHAR) 0); for (j=0; j<3; j++) { VideoPortWritePortUchar(HwDeviceExtension->IOAddress + DAC_DATA_REG_PORT, dac[j]); } // // Re-enable the DAC // VideoPortWritePortUchar(HwDeviceExtension->IOAddress + DAC_PIXEL_MASK_PORT, 0xFF); // // restore _pr19, and _pr1b state // if (bExternal) { HwDeviceExtension->DisplayType |= MONITOR; } else { HwDeviceExtension->DisplayType &= ~MONITOR; } return TRUE; } VP_STATUS VgaSetActiveDisplay( PHW_DEVICE_EXTENSION HwDeviceExtension, ULONG ActiveDisplay ) /*++ Routine Description: This routine selects the active display device(s). Arguments: HwDeviceExtension - Pointer to the miniport driver's device extension. ActiveDisplay - Devices to be active. (See WD90C24A.H for the definition) Return Value: If successful, return NO_ERROR, else return FALSE. --*/ { VP_STATUS status = ERROR_INVALID_PARAMETER; // // Unlock paradise registers // UnlockAll(HwDeviceExtension); // // Enable or Disable LCD output // // Note: To prevent the fuse of LCD from blowing up, LCD should be turns off // while output is disabled. // // If VideoPortPowerControl() returns an error for the absence of HALPM.SYS, // we will try to control LCD by accessing the hardware directly. // if (ActiveDisplay & LCD_ENABLE) { EnableLCD(HwDeviceExtension); } else if (ActiveDisplay & LCD_DISABLE) { DisableLCD(HwDeviceExtension); } // // Enable or Disable CRT output // if (ActiveDisplay & CRT_ENABLE) { EnableCRT(HwDeviceExtension); } else { DisableCRT(HwDeviceExtension); } return NO_ERROR; } // end VgaSetActiveDisplay() VOID DisableLCD( PHW_DEVICE_EXTENSION HwDeviceExtension ) /*++ Routine Description: This routine disables LCD interface of WD90C24A/A2. Arguments: HwDeviceExtension - Pointer to the miniport driver's adapter information. Return Value: None. --*/ { PUCHAR IoBase = HwDeviceExtension->IOAddress; // // Wait until next vertical retrace interval // while (0 == (VideoPortReadPortUchar(IoBase + INPUT_STATUS_1_COLOR) & 0x08)); // // Disables LCD interface // VideoPortWritePortUchar(IoBase + CRTC_ADDRESS_PORT_COLOR, pr19); VideoPortWritePortUchar( IoBase + CRTC_DATA_PORT_COLOR, (UCHAR)(VideoPortReadPortUchar(IoBase + CRTC_DATA_PORT_COLOR) & ~0x10)); // // Tristates LCD control and data signals // VideoPortWritePortUchar(IoBase + GRAPH_ADDRESS_PORT, pr4); VideoPortWritePortUchar( IoBase + GRAPH_DATA_PORT, (CHAR)(VideoPortReadPortUchar(IoBase + GRAPH_DATA_PORT) | 0x20)); // // Unlocks CRTC shadow registers // VideoPortWritePortUshort( (PUSHORT)(IoBase + CRTC_ADDRESS_PORT_COLOR), (USHORT)pr1b | ((USHORT)pr1b_unlock << 8)); } // end DisableLCD() VOID EnableLCD( PHW_DEVICE_EXTENSION HwDeviceExtension ) /*++ Routine Description: This routine enables LCD interface of WD90C24A/A2. Arguments: HwDeviceExtension - Pointer to the miniport driver's adapter information. Return Value: None. --*/ { PUCHAR IoBase = HwDeviceExtension->IOAddress; // // Locks CRTC shadow registers // VideoPortWritePortUshort( (PUSHORT)(IoBase + CRTC_ADDRESS_PORT_COLOR), (USHORT)pr1b | ((USHORT)pr1b_unlock_pr << 8)); // // Wait until next vertical retrace interval // while (0 == (VideoPortReadPortUchar(IoBase + INPUT_STATUS_1_COLOR) & 0x08)); // // Drives LCD control and data signals // VideoPortWritePortUchar(IoBase + GRAPH_ADDRESS_PORT, pr4); VideoPortWritePortUchar( IoBase + GRAPH_DATA_PORT, (CHAR)(VideoPortReadPortUchar(IoBase + GRAPH_DATA_PORT) & ~0x20)); // // Enables LCD interface // VideoPortWritePortUchar(IoBase + CRTC_ADDRESS_PORT_COLOR, pr19); VideoPortWritePortUchar( IoBase + CRTC_DATA_PORT_COLOR, (CHAR)(VideoPortReadPortUchar(IoBase + CRTC_DATA_PORT_COLOR) | 0x10)); } // end EnableLCD() VOID DisableCRT( PHW_DEVICE_EXTENSION HwDeviceExtension ) /*++ Routine Description: This routine disables CRT interface of WD90C24A/A2 Arguments: HwDeviceExtension - Pointer to the miniport driver's adapter information. Return Value: None. --*/ { PUCHAR IoBase = HwDeviceExtension->IOAddress; // // Disables CRT interface // VideoPortWritePortUchar(IoBase + CRTC_ADDRESS_PORT_COLOR, pr19); VideoPortWritePortUchar( IoBase + CRTC_DATA_PORT_COLOR, (UCHAR)(VideoPortReadPortUchar(IoBase + CRTC_DATA_PORT_COLOR) & ~0x20)); // // Shuts off internal RAMDAC // VideoPortWritePortUchar(IoBase + CRTC_ADDRESS_PORT_COLOR, pr18); VideoPortWritePortUchar( IoBase + CRTC_DATA_PORT_COLOR, (UCHAR)(VideoPortReadPortUchar(IoBase + CRTC_DATA_PORT_COLOR) | 0x80)); // // Disables CRT H-sync and V-sync signals // VideoPortWritePortUchar(IoBase + CRTC_ADDRESS_PORT_COLOR, pr39); VideoPortWritePortUchar( IoBase + CRTC_DATA_PORT_COLOR, (UCHAR)(VideoPortReadPortUchar(IoBase + CRTC_DATA_PORT_COLOR) & ~0x04)); } // end DisableCRT() VOID EnableCRT( PHW_DEVICE_EXTENSION HwDeviceExtension ) /*++ Routine Description: This routine enables CRT interface of WD90C24A/A2 Arguments: HwDeviceExtension - Pointer to the miniport driver's adapter information. Return Value: None. --*/ { PUCHAR IoBase = HwDeviceExtension->IOAddress; // // Enables CRT interface // VideoPortWritePortUchar(IoBase + CRTC_ADDRESS_PORT_COLOR, pr19); VideoPortWritePortUchar( IoBase + CRTC_DATA_PORT_COLOR, (UCHAR)(VideoPortReadPortUchar(IoBase + CRTC_DATA_PORT_COLOR) | 0x20)); // // Enables internal RAMDAC // VideoPortWritePortUchar(IoBase + CRTC_ADDRESS_PORT_COLOR, pr18); VideoPortWritePortUchar( IoBase + CRTC_DATA_PORT_COLOR, (UCHAR)(VideoPortReadPortUchar(IoBase + CRTC_DATA_PORT_COLOR) & ~0x80)); // // Enables CRT H-sync and V-sync signals // VideoPortWritePortUchar(IoBase + CRTC_ADDRESS_PORT_COLOR, pr39); VideoPortWritePortUchar( IoBase + CRTC_DATA_PORT_COLOR, (UCHAR)(VideoPortReadPortUchar(IoBase + CRTC_DATA_PORT_COLOR) | 0x04)); } // end EnableCRT() VOID UnlockAll( PHW_DEVICE_EXTENSION HwDeviceExtension ) /*++ Routine Description: This routine unlocks all WD registers, except CRTC shadow registers Arguments: HwDeviceExtension - Pointer to the miniport driver's adapter information. Return Value: None. --*/ { PUCHAR IoBase = HwDeviceExtension->IOAddress; // // Unlocks the all WD registers // VideoPortWritePortUshort( (PUSHORT)(IoBase + GRAPH_ADDRESS_PORT), (USHORT)pr5 | ((USHORT)pr5_unlock << 8)); VideoPortWritePortUshort( (PUSHORT)(IoBase + CRTC_ADDRESS_PORT_COLOR), (USHORT)pr10 | ((USHORT)pr10_unlock << 8)); VideoPortWritePortUshort( (PUSHORT)(IoBase + CRTC_ADDRESS_PORT_COLOR), (USHORT)pr11 | ((USHORT)pr11_unlock << 8)); VideoPortWritePortUshort( (PUSHORT)(IoBase + SEQ_ADDRESS_PORT), (USHORT)pr20 | ((USHORT)pr20_unlock << 8)); VideoPortWritePortUshort( (PUSHORT)(IoBase + SEQ_ADDRESS_PORT), (USHORT)pr72 | ((USHORT)pr72_unlock << 8)); VideoPortWritePortUshort( (PUSHORT)(IoBase + CRTC_ADDRESS_PORT_COLOR), (USHORT)pr1b | ((USHORT)pr1b_unlock_pr << 8)); VideoPortWritePortUshort( (PUSHORT)(IoBase + CRTC_ADDRESS_PORT_COLOR), (USHORT)pr30 | ((USHORT)pr30_unlock << 8)); return; } // end UnlockAll()