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linux/drivers/net/fddi/defza.h

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FDDI: defza: Fix SPDX annotation The SPDX annotation for this driver does not match the license text, which specifies GNU GPL 2 or later. Make the two match by correcting the SPDX tag. Signed-off-by: Maciej W. Rozycki <macro@linux-mips.org> Signed-off-by: David S. Miller <davem@davemloft.net>
2018-11-07 15:06:52 +03:00
/* SPDX-License-Identifier: GPL-2.0+ */
FDDI: defza: Add support for DEC FDDIcontroller 700 TURBOchannel adapter Add support for the DEC FDDIcontroller 700 (DEFZA), Digital Equipment Corporation's first-generation FDDI network interface adapter, made for TURBOchannel and based on a discrete version of what eventually became Motorola's widely used CAMEL chipset. The CAMEL chipset is present for example in the DEC FDDIcontroller TURBOchannel, EISA and PCI adapters (DEFTA/DEFEA/DEFPA) that we support with the `defxx' driver, however the host bus interface logic and the firmware API are different in the DEFZA and hence a separate driver is required. There isn't much to say about the driver except that it works, but there is one peculiarity to mention. The adapter implements two Tx/Rx queue pairs. Of these one pair is the usual network Tx/Rx queue pair, in this case used by the adapter to exchange frames with the ring, via the RMC (Ring Memory Controller) chip. The Tx queue is handled directly by the RMC chip and resides in onboard packet memory. The Rx queue is maintained via DMA in host memory by adapter's firmware copying received data stored by the RMC in onboard packet memory. The other pair is used to communicate SMT frames with adapter's firmware. Any SMT frame received from the RMC via the Rx queue must be queued back by the driver to the SMT Rx queue for the firmware to process. Similarly the firmware uses the SMT Tx queue to supply the driver with SMT frames that must be queued back to the Tx queue for the RMC to send to the ring. This solution was chosen because the designers ran out of PCB space and could not squeeze in more logic onto the board that would be required to handle this SMT frame traffic without the need to involve the driver, as with the later DEFTA/DEFEA/DEFPA adapters. Finally the driver does some Frame Control byte decoding, so to avoid magic numbers some macros are added to <linux/if_fddi.h>. Signed-off-by: Maciej W. Rozycki <macro@linux-mips.org> Signed-off-by: David S. Miller <davem@davemloft.net>
2018-10-10 01:57:43 +03:00
/* FDDI network adapter driver for DEC FDDIcontroller 700/700-C devices.
*
* Copyright (c) 2018 Maciej W. Rozycki
*
* 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.
*
* References:
*
* Dave Sawyer & Phil Weeks & Frank Itkowsky,
* "DEC FDDIcontroller 700 Port Specification",
* Revision 1.1, Digital Equipment Corporation
*/
#include <linux/compiler.h>
#include <linux/if_fddi.h>
#include <linux/spinlock.h>
#include <linux/timer.h>
#include <linux/types.h>
/* IOmem register offsets. */
#define FZA_REG_BASE 0x100000 /* register base address */
#define FZA_REG_RESET 0x100200 /* reset, r/w */
#define FZA_REG_INT_EVENT 0x100400 /* interrupt event, r/w1c */
#define FZA_REG_STATUS 0x100402 /* status, r/o */
#define FZA_REG_INT_MASK 0x100404 /* interrupt mask, r/w */
#define FZA_REG_CONTROL_A 0x100500 /* control A, r/w1s */
#define FZA_REG_CONTROL_B 0x100502 /* control B, r/w */
/* Reset register constants. Bits 1:0 are r/w, others are fixed at 0. */
#define FZA_RESET_DLU 0x0002 /* OR with INIT to blast flash memory */
#define FZA_RESET_INIT 0x0001 /* switch into the reset state */
#define FZA_RESET_CLR 0x0000 /* run self-test and return to work */
/* Interrupt event register constants. All bits are r/w1c. */
#define FZA_EVENT_DLU_DONE 0x0800 /* flash memory write complete */
#define FZA_EVENT_FLUSH_TX 0x0400 /* transmit ring flush request */
#define FZA_EVENT_PM_PARITY_ERR 0x0200 /* onboard packet memory parity err */
#define FZA_EVENT_HB_PARITY_ERR 0x0100 /* host bus parity error */
#define FZA_EVENT_NXM_ERR 0x0080 /* non-existent memory access error;
* also raised for unaligned and
* unsupported partial-word accesses
*/
#define FZA_EVENT_LINK_ST_CHG 0x0040 /* link status change */
#define FZA_EVENT_STATE_CHG 0x0020 /* adapter state change */
#define FZA_EVENT_UNS_POLL 0x0010 /* unsolicited event service request */
#define FZA_EVENT_CMD_DONE 0x0008 /* command done ack */
#define FZA_EVENT_SMT_TX_POLL 0x0004 /* SMT frame transmit request */
#define FZA_EVENT_RX_POLL 0x0002 /* receive request (packet avail.) */
#define FZA_EVENT_TX_DONE 0x0001 /* RMC transmit done ack */
/* Status register constants. All bits are r/o. */
#define FZA_STATUS_DLU_SHIFT 0xc /* down line upgrade status bits */
#define FZA_STATUS_DLU_MASK 0x03
#define FZA_STATUS_LINK_SHIFT 0xb /* link status bits */
#define FZA_STATUS_LINK_MASK 0x01
#define FZA_STATUS_STATE_SHIFT 0x8 /* adapter state bits */
#define FZA_STATUS_STATE_MASK 0x07
#define FZA_STATUS_HALT_SHIFT 0x0 /* halt reason bits */
#define FZA_STATUS_HALT_MASK 0xff
#define FZA_STATUS_TEST_SHIFT 0x0 /* test failure bits */
#define FZA_STATUS_TEST_MASK 0xff
#define FZA_STATUS_GET_DLU(x) (((x) >> FZA_STATUS_DLU_SHIFT) & \
FZA_STATUS_DLU_MASK)
#define FZA_STATUS_GET_LINK(x) (((x) >> FZA_STATUS_LINK_SHIFT) & \
FZA_STATUS_LINK_MASK)
#define FZA_STATUS_GET_STATE(x) (((x) >> FZA_STATUS_STATE_SHIFT) & \
FZA_STATUS_STATE_MASK)
#define FZA_STATUS_GET_HALT(x) (((x) >> FZA_STATUS_HALT_SHIFT) & \
FZA_STATUS_HALT_MASK)
#define FZA_STATUS_GET_TEST(x) (((x) >> FZA_STATUS_TEST_SHIFT) & \
FZA_STATUS_TEST_MASK)
#define FZA_DLU_FAILURE 0x0 /* DLU catastrophic error; brain dead */
#define FZA_DLU_ERROR 0x1 /* DLU error; old firmware intact */
#define FZA_DLU_SUCCESS 0x2 /* DLU OK; new firmware loaded */
#define FZA_LINK_OFF 0x0 /* link unavailable */
#define FZA_LINK_ON 0x1 /* link available */
#define FZA_STATE_RESET 0x0 /* resetting */
#define FZA_STATE_UNINITIALIZED 0x1 /* after a reset */
#define FZA_STATE_INITIALIZED 0x2 /* initialized */
#define FZA_STATE_RUNNING 0x3 /* running (link active) */
#define FZA_STATE_MAINTENANCE 0x4 /* running (link looped back) */
#define FZA_STATE_HALTED 0x5 /* halted (error condition) */
#define FZA_HALT_UNKNOWN 0x00 /* unknown reason */
#define FZA_HALT_HOST 0x01 /* host-directed HALT */
#define FZA_HALT_HB_PARITY 0x02 /* host bus parity error */
#define FZA_HALT_NXM 0x03 /* adapter non-existent memory ref. */
#define FZA_HALT_SW 0x04 /* adapter software fault */
#define FZA_HALT_HW 0x05 /* adapter hardware fault */
#define FZA_HALT_PC_TRACE 0x06 /* PC Trace path test */
#define FZA_HALT_DLSW 0x07 /* data link software fault */
#define FZA_HALT_DLHW 0x08 /* data link hardware fault */
#define FZA_TEST_FATAL 0x00 /* self-test catastrophic failure */
#define FZA_TEST_68K 0x01 /* 68000 CPU */
#define FZA_TEST_SRAM_BWADDR 0x02 /* SRAM byte/word address */
#define FZA_TEST_SRAM_DBUS 0x03 /* SRAM data bus */
#define FZA_TEST_SRAM_STUCK1 0x04 /* SRAM stuck-at range 1 */
#define FZA_TEST_SRAM_STUCK2 0x05 /* SRAM stuck-at range 2 */
#define FZA_TEST_SRAM_COUPL1 0x06 /* SRAM coupling range 1 */
#define FZA_TEST_SRAM_COUPL2 0x07 /* SRAM coupling */
#define FZA_TEST_FLASH_CRC 0x08 /* Flash CRC */
#define FZA_TEST_ROM 0x09 /* option ROM */
#define FZA_TEST_PHY_CSR 0x0a /* PHY CSR */
#define FZA_TEST_MAC_BIST 0x0b /* MAC BiST */
#define FZA_TEST_MAC_CSR 0x0c /* MAC CSR */
#define FZA_TEST_MAC_ADDR_UNIQ 0x0d /* MAC unique address */
#define FZA_TEST_ELM_BIST 0x0e /* ELM BiST */
#define FZA_TEST_ELM_CSR 0x0f /* ELM CSR */
#define FZA_TEST_ELM_ADDR_UNIQ 0x10 /* ELM unique address */
#define FZA_TEST_CAM 0x11 /* CAM */
#define FZA_TEST_NIROM 0x12 /* NI ROM checksum */
#define FZA_TEST_SC_LOOP 0x13 /* SC loopback packet */
#define FZA_TEST_LM_LOOP 0x14 /* LM loopback packet */
#define FZA_TEST_EB_LOOP 0x15 /* EB loopback packet */
#define FZA_TEST_SC_LOOP_BYPS 0x16 /* SC bypass loopback packet */
#define FZA_TEST_LM_LOOP_LOCAL 0x17 /* LM local loopback packet */
#define FZA_TEST_EB_LOOP_LOCAL 0x18 /* EB local loopback packet */
#define FZA_TEST_CDC_LOOP 0x19 /* CDC loopback packet */
#define FZA_TEST_FIBER_LOOP 0x1A /* FIBER loopback packet */
#define FZA_TEST_CAM_MATCH_LOOP 0x1B /* CAM match packet loopback */
#define FZA_TEST_68K_IRQ_STUCK 0x1C /* 68000 interrupt line stuck-at */
#define FZA_TEST_IRQ_PRESENT 0x1D /* interrupt present register */
#define FZA_TEST_RMC_BIST 0x1E /* RMC BiST */
#define FZA_TEST_RMC_CSR 0x1F /* RMC CSR */
#define FZA_TEST_RMC_ADDR_UNIQ 0x20 /* RMC unique address */
#define FZA_TEST_PM_DPATH 0x21 /* packet memory data path */
#define FZA_TEST_PM_ADDR 0x22 /* packet memory address */
#define FZA_TEST_RES_23 0x23 /* reserved */
#define FZA_TEST_PM_DESC 0x24 /* packet memory descriptor */
#define FZA_TEST_PM_OWN 0x25 /* packet memory own bit */
#define FZA_TEST_PM_PARITY 0x26 /* packet memory parity */
#define FZA_TEST_PM_BSWAP 0x27 /* packet memory byte swap */
#define FZA_TEST_PM_WSWAP 0x28 /* packet memory word swap */
#define FZA_TEST_PM_REF 0x29 /* packet memory refresh */
#define FZA_TEST_PM_CSR 0x2A /* PM CSR */
#define FZA_TEST_PORT_STATUS 0x2B /* port status register */
#define FZA_TEST_HOST_IRQMASK 0x2C /* host interrupt mask */
#define FZA_TEST_TIMER_IRQ1 0x2D /* RTOS timer */
#define FZA_TEST_FORCE_IRQ1 0x2E /* force RTOS IRQ1 */
#define FZA_TEST_TIMER_IRQ5 0x2F /* IRQ5 backoff timer */
#define FZA_TEST_FORCE_IRQ5 0x30 /* force IRQ5 */
#define FZA_TEST_RES_31 0x31 /* reserved */
#define FZA_TEST_IC_PRIO 0x32 /* interrupt controller priority */
#define FZA_TEST_PM_FULL 0x33 /* full packet memory */
#define FZA_TEST_PMI_DMA 0x34 /* PMI DMA */
/* Interrupt mask register constants. All bits are r/w. */
#define FZA_MASK_RESERVED 0xf000 /* unused */
#define FZA_MASK_DLU_DONE 0x0800 /* flash memory write complete */
#define FZA_MASK_FLUSH_TX 0x0400 /* transmit ring flush request */
#define FZA_MASK_PM_PARITY_ERR 0x0200 /* onboard packet memory parity error
*/
#define FZA_MASK_HB_PARITY_ERR 0x0100 /* host bus parity error */
#define FZA_MASK_NXM_ERR 0x0080 /* adapter non-existent memory
* reference
*/
#define FZA_MASK_LINK_ST_CHG 0x0040 /* link status change */
#define FZA_MASK_STATE_CHG 0x0020 /* adapter state change */
#define FZA_MASK_UNS_POLL 0x0010 /* unsolicited event service request */
#define FZA_MASK_CMD_DONE 0x0008 /* command ring entry processed */
#define FZA_MASK_SMT_TX_POLL 0x0004 /* SMT frame transmit request */
#define FZA_MASK_RCV_POLL 0x0002 /* receive request (packet available)
*/
#define FZA_MASK_TX_DONE 0x0001 /* RMC transmit done acknowledge */
/* Which interrupts to receive: 0/1 is mask/unmask. */
#define FZA_MASK_NONE 0x0000
#define FZA_MASK_NORMAL \
((~(FZA_MASK_RESERVED | FZA_MASK_DLU_DONE | \
FZA_MASK_PM_PARITY_ERR | FZA_MASK_HB_PARITY_ERR | \
FZA_MASK_NXM_ERR)) & 0xffff)
/* Control A register constants. */
#define FZA_CONTROL_A_HB_PARITY_ERR 0x8000 /* host bus parity error */
#define FZA_CONTROL_A_NXM_ERR 0x4000 /* adapter non-existent memory
* reference
*/
#define FZA_CONTROL_A_SMT_RX_OVFL 0x0040 /* SMT receive overflow */
#define FZA_CONTROL_A_FLUSH_DONE 0x0020 /* flush tx request complete */
#define FZA_CONTROL_A_SHUT 0x0010 /* turn the interface off */
#define FZA_CONTROL_A_HALT 0x0008 /* halt the controller */
#define FZA_CONTROL_A_CMD_POLL 0x0004 /* command ring poll */
#define FZA_CONTROL_A_SMT_RX_POLL 0x0002 /* SMT receive ring poll */
#define FZA_CONTROL_A_TX_POLL 0x0001 /* transmit poll */
/* Control B register constants. All bits are r/w.
*
* Possible values:
* 0x0000 after booting into REX,
* 0x0003 after issuing `boot #/mop'.
*/
#define FZA_CONTROL_B_CONSOLE 0x0002 /* OR with DRIVER for console
* (TC firmware) mode
*/
#define FZA_CONTROL_B_DRIVER 0x0001 /* driver mode */
#define FZA_CONTROL_B_IDLE 0x0000 /* no driver installed */
#define FZA_RESET_PAD \
(FZA_REG_RESET - FZA_REG_BASE)
#define FZA_INT_EVENT_PAD \
(FZA_REG_INT_EVENT - FZA_REG_RESET - sizeof(u16))
#define FZA_CONTROL_A_PAD \
(FZA_REG_CONTROL_A - FZA_REG_INT_MASK - sizeof(u16))
/* Layout of registers. */
struct fza_regs {
u8 pad0[FZA_RESET_PAD];
u16 reset; /* reset register */
u8 pad1[FZA_INT_EVENT_PAD];
u16 int_event; /* interrupt event register */
u16 status; /* status register */
u16 int_mask; /* interrupt mask register */
u8 pad2[FZA_CONTROL_A_PAD];
u16 control_a; /* control A register */
u16 control_b; /* control B register */
};
/* Command descriptor ring entry. */
struct fza_ring_cmd {
u32 cmd_own; /* bit 31: ownership, bits [30:0]: command */
u32 stat; /* command status */
u32 buffer; /* address of the buffer in the FZA space */
u32 pad0;
};
#define FZA_RING_CMD 0x200400 /* command ring address */
#define FZA_RING_CMD_SIZE 0x40 /* command descriptor ring
* size
FDDI: defza: Add missing comment closing Fix: drivers/net/fddi/defza.h:238:1: warning: "/*" within comment [-Wcomment] by adding a missing comment closing. Signed-off-by: Maciej W. Rozycki <macro@linux-mips.org> Signed-off-by: David S. Miller <davem@davemloft.net>
2018-11-07 15:06:59 +03:00
*/
FDDI: defza: Add support for DEC FDDIcontroller 700 TURBOchannel adapter Add support for the DEC FDDIcontroller 700 (DEFZA), Digital Equipment Corporation's first-generation FDDI network interface adapter, made for TURBOchannel and based on a discrete version of what eventually became Motorola's widely used CAMEL chipset. The CAMEL chipset is present for example in the DEC FDDIcontroller TURBOchannel, EISA and PCI adapters (DEFTA/DEFEA/DEFPA) that we support with the `defxx' driver, however the host bus interface logic and the firmware API are different in the DEFZA and hence a separate driver is required. There isn't much to say about the driver except that it works, but there is one peculiarity to mention. The adapter implements two Tx/Rx queue pairs. Of these one pair is the usual network Tx/Rx queue pair, in this case used by the adapter to exchange frames with the ring, via the RMC (Ring Memory Controller) chip. The Tx queue is handled directly by the RMC chip and resides in onboard packet memory. The Rx queue is maintained via DMA in host memory by adapter's firmware copying received data stored by the RMC in onboard packet memory. The other pair is used to communicate SMT frames with adapter's firmware. Any SMT frame received from the RMC via the Rx queue must be queued back by the driver to the SMT Rx queue for the firmware to process. Similarly the firmware uses the SMT Tx queue to supply the driver with SMT frames that must be queued back to the Tx queue for the RMC to send to the ring. This solution was chosen because the designers ran out of PCB space and could not squeeze in more logic onto the board that would be required to handle this SMT frame traffic without the need to involve the driver, as with the later DEFTA/DEFEA/DEFPA adapters. Finally the driver does some Frame Control byte decoding, so to avoid magic numbers some macros are added to <linux/if_fddi.h>. Signed-off-by: Maciej W. Rozycki <macro@linux-mips.org> Signed-off-by: David S. Miller <davem@davemloft.net>
2018-10-10 01:57:43 +03:00
/* Command constants. */
#define FZA_RING_CMD_MASK 0x7fffffff
#define FZA_RING_CMD_NOP 0x00000000 /* nop */
#define FZA_RING_CMD_INIT 0x00000001 /* initialize */
#define FZA_RING_CMD_MODCAM 0x00000002 /* modify CAM */
#define FZA_RING_CMD_PARAM 0x00000003 /* set system parameters */
#define FZA_RING_CMD_MODPROM 0x00000004 /* modify promiscuous mode */
#define FZA_RING_CMD_SETCHAR 0x00000005 /* set link characteristics */
#define FZA_RING_CMD_RDCNTR 0x00000006 /* read counters */
#define FZA_RING_CMD_STATUS 0x00000007 /* get link status */
#define FZA_RING_CMD_RDCAM 0x00000008 /* read CAM */
/* Command status constants. */
#define FZA_RING_STAT_SUCCESS 0x00000000
/* Unsolicited event descriptor ring entry. */
struct fza_ring_uns {
u32 own; /* bit 31: ownership, bits [30:0]: reserved */
u32 id; /* event ID */
u32 buffer; /* address of the buffer in the FZA space */
u32 pad0; /* reserved */
};
#define FZA_RING_UNS 0x200800 /* unsolicited ring address */
#define FZA_RING_UNS_SIZE 0x40 /* unsolicited descriptor ring
* size
*/
/* Unsolicited event constants. */
#define FZA_RING_UNS_UND 0x00000000 /* undefined event ID */
#define FZA_RING_UNS_INIT_IN 0x00000001 /* ring init initiated */
#define FZA_RING_UNS_INIT_RX 0x00000002 /* ring init received */
#define FZA_RING_UNS_BEAC_IN 0x00000003 /* ring beaconing initiated */
#define FZA_RING_UNS_DUP_ADDR 0x00000004 /* duplicate address detected */
#define FZA_RING_UNS_DUP_TOK 0x00000005 /* duplicate token detected */
#define FZA_RING_UNS_PURG_ERR 0x00000006 /* ring purger error */
#define FZA_RING_UNS_STRIP_ERR 0x00000007 /* bridge strip error */
#define FZA_RING_UNS_OP_OSC 0x00000008 /* ring op oscillation */
#define FZA_RING_UNS_BEAC_RX 0x00000009 /* directed beacon received */
#define FZA_RING_UNS_PCT_IN 0x0000000a /* PC trace initiated */
#define FZA_RING_UNS_PCT_RX 0x0000000b /* PC trace received */
#define FZA_RING_UNS_TX_UNDER 0x0000000c /* transmit underrun */
#define FZA_RING_UNS_TX_FAIL 0x0000000d /* transmit failure */
#define FZA_RING_UNS_RX_OVER 0x0000000e /* receive overrun */
/* RMC (Ring Memory Control) transmit descriptor ring entry. */
struct fza_ring_rmc_tx {
u32 rmc; /* RMC information */
u32 avl; /* available for host (unused by RMC) */
u32 own; /* bit 31: ownership, bits [30:0]: reserved */
u32 pad0; /* reserved */
};
#define FZA_TX_BUFFER_ADDR(x) (0x200000 | (((x) & 0xffff) << 5))
#define FZA_TX_BUFFER_SIZE 512
struct fza_buffer_tx {
u32 data[FZA_TX_BUFFER_SIZE / sizeof(u32)];
};
/* Transmit ring RMC constants. */
#define FZA_RING_TX_SOP 0x80000000 /* start of packet */
#define FZA_RING_TX_EOP 0x40000000 /* end of packet */
#define FZA_RING_TX_DTP 0x20000000 /* discard this packet */
#define FZA_RING_TX_VBC 0x10000000 /* valid buffer byte count */
#define FZA_RING_TX_DCC_MASK 0x0f000000 /* DMA completion code */
#define FZA_RING_TX_DCC_SUCCESS 0x01000000 /* transmit succeeded */
#define FZA_RING_TX_DCC_DTP_SOP 0x02000000 /* DTP set at SOP */
#define FZA_RING_TX_DCC_DTP 0x04000000 /* DTP set within packet */
#define FZA_RING_TX_DCC_ABORT 0x05000000 /* MAC-requested abort */
#define FZA_RING_TX_DCC_PARITY 0x06000000 /* xmit data parity error */
#define FZA_RING_TX_DCC_UNDRRUN 0x07000000 /* transmit underrun */
#define FZA_RING_TX_XPO_MASK 0x003fe000 /* transmit packet offset */
/* Host receive descriptor ring entry. */
struct fza_ring_hst_rx {
u32 buf0_own; /* bit 31: ownership, bits [30:23]: unused,
* bits [22:0]: right-shifted address of the
* buffer in system memory (low buffer)
*/
u32 buffer1; /* bits [31:23]: unused,
* bits [22:0]: right-shifted address of the
* buffer in system memory (high buffer)
*/
u32 rmc; /* RMC information */
u32 pad0;
};
#define FZA_RX_BUFFER_SIZE (4096 + 512) /* buffer length */
/* Receive ring RMC constants. */
#define FZA_RING_RX_SOP 0x80000000 /* start of packet */
#define FZA_RING_RX_EOP 0x40000000 /* end of packet */
#define FZA_RING_RX_FSC_MASK 0x38000000 /* # of frame status bits */
#define FZA_RING_RX_FSB_MASK 0x07c00000 /* frame status bits */
#define FZA_RING_RX_FSB_ERR 0x04000000 /* error detected */
#define FZA_RING_RX_FSB_ADDR 0x02000000 /* address recognized */
#define FZA_RING_RX_FSB_COP 0x01000000 /* frame copied */
#define FZA_RING_RX_FSB_F0 0x00800000 /* first additional flag */
#define FZA_RING_RX_FSB_F1 0x00400000 /* second additional flag */
#define FZA_RING_RX_BAD 0x00200000 /* bad packet */
#define FZA_RING_RX_CRC 0x00100000 /* CRC error */
#define FZA_RING_RX_RRR_MASK 0x000e0000 /* MAC receive status bits */
#define FZA_RING_RX_RRR_OK 0x00000000 /* receive OK */
#define FZA_RING_RX_RRR_SADDR 0x00020000 /* source address matched */
#define FZA_RING_RX_RRR_DADDR 0x00040000 /* dest address not matched */
#define FZA_RING_RX_RRR_ABORT 0x00060000 /* RMC abort */
#define FZA_RING_RX_RRR_LENGTH 0x00080000 /* invalid length */
#define FZA_RING_RX_RRR_FRAG 0x000a0000 /* fragment */
#define FZA_RING_RX_RRR_FORMAT 0x000c0000 /* format error */
#define FZA_RING_RX_RRR_RESET 0x000e0000 /* MAC reset */
#define FZA_RING_RX_DA_MASK 0x00018000 /* daddr match status bits */
#define FZA_RING_RX_DA_NONE 0x00000000 /* no match */
#define FZA_RING_RX_DA_PROM 0x00008000 /* promiscuous match */
#define FZA_RING_RX_DA_CAM 0x00010000 /* CAM entry match */
#define FZA_RING_RX_DA_LOCAL 0x00018000 /* link addr or LLC bcast */
#define FZA_RING_RX_SA_MASK 0x00006000 /* saddr match status bits */
#define FZA_RING_RX_SA_NONE 0x00000000 /* no match */
#define FZA_RING_RX_SA_ALIAS 0x00002000 /* alias address match */
#define FZA_RING_RX_SA_CAM 0x00004000 /* CAM entry match */
#define FZA_RING_RX_SA_LOCAL 0x00006000 /* link address match */
/* SMT (Station Management) transmit/receive descriptor ring entry. */
struct fza_ring_smt {
u32 own; /* bit 31: ownership, bits [30:0]: unused */
u32 rmc; /* RMC information */
u32 buffer; /* address of the buffer */
u32 pad0; /* reserved */
};
/* Ownership constants.
*
* Only an owner is permitted to process a given ring entry.
* RMC transmit ring meanings are reversed.
*/
#define FZA_RING_OWN_MASK 0x80000000
#define FZA_RING_OWN_FZA 0x00000000 /* permit FZA, forbid host */
#define FZA_RING_OWN_HOST 0x80000000 /* permit host, forbid FZA */
#define FZA_RING_TX_OWN_RMC 0x80000000 /* permit RMC, forbid host */
#define FZA_RING_TX_OWN_HOST 0x00000000 /* permit host, forbid RMC */
/* RMC constants. */
#define FZA_RING_PBC_MASK 0x00001fff /* frame length */
/* Layout of counter buffers. */
struct fza_counter {
u32 msw;
u32 lsw;
};
struct fza_counters {
struct fza_counter sys_buf; /* system buffer unavailable */
struct fza_counter tx_under; /* transmit underruns */
struct fza_counter tx_fail; /* transmit failures */
struct fza_counter rx_over; /* receive data overruns */
struct fza_counter frame_cnt; /* frame count */
struct fza_counter error_cnt; /* error count */
struct fza_counter lost_cnt; /* lost count */
struct fza_counter rinit_in; /* ring initialization initiated */
struct fza_counter rinit_rx; /* ring initialization received */
struct fza_counter beac_in; /* ring beacon initiated */
struct fza_counter dup_addr; /* duplicate address test failures */
struct fza_counter dup_tok; /* duplicate token detected */
struct fza_counter purg_err; /* ring purge errors */
struct fza_counter strip_err; /* bridge strip errors */
struct fza_counter pct_in; /* traces initiated */
struct fza_counter pct_rx; /* traces received */
struct fza_counter lem_rej; /* LEM rejects */
struct fza_counter tne_rej; /* TNE expiry rejects */
struct fza_counter lem_event; /* LEM events */
struct fza_counter lct_rej; /* LCT rejects */
struct fza_counter conn_cmpl; /* connections completed */
struct fza_counter el_buf; /* elasticity buffer errors */
};
/* Layout of command buffers. */
/* INIT command buffer.
*
* Values of default link parameters given are as obtained from a
* DEFZA-AA rev. C03 board. The board counts time in units of 80ns.
*/
struct fza_cmd_init {
u32 tx_mode; /* transmit mode */
u32 hst_rx_size; /* host receive ring entries */
struct fza_counters counters; /* counters */
u8 rmc_rev[4]; /* RMC revision */
u8 rom_rev[4]; /* ROM revision */
u8 fw_rev[4]; /* firmware revision */
u32 mop_type; /* MOP device type */
u32 hst_rx; /* base of host rx descriptor ring */
u32 rmc_tx; /* base of RMC tx descriptor ring */
u32 rmc_tx_size; /* size of RMC tx descriptor ring */
u32 smt_tx; /* base of SMT tx descriptor ring */
u32 smt_tx_size; /* size of SMT tx descriptor ring */
u32 smt_rx; /* base of SMT rx descriptor ring */
u32 smt_rx_size; /* size of SMT rx descriptor ring */
u32 hw_addr[2]; /* link address */
u32 def_t_req; /* default Requested TTRT (T_REQ) --
* C03: 100000 [80ns]
*/
u32 def_tvx; /* default Valid Transmission Time
* (TVX) -- C03: 32768 [80ns]
*/
u32 def_t_max; /* default Maximum TTRT (T_MAX) --
* C03: 2162688 [80ns]
*/
u32 lem_threshold; /* default LEM threshold -- C03: 8 */
u32 def_station_id[2]; /* default station ID */
u32 pmd_type_alt; /* alternative PMD type code */
u32 smt_ver; /* SMT version */
u32 rtoken_timeout; /* default restricted token timeout
* -- C03: 12500000 [80ns]
*/
u32 ring_purger; /* default ring purger enable --
* C03: 1
*/
u32 smt_ver_max; /* max SMT version ID */
u32 smt_ver_min; /* min SMT version ID */
u32 pmd_type; /* PMD type code */
};
/* INIT command PMD type codes. */
#define FZA_PMD_TYPE_MMF 0 /* Multimode fiber */
#define FZA_PMD_TYPE_TW 101 /* ThinWire */
#define FZA_PMD_TYPE_STP 102 /* STP */
/* MODCAM/RDCAM command buffer. */
#define FZA_CMD_CAM_SIZE 64 /* CAM address entry count */
struct fza_cmd_cam {
u32 hw_addr[FZA_CMD_CAM_SIZE][2]; /* CAM address entries */
};
/* PARAM command buffer.
*
* Permitted ranges given are as defined by the spec and obtained from a
* DEFZA-AA rev. C03 board, respectively. The rtoken_timeout field is
* erroneously interpreted in units of ms.
*/
struct fza_cmd_param {
u32 loop_mode; /* loopback mode */
u32 t_max; /* Maximum TTRT (T_MAX)
* def: ??? [80ns]
* C03: [t_req+1,4294967295] [80ns]
*/
u32 t_req; /* Requested TTRT (T_REQ)
* def: [50000,2097151] [80ns]
* C03: [50001,t_max-1] [80ns]
*/
u32 tvx; /* Valid Transmission Time (TVX)
* def: [29375,65280] [80ns]
* C03: [29376,65279] [80ns]
*/
u32 lem_threshold; /* LEM threshold */
u32 station_id[2]; /* station ID */
u32 rtoken_timeout; /* restricted token timeout
* def: [0,125000000] [80ns]
* C03: [0,9999] [ms]
*/
u32 ring_purger; /* ring purger enable: 0|1 */
};
/* Loopback modes for the PARAM command. */
#define FZA_LOOP_NORMAL 0
#define FZA_LOOP_INTERN 1
#define FZA_LOOP_EXTERN 2
/* MODPROM command buffer. */
struct fza_cmd_modprom {
u32 llc_prom; /* LLC promiscuous enable */
u32 smt_prom; /* SMT promiscuous enable */
u32 llc_multi; /* LLC multicast promiscuous enable */
u32 llc_bcast; /* LLC broadcast promiscuous enable */
};
/* SETCHAR command buffer.
*
* Permitted ranges are as for the PARAM command.
*/
struct fza_cmd_setchar {
u32 t_max; /* Maximum TTRT (T_MAX) */
u32 t_req; /* Requested TTRT (T_REQ) */
u32 tvx; /* Valid Transmission Time (TVX) */
u32 lem_threshold; /* LEM threshold */
u32 rtoken_timeout; /* restricted token timeout */
u32 ring_purger; /* ring purger enable */
};
/* RDCNTR command buffer. */
struct fza_cmd_rdcntr {
struct fza_counters counters; /* counters */
};
/* STATUS command buffer. */
struct fza_cmd_status {
u32 led_state; /* LED state */
u32 rmt_state; /* ring management state */
u32 link_state; /* link state */
u32 dup_addr; /* duplicate address flag */
u32 ring_purger; /* ring purger state */
u32 t_neg; /* negotiated TTRT [80ns] */
u32 una[2]; /* upstream neighbour address */
u32 una_timeout; /* UNA timed out */
u32 strip_mode; /* frame strip mode */
u32 yield_mode; /* claim token yield mode */
u32 phy_state; /* PHY state */
u32 neigh_phy; /* neighbour PHY type */
u32 reject; /* reject reason */
u32 phy_lee; /* PHY link error estimate [-log10] */
u32 una_old[2]; /* old upstream neighbour address */
u32 rmt_mac; /* remote MAC indicated */
u32 ring_err; /* ring error reason */
u32 beac_rx[2]; /* sender of last directed beacon */
u32 un_dup_addr; /* upstream neighbr dup address flag */
u32 dna[2]; /* downstream neighbour address */
u32 dna_old[2]; /* old downstream neighbour address */
};
/* Common command buffer. */
union fza_cmd_buf {
struct fza_cmd_init init;
struct fza_cmd_cam cam;
struct fza_cmd_param param;
struct fza_cmd_modprom modprom;
struct fza_cmd_setchar setchar;
struct fza_cmd_rdcntr rdcntr;
struct fza_cmd_status status;
};
/* MAC (Media Access Controller) chip packet request header constants. */
/* Packet request header byte #0. */
#define FZA_PRH0_FMT_TYPE_MASK 0xc0 /* type of packet, always zero */
#define FZA_PRH0_TOK_TYPE_MASK 0x30 /* type of token required
* to send this frame
*/
#define FZA_PRH0_TKN_TYPE_ANY 0x30 /* use either token type */
#define FZA_PRH0_TKN_TYPE_UNR 0x20 /* use an unrestricted token */
#define FZA_PRH0_TKN_TYPE_RST 0x10 /* use a restricted token */
#define FZA_PRH0_TKN_TYPE_IMM 0x00 /* send immediately, no token required
*/
#define FZA_PRH0_FRAME_MASK 0x08 /* type of frame to send */
#define FZA_PRH0_FRAME_SYNC 0x08 /* send a synchronous frame */
#define FZA_PRH0_FRAME_ASYNC 0x00 /* send an asynchronous frame */
#define FZA_PRH0_MODE_MASK 0x04 /* send mode */
#define FZA_PRH0_MODE_IMMED 0x04 /* an immediate mode, send regardless
* of the ring operational state
*/
#define FZA_PRH0_MODE_NORMAL 0x00 /* a normal mode, send only if ring
* operational
*/
#define FZA_PRH0_SF_MASK 0x02 /* send frame first */
#define FZA_PRH0_SF_FIRST 0x02 /* send this frame first
* with this token capture
*/
#define FZA_PRH0_SF_NORMAL 0x00 /* treat this frame normally */
#define FZA_PRH0_BCN_MASK 0x01 /* beacon frame */
#define FZA_PRH0_BCN_BEACON 0x01 /* send the frame only
* if in the beacon state
*/
#define FZA_PRH0_BCN_DATA 0x01 /* send the frame only
* if in the data state
*/
/* Packet request header byte #1. */
/* bit 7 always zero */
#define FZA_PRH1_SL_MASK 0x40 /* send frame last */
#define FZA_PRH1_SL_LAST 0x40 /* send this frame last, releasing
* the token afterwards
*/
#define FZA_PRH1_SL_NORMAL 0x00 /* treat this frame normally */
#define FZA_PRH1_CRC_MASK 0x20 /* CRC append */
#define FZA_PRH1_CRC_NORMAL 0x20 /* calculate the CRC and append it
* as the FCS field to the frame
*/
#define FZA_PRH1_CRC_SKIP 0x00 /* leave the frame as is */
#define FZA_PRH1_TKN_SEND_MASK 0x18 /* type of token to send after the
* frame if this is the last frame
*/
#define FZA_PRH1_TKN_SEND_ORIG 0x18 /* send a token of the same type as the
* originally captured one
*/
#define FZA_PRH1_TKN_SEND_RST 0x10 /* send a restricted token */
#define FZA_PRH1_TKN_SEND_UNR 0x08 /* send an unrestricted token */
#define FZA_PRH1_TKN_SEND_NONE 0x00 /* send no token */
#define FZA_PRH1_EXTRA_FS_MASK 0x07 /* send extra frame status indicators
*/
#define FZA_PRH1_EXTRA_FS_ST 0x07 /* TR RR ST II */
#define FZA_PRH1_EXTRA_FS_SS 0x06 /* TR RR SS II */
#define FZA_PRH1_EXTRA_FS_SR 0x05 /* TR RR SR II */
#define FZA_PRH1_EXTRA_FS_NONE1 0x04 /* TR RR II II */
#define FZA_PRH1_EXTRA_FS_RT 0x03 /* TR RR RT II */
#define FZA_PRH1_EXTRA_FS_RS 0x02 /* TR RR RS II */
#define FZA_PRH1_EXTRA_FS_RR 0x01 /* TR RR RR II */
#define FZA_PRH1_EXTRA_FS_NONE 0x00 /* TR RR II II */
/* Packet request header byte #2. */
#define FZA_PRH2_NORMAL 0x00 /* always zero */
/* PRH used for LLC frames. */
#define FZA_PRH0_LLC (FZA_PRH0_TKN_TYPE_UNR)
#define FZA_PRH1_LLC (FZA_PRH1_CRC_NORMAL | FZA_PRH1_TKN_SEND_UNR)
#define FZA_PRH2_LLC (FZA_PRH2_NORMAL)
/* PRH used for SMT frames. */
#define FZA_PRH0_SMT (FZA_PRH0_TKN_TYPE_UNR)
#define FZA_PRH1_SMT (FZA_PRH1_CRC_NORMAL | FZA_PRH1_TKN_SEND_UNR)
#define FZA_PRH2_SMT (FZA_PRH2_NORMAL)
#if ((FZA_RING_RX_SIZE) < 2) || ((FZA_RING_RX_SIZE) > 256)
# error FZA_RING_RX_SIZE has to be from 2 up to 256
#endif
#if ((FZA_RING_TX_MODE) != 0) && ((FZA_RING_TX_MODE) != 1)
# error FZA_RING_TX_MODE has to be either 0 or 1
#endif
#define FZA_RING_TX_SIZE (512 << (FZA_RING_TX_MODE))
struct fza_private {
struct device *bdev; /* pointer to the bus device */
const char *name; /* printable device name */
void __iomem *mmio; /* MMIO ioremap cookie */
struct fza_regs __iomem *regs; /* pointer to FZA registers */
struct sk_buff *rx_skbuff[FZA_RING_RX_SIZE];
/* all skbs assigned to the host
* receive descriptors
*/
dma_addr_t rx_dma[FZA_RING_RX_SIZE];
/* their corresponding DMA addresses */
struct fza_ring_cmd __iomem *ring_cmd;
/* pointer to the command descriptor
* ring
*/
int ring_cmd_index; /* index to the command descriptor ring
* for the next command
*/
struct fza_ring_uns __iomem *ring_uns;
/* pointer to the unsolicited
* descriptor ring
*/
int ring_uns_index; /* index to the unsolicited descriptor
* ring for the next event
*/
struct fza_ring_rmc_tx __iomem *ring_rmc_tx;
/* pointer to the RMC transmit
* descriptor ring (obtained from the
* INIT command)
*/
int ring_rmc_tx_size; /* number of entries in the RMC
* transmit descriptor ring (obtained
* from the INIT command)
*/
int ring_rmc_tx_index; /* index to the RMC transmit descriptor
* ring for the next transmission
*/
int ring_rmc_txd_index; /* index to the RMC transmit descriptor
* ring for the next transmit done
* acknowledge
*/
struct fza_ring_hst_rx __iomem *ring_hst_rx;
/* pointer to the host receive
* descriptor ring (obtained from the
* INIT command)
*/
int ring_hst_rx_size; /* number of entries in the host
* receive descriptor ring (set by the
* INIT command)
*/
int ring_hst_rx_index; /* index to the host receive descriptor
* ring for the next transmission
*/
struct fza_ring_smt __iomem *ring_smt_tx;
/* pointer to the SMT transmit
* descriptor ring (obtained from the
* INIT command)
*/
int ring_smt_tx_size; /* number of entries in the SMT
* transmit descriptor ring (obtained
* from the INIT command)
*/
int ring_smt_tx_index; /* index to the SMT transmit descriptor
* ring for the next transmission
*/
struct fza_ring_smt __iomem *ring_smt_rx;
/* pointer to the SMT transmit
* descriptor ring (obtained from the
* INIT command)
*/
int ring_smt_rx_size; /* number of entries in the SMT
* receive descriptor ring (obtained
* from the INIT command)
*/
int ring_smt_rx_index; /* index to the SMT receive descriptor
* ring for the next transmission
*/
struct fza_buffer_tx __iomem *buffer_tx;
/* pointer to the RMC transmit buffers
*/
uint state; /* adapter expected state */
spinlock_t lock; /* for device & private data access */
uint int_mask; /* interrupt source selector */
int cmd_done_flag; /* command completion trigger */
wait_queue_head_t cmd_done_wait;
int state_chg_flag; /* state change trigger */
wait_queue_head_t state_chg_wait;
struct timer_list reset_timer; /* RESET time-out trigger */
int timer_state; /* RESET trigger state */
int queue_active; /* whether to enable queueing */
struct net_device_stats stats;
uint irq_count_flush_tx; /* transmit flush irqs */
uint irq_count_uns_poll; /* unsolicited event irqs */
uint irq_count_smt_tx_poll; /* SMT transmit irqs */
uint irq_count_rx_poll; /* host receive irqs */
uint irq_count_tx_done; /* transmit done irqs */
uint irq_count_cmd_done; /* command done irqs */
uint irq_count_state_chg; /* state change irqs */
uint irq_count_link_st_chg; /* link status change irqs */
uint t_max; /* T_MAX */
uint t_req; /* T_REQ */
uint tvx; /* TVX */
uint lem_threshold; /* LEM threshold */
uint station_id[2]; /* station ID */
uint rtoken_timeout; /* restricted token timeout */
uint ring_purger; /* ring purger enable flag */
};
struct fza_fddihdr {
u8 pa[2]; /* preamble */
u8 sd; /* starting delimiter */
struct fddihdr hdr;
} __packed;
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