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ahc_pci.c: ahd_pci.c: aic7xxx.c: aic79xx.c: aic_osm_lib.c: aic_osm_lib.h: Use common OSM routines from aic_osm_lib for bus dma operations, delay routines, accessing CCBs, byte swapping, etc. aic7xxx_pci.c: Provide a better description for the 2915/30LP on attach. aic7xxx.c: aic79xx.c: aic7770.c: aic79xx_pci.c: aic7xxx_pci.c: aic7xxx_93cx6.c: Move FBSDID behind an ifdef so that these core files will still compile under other OSes. aic79xx.h: aic79xx_pci.c: aic79xx.seq: To speed up non-packetized CDB delivery in Rev B, all CDB acks are "released" to the output sync as soon as the command phase starts. There is only one problem with this approach. If the target changes phase before all data are sent, we have left over acks that can go out on the bus in a data phase. Due to other chip contraints, this only happens if the target goes to data-in, but if the acks go out before we can test SDONE, we'll think that the transfer has completed successfully. Work around this by taking advantage of the 400ns or 800ns dead time between command phase and the REQ of the new phase. If the transfer has completed successfully, SCSIEN should fall *long* before we see a phase change. We thus treat any phasemiss that occurs before SCSIEN falls as an incomplete transfer. aic79xx.h: Add the AHD_FAST_CDB_DELIVERY feature. aic79xx_pci.c: Set AHD_FAST_CDB_DELIVERY for all Rev. B parts. aic79xx.seq: Test for PHASEMIS in the command phase for all AHD_FAST_CDB_DELIVERY controlelrs. ahd_pci.c: ahc_pci.c: aic7xxx.h: aic79xx.h: Move definition of controller BAR offsets to core header files. aic7xxx.c: aic79xx.c: In the softc free routine, leave removal of a softc from the global list of softcs to the OSM (the caller of this routine). This allows us to avoid holding the softc list_lock during device destruction where we may have to sleep waiting for our recovery thread to halt. ahc_pci.c: Use ahc_pci_test_register access to validate I/O mapped in addition to the tests already performed for memory mapped access. Remove unused ahc_power_state_change() function. The PCI layer in both 4.X and 5.X now offer this functionality. ahd_pci.c: Remove reduntant definition of controller BAR offsets. These are also defined in aic79xx.h. Remove unused ahd_power_state_change() function. The PCI layer in both 4.X and 5.X now offer this functionality. aic7xxx.c: aic79xx.c: aic79xx.h: aic7xxx.h: aic7xxx_osm.c: aic79xx_osm.c: Move timeout handling to the driver cores. In the case of the aic79xx driver, the algorithm has been enhanced to try target resets before performing a bus reset. For the aic7xxx driver, the algorithm is unchanged. Although the drivers do not currently sleep during recovery (recovery is timeout driven), the cores do expect all processing to be performed via a recovery thread. Our timeout handlers are now little stubs that wakeup the recovery thread. aic79xx.c: aic79xx.h: aic79xx_inline.h: Change shared_data allocation to use a map_node so that the sentinel hscb can use this map node in ahd_swap_with_next_hscb. This routine now swaps the hscb_map pointer in additon to the hscb contents so that any sync operations occur on the correct map. physaddr -> busaddr Pointed out by: Jason Thorpe <thorpej@wasabisystems.com> aic79xx.c: Make more use of the in/out/w/l/q macros for accessing byte registers in the chip. Correct some issues in the ahd_flush_qoutfifo() routine. o Run the qoutfifo only once the command channel DMA engine has been halted. This closes a window where we might have missed some entries. o Change ahd_run_data_fifo() to not loop to completion. If we happen to start on the wrong FIFO and the other FIFO has a snapshot savepointers, we might deadlock. This required our delay between FIFO tests to be moved to the ahd_flush_qoutfifo() routine. o Update/add comments. o Remove spurious test for COMPLETE_DMA list being empty when completing transactions from the GSFIFO with residuals. The SCB must be put on the COMPLETE_DMA scb list unconditionally. o When halting command channel DMA activity, we must disable the DMA channel in all cases but an update of the QOUTFIFO. The latter case is required so that the sequencer will update its position in the QOUTFIFO. Previously, we left the channel enabled for all "push" DMAs. This left us vulnerable to the sequencer handling an SCB push long after that SCB was already processed manually by this routine. o Correct the polarity of tests involving ahd_scb_active_in_fifo(). This routine returns non-zero for true. Return to processing bad status completions through the qoutfifo. This reduces the time that the sequencer is kept paused when handling transactions with bad status or underruns. When waiting for the controller to quiece selections, add a delay to our loop. Otherwise we may fail to wait long enough for the sequencer to comply. On H2A4 hardware, use the slow slewrate for non-paced transfers. This mirrors what the Adaptec Windows drivers do. On the Rev B. only slow down the CRC timing for older U160 devices that might need the slower timing. We define "older" as devices that do not support packetized protocol. Wait up to 5000 * 5us for the SEEPROM to become unbusy. Write ops seem to take much longer than read ops. aic79xx.seq: For controllers with the FAINT_LED bug, turn the diagnostic led feature on during selection and reselection. This covers the non-packetized case. The LED will be disabled for non-packetized transfers once we return to the top level idle loop. Add more comments about the busy LED workaround. Extend a critical section around the entire command channel idle loop process. Previously the portion of this handler that directly manipulated the linked list of completed SCBs was not protected. This is the likely cause of the recent reports of commands being completed twice by the driver. Extend critical sections across the test for, and the longjump to, longjump routines. This prevents the firmware from trying to jump to a longjmp handler that was just cleared by the host. Improve the locations of several critical section begin and end points. Typically these changes remove instructions that did not need to be inside a critical section. Close the "busfree after selection, but before busfree interrupts can be enabled" race to just a single sequencer instruction. We now test the BSY line explicitly before clearing the busfree status and enabling the busfree interrupt. Close a race condition in the processing of HS_MAILBOX updates. We now clear the "updated" status before the copy. This ensures that we don't accidentally clear the status incorrectly when the host sneaks in an update just after our last copy, but before we clear the status. This race has never been observed. Don't re-enable SCSIEN if we lose the race to disable SCSIEN in our interrupt handler's workaround for the RevA data-valid too early issue. aic79xx_inline.h: Add comments indicating that the order in which bytes are read or written in ahd_inw and ahd_outw is important. This allows us to use these inlines when accessing registers with side-effects. aic79xx_pci.c: The 29320 and the 29320B are 7902 not 7901 based products. Correct the driver banner. aic7xxx.h: Enable the use of the auto-access pause feature on the aic7870 and aic7880. It was disabled due to an oversight. aic7xxx.reg: Move TARG_IMMEDIATE_SCB to alias LAST_MSG to avoid leaving garbage in MWI_RESIDUAL. This prevents spurious overflows whn operating target mode on controllers that require the MWI_RESIDUAL work-around. aic7xxx.seq: AHC_TMODE_WIDEODD_BUG is a bug, not a softc flag. Reference the correct softc field when testing for its presence. Set the NOT_IDENTIFIED and NO_CDB_SENT bits in SEQ_FLAGS to indicate that the nexus is invalid in await busfree. aic7xxx_93cx6.c: Add support for the C56/C66 versions of the EWEN and EWDS commands. aic7xxx.c: aic7xxx_pci.c: Move test for the validity of left over BIOS data to ahc_test_register_access(). This guarantees that any left over CHIPRST value is not clobbered by our register access test and lost to the test that was in ahc_reset.
327 lines
9.5 KiB
C
327 lines
9.5 KiB
C
/*
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* Interface for the 93C66/56/46/26/06 serial eeprom parts.
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*
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* Copyright (c) 1995, 1996 Daniel M. Eischen
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* All rights reserved.
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*
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* Redistribution and use in source and binary forms, with or without
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* modification, are permitted provided that the following conditions
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* are met:
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* 1. Redistributions of source code must retain the above copyright
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* notice, this list of conditions, and the following disclaimer,
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* without modification.
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* 2. The name of the author may not be used to endorse or promote products
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* derived from this software without specific prior written permission.
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*
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* Alternatively, this software may be distributed under the terms of the
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* GNU General Public License ("GPL").
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*
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* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
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* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE FOR
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* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
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* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
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* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
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* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
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* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
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* SUCH DAMAGE.
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*
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* $Id: //depot/aic7xxx/aic7xxx/aic7xxx_93cx6.c#19 $
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*/
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/*
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* The instruction set of the 93C66/56/46/26/06 chips are as follows:
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*
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* Start OP *
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* Function Bit Code Address** Data Description
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* -------------------------------------------------------------------
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* READ 1 10 A5 - A0 Reads data stored in memory,
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* starting at specified address
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* EWEN 1 00 11XXXX Write enable must precede
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* all programming modes
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* ERASE 1 11 A5 - A0 Erase register A5A4A3A2A1A0
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* WRITE 1 01 A5 - A0 D15 - D0 Writes register
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* ERAL 1 00 10XXXX Erase all registers
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* WRAL 1 00 01XXXX D15 - D0 Writes to all registers
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* EWDS 1 00 00XXXX Disables all programming
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* instructions
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* *Note: A value of X for address is a don't care condition.
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* **Note: There are 8 address bits for the 93C56/66 chips unlike
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* the 93C46/26/06 chips which have 6 address bits.
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*
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* The 93C46 has a four wire interface: clock, chip select, data in, and
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* data out. In order to perform one of the above functions, you need
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* to enable the chip select for a clock period (typically a minimum of
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* 1 usec, with the clock high and low a minimum of 750 and 250 nsec
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* respectively). While the chip select remains high, you can clock in
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* the instructions (above) starting with the start bit, followed by the
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* OP code, Address, and Data (if needed). For the READ instruction, the
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* requested 16-bit register contents is read from the data out line but
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* is preceded by an initial zero (leading 0, followed by 16-bits, MSB
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* first). The clock cycling from low to high initiates the next data
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* bit to be sent from the chip.
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*/
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#ifdef __linux__
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#include "aic7xxx_osm.h"
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#include "aic7xxx_inline.h"
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#include "aic7xxx_93cx6.h"
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#else
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#include <sys/cdefs.h>
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__FBSDID("$FreeBSD$");
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#include <dev/aic7xxx/aic7xxx_osm.h>
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#include <dev/aic7xxx/aic7xxx_inline.h>
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#include <dev/aic7xxx/aic7xxx_93cx6.h>
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#endif
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/*
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* Right now, we only have to read the SEEPROM. But we make it easier to
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* add other 93Cx6 functions.
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*/
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struct seeprom_cmd {
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uint8_t len;
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uint8_t bits[11];
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};
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/* Short opcodes for the c46 */
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static struct seeprom_cmd seeprom_ewen = {9, {1, 0, 0, 1, 1, 0, 0, 0, 0}};
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static struct seeprom_cmd seeprom_ewds = {9, {1, 0, 0, 0, 0, 0, 0, 0, 0}};
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/* Long opcodes for the C56/C66 */
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static struct seeprom_cmd seeprom_long_ewen = {11, {1, 0, 0, 1, 1, 0, 0, 0, 0}};
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static struct seeprom_cmd seeprom_long_ewds = {11, {1, 0, 0, 0, 0, 0, 0, 0, 0}};
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/* Common opcodes */
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static struct seeprom_cmd seeprom_write = {3, {1, 0, 1}};
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static struct seeprom_cmd seeprom_read = {3, {1, 1, 0}};
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/*
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* Wait for the SEERDY to go high; about 800 ns.
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*/
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#define CLOCK_PULSE(sd, rdy) \
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while ((SEEPROM_STATUS_INB(sd) & rdy) == 0) { \
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; /* Do nothing */ \
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} \
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(void)SEEPROM_INB(sd); /* Clear clock */
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/*
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* Send a START condition and the given command
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*/
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static void
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send_seeprom_cmd(struct seeprom_descriptor *sd, struct seeprom_cmd *cmd)
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{
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uint8_t temp;
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int i = 0;
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/* Send chip select for one clock cycle. */
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temp = sd->sd_MS ^ sd->sd_CS;
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SEEPROM_OUTB(sd, temp ^ sd->sd_CK);
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CLOCK_PULSE(sd, sd->sd_RDY);
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for (i = 0; i < cmd->len; i++) {
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if (cmd->bits[i] != 0)
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temp ^= sd->sd_DO;
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SEEPROM_OUTB(sd, temp);
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CLOCK_PULSE(sd, sd->sd_RDY);
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SEEPROM_OUTB(sd, temp ^ sd->sd_CK);
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CLOCK_PULSE(sd, sd->sd_RDY);
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if (cmd->bits[i] != 0)
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temp ^= sd->sd_DO;
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}
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}
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/*
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* Clear CS put the chip in the reset state, where it can wait for new commands.
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*/
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static void
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reset_seeprom(struct seeprom_descriptor *sd)
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{
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uint8_t temp;
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temp = sd->sd_MS;
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SEEPROM_OUTB(sd, temp);
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CLOCK_PULSE(sd, sd->sd_RDY);
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SEEPROM_OUTB(sd, temp ^ sd->sd_CK);
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CLOCK_PULSE(sd, sd->sd_RDY);
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SEEPROM_OUTB(sd, temp);
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CLOCK_PULSE(sd, sd->sd_RDY);
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}
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/*
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* Read the serial EEPROM and returns 1 if successful and 0 if
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* not successful.
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*/
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int
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ahc_read_seeprom(struct seeprom_descriptor *sd, uint16_t *buf,
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u_int start_addr, u_int count)
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{
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int i = 0;
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u_int k = 0;
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uint16_t v;
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uint8_t temp;
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/*
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* Read the requested registers of the seeprom. The loop
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* will range from 0 to count-1.
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*/
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for (k = start_addr; k < count + start_addr; k++) {
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/*
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* Now we're ready to send the read command followed by the
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* address of the 16-bit register we want to read.
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*/
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send_seeprom_cmd(sd, &seeprom_read);
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/* Send the 6 or 8 bit address (MSB first, LSB last). */
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temp = sd->sd_MS ^ sd->sd_CS;
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for (i = (sd->sd_chip - 1); i >= 0; i--) {
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if ((k & (1 << i)) != 0)
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temp ^= sd->sd_DO;
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SEEPROM_OUTB(sd, temp);
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CLOCK_PULSE(sd, sd->sd_RDY);
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SEEPROM_OUTB(sd, temp ^ sd->sd_CK);
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CLOCK_PULSE(sd, sd->sd_RDY);
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if ((k & (1 << i)) != 0)
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temp ^= sd->sd_DO;
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}
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/*
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* Now read the 16 bit register. An initial 0 precedes the
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* register contents which begins with bit 15 (MSB) and ends
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* with bit 0 (LSB). The initial 0 will be shifted off the
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* top of our word as we let the loop run from 0 to 16.
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*/
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v = 0;
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for (i = 16; i >= 0; i--) {
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SEEPROM_OUTB(sd, temp);
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CLOCK_PULSE(sd, sd->sd_RDY);
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v <<= 1;
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if (SEEPROM_DATA_INB(sd) & sd->sd_DI)
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v |= 1;
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SEEPROM_OUTB(sd, temp ^ sd->sd_CK);
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CLOCK_PULSE(sd, sd->sd_RDY);
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}
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buf[k - start_addr] = v;
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/* Reset the chip select for the next command cycle. */
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reset_seeprom(sd);
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}
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#ifdef AHC_DUMP_EEPROM
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printf("\nSerial EEPROM:\n\t");
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for (k = 0; k < count; k = k + 1) {
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if (((k % 8) == 0) && (k != 0)) {
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printf ("\n\t");
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}
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printf (" 0x%x", buf[k]);
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}
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printf ("\n");
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#endif
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return (1);
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}
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/*
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* Write the serial EEPROM and return 1 if successful and 0 if
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* not successful.
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*/
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int
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ahc_write_seeprom(struct seeprom_descriptor *sd, uint16_t *buf,
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u_int start_addr, u_int count)
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{
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struct seeprom_cmd *ewen, *ewds;
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uint16_t v;
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uint8_t temp;
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int i, k;
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/* Place the chip into write-enable mode */
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if (sd->sd_chip == C46) {
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ewen = &seeprom_ewen;
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ewds = &seeprom_ewds;
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} else if (sd->sd_chip == C56_66) {
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ewen = &seeprom_long_ewen;
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ewds = &seeprom_long_ewds;
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} else {
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printf("ahc_write_seeprom: unsupported seeprom type %d\n",
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sd->sd_chip);
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return (0);
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}
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send_seeprom_cmd(sd, ewen);
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reset_seeprom(sd);
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/* Write all requested data out to the seeprom. */
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temp = sd->sd_MS ^ sd->sd_CS;
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for (k = start_addr; k < count + start_addr; k++) {
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/* Send the write command */
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send_seeprom_cmd(sd, &seeprom_write);
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/* Send the 6 or 8 bit address (MSB first). */
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for (i = (sd->sd_chip - 1); i >= 0; i--) {
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if ((k & (1 << i)) != 0)
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temp ^= sd->sd_DO;
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SEEPROM_OUTB(sd, temp);
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CLOCK_PULSE(sd, sd->sd_RDY);
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SEEPROM_OUTB(sd, temp ^ sd->sd_CK);
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CLOCK_PULSE(sd, sd->sd_RDY);
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if ((k & (1 << i)) != 0)
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temp ^= sd->sd_DO;
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}
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/* Write the 16 bit value, MSB first */
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v = buf[k - start_addr];
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for (i = 15; i >= 0; i--) {
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if ((v & (1 << i)) != 0)
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temp ^= sd->sd_DO;
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SEEPROM_OUTB(sd, temp);
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CLOCK_PULSE(sd, sd->sd_RDY);
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SEEPROM_OUTB(sd, temp ^ sd->sd_CK);
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CLOCK_PULSE(sd, sd->sd_RDY);
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if ((v & (1 << i)) != 0)
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temp ^= sd->sd_DO;
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}
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/* Wait for the chip to complete the write */
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temp = sd->sd_MS;
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SEEPROM_OUTB(sd, temp);
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CLOCK_PULSE(sd, sd->sd_RDY);
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temp = sd->sd_MS ^ sd->sd_CS;
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do {
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SEEPROM_OUTB(sd, temp);
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CLOCK_PULSE(sd, sd->sd_RDY);
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SEEPROM_OUTB(sd, temp ^ sd->sd_CK);
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CLOCK_PULSE(sd, sd->sd_RDY);
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} while ((SEEPROM_DATA_INB(sd) & sd->sd_DI) == 0);
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reset_seeprom(sd);
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}
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/* Put the chip back into write-protect mode */
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send_seeprom_cmd(sd, ewds);
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reset_seeprom(sd);
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return (1);
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}
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int
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ahc_verify_cksum(struct seeprom_config *sc)
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{
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int i;
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int maxaddr;
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uint32_t checksum;
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uint16_t *scarray;
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maxaddr = (sizeof(*sc)/2) - 1;
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checksum = 0;
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scarray = (uint16_t *)sc;
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for (i = 0; i < maxaddr; i++)
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checksum = checksum + scarray[i];
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if (checksum == 0
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|| (checksum & 0xFFFF) != sc->checksum) {
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return (0);
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} else {
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return(1);
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}
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}
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