/* * Edgeport USB Serial Converter driver * * Copyright (C) 2000-2002 Inside Out Networks, All rights reserved. * Copyright (C) 2001-2002 Greg Kroah-Hartman * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * Supports the following devices: * EP/1 EP/2 EP/4 * * Version history: * * July 11, 2002 Removed 4 port device structure since all TI UMP * chips have only 2 ports * David Iacovelli (davidi@ionetworks.com) * */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef CONFIG_USB_SERIAL_DEBUG static int debug = 1; #else static int debug; #endif #include "usb-serial.h" #include "io_16654.h" #include "io_usbvend.h" #include "io_ti.h" /* * Version Information */ #define DRIVER_VERSION "v0.2" #define DRIVER_AUTHOR "Greg Kroah-Hartman and David Iacovelli" #define DRIVER_DESC "Edgeport USB Serial Driver" /* firmware image code */ #define IMAGE_VERSION_NAME PagableOperationalCodeImageVersion #define IMAGE_ARRAY_NAME PagableOperationalCodeImage #define IMAGE_SIZE PagableOperationalCodeSize #include "io_fw_down3.h" /* Define array OperationalCodeImage[] */ #define EPROM_PAGE_SIZE 64 struct edgeport_uart_buf_desc { __u32 count; // Number of bytes currently in buffer }; /* different hardware types */ #define HARDWARE_TYPE_930 0 #define HARDWARE_TYPE_TIUMP 1 // IOCTL_PRIVATE_TI_GET_MODE Definitions #define TI_MODE_CONFIGURING 0 // Device has not entered start device #define TI_MODE_BOOT 1 // Staying in boot mode #define TI_MODE_DOWNLOAD 2 // Made it to download mode #define TI_MODE_TRANSITIONING 3 // Currently in boot mode but transitioning to download mode /* Product information read from the Edgeport */ struct product_info { int TiMode; // Current TI Mode __u8 hardware_type; // Type of hardware } __attribute__((packed)); struct edgeport_port { __u16 uart_base; __u16 dma_address; __u8 shadow_msr; __u8 shadow_mcr; __u8 shadow_lsr; __u8 lsr_mask; __u32 ump_read_timeout; /* Number of miliseconds the UMP will wait without data before completing a read short */ int baud_rate; int close_pending; int lsr_event; struct edgeport_uart_buf_desc tx; struct async_icount icount; wait_queue_head_t delta_msr_wait; /* for handling sleeping while waiting for msr change to happen */ struct edgeport_serial *edge_serial; struct usb_serial_port *port; }; struct edgeport_serial { struct product_info product_info; u8 TI_I2C_Type; // Type of I2C in UMP u8 TiReadI2C; // Set to TRUE if we have read the I2c in Boot Mode int num_ports_open; struct usb_serial *serial; }; /* Devices that this driver supports */ static struct usb_device_id edgeport_1port_id_table [] = { { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_1) }, { } }; static struct usb_device_id edgeport_2port_id_table [] = { { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_2) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_2C) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_2I) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_421) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_421_BOOT) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_421_DOWN) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_21) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_21_BOOT) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_21_DOWN) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_42) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_4) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_4I) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_22) }, { } }; /* Devices that this driver supports */ static __devinitdata struct usb_device_id id_table_combined [] = { { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_1) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_2) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_2C) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_2I) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_421) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_421_BOOT) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_421_DOWN) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_21) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_21_BOOT) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_21_DOWN) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_42) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_4) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_4I) }, { USB_DEVICE(USB_VENDOR_ID_ION, ION_DEVICE_ID_TI_EDGEPORT_22) }, { } }; MODULE_DEVICE_TABLE (usb, id_table_combined); static struct EDGE_FIRMWARE_VERSION_INFO OperationalCodeImageVersion; static int TIStayInBootMode = 0; static int ignore_cpu_rev = 0; static void edge_set_termios (struct usb_serial_port *port, struct termios *old_termios); static int TIReadVendorRequestSync (struct usb_device *dev, __u8 request, __u16 value, __u16 index, u8 *data, int size) { int status; status = usb_control_msg (dev, usb_rcvctrlpipe(dev, 0), request, (USB_TYPE_VENDOR | USB_RECIP_DEVICE | USB_DIR_IN), value, index, data, size, HZ); if (status < 0) return status; if (status != size) { dbg ("%s - wanted to write %d, but only wrote %d", __FUNCTION__, size, status); return -ECOMM; } return 0; } static int TISendVendorRequestSync (struct usb_device *dev, __u8 request, __u16 value, __u16 index, u8 *data, int size) { int status; status = usb_control_msg (dev, usb_sndctrlpipe(dev, 0), request, (USB_TYPE_VENDOR | USB_RECIP_DEVICE | USB_DIR_OUT), value, index, data, size, HZ); if (status < 0) return status; if (status != size) { dbg ("%s - wanted to write %d, but only wrote %d", __FUNCTION__, size, status); return -ECOMM; } return 0; } static int TIWriteCommandSync (struct usb_device *dev, __u8 command, __u8 moduleid, __u16 value, u8 *data, int size) { return TISendVendorRequestSync (dev, command, // Request value, // wValue moduleid, // wIndex data, // TransferBuffer size); // TransferBufferLength } /* clear tx/rx buffers and fifo in TI UMP */ static int TIPurgeDataSync (struct usb_serial_port *port, __u16 mask) { int port_number = port->number - port->serial->minor; dbg ("%s - port %d, mask %x", __FUNCTION__, port_number, mask); return TIWriteCommandSync (port->serial->dev, UMPC_PURGE_PORT, (__u8)(UMPM_UART1_PORT + port_number), mask, NULL, 0); } /** * TIReadDownloadMemory - Read edgeport memory from TI chip * @dev: usb device pointer * @address: Device CPU address at which to read * @length: Length of above data * @address_type: Can read both XDATA and I2C * @buffer: pointer to input data buffer */ int TIReadDownloadMemory (struct usb_device *dev, int start_address, int length, __u8 address_type, __u8 *buffer) { int status = 0; __u8 read_length; __u16 be_start_address; dbg ("%s - @ %x for %d", __FUNCTION__, start_address, length); /* Read in blocks of 64 bytes * (TI firmware can't handle more than 64 byte reads) */ while (length) { if (length > 64) read_length= 64; else read_length = (__u8)length; if (read_length > 1) { dbg ("%s - @ %x for %d", __FUNCTION__, start_address, read_length); } be_start_address = cpu_to_be16 (start_address); status = TIReadVendorRequestSync (dev, UMPC_MEMORY_READ, // Request (__u16)address_type, // wValue (Address type) be_start_address, // wIndex (Address to read) buffer, // TransferBuffer read_length); // TransferBufferLength if (status) { dbg ("%s - ERROR %x", __FUNCTION__, status); return status; } if (read_length > 1) { usb_serial_debug_data (__FILE__, __FUNCTION__, read_length, buffer); } /* Update pointers/length */ start_address += read_length; buffer += read_length; length -= read_length; } return status; } int TIReadRam (struct usb_device *dev, int start_address, int length, __u8 *buffer) { return TIReadDownloadMemory (dev, start_address, length, DTK_ADDR_SPACE_XDATA, buffer); } /* Read edgeport memory to a given block */ static int TIReadBootMemory (struct edgeport_serial *serial, int start_address, int length, __u8 * buffer) { int status = 0; int i; for (i=0; i< length; i++) { status = TIReadVendorRequestSync (serial->serial->dev, UMPC_MEMORY_READ, // Request serial->TI_I2C_Type, // wValue (Address type) (__u16)(start_address+i), // wIndex &buffer[i], // TransferBuffer 0x01); // TransferBufferLength if (status) { dbg ("%s - ERROR %x", __FUNCTION__, status); return status; } } dbg ("%s - start_address = %x, length = %d", __FUNCTION__, start_address, length); usb_serial_debug_data (__FILE__, __FUNCTION__, length, buffer); serial->TiReadI2C = 1; return status; } /* Write given block to TI EPROM memory */ static int TIWriteBootMemory (struct edgeport_serial *serial, int start_address, int length, __u8 *buffer) { int status = 0; int i; __u8 temp; /* Must do a read before write */ if (!serial->TiReadI2C) { status = TIReadBootMemory(serial, 0, 1, &temp); if (status) return status; } for (i=0; i < length; ++i) { status = TISendVendorRequestSync (serial->serial->dev, UMPC_MEMORY_WRITE, // Request buffer[i], // wValue (__u16)(i+start_address), // wIndex NULL, // TransferBuffer 0); // TransferBufferLength if (status) return status; } dbg ("%s - start_sddr = %x, length = %d", __FUNCTION__, start_address, length); usb_serial_debug_data (__FILE__, __FUNCTION__, length, buffer); return status; } /* Write edgeport I2C memory to TI chip */ static int TIWriteDownloadI2C (struct edgeport_serial *serial, int start_address, int length, __u8 address_type, __u8 *buffer) { int status = 0; int write_length; __u16 be_start_address; /* We can only send a maximum of 1 aligned byte page at a time */ /* calulate the number of bytes left in the first page */ write_length = EPROM_PAGE_SIZE - (start_address & (EPROM_PAGE_SIZE - 1)); if (write_length > length) write_length = length; dbg ("%s - BytesInFirstPage Addr = %x, length = %d", __FUNCTION__, start_address, write_length); usb_serial_debug_data (__FILE__, __FUNCTION__, write_length, buffer); /* Write first page */ be_start_address = cpu_to_be16 (start_address); status = TISendVendorRequestSync (serial->serial->dev, UMPC_MEMORY_WRITE, // Request (__u16)address_type, // wValue be_start_address, // wIndex buffer, // TransferBuffer write_length); if (status) { dbg ("%s - ERROR %d", __FUNCTION__, status); return status; } length -= write_length; start_address += write_length; buffer += write_length; /* We should be aligned now -- can write max page size bytes at a time */ while (length) { if (length > EPROM_PAGE_SIZE) write_length = EPROM_PAGE_SIZE; else write_length = length; dbg ("%s - Page Write Addr = %x, length = %d", __FUNCTION__, start_address, write_length); usb_serial_debug_data (__FILE__, __FUNCTION__, write_length, buffer); /* Write next page */ be_start_address = cpu_to_be16 (start_address); status = TISendVendorRequestSync (serial->serial->dev, UMPC_MEMORY_WRITE, // Request (__u16)address_type, // wValue be_start_address, // wIndex buffer, // TransferBuffer write_length); // TransferBufferLength if (status) { dbg ("%s - ERROR %d", __FUNCTION__, status); return status; } length -= write_length; start_address += write_length; buffer += write_length; } return status; } /* Examine the UMP DMA registers and LSR * * Check the MSBit of the X and Y DMA byte count registers. * A zero in this bit indicates that the TX DMA buffers are empty * then check the TX Empty bit in the UART. */ static int TIIsTxActive (struct edgeport_port *port) { int status; struct out_endpoint_desc_block *oedb; __u8 *lsr; int bytes_left = 0; oedb = kmalloc (sizeof (* oedb), GFP_KERNEL); if (!oedb) { err ("%s - out of memory", __FUNCTION__); return -ENOMEM; } lsr = kmalloc (1, GFP_KERNEL); /* Sigh, that's right, just one byte, as not all platforms can do DMA from stack */ if (!lsr) { kfree(oedb); return -ENOMEM; } /* Read the DMA Count Registers */ status = TIReadRam (port->port->serial->dev, port->dma_address, sizeof( *oedb), (void *)oedb); if (status) goto exit_is_tx_active; dbg ("%s - XByteCount 0x%X", __FUNCTION__, oedb->XByteCount); /* and the LSR */ status = TIReadRam (port->port->serial->dev, port->uart_base + UMPMEM_OFFS_UART_LSR, 1, lsr); if (status) goto exit_is_tx_active; dbg ("%s - LSR = 0x%X", __FUNCTION__, *lsr); /* If either buffer has data or we are transmitting then return TRUE */ if ((oedb->XByteCount & 0x80 ) != 0 ) bytes_left += 64; if ((*lsr & UMP_UART_LSR_TX_MASK ) == 0 ) bytes_left += 1; /* We return Not Active if we get any kind of error */ exit_is_tx_active: dbg ("%s - return %d", __FUNCTION__, bytes_left ); kfree(lsr); kfree(oedb); return bytes_left; } static void TIChasePort(struct edgeport_port *port) { int loops; int last_count; int write_size; restart_tx_loop: // Base the LoopTime on the baud rate if (port->baud_rate == 0) port->baud_rate = 1200; write_size = port->tx.count; loops = max(100, (100*write_size)/(port->baud_rate/10)); dbg ("%s - write_size %d, baud %d loop = %d", __FUNCTION__, write_size, port->baud_rate, loops); while (1) { // Save Last count last_count = port->tx.count; dbg ("%s - Tx Buffer Size = %d loops = %d", __FUNCTION__, last_count, loops); /* Is the Edgeport Buffer empty? */ if (port->tx.count == 0) break; /* Block the thread for 10ms */ wait_ms (10); if (last_count == port->tx.count) { /* No activity.. count down. */ --loops; if (loops == 0) { dbg ("%s - Wait for TxEmpty - TIMEOUT", __FUNCTION__); return; } } else { /* Reset timeout value back to a minimum of 1 second */ dbg ("%s - Wait for TxEmpty Reset Count", __FUNCTION__); goto restart_tx_loop; } } dbg ("%s - Local Tx Buffer Empty -- Waiting for TI UMP to EMPTY X/Y and FIFO", __FUNCTION__); write_size = TIIsTxActive (port); loops = max(50, (100*write_size)/(port->baud_rate/10)); dbg ("%s - write_size %d, baud %d loop = %d", __FUNCTION__, write_size, port->baud_rate, loops); while (1) { /* This function takes 4 ms; */ if (!TIIsTxActive (port)) { /* Delay a few char times */ wait_ms (50); dbg ("%s - Empty", __FUNCTION__); return; } --loops; if (loops == 0) { dbg ("%s - TIMEOUT", __FUNCTION__); return; } } } static int TIChooseConfiguration (struct usb_device *dev) { // There may be multiple configurations on this device, in which case // we would need to read and parse all of them to find out which one // we want. However, we just support one config at this point, // configuration # 1, which is Config Descriptor 0. dbg ("%s - Number of Interfaces = %d", __FUNCTION__, dev->config->bNumInterfaces); dbg ("%s - MAX Power = %d", __FUNCTION__, dev->config->MaxPower*2); if (dev->config->bNumInterfaces != 1) { err ("%s - bNumInterfaces is not 1, ERROR!", __FUNCTION__); return -ENODEV; } return 0; } int TIReadRom (struct edgeport_serial *serial, int start_address, int length, __u8 *buffer) { int status; if (serial->product_info.TiMode == TI_MODE_DOWNLOAD) { status = TIReadDownloadMemory (serial->serial->dev, start_address, length, serial->TI_I2C_Type, buffer); } else { status = TIReadBootMemory (serial, start_address, length, buffer); } return status; } int TIWriteRom (struct edgeport_serial *serial, int start_address, int length, __u8 *buffer) { if (serial->product_info.TiMode == TI_MODE_BOOT) return TIWriteBootMemory (serial, start_address, length, buffer); if (serial->product_info.TiMode == TI_MODE_DOWNLOAD) return TIWriteDownloadI2C (serial, start_address, length, serial->TI_I2C_Type, buffer); return -EINVAL; } /* Read a descriptor header from I2C based on type */ static int TIGetDescriptorAddress (struct edgeport_serial *serial, int desc_type, struct ti_i2c_desc *rom_desc) { int start_address; int status; /* Search for requested descriptor in I2C */ start_address = 2; do { status = TIReadRom (serial, start_address, sizeof(struct ti_i2c_desc), (__u8 *)rom_desc ); if (status) return 0; if (rom_desc->Type == desc_type) return start_address; start_address = start_address + sizeof(struct ti_i2c_desc) + rom_desc->Size; } while ((start_address < TI_MAX_I2C_SIZE) && rom_desc->Type); return 0; } /* Validate descriptor checksum */ static int ValidChecksum(struct ti_i2c_desc *rom_desc, __u8 *buffer) { __u16 i; __u8 cs = 0; for (i=0; i < rom_desc->Size; i++) { cs = (__u8)(cs + buffer[i]); } if (cs != rom_desc->CheckSum) { dbg ("%s - Mismatch %x - %x", __FUNCTION__, rom_desc->CheckSum, cs); return -EINVAL; } return 0; } /* Make sure that the I2C image is good */ static int TiValidateI2cImage (struct edgeport_serial *serial) { int status = 0; struct ti_i2c_desc *rom_desc; int start_address = 2; __u8 *buffer; rom_desc = kmalloc (sizeof (*rom_desc), GFP_KERNEL); if (!rom_desc) { err ("%s - out of memory", __FUNCTION__); return -ENOMEM; } buffer = kmalloc (TI_MAX_I2C_SIZE, GFP_KERNEL); if (!buffer) { err ("%s - out of memory when allocating buffer", __FUNCTION__); kfree (rom_desc); return -ENOMEM; } // Read the first byte (Signature0) must be 0x52 status = TIReadRom (serial, 0, 1, buffer); if (status) goto ExitTiValidateI2cImage; if (*buffer != 0x52) { err ("%s - invalid buffer signature", __FUNCTION__); status = -ENODEV; goto ExitTiValidateI2cImage; } do { // Validate the I2C status = TIReadRom (serial, start_address, sizeof(struct ti_i2c_desc), (__u8 *)rom_desc); if (status) break; if ((start_address + sizeof(struct ti_i2c_desc) + rom_desc->Size) > TI_MAX_I2C_SIZE) { status = -ENODEV; dbg ("%s - structure too big, erroring out.", __FUNCTION__); break; } dbg ("%s Type = 0x%x", __FUNCTION__, rom_desc->Type); // Skip type 2 record if ((rom_desc->Type & 0x0f) != I2C_DESC_TYPE_FIRMWARE_BASIC) { // Read the descriptor data status = TIReadRom(serial, start_address+sizeof(struct ti_i2c_desc), rom_desc->Size, buffer); if (status) break; status = ValidChecksum(rom_desc, buffer); if (status) break; } start_address = start_address + sizeof(struct ti_i2c_desc) + rom_desc->Size; } while ((rom_desc->Type != I2C_DESC_TYPE_ION) && (start_address < TI_MAX_I2C_SIZE)); if ((rom_desc->Type != I2C_DESC_TYPE_ION) || (start_address > TI_MAX_I2C_SIZE)) status = -ENODEV; ExitTiValidateI2cImage: kfree (buffer); kfree (rom_desc); return status; } static int TIReadManufDescriptor (struct edgeport_serial *serial, __u8 *buffer) { int status; int start_address; struct ti_i2c_desc *rom_desc; struct edge_ti_manuf_descriptor *desc; rom_desc = kmalloc (sizeof (*rom_desc), GFP_KERNEL); if (!rom_desc) { err ("%s - out of memory", __FUNCTION__); return -ENOMEM; } start_address = TIGetDescriptorAddress (serial, I2C_DESC_TYPE_ION, rom_desc); if (!start_address) { dbg ("%s - Edge Descriptor not found in I2C", __FUNCTION__); status = -ENODEV; goto exit; } // Read the descriptor data status = TIReadRom (serial, start_address+sizeof(struct ti_i2c_desc), rom_desc->Size, buffer); if (status) goto exit; status = ValidChecksum(rom_desc, buffer); desc = (struct edge_ti_manuf_descriptor *)buffer; dbg ( "%s - IonConfig 0x%x", __FUNCTION__, desc->IonConfig ); dbg ( "%s - Version %d", __FUNCTION__, desc->Version ); dbg ( "%s - Cpu/Board 0x%x", __FUNCTION__, desc->CpuRev_BoardRev ); dbg ( "%s - NumPorts %d", __FUNCTION__, desc->NumPorts ); dbg ( "%s - NumVirtualPorts %d", __FUNCTION__, desc->NumVirtualPorts ); dbg ( "%s - TotalPorts %d", __FUNCTION__, desc->TotalPorts ); exit: kfree (rom_desc); return status; } /* Build firmware header used for firmware update */ static int BuildI2CFirmwareHeader (__u8 *header) { __u8 *buffer; int buffer_size; int i; __u8 cs = 0; struct ti_i2c_desc *i2c_header; struct ti_i2c_image_header *img_header; struct ti_i2c_firmware_rec *firmware_rec; // In order to update the I2C firmware we must change the type 2 record to type 0xF2. // This will force the UMP to come up in Boot Mode. Then while in boot mode, the driver // will download the latest firmware (padded to 15.5k) into the UMP ram. // And finally when the device comes back up in download mode the driver will cause // the new firmware to be copied from the UMP Ram to I2C and the firmware will update // the record type from 0xf2 to 0x02. // Allocate a 15.5k buffer + 2 bytes for version number (Firmware Record) buffer_size = (((1024 * 16) - 512 )+ sizeof(struct ti_i2c_firmware_rec)); buffer = kmalloc (buffer_size, GFP_KERNEL); if (!buffer) { err ("%s - out of memory", __FUNCTION__); return -ENOMEM; } // Set entire image of 0xffs memset (buffer, 0xff, buffer_size); // Copy version number into firmware record firmware_rec = (struct ti_i2c_firmware_rec *)buffer; firmware_rec->Ver_Major = OperationalCodeImageVersion.MajorVersion; firmware_rec->Ver_Minor = OperationalCodeImageVersion.MinorVersion; // Pointer to fw_down memory image img_header = (struct ti_i2c_image_header *)&PagableOperationalCodeImage[0]; memcpy (buffer + sizeof(struct ti_i2c_firmware_rec), &PagableOperationalCodeImage[sizeof(struct ti_i2c_image_header)], img_header->Length); for (i=0; i < buffer_size; i++) { cs = (__u8)(cs + buffer[i]); } kfree (buffer); // Build new header i2c_header = (struct ti_i2c_desc *)header; firmware_rec = (struct ti_i2c_firmware_rec*)i2c_header->Data; i2c_header->Type = I2C_DESC_TYPE_FIRMWARE_BLANK; i2c_header->Size = (__u16)buffer_size; i2c_header->CheckSum = cs; firmware_rec->Ver_Major = OperationalCodeImageVersion.MajorVersion; firmware_rec->Ver_Minor = OperationalCodeImageVersion.MinorVersion; return 0; } /* Try to figure out what type of I2c we have */ static int TIGetI2cTypeInBootMode (struct edgeport_serial *serial) { int status; __u8 data; // Try to read type 2 status = TIReadVendorRequestSync (serial->serial->dev, UMPC_MEMORY_READ, // Request DTK_ADDR_SPACE_I2C_TYPE_II, // wValue (Address type) 0, // wIndex &data, // TransferBuffer 0x01); // TransferBufferLength if (status) dbg ("%s - read 2 status error = %d", __FUNCTION__, status); else dbg ("%s - read 2 data = 0x%x", __FUNCTION__, data); if ((!status) && data == 0x52) { dbg ("%s - ROM_TYPE_II", __FUNCTION__); serial->TI_I2C_Type = DTK_ADDR_SPACE_I2C_TYPE_II; return 0; } // Try to read type 3 status = TIReadVendorRequestSync (serial->serial->dev, UMPC_MEMORY_READ, // Request DTK_ADDR_SPACE_I2C_TYPE_III, // wValue (Address type) 0, // wIndex &data, // TransferBuffer 0x01); // TransferBufferLength if (status) dbg ("%s - read 3 status error = %d", __FUNCTION__, status); else dbg ("%s - read 2 data = 0x%x", __FUNCTION__, data); if ((!status) && data == 0x52) { dbg ("%s - ROM_TYPE_III", __FUNCTION__); serial->TI_I2C_Type = DTK_ADDR_SPACE_I2C_TYPE_III; return 0; } dbg ("%s - Unknown", __FUNCTION__); serial->TI_I2C_Type = DTK_ADDR_SPACE_I2C_TYPE_II; return -ENODEV; } static int TISendBulkTransferSync (struct usb_serial *serial, void *buffer, int length, int *num_sent) { int status; status = usb_bulk_msg (serial->dev, usb_sndbulkpipe(serial->dev, serial->port[0].bulk_out_endpointAddress), buffer, length, num_sent, HZ); return status; } /* Download given firmware image to the device (IN BOOT MODE) */ static int TIDownloadCodeImage (struct edgeport_serial *serial, __u8 *image, int image_length) { int status = 0; int pos; int transfer; int done; // Transfer firmware image for (pos = 0; pos < image_length; ) { // Read the next buffer from file transfer = image_length - pos; if (transfer > EDGE_FW_BULK_MAX_PACKET_SIZE) transfer = EDGE_FW_BULK_MAX_PACKET_SIZE; // Transfer data status = TISendBulkTransferSync (serial->serial, &image[pos], transfer, &done); if (status) break; // Advance buffer pointer pos += done; } return status; } // FIXME!!! static int TIConfigureBootDevice (struct usb_device *dev) { return 0; } /** * DownloadTIFirmware - Download run-time operating firmware to the TI5052 * * This routine downloads the main operating code into the TI5052, using the * boot code already burned into E2PROM or ROM. */ static int TIDownloadFirmware (struct edgeport_serial *serial) { int status = 0; int start_address; struct edge_ti_manuf_descriptor *ti_manuf_desc; struct usb_interface_descriptor *interface; int download_cur_ver; int download_new_ver; /* This routine is entered by both the BOOT mode and the Download mode * We can determine which code is running by the reading the config * descriptor and if we have only one bulk pipe it is in boot mode */ serial->product_info.hardware_type = HARDWARE_TYPE_TIUMP; /* Default to type 2 i2c */ serial->TI_I2C_Type = DTK_ADDR_SPACE_I2C_TYPE_II; status = TIChooseConfiguration (serial->serial->dev); if (status) return status; interface = serial->serial->dev->config->interface->altsetting; if (!interface) { err ("%s - no interface set, error!", __FUNCTION__); return -ENODEV; } // Setup initial mode -- the default mode 0 is TI_MODE_CONFIGURING // if we have more than one endpoint we are definitely in download mode if (interface->bNumEndpoints > 1) serial->product_info.TiMode = TI_MODE_DOWNLOAD; else // Otherwise we will remain in configuring mode serial->product_info.TiMode = TI_MODE_CONFIGURING; // Save Download Version Number OperationalCodeImageVersion.MajorVersion = PagableOperationalCodeImageVersion.MajorVersion; OperationalCodeImageVersion.MinorVersion = PagableOperationalCodeImageVersion.MinorVersion; OperationalCodeImageVersion.BuildNumber = PagableOperationalCodeImageVersion.BuildNumber; /********************************************************************/ /* Download Mode */ /********************************************************************/ if (serial->product_info.TiMode == TI_MODE_DOWNLOAD) { struct ti_i2c_desc *rom_desc; dbg ("%s - <<<<<<<<<<<<<<>>>>>>>>>", __FUNCTION__); status = TiValidateI2cImage (serial); if (status) { dbg ("%s - <<<<<<<<<<<<<<>>>>>>>>>", __FUNCTION__); return status; } /* Validate Hardware version number * Read Manufacturing Descriptor from TI Based Edgeport */ ti_manuf_desc = kmalloc (sizeof (*ti_manuf_desc), GFP_KERNEL); if (!ti_manuf_desc) { err ("%s - out of memory.", __FUNCTION__); return -ENOMEM; } status = TIReadManufDescriptor (serial, (__u8 *)ti_manuf_desc); if (status) { kfree (ti_manuf_desc); return status; } // Check version number of ION descriptor if (!ignore_cpu_rev && TI_GET_CPU_REVISION(ti_manuf_desc->CpuRev_BoardRev) < 2) { dbg ( "%s - Wrong CPU Rev %d (Must be 2)", __FUNCTION__, TI_GET_CPU_REVISION(ti_manuf_desc->CpuRev_BoardRev)); kfree (ti_manuf_desc); return -EINVAL; } rom_desc = kmalloc (sizeof (*rom_desc), GFP_KERNEL); if (!rom_desc) { err ("%s - out of memory.", __FUNCTION__); kfree (ti_manuf_desc); return -ENOMEM; } // Search for type 2 record (firmware record) if ((start_address = TIGetDescriptorAddress (serial, I2C_DESC_TYPE_FIRMWARE_BASIC, rom_desc)) != 0) { struct ti_i2c_firmware_rec *firmware_version; __u8 record; dbg ("%s - Found Type FIRMWARE (Type 2) record", __FUNCTION__); firmware_version = kmalloc (sizeof (*firmware_version), GFP_KERNEL); if (!firmware_version) { err ("%s - out of memory.", __FUNCTION__); kfree (rom_desc); kfree (ti_manuf_desc); return -ENOMEM; } // Validate version number // Read the descriptor data status = TIReadRom (serial, start_address+sizeof(struct ti_i2c_desc), sizeof(struct ti_i2c_firmware_rec), (__u8 *)firmware_version); if (status) { kfree (firmware_version); kfree (rom_desc); kfree (ti_manuf_desc); return status; } // Check version number of download with current version in I2c download_cur_ver = (firmware_version->Ver_Major << 8) + (firmware_version->Ver_Minor); download_new_ver = (OperationalCodeImageVersion.MajorVersion << 8) + (OperationalCodeImageVersion.MinorVersion); dbg ("%s - >>>Firmware Versions Device %d.%d Driver %d.%d", __FUNCTION__, firmware_version->Ver_Major, firmware_version->Ver_Minor, OperationalCodeImageVersion.MajorVersion, OperationalCodeImageVersion.MinorVersion); // Check if we have an old version in the I2C and update if necessary if (download_cur_ver != download_new_ver) { dbg ("%s - Update I2C Download from %d.%d to %d.%d", __FUNCTION__, firmware_version->Ver_Major, firmware_version->Ver_Minor, OperationalCodeImageVersion.MajorVersion, OperationalCodeImageVersion.MinorVersion); // In order to update the I2C firmware we must change the type 2 record to type 0xF2. // This will force the UMP to come up in Boot Mode. Then while in boot mode, the driver // will download the latest firmware (padded to 15.5k) into the UMP ram. // And finally when the device comes back up in download mode the driver will cause // the new firmware to be copied from the UMP Ram to I2C and the firmware will update // the record type from 0xf2 to 0x02. record = I2C_DESC_TYPE_FIRMWARE_BLANK; // Change the I2C Firmware record type to 0xf2 to trigger an update status = TIWriteRom (serial, start_address, sizeof(record), &record); if (status) { kfree (firmware_version); kfree (rom_desc); kfree (ti_manuf_desc); return status; } // verify the write -- must do this in order for write to // complete before we do the hardware reset status = TIReadRom (serial, start_address, sizeof(record), &record); if (status) { kfree (firmware_version); kfree (rom_desc); kfree (ti_manuf_desc); return status; } if (record != I2C_DESC_TYPE_FIRMWARE_BLANK) { err ("%s - error resetting device", __FUNCTION__); kfree (firmware_version); kfree (rom_desc); kfree (ti_manuf_desc); return -ENODEV; } dbg ("%s - HARDWARE RESET", __FUNCTION__); // Reset UMP -- Back to BOOT MODE status = TISendVendorRequestSync (serial->serial->dev, UMPC_HARDWARE_RESET, // Request 0, // wValue 0, // wIndex NULL, // TransferBuffer 0); // TransferBufferLength dbg ( "%s - HARDWARE RESET return %d", __FUNCTION__, status); /* return an error on purpose. */ kfree (firmware_version); kfree (rom_desc); kfree (ti_manuf_desc); return -ENODEV; } kfree (firmware_version); } // Search for type 0xF2 record (firmware blank record) else if ((start_address = TIGetDescriptorAddress (serial, I2C_DESC_TYPE_FIRMWARE_BLANK, rom_desc)) != 0) { #define HEADER_SIZE (sizeof(struct ti_i2c_desc) + sizeof(struct ti_i2c_firmware_rec)) __u8 *header; __u8 *vheader; header = kmalloc (HEADER_SIZE, GFP_KERNEL); if (!header) { err ("%s - out of memory.", __FUNCTION__); kfree (rom_desc); kfree (ti_manuf_desc); return -ENOMEM; } vheader = kmalloc (HEADER_SIZE, GFP_KERNEL); if (!vheader) { err ("%s - out of memory.", __FUNCTION__); kfree (header); kfree (rom_desc); kfree (ti_manuf_desc); return -ENOMEM; } dbg ("%s - Found Type BLANK FIRMWARE (Type F2) record", __FUNCTION__); // In order to update the I2C firmware we must change the type 2 record to type 0xF2. // This will force the UMP to come up in Boot Mode. Then while in boot mode, the driver // will download the latest firmware (padded to 15.5k) into the UMP ram. // And finally when the device comes back up in download mode the driver will cause // the new firmware to be copied from the UMP Ram to I2C and the firmware will update // the record type from 0xf2 to 0x02. status = BuildI2CFirmwareHeader(header); if (status) { kfree (vheader); kfree (header); kfree (rom_desc); kfree (ti_manuf_desc); return status; } // Update I2C with type 0xf2 record with correct size and checksum status = TIWriteRom (serial, start_address, HEADER_SIZE, header); if (status) { kfree (vheader); kfree (header); kfree (rom_desc); kfree (ti_manuf_desc); return status; } // verify the write -- must do this in order for write to // complete before we do the hardware reset status = TIReadRom (serial, start_address, HEADER_SIZE, vheader); if (status) { dbg ("%s - can't read header back", __FUNCTION__); kfree (vheader); kfree (header); kfree (rom_desc); kfree (ti_manuf_desc); return status; } if (memcmp(vheader, header, HEADER_SIZE)) { dbg ("%s - write download record failed", __FUNCTION__); kfree (vheader); kfree (header); kfree (rom_desc); kfree (ti_manuf_desc); return status; } kfree (vheader); kfree (header); dbg ("%s - Start firmware update", __FUNCTION__); // Tell firmware to copy download image into I2C status = TISendVendorRequestSync (serial->serial->dev, UMPC_COPY_DNLD_TO_I2C, // Request 0, // wValue 0, // wIndex NULL, // TransferBuffer 0); // TransferBufferLength dbg ("%s - Update complete 0x%x", __FUNCTION__, status); if (status) { dbg ("%s - UMPC_COPY_DNLD_TO_I2C failed", __FUNCTION__); kfree (rom_desc); kfree (ti_manuf_desc); return status; } } // The device is running the download code kfree (rom_desc); kfree (ti_manuf_desc); return 0; } /********************************************************************/ /* Boot Mode */ /********************************************************************/ dbg ("%s - <<<<<<<<<<<<<<>>>>>>>>>>>>>>", __FUNCTION__); // Configure the TI device so we can use the BULK pipes for download status = TIConfigureBootDevice (serial->serial->dev); if (status) return status; if (serial->serial->dev->descriptor.idVendor != USB_VENDOR_ID_ION) { dbg ("%s - VID = 0x%x", __FUNCTION__, serial->serial->dev->descriptor.idVendor); serial->TI_I2C_Type = DTK_ADDR_SPACE_I2C_TYPE_II; goto StayInBootMode; } // We have an ION device (I2c Must be programmed) // Determine I2C image type if (TIGetI2cTypeInBootMode(serial)) { goto StayInBootMode; } // Registry variable set? if (TIStayInBootMode) { dbg ("%s - TIStayInBootMode", __FUNCTION__); goto StayInBootMode; } // Check for ION Vendor ID and that the I2C is valid if (!TiValidateI2cImage(serial)) { struct ti_i2c_image_header *header; int i; __u8 cs = 0; __u8 *buffer; int buffer_size; /* Validate Hardware version number * Read Manufacturing Descriptor from TI Based Edgeport */ ti_manuf_desc = kmalloc (sizeof (*ti_manuf_desc), GFP_KERNEL); if (!ti_manuf_desc) { err ("%s - out of memory.", __FUNCTION__); return -ENOMEM; } status = TIReadManufDescriptor (serial, (__u8 *)ti_manuf_desc); if (status) { kfree (ti_manuf_desc); goto StayInBootMode; } // Check for version 2 if (!ignore_cpu_rev && TI_GET_CPU_REVISION(ti_manuf_desc->CpuRev_BoardRev) < 2) { dbg ("%s - Wrong CPU Rev %d (Must be 2)", __FUNCTION__, TI_GET_CPU_REVISION(ti_manuf_desc->CpuRev_BoardRev)); kfree (ti_manuf_desc); goto StayInBootMode; } kfree (ti_manuf_desc); // In order to update the I2C firmware we must change the type 2 record to type 0xF2. // This will force the UMP to come up in Boot Mode. Then while in boot mode, the driver // will download the latest firmware (padded to 15.5k) into the UMP ram. // And finally when the device comes back up in download mode the driver will cause // the new firmware to be copied from the UMP Ram to I2C and the firmware will update // the record type from 0xf2 to 0x02. /* * Do we really have to copy the whole firmware image, * or could we do this in place! */ // Allocate a 15.5k buffer + 3 byte header buffer_size = (((1024 * 16) - 512) + sizeof(struct ti_i2c_image_header)); buffer = kmalloc (buffer_size, GFP_KERNEL); if (!buffer) { err ("%s - out of memory", __FUNCTION__); return -ENOMEM; } // Initialize the buffer to 0xff (pad the buffer) memset (buffer, 0xff, buffer_size); memcpy (buffer, &PagableOperationalCodeImage[0], PagableOperationalCodeSize); for(i = sizeof(struct ti_i2c_image_header); i < buffer_size; i++) { cs = (__u8)(cs + buffer[i]); } header = (struct ti_i2c_image_header *)buffer; // update length and checksum after padding header->Length = (__u16)(buffer_size - sizeof(struct ti_i2c_image_header)); header->CheckSum = cs; // Download the operational code dbg ("%s - Downloading operational code image (TI UMP)", __FUNCTION__); status = TIDownloadCodeImage (serial, buffer, buffer_size); kfree (buffer); if (status) { dbg ("%s - Error downloading operational code image", __FUNCTION__); return status; } // Device will reboot serial->product_info.TiMode = TI_MODE_TRANSITIONING; dbg ("%s - Download successful -- Device rebooting...", __FUNCTION__); /* return an error on purpose */ return -ENODEV; } StayInBootMode: // Eprom is invalid or blank stay in boot mode dbg ("%s - <<<<<<<<<<<<<<>>>>>>>>>>>", __FUNCTION__); serial->product_info.TiMode = TI_MODE_BOOT; return 0; } static int TISetDtr (struct edgeport_port *port) { int port_number = port->port->number - port->port->serial->minor; dbg ("%s", __FUNCTION__); port->shadow_mcr |= MCR_DTR; return TIWriteCommandSync (port->port->serial->dev, UMPC_SET_CLR_DTR, (__u8)(UMPM_UART1_PORT + port_number), 1, /* set */ NULL, 0); } static int TIClearDtr (struct edgeport_port *port) { int port_number = port->port->number - port->port->serial->minor; dbg ("%s", __FUNCTION__); port->shadow_mcr &= ~MCR_DTR; return TIWriteCommandSync (port->port->serial->dev, UMPC_SET_CLR_DTR, (__u8)(UMPM_UART1_PORT + port_number), 0, /* clear */ NULL, 0); } static int TISetRts (struct edgeport_port *port) { int port_number = port->port->number - port->port->serial->minor; dbg ("%s", __FUNCTION__); port->shadow_mcr |= MCR_RTS; return TIWriteCommandSync (port->port->serial->dev, UMPC_SET_CLR_RTS, (__u8)(UMPM_UART1_PORT + port_number), 1, /* set */ NULL, 0); } static int TIClearRts (struct edgeport_port *port) { int port_number = port->port->number - port->port->serial->minor; dbg ("%s", __FUNCTION__); port->shadow_mcr &= ~MCR_RTS; return TIWriteCommandSync (port->port->serial->dev, UMPC_SET_CLR_RTS, (__u8)(UMPM_UART1_PORT + port_number), 0, /* clear */ NULL, 0); } static int TISetLoopBack (struct edgeport_port *port) { int port_number = port->port->number - port->port->serial->minor; dbg ("%s", __FUNCTION__); return TIWriteCommandSync (port->port->serial->dev, UMPC_SET_CLR_LOOPBACK, (__u8)(UMPM_UART1_PORT + port_number), 1, /* set */ NULL, 0); } static int TIClearLoopBack (struct edgeport_port *port) { int port_number = port->port->number - port->port->serial->minor; dbg ("%s", __FUNCTION__); return TIWriteCommandSync (port->port->serial->dev, UMPC_SET_CLR_LOOPBACK, (__u8)(UMPM_UART1_PORT + port_number), 0, /* clear */ NULL, 0); } static int TISetBreak (struct edgeport_port *port) { int port_number = port->port->number - port->port->serial->minor; dbg ("%s", __FUNCTION__); return TIWriteCommandSync (port->port->serial->dev, UMPC_SET_CLR_BREAK, (__u8)(UMPM_UART1_PORT + port_number), 1, /* set */ NULL, 0); } static int TIClearBreak (struct edgeport_port *port) { int port_number = port->port->number - port->port->serial->minor; dbg ("%s", __FUNCTION__); return TIWriteCommandSync (port->port->serial->dev, UMPC_SET_CLR_BREAK, (__u8)(UMPM_UART1_PORT + port_number), 0, /* clear */ NULL, 0); } static int TIRestoreMCR (struct edgeport_port *port, __u8 mcr) { int status = 0; dbg ("%s - %x", __FUNCTION__, mcr); if (mcr & MCR_DTR) status = TISetDtr (port); else status = TIClearDtr (port); if (status) return status; if (mcr & MCR_RTS) status = TISetRts (port); else status = TIClearRts (port); if (status) return status; if (mcr & MCR_LOOPBACK) status = TISetLoopBack (port); else status = TIClearLoopBack (port); return status; } /* Convert TI LSR to standard UART flags */ static __u8 MapLineStatus (__u8 ti_lsr) { __u8 lsr = 0; #define MAP_FLAG(flagUmp, flagUart) \ if (ti_lsr & flagUmp) lsr |= flagUart; MAP_FLAG(UMP_UART_LSR_OV_MASK, LSR_OVER_ERR) /* overrun */ MAP_FLAG(UMP_UART_LSR_PE_MASK, LSR_PAR_ERR) /* parity error */ MAP_FLAG(UMP_UART_LSR_FE_MASK, LSR_FRM_ERR) /* framing error */ MAP_FLAG(UMP_UART_LSR_BR_MASK, LSR_BREAK) /* break detected */ MAP_FLAG(UMP_UART_LSR_RX_MASK, LSR_RX_AVAIL) /* receive data available */ MAP_FLAG(UMP_UART_LSR_TX_MASK, LSR_TX_EMPTY) /* transmit holding register empty */ #undef MAP_FLAG return lsr; } static void handle_new_msr (struct edgeport_port *edge_port, __u8 msr) { struct async_icount *icount; dbg ("%s - %02x", __FUNCTION__, msr); if (msr & (EDGEPORT_MSR_DELTA_CTS | EDGEPORT_MSR_DELTA_DSR | EDGEPORT_MSR_DELTA_RI | EDGEPORT_MSR_DELTA_CD)) { icount = &edge_port->icount; /* update input line counters */ if (msr & EDGEPORT_MSR_DELTA_CTS) icount->cts++; if (msr & EDGEPORT_MSR_DELTA_DSR) icount->dsr++; if (msr & EDGEPORT_MSR_DELTA_CD) icount->dcd++; if (msr & EDGEPORT_MSR_DELTA_RI) icount->rng++; wake_up_interruptible (&edge_port->delta_msr_wait); } /* Save the new modem status */ edge_port->shadow_msr = msr & 0xf0; return; } static void handle_new_lsr (struct edgeport_port *edge_port, int lsr_data, __u8 lsr, __u8 data) { struct async_icount *icount; __u8 new_lsr = (__u8)(lsr & (__u8)(LSR_OVER_ERR | LSR_PAR_ERR | LSR_FRM_ERR | LSR_BREAK)); dbg ("%s - %02x", __FUNCTION__, new_lsr); edge_port->shadow_lsr = lsr; if (new_lsr & LSR_BREAK) { /* * Parity and Framing errors only count if they * occur exclusive of a break being received. */ new_lsr &= (__u8)(LSR_OVER_ERR | LSR_BREAK); } /* Place LSR data byte into Rx buffer */ if (lsr_data && edge_port->port->tty) { tty_insert_flip_char(edge_port->port->tty, data, 0); tty_flip_buffer_push(edge_port->port->tty); } /* update input line counters */ icount = &edge_port->icount; if (new_lsr & LSR_BREAK) icount->brk++; if (new_lsr & LSR_OVER_ERR) icount->overrun++; if (new_lsr & LSR_PAR_ERR) icount->parity++; if (new_lsr & LSR_FRM_ERR) icount->frame++; } static void edge_interrupt_callback (struct urb *urb) { struct edgeport_serial *edge_serial = (struct edgeport_serial *)urb->context; struct usb_serial_port *port; struct edgeport_port *edge_port; unsigned char *data = urb->transfer_buffer; int length = urb->actual_length; int port_number; int function; __u8 lsr; __u8 msr; dbg("%s", __FUNCTION__); if (serial_paranoia_check (edge_serial->serial, __FUNCTION__)) { return; } if (urb->status) { dbg("%s - nonzero control read status received: %d", __FUNCTION__, urb->status); return; } if (!length) { dbg ("%s - no data in urb", __FUNCTION__); return; } usb_serial_debug_data (__FILE__, __FUNCTION__, length, data); if (length != 2) { dbg ("%s - expecting packet of size 2, got %d", __FUNCTION__, length); return; } port_number = TIUMP_GET_PORT_FROM_CODE (data[0]); function = TIUMP_GET_FUNC_FROM_CODE (data[0]); dbg ("%s - port_number %d, function %d, info 0x%x", __FUNCTION__, port_number, function, data[1]); port = &edge_serial->serial->port[port_number]; if (port_paranoia_check (port, __FUNCTION__)) { dbg ("%s - change found for port that is not present", __FUNCTION__); return; } edge_port = port->private; if (!edge_port) { dbg ("%s - edge_port not found", __FUNCTION__); return; } switch (function) { case TIUMP_INTERRUPT_CODE_LSR: lsr = MapLineStatus(data[1]); if (lsr & UMP_UART_LSR_DATA_MASK) { /* Save the LSR event for bulk read completion routine */ dbg ("%s - LSR Event Port %u LSR Status = %02x", __FUNCTION__, port_number, lsr); edge_port->lsr_event = 1; edge_port->lsr_mask = lsr; } else { dbg ("%s - ===== Port %d LSR Status = %02x ======", __FUNCTION__, port_number, lsr); handle_new_lsr (edge_port, 0, lsr, 0); } break; case TIUMP_INTERRUPT_CODE_MSR: // MSR /* Copy MSR from UMP */ msr = data[1]; dbg ("%s - ===== Port %u MSR Status = %02x ======\n", __FUNCTION__, port_number, msr); handle_new_msr (edge_port, msr); break; default: err ("%s - Unknown Interrupt code from UMP %x\n", __FUNCTION__, data[1]); break; } } static void edge_bulk_in_callback (struct urb *urb) { struct edgeport_port *edge_port = (struct edgeport_port *)urb->context; unsigned char *data = urb->transfer_buffer; struct tty_struct *tty; int status; int i; int port_number; dbg("%s", __FUNCTION__); if (port_paranoia_check (edge_port->port, __FUNCTION__)) return; if (urb->status) { dbg ("%s - nonzero read bulk status received: %d", __FUNCTION__, urb->status); if (urb->status == -EPIPE) { /* clear any problem that might have happened on this pipe */ usb_clear_halt (edge_port->port->serial->dev, urb->pipe); goto exit; } return; } port_number = edge_port->port->number - edge_port->port->serial->minor; if (edge_port->lsr_event) { edge_port->lsr_event = 0; dbg ("%s ===== Port %u LSR Status = %02x, Data = %02x ======", __FUNCTION__, port_number, edge_port->lsr_mask, *data); handle_new_lsr (edge_port, 1, edge_port->lsr_mask, *data); /* Adjust buffer length/pointer */ --urb->actual_length; ++data; } tty = edge_port->port->tty; if (tty && urb->actual_length) { usb_serial_debug_data (__FILE__, __FUNCTION__, urb->actual_length, data); if (edge_port->close_pending) { dbg ("%s - close is pending, dropping data on the floor.", __FUNCTION__); } else { for (i = 0; i < urb->actual_length ; ++i) { /* if we insert more than TTY_FLIPBUF_SIZE characters, * we drop them. */ if (tty->flip.count >= TTY_FLIPBUF_SIZE) { tty_flip_buffer_push(tty); } /* this doesn't actually push the data through unless * tty->low_latency is set */ tty_insert_flip_char(tty, data[i], 0); } tty_flip_buffer_push(tty); } edge_port->icount.rx += urb->actual_length; } exit: /* continue always trying to read */ urb->dev = edge_port->port->serial->dev; status = usb_submit_urb (urb); if (status) err ("%s - usb_submit_urb failed with result %d", __FUNCTION__, status); } static void edge_bulk_out_callback (struct urb *urb) { struct usb_serial_port *port = (struct usb_serial_port *)urb->context; struct usb_serial *serial = get_usb_serial (port, __FUNCTION__); struct tty_struct *tty; dbg ("%s - port %d", __FUNCTION__, port->number); if (!serial) { dbg ("%s - bad serial pointer, exiting", __FUNCTION__); return; } if (urb->status) { dbg ("%s - nonzero write bulk status received: %d", __FUNCTION__, urb->status); if (urb->status == -EPIPE) { /* clear any problem that might have happened on this pipe */ usb_clear_halt (serial->dev, urb->pipe); } return; } tty = port->tty; if (tty) { /* let the tty driver wakeup if it has a special write_wakeup function */ tty_wakeup(tty); } } static int edge_open (struct usb_serial_port *port, struct file * filp) { struct edgeport_port *edge_port = (struct edgeport_port *)port->private; struct edgeport_serial *edge_serial; struct usb_device *dev; struct urb *urb; int port_number; int status; u16 open_settings; u8 transaction_timeout; if (port_paranoia_check (port, __FUNCTION__)) return -ENODEV; dbg("%s - port %d", __FUNCTION__, port->number); if (edge_port == NULL) return -ENODEV; /* force low_latency on so that our tty_push actually forces the data through, otherwise it is scheduled, and with high data rates (like with OHCI) data can get lost. */ if (port->tty) port->tty->low_latency = 1; port_number = port->number - port->serial->minor; switch (port_number) { case 0: edge_port->uart_base = UMPMEM_BASE_UART1; edge_port->dma_address = UMPD_OEDB1_ADDRESS; break; case 1: edge_port->uart_base = UMPMEM_BASE_UART2; edge_port->dma_address = UMPD_OEDB2_ADDRESS; break; default: err ("Unknown port number!!!"); return -ENODEV; } dbg ("%s - port_number = %d, uart_base = %04x, dma_address = %04x", __FUNCTION__, port_number, edge_port->uart_base, edge_port->dma_address); dev = port->serial->dev; memset (&(edge_port->icount), 0x00, sizeof(edge_port->icount)); init_waitqueue_head (&edge_port->delta_msr_wait); /* turn off loopback */ status = TIClearLoopBack (edge_port); if (status) return status; /* set up the port settings */ edge_set_termios (port, NULL); /* open up the port */ /* milliseconds to timeout for DMA transfer */ transaction_timeout = 2; edge_port->ump_read_timeout = max (20, ((transaction_timeout * 3) / 2) ); // milliseconds to timeout for DMA transfer open_settings = (u8)(UMP_DMA_MODE_CONTINOUS | UMP_PIPE_TRANS_TIMEOUT_ENA | (transaction_timeout << 2)); dbg ("%s - Sending UMPC_OPEN_PORT", __FUNCTION__); /* Tell TI to open and start the port */ status = TIWriteCommandSync (dev, UMPC_OPEN_PORT, (u8)(UMPM_UART1_PORT + port_number), open_settings, NULL, 0); if (status) return status; /* Start the DMA? */ status = TIWriteCommandSync (dev, UMPC_START_PORT, (u8)(UMPM_UART1_PORT + port_number), 0, NULL, 0); if (status) return status; /* Clear TX and RX buffers in UMP */ status = TIPurgeDataSync (port, UMP_PORT_DIR_OUT | UMP_PORT_DIR_IN); if (status) return status; /* Read Initial MSR */ status = TIReadVendorRequestSync (dev, UMPC_READ_MSR, // Request 0, // wValue (__u16)(UMPM_UART1_PORT + port_number), // wIndex (Address) &edge_port->shadow_msr, // TransferBuffer 1); // TransferBufferLength if (status) return status; dbg ("ShadowMSR 0x%X", edge_port->shadow_msr); edge_serial = edge_port->edge_serial; if (edge_serial->num_ports_open == 0) { dbg ("%s - setting up bulk in urb", __FUNCTION__); /* we are the first port to be opened, let's post the interrupt urb */ urb = edge_serial->serial->port[0].interrupt_in_urb; if (!urb) { err ("%s - no interrupt urb present, exiting", __FUNCTION__); return -EINVAL; } urb->complete = edge_interrupt_callback; urb->context = edge_serial; urb->dev = dev; status = usb_submit_urb (urb); if (status) { err ("%s - usb_submit_urb failed with value %d", __FUNCTION__, status); return status; } } /* * reset the data toggle on the bulk endpoints to work around bug in * host controllers where things get out of sync some times */ usb_clear_halt (dev, port->write_urb->pipe); usb_clear_halt (dev, port->read_urb->pipe); /* start up our bulk read urb */ urb = port->read_urb; if (!urb) { err ("%s - no read urb present, exiting", __FUNCTION__); return -EINVAL; } urb->complete = edge_bulk_in_callback; urb->context = edge_port; urb->dev = dev; status = usb_submit_urb (urb); if (status) { err ("%s - read bulk usb_submit_urb failed with value %d", __FUNCTION__, status); return status; } ++edge_serial->num_ports_open; dbg("%s - exited", __FUNCTION__); return 0; } static void edge_close (struct usb_serial_port *port, struct file * filp) { struct usb_serial *serial; struct edgeport_serial *edge_serial; struct edgeport_port *edge_port; int port_number; int status; if (port_paranoia_check (port, __FUNCTION__)) return; dbg("%s - port %d", __FUNCTION__, port->number); serial = get_usb_serial (port, __FUNCTION__); if (!serial) return; edge_serial = (struct edgeport_serial *)serial->private; edge_port = (struct edgeport_port *)port->private; if ((edge_serial == NULL) || (edge_port == NULL)) return; if (serial->dev) { /* The bulkreadcompletion routine will check * this flag and dump add read data */ edge_port->close_pending = 1; /* chase the port close */ TIChasePort (edge_port); usb_unlink_urb (port->read_urb); /* assuming we can still talk to the device, * send a close port command to it */ dbg("%s - send umpc_close_port", __FUNCTION__); port_number = port->number - port->serial->minor; status = TIWriteCommandSync (port->serial->dev, UMPC_CLOSE_PORT, (__u8)(UMPM_UART1_PORT + port_number), 0, NULL, 0); --edge_port->edge_serial->num_ports_open; if (edge_port->edge_serial->num_ports_open <= 0) { /* last port is now closed, let's shut down our interrupt urb */ usb_unlink_urb (serial->port[0].interrupt_in_urb); edge_port->edge_serial->num_ports_open = 0; } edge_port->close_pending = 0; } dbg("%s - exited", __FUNCTION__); } static int edge_write (struct usb_serial_port *port, int from_user, const unsigned char *data, int count) { struct usb_serial *serial = port->serial; struct edgeport_port *edge_port = port->private; int result; dbg("%s - port %d", __FUNCTION__, port->number); if (count == 0) { dbg("%s - write request of 0 bytes", __FUNCTION__); return 0; } if (edge_port == NULL) return -ENODEV; if (edge_port->close_pending == 1) return -ENODEV; if (port->write_urb->status == -EINPROGRESS) { dbg ("%s - already writing", __FUNCTION__); return 0; } count = min (count, port->bulk_out_size); if (from_user) { if (copy_from_user(port->write_urb->transfer_buffer, data, count)) return -EFAULT; } else { memcpy (port->write_urb->transfer_buffer, data, count); } usb_serial_debug_data (__FILE__, __FUNCTION__, count, port->write_urb->transfer_buffer); /* set up our urb */ usb_fill_bulk_urb (port->write_urb, serial->dev, usb_sndbulkpipe (serial->dev, port->bulk_out_endpointAddress), port->write_urb->transfer_buffer, count, edge_bulk_out_callback, port); /* send the data out the bulk port */ result = usb_submit_urb(port->write_urb); if (result) err("%s - failed submitting write urb, error %d", __FUNCTION__, result); else result = count; if (result > 0) edge_port->icount.tx += count; return result; } static int edge_write_room (struct usb_serial_port *port) { struct edgeport_port *edge_port = (struct edgeport_port *)(port->private); int room = 0; dbg("%s", __FUNCTION__); if (edge_port == NULL) return -ENODEV; if (edge_port->close_pending == 1) return -ENODEV; dbg("%s - port %d", __FUNCTION__, port->number); if (port->write_urb->status != -EINPROGRESS) room = port->bulk_out_size; dbg("%s - returns %d", __FUNCTION__, room); return room; } static int edge_chars_in_buffer (struct usb_serial_port *port) { struct edgeport_port *edge_port = (struct edgeport_port *)(port->private); int chars = 0; dbg("%s", __FUNCTION__); if (edge_port == NULL) return -ENODEV; if (edge_port->close_pending == 1) return -ENODEV; dbg("%s - port %d", __FUNCTION__, port->number); if (port->write_urb->status == -EINPROGRESS) chars = port->write_urb->transfer_buffer_length; dbg ("%s - returns %d", __FUNCTION__, chars); return chars; } static void edge_throttle (struct usb_serial_port *port) { struct edgeport_port *edge_port = (struct edgeport_port *)(port->private); struct tty_struct *tty; int status; dbg("%s - port %d", __FUNCTION__, port->number); if (edge_port == NULL) return; tty = port->tty; if (!tty) { dbg ("%s - no tty available", __FUNCTION__); return; } /* if we are implementing XON/XOFF, send the stop character */ if (I_IXOFF(tty)) { unsigned char stop_char = STOP_CHAR(tty); status = edge_write (port, 0, &stop_char, 1); if (status <= 0) { return; } } /* if we are implementing RTS/CTS, toggle that line */ if (tty->termios->c_cflag & CRTSCTS) { status = TIClearRts (edge_port); } usb_unlink_urb (port->read_urb); } static void edge_unthrottle (struct usb_serial_port *port) { struct edgeport_port *edge_port = (struct edgeport_port *)(port->private); struct tty_struct *tty; int status; dbg("%s - port %d", __FUNCTION__, port->number); if (edge_port == NULL) return; tty = port->tty; if (!tty) { dbg ("%s - no tty available", __FUNCTION__); return; } /* if we are implementing XON/XOFF, send the start character */ if (I_IXOFF(tty)) { unsigned char start_char = START_CHAR(tty); status = edge_write (port, 0, &start_char, 1); if (status <= 0) { return; } } /* if we are implementing RTS/CTS, toggle that line */ if (tty->termios->c_cflag & CRTSCTS) { status = TISetRts (edge_port); } port->read_urb->dev = port->serial->dev; status = usb_submit_urb (port->read_urb); if (status) { err ("%s - usb_submit_urb failed with value %d", __FUNCTION__, status); } } static void change_port_settings (struct edgeport_port *edge_port, struct termios *old_termios) { struct ump_uart_config *config; struct tty_struct *tty; int baud; int round; unsigned cflag; int status; int port_number = edge_port->port->number - edge_port->port->serial->minor; dbg("%s - port %d", __FUNCTION__, edge_port->port->number); tty = edge_port->port->tty; if ((!tty) || (!tty->termios)) { dbg("%s - no tty structures", __FUNCTION__); return; } config = kmalloc (sizeof (*config), GFP_KERNEL); if (!config) { err ("%s - out of memory", __FUNCTION__); return; } cflag = tty->termios->c_cflag; config->wFlags = 0; /* These flags must be set */ config->wFlags |= UMP_MASK_UART_FLAGS_RECEIVE_MS_INT; config->wFlags |= UMP_MASK_UART_FLAGS_AUTO_START_ON_ERR; config->bUartMode = 0; switch (cflag & CSIZE) { case CS5: config->bDataBits = UMP_UART_CHAR5BITS; dbg ("%s - data bits = 5", __FUNCTION__); break; case CS6: config->bDataBits = UMP_UART_CHAR6BITS; dbg ("%s - data bits = 6", __FUNCTION__); break; case CS7: config->bDataBits = UMP_UART_CHAR7BITS; dbg ("%s - data bits = 7", __FUNCTION__); break; default: case CS8: config->bDataBits = UMP_UART_CHAR8BITS; dbg ("%s - data bits = 8", __FUNCTION__); break; } if (cflag & PARENB) { if (cflag & PARODD) { config->wFlags |= UMP_MASK_UART_FLAGS_PARITY; config->bParity = UMP_UART_ODDPARITY; dbg("%s - parity = odd", __FUNCTION__); } else { config->wFlags |= UMP_MASK_UART_FLAGS_PARITY; config->bParity = UMP_UART_EVENPARITY; dbg("%s - parity = even", __FUNCTION__); } } else { config->bParity = UMP_UART_NOPARITY; dbg("%s - parity = none", __FUNCTION__); } if (cflag & CSTOPB) { config->bStopBits = UMP_UART_STOPBIT2; dbg("%s - stop bits = 2", __FUNCTION__); } else { config->bStopBits = UMP_UART_STOPBIT1; dbg("%s - stop bits = 1", __FUNCTION__); } /* figure out the flow control settings */ if (cflag & CRTSCTS) { config->wFlags |= UMP_MASK_UART_FLAGS_OUT_X_CTS_FLOW; config->wFlags |= UMP_MASK_UART_FLAGS_RTS_FLOW; dbg("%s - RTS/CTS is enabled", __FUNCTION__); } else { dbg("%s - RTS/CTS is disabled", __FUNCTION__); } /* if we are implementing XON/XOFF, set the start and stop character in the device */ if (I_IXOFF(tty) || I_IXON(tty)) { config->cXon = START_CHAR(tty); config->cXoff = STOP_CHAR(tty); /* if we are implementing INBOUND XON/XOFF */ if (I_IXOFF(tty)) { config->wFlags |= UMP_MASK_UART_FLAGS_IN_X; dbg ("%s - INBOUND XON/XOFF is enabled, XON = %2x, XOFF = %2x", __FUNCTION__, config->cXon, config->cXoff); } else { dbg ("%s - INBOUND XON/XOFF is disabled", __FUNCTION__); } /* if we are implementing OUTBOUND XON/XOFF */ if (I_IXON(tty)) { config->wFlags |= UMP_MASK_UART_FLAGS_OUT_X; dbg ("%s - OUTBOUND XON/XOFF is enabled, XON = %2x, XOFF = %2x", __FUNCTION__, config->cXon, config->cXoff); } else { dbg ("%s - OUTBOUND XON/XOFF is disabled", __FUNCTION__); } } /* Round the baud rate */ baud = tty_get_baud_rate(tty); if (!baud) { /* pick a default, any default... */ baud = 9600; } config->wBaudRate = (__u16)(461550L / baud); round = 4615500L / baud; if ((round - (config->wBaudRate * 10)) >= 5) config->wBaudRate++; dbg ("%s - baud rate = %d, wBaudRate = %d", __FUNCTION__, baud, config->wBaudRate); dbg ("wBaudRate: %d", (int)(461550L / config->wBaudRate)); dbg ("wFlags: 0x%x", config->wFlags); dbg ("bDataBits: %d", config->bDataBits); dbg ("bParity: %d", config->bParity); dbg ("bStopBits: %d", config->bStopBits); dbg ("cXon: %d", config->cXon); dbg ("cXoff: %d", config->cXoff); dbg ("bUartMode: %d", config->bUartMode); /* move the word values into big endian mode */ cpu_to_be16s (&config->wFlags); cpu_to_be16s (&config->wBaudRate); status = TIWriteCommandSync (edge_port->port->serial->dev, UMPC_SET_CONFIG, (__u8)(UMPM_UART1_PORT + port_number), 0, (__u8 *)config, sizeof(*config)); if (status) { dbg ("%s - error %d when trying to write config to device", __FUNCTION__, status); } kfree (config); return; } static void edge_set_termios (struct usb_serial_port *port, struct termios *old_termios) { struct edgeport_port *edge_port = (struct edgeport_port *)(port->private); struct tty_struct *tty = port->tty; unsigned int cflag; if (!port->tty || !port->tty->termios) { dbg ("%s - no tty or termios", __FUNCTION__); return; } cflag = tty->termios->c_cflag; /* check that they really want us to change something */ if (old_termios) { if ((cflag == old_termios->c_cflag) && (RELEVANT_IFLAG(tty->termios->c_iflag) == RELEVANT_IFLAG(old_termios->c_iflag))) { dbg ("%s - nothing to change", __FUNCTION__); return; } } dbg("%s - clfag %08x iflag %08x", __FUNCTION__, tty->termios->c_cflag, RELEVANT_IFLAG(tty->termios->c_iflag)); if (old_termios) { dbg("%s - old clfag %08x old iflag %08x", __FUNCTION__, old_termios->c_cflag, RELEVANT_IFLAG(old_termios->c_iflag)); } dbg("%s - port %d", __FUNCTION__, port->number); if (edge_port == NULL) return; /* change the port settings to the new ones specified */ change_port_settings (edge_port, old_termios); return; } static int set_modem_info (struct edgeport_port *edge_port, unsigned int cmd, unsigned int *value) { unsigned int mcr = edge_port->shadow_mcr; unsigned int arg; if (copy_from_user(&arg, value, sizeof(int))) return -EFAULT; switch (cmd) { case TIOCMBIS: if (arg & TIOCM_RTS) mcr |= MCR_RTS; if (arg & TIOCM_DTR) mcr |= MCR_RTS; if (arg & TIOCM_LOOP) mcr |= MCR_LOOPBACK; break; case TIOCMBIC: if (arg & TIOCM_RTS) mcr &= ~MCR_RTS; if (arg & TIOCM_DTR) mcr &= ~MCR_RTS; if (arg & TIOCM_LOOP) mcr &= ~MCR_LOOPBACK; break; case TIOCMSET: /* turn off the RTS and DTR and LOOPBACK * and then only turn on what was asked to */ mcr &= ~(MCR_RTS | MCR_DTR | MCR_LOOPBACK); mcr |= ((arg & TIOCM_RTS) ? MCR_RTS : 0); mcr |= ((arg & TIOCM_DTR) ? MCR_DTR : 0); mcr |= ((arg & TIOCM_LOOP) ? MCR_LOOPBACK : 0); break; } edge_port->shadow_mcr = mcr; TIRestoreMCR (edge_port, mcr); return 0; } static int get_modem_info (struct edgeport_port *edge_port, unsigned int *value) { unsigned int result = 0; unsigned int msr = edge_port->shadow_msr; unsigned int mcr = edge_port->shadow_mcr; result = ((mcr & MCR_DTR) ? TIOCM_DTR: 0) /* 0x002 */ | ((mcr & MCR_RTS) ? TIOCM_RTS: 0) /* 0x004 */ | ((msr & EDGEPORT_MSR_CTS) ? TIOCM_CTS: 0) /* 0x020 */ | ((msr & EDGEPORT_MSR_CD) ? TIOCM_CAR: 0) /* 0x040 */ | ((msr & EDGEPORT_MSR_RI) ? TIOCM_RI: 0) /* 0x080 */ | ((msr & EDGEPORT_MSR_DSR) ? TIOCM_DSR: 0); /* 0x100 */ dbg("%s -- %x", __FUNCTION__, result); if (copy_to_user(value, &result, sizeof(int))) return -EFAULT; return 0; } static int get_serial_info (struct edgeport_port *edge_port, struct serial_struct * retinfo) { struct serial_struct tmp; if (!retinfo) return -EFAULT; memset(&tmp, 0, sizeof(tmp)); tmp.type = PORT_16550A; tmp.line = edge_port->port->serial->minor; tmp.port = edge_port->port->number; tmp.irq = 0; tmp.flags = ASYNC_SKIP_TEST | ASYNC_AUTO_IRQ; tmp.xmit_fifo_size = edge_port->port->bulk_out_size; tmp.baud_base = 9600; tmp.close_delay = 5*HZ; tmp.closing_wait = 30*HZ; // tmp.custom_divisor = state->custom_divisor; // tmp.hub6 = state->hub6; // tmp.io_type = state->io_type; if (copy_to_user(retinfo, &tmp, sizeof(*retinfo))) return -EFAULT; return 0; } static int edge_ioctl (struct usb_serial_port *port, struct file *file, unsigned int cmd, unsigned long arg) { struct edgeport_port *edge_port = (struct edgeport_port *)(port->private); struct async_icount cnow; struct async_icount cprev; dbg("%s - port %d, cmd = 0x%x", __FUNCTION__, port->number, cmd); switch (cmd) { case TIOCINQ: dbg("%s - (%d) TIOCINQ", __FUNCTION__, port->number); // return get_number_bytes_avail(edge_port, (unsigned int *) arg); break; case TIOCSERGETLSR: dbg("%s - (%d) TIOCSERGETLSR", __FUNCTION__, port->number); // return get_lsr_info(edge_port, (unsigned int *) arg); break; case TIOCMBIS: case TIOCMBIC: case TIOCMSET: dbg("%s - (%d) TIOCMSET/TIOCMBIC/TIOCMSET", __FUNCTION__, port->number); return set_modem_info(edge_port, cmd, (unsigned int *) arg); break; case TIOCMGET: dbg("%s - (%d) TIOCMGET", __FUNCTION__, port->number); return get_modem_info(edge_port, (unsigned int *) arg); break; case TIOCGSERIAL: dbg("%s - (%d) TIOCGSERIAL", __FUNCTION__, port->number); return get_serial_info(edge_port, (struct serial_struct *) arg); break; case TIOCSSERIAL: dbg("%s - (%d) TIOCSSERIAL", __FUNCTION__, port->number); break; case TIOCMIWAIT: dbg("%s - (%d) TIOCMIWAIT", __FUNCTION__, port->number); cprev = edge_port->icount; while (1) { interruptible_sleep_on(&edge_port->delta_msr_wait); /* see if a signal did it */ if (signal_pending(current)) return -ERESTARTSYS; cnow = edge_port->icount; if (cnow.rng == cprev.rng && cnow.dsr == cprev.dsr && cnow.dcd == cprev.dcd && cnow.cts == cprev.cts) return -EIO; /* no change => error */ if (((arg & TIOCM_RNG) && (cnow.rng != cprev.rng)) || ((arg & TIOCM_DSR) && (cnow.dsr != cprev.dsr)) || ((arg & TIOCM_CD) && (cnow.dcd != cprev.dcd)) || ((arg & TIOCM_CTS) && (cnow.cts != cprev.cts)) ) { return 0; } cprev = cnow; } /* not reached */ break; case TIOCGICOUNT: dbg ("%s - (%d) TIOCGICOUNT RX=%d, TX=%d", __FUNCTION__, port->number, edge_port->icount.rx, edge_port->icount.tx); if (copy_to_user((void *)arg, &edge_port->icount, sizeof(edge_port->icount))) return -EFAULT; return 0; } return -ENOIOCTLCMD; } static void edge_break (struct usb_serial_port *port, int break_state) { struct edgeport_port *edge_port = (struct edgeport_port *)(port->private); int status; dbg ("%s - state = %d", __FUNCTION__, break_state); /* chase the port close */ TIChasePort (edge_port); if (break_state == -1) { status = TISetBreak (edge_port); } else { status = TIClearBreak (edge_port); } if (status) { dbg ("%s - error %d sending break set/clear command.", __FUNCTION__, status); } } static int edge_startup (struct usb_serial *serial) { struct edgeport_serial *edge_serial; struct edgeport_port *edge_port; struct usb_device *dev; int status; int i; dev = serial->dev; /* create our private serial structure */ edge_serial = kmalloc (sizeof(struct edgeport_serial), GFP_KERNEL); if (edge_serial == NULL) { err("%s - Out of memory", __FUNCTION__); return -ENOMEM; } memset (edge_serial, 0, sizeof(struct edgeport_serial)); edge_serial->serial = serial; serial->private = edge_serial; status = TIDownloadFirmware (edge_serial); if (status) { kfree (edge_serial); return status; } /* set up our port private structures */ for (i = 0; i < serial->num_ports; ++i) { edge_port = kmalloc (sizeof(struct edgeport_port), GFP_KERNEL); if (edge_port == NULL) { err("%s - Out of memory", __FUNCTION__); return -ENOMEM; } memset (edge_port, 0, sizeof(struct edgeport_port)); edge_port->port = &serial->port[i]; edge_port->edge_serial = edge_serial; serial->port[i].private = edge_port; } return 0; } static void edge_shutdown (struct usb_serial *serial) { int i; dbg ("%s", __FUNCTION__); for (i=0; i < serial->num_ports; ++i) { kfree (serial->port[i].private); serial->port[i].private = NULL; } kfree (serial->private); serial->private = NULL; } static struct usb_serial_device_type edgeport_1port_device = { owner: THIS_MODULE, name: "Edgeport TI 1 port adapter", id_table: edgeport_1port_id_table, num_interrupt_in: 1, num_bulk_in: 1, num_bulk_out: 1, num_ports: 1, open: edge_open, close: edge_close, throttle: edge_throttle, unthrottle: edge_unthrottle, startup: edge_startup, shutdown: edge_shutdown, ioctl: edge_ioctl, set_termios: edge_set_termios, write: edge_write, write_room: edge_write_room, chars_in_buffer: edge_chars_in_buffer, break_ctl: edge_break, }; static struct usb_serial_device_type edgeport_2port_device = { owner: THIS_MODULE, name: "Edgeport TI 2 port adapter", id_table: edgeport_2port_id_table, num_interrupt_in: 1, num_bulk_in: 2, num_bulk_out: 2, num_ports: 2, open: edge_open, close: edge_close, throttle: edge_throttle, unthrottle: edge_unthrottle, startup: edge_startup, shutdown: edge_shutdown, ioctl: edge_ioctl, set_termios: edge_set_termios, write: edge_write, write_room: edge_write_room, chars_in_buffer: edge_chars_in_buffer, break_ctl: edge_break, }; static int __init edgeport_init(void) { usb_serial_register (&edgeport_1port_device); usb_serial_register (&edgeport_2port_device); info(DRIVER_DESC " " DRIVER_VERSION); return 0; } static void __exit edgeport_exit (void) { usb_serial_deregister (&edgeport_1port_device); usb_serial_deregister (&edgeport_2port_device); } module_init(edgeport_init); module_exit(edgeport_exit); /* Module information */ MODULE_AUTHOR(DRIVER_AUTHOR); MODULE_DESCRIPTION(DRIVER_DESC); MODULE_LICENSE("GPL"); MODULE_PARM(debug, "i"); MODULE_PARM_DESC(debug, "Debug enabled or not"); MODULE_PARM(ignore_cpu_rev, "i"); MODULE_PARM_DESC(ignore_cpu_rev, "Ignore the cpu revision when connecting to a device");