/*-
* Copyright (c) 2017 Broadcom. All rights reserved.
* The term "Broadcom" refers to Broadcom Limited and/or its subsidiaries.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* 3. Neither the name of the copyright holder nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
* $FreeBSD$
*/
/**
* @defgroup sli SLI-4 Base APIs
*/
/**
* @file
* All common (i.e. transport-independent) SLI-4 functions are implemented
* in this file.
*/
#include "sli4.h"
#if defined(OCS_INCLUDE_DEBUG)
#include "ocs_utils.h"
#endif
#define SLI4_BMBX_DELAY_US 1000 /* 1 ms */
#define SLI4_INIT_PORT_DELAY_US 10000 /* 10 ms */
static int32_t sli_fw_init(sli4_t *);
static int32_t sli_fw_term(sli4_t *);
static int32_t sli_sliport_control(sli4_t *sli4, uint32_t endian);
static int32_t sli_cmd_fw_deinitialize(sli4_t *, void *, size_t);
static int32_t sli_cmd_fw_initialize(sli4_t *, void *, size_t);
static int32_t sli_queue_doorbell(sli4_t *, sli4_queue_t *);
static uint8_t sli_queue_entry_is_valid(sli4_queue_t *, uint8_t *, uint8_t);
const uint8_t sli4_fw_initialize[] = {
0xff, 0x12, 0x34, 0xff,
0xff, 0x56, 0x78, 0xff,
};
const uint8_t sli4_fw_deinitialize[] = {
0xff, 0xaa, 0xbb, 0xff,
0xff, 0xcc, 0xdd, 0xff,
};
typedef struct {
uint32_t rev_id;
uint32_t family; /* generation */
sli4_asic_type_e type;
sli4_asic_rev_e rev;
} sli4_asic_entry_t;
sli4_asic_entry_t sli4_asic_table[] = {
{ 0x00, 1, SLI4_ASIC_TYPE_BE3, SLI4_ASIC_REV_A0},
{ 0x01, 1, SLI4_ASIC_TYPE_BE3, SLI4_ASIC_REV_A1},
{ 0x02, 1, SLI4_ASIC_TYPE_BE3, SLI4_ASIC_REV_A2},
{ 0x00, 4, SLI4_ASIC_TYPE_SKYHAWK, SLI4_ASIC_REV_A0},
{ 0x00, 2, SLI4_ASIC_TYPE_SKYHAWK, SLI4_ASIC_REV_A0},
{ 0x10, 1, SLI4_ASIC_TYPE_BE3, SLI4_ASIC_REV_B0},
{ 0x10, 0x04, SLI4_ASIC_TYPE_SKYHAWK, SLI4_ASIC_REV_B0},
{ 0x11, 0x04, SLI4_ASIC_TYPE_SKYHAWK, SLI4_ASIC_REV_B1},
{ 0x0, 0x0a, SLI4_ASIC_TYPE_LANCER, SLI4_ASIC_REV_A0},
{ 0x10, 0x0b, SLI4_ASIC_TYPE_LANCER, SLI4_ASIC_REV_B0},
{ 0x30, 0x0b, SLI4_ASIC_TYPE_LANCER, SLI4_ASIC_REV_D0},
{ 0x3, 0x0b, SLI4_ASIC_TYPE_LANCERG6,SLI4_ASIC_REV_A3},
{ 0x0, 0x0c, SLI4_ASIC_TYPE_LANCERG6,SLI4_ASIC_REV_A0},
{ 0x1, 0x0c, SLI4_ASIC_TYPE_LANCERG6,SLI4_ASIC_REV_A1},
{ 0x3, 0x0c, SLI4_ASIC_TYPE_LANCERG6,SLI4_ASIC_REV_A3},
{ 0x00, 0x05, SLI4_ASIC_TYPE_CORSAIR, SLI4_ASIC_REV_A0},
};
/*
* @brief Convert queue type enum (SLI_QTYPE_*) into a string.
*/
const char *SLI_QNAME[] = {
"Event Queue",
"Completion Queue",
"Mailbox Queue",
"Work Queue",
"Receive Queue",
"Undefined"
};
/**
* @brief Define the mapping of registers to their BAR and offset.
*
* @par Description
* Although SLI-4 specification defines a common set of registers, their locations
* (both BAR and offset) depend on the interface type. This array maps a register
* enum to an array of BAR/offset pairs indexed by the interface type. For
* example, to access the bootstrap mailbox register on an interface type 0
* device, code can refer to the offset using regmap[SLI4_REG_BMBX][0].offset.
*
* @b Note: A value of UINT32_MAX for either the register set (rset) or offset (off)
* indicates an invalid mapping.
*/
const sli4_reg_t regmap[SLI4_REG_MAX][SLI4_MAX_IF_TYPES] = {
/* SLI4_REG_BMBX */
{
{ 2, SLI4_BMBX_REG }, { 0, SLI4_BMBX_REG }, { 0, SLI4_BMBX_REG }, { 0, SLI4_BMBX_REG },
},
/* SLI4_REG_EQCQ_DOORBELL */
{
{ 2, SLI4_EQCQ_DOORBELL_REG }, { 0, SLI4_EQCQ_DOORBELL_REG },
{ 0, SLI4_EQCQ_DOORBELL_REG }, { 0, SLI4_EQCQ_DOORBELL_REG },
},
/* SLI4_REG_FCOE_RQ_DOORBELL */
{
{ 2, SLI4_RQ_DOORBELL_REG }, { 0, SLI4_RQ_DOORBELL_REG },
{ 0, SLI4_RQ_DOORBELL_REG }, { UINT32_MAX, UINT32_MAX },
},
/* SLI4_REG_IO_WQ_DOORBELL */
{
{ 2, SLI4_IO_WQ_DOORBELL_REG }, { 0, SLI4_IO_WQ_DOORBELL_REG }, { 0, SLI4_IO_WQ_DOORBELL_REG }, { UINT32_MAX, UINT32_MAX },
},
/* SLI4_REG_MQ_DOORBELL */
{
{ 2, SLI4_MQ_DOORBELL_REG }, { 0, SLI4_MQ_DOORBELL_REG },
{ 0, SLI4_MQ_DOORBELL_REG }, { 0, SLI4_MQ_DOORBELL_REG },
},
/* SLI4_REG_PHYSDEV_CONTROL */
{
{ UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX }, { 0, SLI4_PHSDEV_CONTROL_REG_23 }, { 0, SLI4_PHSDEV_CONTROL_REG_23 },
},
/* SLI4_REG_SLIPORT_CONTROL */
{
{ UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX }, { 0, SLI4_SLIPORT_CONTROL_REG }, { UINT32_MAX, UINT32_MAX },
},
/* SLI4_REG_SLIPORT_ERROR1 */
{
{ UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX }, { 0, SLI4_SLIPORT_ERROR1 }, { UINT32_MAX, UINT32_MAX },
},
/* SLI4_REG_SLIPORT_ERROR2 */
{
{ UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX }, { 0, SLI4_SLIPORT_ERROR2 }, { UINT32_MAX, UINT32_MAX },
},
/* SLI4_REG_SLIPORT_SEMAPHORE */
{
{ 1, SLI4_PORT_SEMAPHORE_REG_0 }, { 0, SLI4_PORT_SEMAPHORE_REG_1 },
{ 0, SLI4_PORT_SEMAPHORE_REG_23 }, { 0, SLI4_PORT_SEMAPHORE_REG_23 },
},
/* SLI4_REG_SLIPORT_STATUS */
{
{ UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX }, { 0, SLI4_PORT_STATUS_REG_23 }, { 0, SLI4_PORT_STATUS_REG_23 },
},
/* SLI4_REG_UERR_MASK_HI */
{
{ 0, SLI4_UERR_MASK_HIGH_REG }, { UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX },
},
/* SLI4_REG_UERR_MASK_LO */
{
{ 0, SLI4_UERR_MASK_LOW_REG }, { UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX },
},
/* SLI4_REG_UERR_STATUS_HI */
{
{ 0, SLI4_UERR_STATUS_HIGH_REG }, { UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX },
},
/* SLI4_REG_UERR_STATUS_LO */
{
{ 0, SLI4_UERR_STATUS_LOW_REG }, { UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX },
},
/* SLI4_REG_SW_UE_CSR1 */
{
{ 1, SLI4_SW_UE_CSR1}, { UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX },
},
/* SLI4_REG_SW_UE_CSR2 */
{
{ 1, SLI4_SW_UE_CSR2}, { UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX }, { UINT32_MAX, UINT32_MAX },
},
};
/**
* @brief Read the given SLI register.
*
* @param sli Pointer to the SLI context.
* @param reg Register name enum.
*
* @return Returns the register value.
*/
uint32_t
sli_reg_read(sli4_t *sli, sli4_regname_e reg)
{
const sli4_reg_t *r = &(regmap[reg][sli->if_type]);
if ((UINT32_MAX == r->rset) || (UINT32_MAX == r->off)) {
ocs_log_err(sli->os, "regname %d not defined for if_type %d\n", reg, sli->if_type);
return UINT32_MAX;
}
return ocs_reg_read32(sli->os, r->rset, r->off);
}
/**
* @brief Write the value to the given SLI register.
*
* @param sli Pointer to the SLI context.
* @param reg Register name enum.
* @param val Value to write.
*
* @return None.
*/
void
sli_reg_write(sli4_t *sli, sli4_regname_e reg, uint32_t val)
{
const sli4_reg_t *r = &(regmap[reg][sli->if_type]);
if ((UINT32_MAX == r->rset) || (UINT32_MAX == r->off)) {
ocs_log_err(sli->os, "regname %d not defined for if_type %d\n", reg, sli->if_type);
return;
}
ocs_reg_write32(sli->os, r->rset, r->off, val);
}
/**
* @brief Check if the SLI_INTF register is valid.
*
* @param val 32-bit SLI_INTF register value.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
static uint8_t
sli_intf_valid_check(uint32_t val)
{
return ((val >> SLI4_INTF_VALID_SHIFT) & SLI4_INTF_VALID_MASK) != SLI4_INTF_VALID;
}
/**
* @brief Retrieve the SLI revision level.
*
* @param val 32-bit SLI_INTF register value.
*
* @return Returns the SLI revision level.
*/
static uint8_t
sli_intf_sli_revision(uint32_t val)
{
return ((val >> SLI4_INTF_SLI_REVISION_SHIFT) & SLI4_INTF_SLI_REVISION_MASK);
}
static uint8_t
sli_intf_sli_family(uint32_t val)
{
return ((val >> SLI4_INTF_SLI_FAMILY_SHIFT) & SLI4_INTF_SLI_FAMILY_MASK);
}
/**
* @brief Retrieve the SLI interface type.
*
* @param val 32-bit SLI_INTF register value.
*
* @return Returns the SLI interface type.
*/
static uint8_t
sli_intf_if_type(uint32_t val)
{
return ((val >> SLI4_INTF_IF_TYPE_SHIFT) & SLI4_INTF_IF_TYPE_MASK);
}
/**
* @brief Retrieve PCI revision ID.
*
* @param val 32-bit PCI CLASS_REVISION register value.
*
* @return Returns the PCI revision ID.
*/
static uint8_t
sli_pci_rev_id(uint32_t val)
{
return ((val >> SLI4_PCI_REV_ID_SHIFT) & SLI4_PCI_REV_ID_MASK);
}
/**
* @brief retrieve SLI ASIC generation
*
* @param val 32-bit SLI_ASIC_ID register value
*
* @return SLI ASIC generation
*/
static uint8_t
sli_asic_gen(uint32_t val)
{
return ((val >> SLI4_ASIC_GEN_SHIFT) & SLI4_ASIC_GEN_MASK);
}
/**
* @brief Wait for the bootstrap mailbox to report "ready".
*
* @param sli4 SLI context pointer.
* @param msec Number of milliseconds to wait.
*
* @return Returns 0 if BMBX is ready, or non-zero otherwise (i.e. time out occurred).
*/
static int32_t
sli_bmbx_wait(sli4_t *sli4, uint32_t msec)
{
uint32_t val = 0;
do {
ocs_udelay(SLI4_BMBX_DELAY_US);
val = sli_reg_read(sli4, SLI4_REG_BMBX);
msec--;
} while(msec && !(val & SLI4_BMBX_RDY));
return(!(val & SLI4_BMBX_RDY));
}
/**
* @brief Write bootstrap mailbox.
*
* @param sli4 SLI context pointer.
*
* @return Returns 0 if command succeeded, or non-zero otherwise.
*/
static int32_t
sli_bmbx_write(sli4_t *sli4)
{
uint32_t val = 0;
/* write buffer location to bootstrap mailbox register */
ocs_dma_sync(&sli4->bmbx, OCS_DMASYNC_PREWRITE);
val = SLI4_BMBX_WRITE_HI(sli4->bmbx.phys);
sli_reg_write(sli4, SLI4_REG_BMBX, val);
if (sli_bmbx_wait(sli4, SLI4_BMBX_DELAY_US)) {
ocs_log_crit(sli4->os, "BMBX WRITE_HI failed\n");
return -1;
}
val = SLI4_BMBX_WRITE_LO(sli4->bmbx.phys);
sli_reg_write(sli4, SLI4_REG_BMBX, val);
/* wait for SLI Port to set ready bit */
return sli_bmbx_wait(sli4, SLI4_BMBX_TIMEOUT_MSEC/*XXX*/);
}
#if defined(OCS_INCLUDE_DEBUG)
/**
* @ingroup sli
* @brief Dump BMBX mailbox command.
*
* @par Description
* Convenience function for dumping BMBX mailbox commands. Takes
* into account which mailbox command is given since SLI_CONFIG
* commands are special.
*
* @b Note: This function takes advantage of
* the one-command-at-a-time nature of the BMBX to be able to
* display non-embedded SLI_CONFIG commands. This will not work
* for mailbox commands on the MQ. Luckily, all current non-emb
* mailbox commands go through the BMBX.
*
* @param sli4 SLI context pointer.
* @param mbx Pointer to mailbox command to dump.
* @param prefix Prefix for dump label.
*
* @return None.
*/
static void
sli_dump_bmbx_command(sli4_t *sli4, void *mbx, const char *prefix)
{
uint32_t size = 0;
char label[64];
uint32_t i;
/* Mailbox diagnostic logging */
sli4_mbox_command_header_t *hdr = (sli4_mbox_command_header_t *)mbx;
if (!ocs_debug_is_enabled(OCS_DEBUG_ENABLE_MQ_DUMP)) {
return;
}
if (hdr->command == SLI4_MBOX_COMMAND_SLI_CONFIG) {
sli4_cmd_sli_config_t *sli_config = (sli4_cmd_sli_config_t *)hdr;
sli4_req_hdr_t *sli_config_hdr;
if (sli_config->emb) {
ocs_snprintf(label, sizeof(label), "%s (emb)", prefix);
/* if embedded, dump entire command */
sli_config_hdr = (sli4_req_hdr_t *)sli_config->payload.embed;
size = sizeof(*sli_config) - sizeof(sli_config->payload) +
sli_config_hdr->request_length + (4*sizeof(uint32_t));
ocs_dump32(OCS_DEBUG_ENABLE_MQ_DUMP, sli4->os, label,
(uint8_t *)sli4->bmbx.virt, size);
} else {
sli4_sli_config_pmd_t *pmd;
ocs_snprintf(label, sizeof(label), "%s (non-emb hdr)", prefix);
/* if non-embedded, break up into two parts: SLI_CONFIG hdr
and the payload(s) */
size = sizeof(*sli_config) - sizeof(sli_config->payload) + (12 * sli_config->pmd_count);
ocs_dump32(OCS_DEBUG_ENABLE_MQ_DUMP, sli4->os, label,
(uint8_t *)sli4->bmbx.virt, size);
/* as sanity check, make sure first PMD matches what was saved */
pmd = &sli_config->payload.mem;
if ((pmd->address_high == ocs_addr32_hi(sli4->bmbx_non_emb_pmd->phys)) &&
(pmd->address_low == ocs_addr32_lo(sli4->bmbx_non_emb_pmd->phys))) {
for (i = 0; i < sli_config->pmd_count; i++, pmd++) {
sli_config_hdr = sli4->bmbx_non_emb_pmd->virt;
ocs_snprintf(label, sizeof(label), "%s (non-emb pay[%d])",
prefix, i);
ocs_dump32(OCS_DEBUG_ENABLE_MQ_DUMP, sli4->os, label,
(uint8_t *)sli4->bmbx_non_emb_pmd->virt,
sli_config_hdr->request_length + (4*sizeof(uint32_t)));
}
} else {
ocs_log_debug(sli4->os, "pmd addr does not match pmd:%x %x (%x %x)\n",
pmd->address_high, pmd->address_low,
ocs_addr32_hi(sli4->bmbx_non_emb_pmd->phys),
ocs_addr32_lo(sli4->bmbx_non_emb_pmd->phys));
}
}
} else {
/* not an SLI_CONFIG command, just display first 64 bytes, like we do
for MQEs */
size = 64;
ocs_dump32(OCS_DEBUG_ENABLE_MQ_DUMP, sli4->os, prefix,
(uint8_t *)mbx, size);
}
}
#endif
/**
* @ingroup sli
* @brief Submit a command to the bootstrap mailbox and check the status.
*
* @param sli4 SLI context pointer.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_bmbx_command(sli4_t *sli4)
{
void *cqe = (uint8_t *)sli4->bmbx.virt + SLI4_BMBX_SIZE;
#if defined(OCS_INCLUDE_DEBUG)
sli_dump_bmbx_command(sli4, sli4->bmbx.virt, "bmbx cmd");
#endif
if (sli_fw_error_status(sli4) > 0) {
ocs_log_crit(sli4->os, "Chip is in an error state - Mailbox "
"command rejected status=%#x error1=%#x error2=%#x\n",
sli_reg_read(sli4, SLI4_REG_SLIPORT_STATUS),
sli_reg_read(sli4, SLI4_REG_SLIPORT_ERROR1),
sli_reg_read(sli4, SLI4_REG_SLIPORT_ERROR2));
return -1;
}
if (sli_bmbx_write(sli4)) {
ocs_log_crit(sli4->os, "bootstrap mailbox write fail phys=%p reg=%#x\n",
(void*)sli4->bmbx.phys,
sli_reg_read(sli4, SLI4_REG_BMBX));
return -1;
}
/* check completion queue entry status */
ocs_dma_sync(&sli4->bmbx, OCS_DMASYNC_POSTREAD);
if (((sli4_mcqe_t *)cqe)->val) {
#if defined(OCS_INCLUDE_DEBUG)
sli_dump_bmbx_command(sli4, sli4->bmbx.virt, "bmbx cmpl");
ocs_dump32(OCS_DEBUG_ENABLE_CQ_DUMP, sli4->os, "bmbx cqe", cqe, sizeof(sli4_mcqe_t));
#endif
return sli_cqe_mq(cqe);
} else {
ocs_log_err(sli4->os, "invalid or wrong type\n");
return -1;
}
}
/****************************************************************************
* Messages
*/
/**
* @ingroup sli
* @brief Write a CONFIG_LINK command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_config_link(sli4_t *sli4, void *buf, size_t size)
{
sli4_cmd_config_link_t *config_link = buf;
ocs_memset(buf, 0, size);
config_link->hdr.command = SLI4_MBOX_COMMAND_CONFIG_LINK;
/* Port interprets zero in a field as "use default value" */
return sizeof(sli4_cmd_config_link_t);
}
/**
* @ingroup sli
* @brief Write a DOWN_LINK command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_down_link(sli4_t *sli4, void *buf, size_t size)
{
sli4_mbox_command_header_t *hdr = buf;
ocs_memset(buf, 0, size);
hdr->command = SLI4_MBOX_COMMAND_DOWN_LINK;
/* Port interprets zero in a field as "use default value" */
return sizeof(sli4_mbox_command_header_t);
}
/**
* @ingroup sli
* @brief Write a DUMP Type 4 command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param wki The well known item ID.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_dump_type4(sli4_t *sli4, void *buf, size_t size, uint16_t wki)
{
sli4_cmd_dump4_t *cmd = buf;
ocs_memset(buf, 0, size);
cmd->hdr.command = SLI4_MBOX_COMMAND_DUMP;
cmd->type = 4;
cmd->wki_selection = wki;
return sizeof(sli4_cmd_dump4_t);
}
/**
* @ingroup sli
* @brief Write a COMMON_READ_TRANSCEIVER_DATA command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param page_num The page of SFP data to retrieve (0xa0 or 0xa2).
* @param dma DMA structure from which the data will be copied.
*
* @note This creates a Version 0 message.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_common_read_transceiver_data(sli4_t *sli4, void *buf, size_t size, uint32_t page_num,
ocs_dma_t *dma)
{
sli4_req_common_read_transceiver_data_t *req = NULL;
uint32_t sli_config_off = 0;
uint32_t payload_size;
if (dma == NULL) {
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_common_read_transceiver_data_t),
sizeof(sli4_res_common_read_transceiver_data_t));
} else {
payload_size = dma->size;
}
if (sli4->port_type == SLI4_PORT_TYPE_FC) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size, payload_size, dma);
}
if (dma == NULL) {
req = (sli4_req_common_read_transceiver_data_t *)((uint8_t *)buf + sli_config_off);
} else {
req = (sli4_req_common_read_transceiver_data_t *)dma->virt;
ocs_memset(req, 0, dma->size);
}
req->hdr.opcode = SLI4_OPC_COMMON_READ_TRANSCEIVER_DATA;
req->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
req->hdr.request_length = payload_size - sizeof(sli4_req_hdr_t);
req->page_number = page_num;
req->port = sli4->physical_port;
return(sli_config_off + sizeof(sli4_req_common_read_transceiver_data_t));
}
/**
* @ingroup sli
* @brief Write a READ_LINK_STAT command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param req_ext_counters If TRUE, then the extended counters will be requested.
* @param clear_overflow_flags If TRUE, then overflow flags will be cleared.
* @param clear_all_counters If TRUE, the counters will be cleared.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_read_link_stats(sli4_t *sli4, void *buf, size_t size,
uint8_t req_ext_counters,
uint8_t clear_overflow_flags,
uint8_t clear_all_counters)
{
sli4_cmd_read_link_stats_t *cmd = buf;
ocs_memset(buf, 0, size);
cmd->hdr.command = SLI4_MBOX_COMMAND_READ_LNK_STAT;
cmd->rec = req_ext_counters;
cmd->clrc = clear_all_counters;
cmd->clof = clear_overflow_flags;
return sizeof(sli4_cmd_read_link_stats_t);
}
/**
* @ingroup sli
* @brief Write a READ_STATUS command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param clear_counters If TRUE, the counters will be cleared.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_read_status(sli4_t *sli4, void *buf, size_t size,
uint8_t clear_counters)
{
sli4_cmd_read_status_t *cmd = buf;
ocs_memset(buf, 0, size);
cmd->hdr.command = SLI4_MBOX_COMMAND_READ_STATUS;
cmd->cc = clear_counters;
return sizeof(sli4_cmd_read_status_t);
}
/**
* @brief Write a FW_DEINITIALIZE command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
*
* @return Returns the number of bytes written.
*/
static int32_t
sli_cmd_fw_deinitialize(sli4_t *sli4, void *buf, size_t size)
{
ocs_memset(buf, 0, size);
ocs_memcpy(buf, sli4_fw_deinitialize, sizeof(sli4_fw_deinitialize));
return sizeof(sli4_fw_deinitialize);
}
/**
* @brief Write a FW_INITIALIZE command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
*
* @return Returns the number of bytes written.
*/
static int32_t
sli_cmd_fw_initialize(sli4_t *sli4, void *buf, size_t size)
{
ocs_memset(buf, 0, size);
ocs_memcpy(buf, sli4_fw_initialize, sizeof(sli4_fw_initialize));
return sizeof(sli4_fw_initialize);
}
/**
* @ingroup sli
* @brief Write an INIT_LINK command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param speed Link speed.
* @param reset_alpa For native FC, this is the selective reset AL_PA
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_init_link(sli4_t *sli4, void *buf, size_t size, uint32_t speed, uint8_t reset_alpa)
{
sli4_cmd_init_link_t *init_link = buf;
ocs_memset(buf, 0, size);
init_link->hdr.command = SLI4_MBOX_COMMAND_INIT_LINK;
/* Most fields only have meaning for FC links */
if (sli4->config.topology != SLI4_READ_CFG_TOPO_FCOE) {
init_link->selective_reset_al_pa = reset_alpa;
init_link->link_flags.loopback = FALSE;
init_link->link_speed_selection_code = speed;
switch (speed) {
case FC_LINK_SPEED_1G:
case FC_LINK_SPEED_2G:
case FC_LINK_SPEED_4G:
case FC_LINK_SPEED_8G:
case FC_LINK_SPEED_16G:
case FC_LINK_SPEED_32G:
init_link->link_flags.fixed_speed = TRUE;
break;
case FC_LINK_SPEED_10G:
ocs_log_test(sli4->os, "unsupported FC speed %d\n", speed);
return 0;
}
switch (sli4->config.topology) {
case SLI4_READ_CFG_TOPO_FC:
/* Attempt P2P but failover to FC-AL */
init_link->link_flags.enable_topology_failover = TRUE;
if (sli_get_asic_type(sli4) == SLI4_ASIC_TYPE_LANCER)
init_link->link_flags.topology = SLI4_INIT_LINK_F_FCAL_FAIL_OVER;
else
init_link->link_flags.topology = SLI4_INIT_LINK_F_P2P_FAIL_OVER;
break;
case SLI4_READ_CFG_TOPO_FC_AL:
init_link->link_flags.topology = SLI4_INIT_LINK_F_FCAL_ONLY;
if ((init_link->link_speed_selection_code == FC_LINK_SPEED_16G) ||
(init_link->link_speed_selection_code == FC_LINK_SPEED_32G)) {
ocs_log_test(sli4->os, "unsupported FC-AL speed %d\n", speed);
return 0;
}
break;
case SLI4_READ_CFG_TOPO_FC_DA:
init_link->link_flags.topology = FC_TOPOLOGY_P2P;
break;
default:
ocs_log_test(sli4->os, "unsupported topology %#x\n", sli4->config.topology);
return 0;
}
init_link->link_flags.unfair = FALSE;
init_link->link_flags.skip_lirp_lilp = FALSE;
init_link->link_flags.gen_loop_validity_check = FALSE;
init_link->link_flags.skip_lisa = FALSE;
init_link->link_flags.select_hightest_al_pa = FALSE;
}
return sizeof(sli4_cmd_init_link_t);
}
/**
* @ingroup sli
* @brief Write an INIT_VFI command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param vfi VFI
* @param fcfi FCFI
* @param vpi VPI (Set to -1 if unused.)
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_init_vfi(sli4_t *sli4, void *buf, size_t size, uint16_t vfi,
uint16_t fcfi, uint16_t vpi)
{
sli4_cmd_init_vfi_t *init_vfi = buf;
ocs_memset(buf, 0, size);
init_vfi->hdr.command = SLI4_MBOX_COMMAND_INIT_VFI;
init_vfi->vfi = vfi;
init_vfi->fcfi = fcfi;
/*
* If the VPI is valid, initialize it at the same time as
* the VFI
*/
if (0xffff != vpi) {
init_vfi->vp = TRUE;
init_vfi->vpi = vpi;
}
return sizeof(sli4_cmd_init_vfi_t);
}
/**
* @ingroup sli
* @brief Write an INIT_VPI command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param vpi VPI allocated.
* @param vfi VFI associated with this VPI.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_init_vpi(sli4_t *sli4, void *buf, size_t size, uint16_t vpi, uint16_t vfi)
{
sli4_cmd_init_vpi_t *init_vpi = buf;
ocs_memset(buf, 0, size);
init_vpi->hdr.command = SLI4_MBOX_COMMAND_INIT_VPI;
init_vpi->vpi = vpi;
init_vpi->vfi = vfi;
return sizeof(sli4_cmd_init_vpi_t);
}
/**
* @ingroup sli
* @brief Write a POST_XRI command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param xri_base Starting XRI value for range of XRI given to SLI Port.
* @param xri_count Number of XRIs provided to the SLI Port.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_post_xri(sli4_t *sli4, void *buf, size_t size, uint16_t xri_base, uint16_t xri_count)
{
sli4_cmd_post_xri_t *post_xri = buf;
ocs_memset(buf, 0, size);
post_xri->hdr.command = SLI4_MBOX_COMMAND_POST_XRI;
post_xri->xri_base = xri_base;
post_xri->xri_count = xri_count;
if (sli4->config.auto_xfer_rdy == 0) {
post_xri->enx = TRUE;
post_xri->val = TRUE;
}
return sizeof(sli4_cmd_post_xri_t);
}
/**
* @ingroup sli
* @brief Write a RELEASE_XRI command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param num_xri The number of XRIs to be released.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_release_xri(sli4_t *sli4, void *buf, size_t size, uint8_t num_xri)
{
sli4_cmd_release_xri_t *release_xri = buf;
ocs_memset(buf, 0, size);
release_xri->hdr.command = SLI4_MBOX_COMMAND_RELEASE_XRI;
release_xri->xri_count = num_xri;
return sizeof(sli4_cmd_release_xri_t);
}
/**
* @brief Write a READ_CONFIG command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes
*
* @return Returns the number of bytes written.
*/
static int32_t
sli_cmd_read_config(sli4_t *sli4, void *buf, size_t size)
{
sli4_cmd_read_config_t *read_config = buf;
ocs_memset(buf, 0, size);
read_config->hdr.command = SLI4_MBOX_COMMAND_READ_CONFIG;
return sizeof(sli4_cmd_read_config_t);
}
/**
* @brief Write a READ_NVPARMS command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_read_nvparms(sli4_t *sli4, void *buf, size_t size)
{
sli4_cmd_read_nvparms_t *read_nvparms = buf;
ocs_memset(buf, 0, size);
read_nvparms->hdr.command = SLI4_MBOX_COMMAND_READ_NVPARMS;
return sizeof(sli4_cmd_read_nvparms_t);
}
/**
* @brief Write a WRITE_NVPARMS command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param wwpn WWPN to write - pointer to array of 8 uint8_t.
* @param wwnn WWNN to write - pointer to array of 8 uint8_t.
* @param hard_alpa Hard ALPA to write.
* @param preferred_d_id Preferred D_ID to write.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_write_nvparms(sli4_t *sli4, void *buf, size_t size, uint8_t *wwpn, uint8_t *wwnn, uint8_t hard_alpa,
uint32_t preferred_d_id)
{
sli4_cmd_write_nvparms_t *write_nvparms = buf;
ocs_memset(buf, 0, size);
write_nvparms->hdr.command = SLI4_MBOX_COMMAND_WRITE_NVPARMS;
ocs_memcpy(write_nvparms->wwpn, wwpn, 8);
ocs_memcpy(write_nvparms->wwnn, wwnn, 8);
write_nvparms->hard_alpa = hard_alpa;
write_nvparms->preferred_d_id = preferred_d_id;
return sizeof(sli4_cmd_write_nvparms_t);
}
/**
* @brief Write a READ_REV command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param vpd Pointer to the buffer.
*
* @return Returns the number of bytes written.
*/
static int32_t
sli_cmd_read_rev(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *vpd)
{
sli4_cmd_read_rev_t *read_rev = buf;
ocs_memset(buf, 0, size);
read_rev->hdr.command = SLI4_MBOX_COMMAND_READ_REV;
if (vpd && vpd->size) {
read_rev->vpd = TRUE;
read_rev->available_length = vpd->size;
read_rev->physical_address_low = ocs_addr32_lo(vpd->phys);
read_rev->physical_address_high = ocs_addr32_hi(vpd->phys);
}
return sizeof(sli4_cmd_read_rev_t);
}
/**
* @ingroup sli
* @brief Write a READ_SPARM64 command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param dma DMA buffer for the service parameters.
* @param vpi VPI used to determine the WWN.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_read_sparm64(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *dma,
uint16_t vpi)
{
sli4_cmd_read_sparm64_t *read_sparm64 = buf;
ocs_memset(buf, 0, size);
if (SLI4_READ_SPARM64_VPI_SPECIAL == vpi) {
ocs_log_test(sli4->os, "special VPI not supported!!!\n");
return -1;
}
if (!dma || !dma->phys) {
ocs_log_test(sli4->os, "bad DMA buffer\n");
return -1;
}
read_sparm64->hdr.command = SLI4_MBOX_COMMAND_READ_SPARM64;
read_sparm64->bde_64.bde_type = SLI4_BDE_TYPE_BDE_64;
read_sparm64->bde_64.buffer_length = dma->size;
read_sparm64->bde_64.u.data.buffer_address_low = ocs_addr32_lo(dma->phys);
read_sparm64->bde_64.u.data.buffer_address_high = ocs_addr32_hi(dma->phys);
read_sparm64->vpi = vpi;
return sizeof(sli4_cmd_read_sparm64_t);
}
/**
* @ingroup sli
* @brief Write a READ_TOPOLOGY command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param dma DMA buffer for loop map (optional).
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_read_topology(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *dma)
{
sli4_cmd_read_topology_t *read_topo = buf;
ocs_memset(buf, 0, size);
read_topo->hdr.command = SLI4_MBOX_COMMAND_READ_TOPOLOGY;
if (dma && dma->size) {
if (dma->size < SLI4_MIN_LOOP_MAP_BYTES) {
ocs_log_test(sli4->os, "loop map buffer too small %jd\n",
dma->size);
return 0;
}
ocs_memset(dma->virt, 0, dma->size);
read_topo->bde_loop_map.bde_type = SLI4_BDE_TYPE_BDE_64;
read_topo->bde_loop_map.buffer_length = dma->size;
read_topo->bde_loop_map.u.data.buffer_address_low = ocs_addr32_lo(dma->phys);
read_topo->bde_loop_map.u.data.buffer_address_high = ocs_addr32_hi(dma->phys);
}
return sizeof(sli4_cmd_read_topology_t);
}
/**
* @ingroup sli
* @brief Write a REG_FCFI command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param index FCF index returned by READ_FCF_TABLE.
* @param rq_cfg RQ_ID/R_CTL/TYPE routing information
* @param vlan_id VLAN ID tag.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_reg_fcfi(sli4_t *sli4, void *buf, size_t size, uint16_t index, sli4_cmd_rq_cfg_t rq_cfg[SLI4_CMD_REG_FCFI_NUM_RQ_CFG], uint16_t vlan_id)
{
sli4_cmd_reg_fcfi_t *reg_fcfi = buf;
uint32_t i;
ocs_memset(buf, 0, size);
reg_fcfi->hdr.command = SLI4_MBOX_COMMAND_REG_FCFI;
reg_fcfi->fcf_index = index;
for (i = 0; i < SLI4_CMD_REG_FCFI_NUM_RQ_CFG; i++) {
switch(i) {
case 0: reg_fcfi->rq_id_0 = rq_cfg[0].rq_id; break;
case 1: reg_fcfi->rq_id_1 = rq_cfg[1].rq_id; break;
case 2: reg_fcfi->rq_id_2 = rq_cfg[2].rq_id; break;
case 3: reg_fcfi->rq_id_3 = rq_cfg[3].rq_id; break;
}
reg_fcfi->rq_cfg[i].r_ctl_mask = rq_cfg[i].r_ctl_mask;
reg_fcfi->rq_cfg[i].r_ctl_match = rq_cfg[i].r_ctl_match;
reg_fcfi->rq_cfg[i].type_mask = rq_cfg[i].type_mask;
reg_fcfi->rq_cfg[i].type_match = rq_cfg[i].type_match;
}
if (vlan_id) {
reg_fcfi->vv = TRUE;
reg_fcfi->vlan_tag = vlan_id;
}
return sizeof(sli4_cmd_reg_fcfi_t);
}
/**
* @brief Write REG_FCFI_MRQ to provided command buffer
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param fcf_index FCF index returned by READ_FCF_TABLE.
* @param vlan_id VLAN ID tag.
* @param rr_quant Round robin quanta if RQ selection policy is 2
* @param rq_selection_policy RQ selection policy
* @param num_rqs Array of count of RQs per filter
* @param rq_ids Array of RQ ids per filter
* @param rq_cfg RQ_ID/R_CTL/TYPE routing information
*
* @return returns 0 for success, a negative error code value for failure.
*/
int32_t
sli_cmd_reg_fcfi_mrq(sli4_t *sli4, void *buf, size_t size, uint8_t mode,
uint16_t fcf_index, uint16_t vlan_id, uint8_t rq_selection_policy,
uint8_t mrq_bit_mask, uint16_t num_mrqs,
sli4_cmd_rq_cfg_t rq_cfg[SLI4_CMD_REG_FCFI_NUM_RQ_CFG])
{
sli4_cmd_reg_fcfi_mrq_t *reg_fcfi_mrq = buf;
uint32_t i;
ocs_memset(buf, 0, size);
reg_fcfi_mrq->hdr.command = SLI4_MBOX_COMMAND_REG_FCFI_MRQ;
if (mode == SLI4_CMD_REG_FCFI_SET_FCFI_MODE) {
reg_fcfi_mrq->fcf_index = fcf_index;
if (vlan_id) {
reg_fcfi_mrq->vv = TRUE;
reg_fcfi_mrq->vlan_tag = vlan_id;
}
goto done;
}
reg_fcfi_mrq->mode = mode;
for (i = 0; i < SLI4_CMD_REG_FCFI_NUM_RQ_CFG; i++) {
reg_fcfi_mrq->rq_cfg[i].r_ctl_mask = rq_cfg[i].r_ctl_mask;
reg_fcfi_mrq->rq_cfg[i].r_ctl_match = rq_cfg[i].r_ctl_match;
reg_fcfi_mrq->rq_cfg[i].type_mask = rq_cfg[i].type_mask;
reg_fcfi_mrq->rq_cfg[i].type_match = rq_cfg[i].type_match;
switch(i) {
case 3: reg_fcfi_mrq->rq_id_3 = rq_cfg[i].rq_id; break;
case 2: reg_fcfi_mrq->rq_id_2 = rq_cfg[i].rq_id; break;
case 1: reg_fcfi_mrq->rq_id_1 = rq_cfg[i].rq_id; break;
case 0: reg_fcfi_mrq->rq_id_0 = rq_cfg[i].rq_id; break;
}
}
reg_fcfi_mrq->rq_selection_policy = rq_selection_policy;
reg_fcfi_mrq->mrq_filter_bitmask = mrq_bit_mask;
reg_fcfi_mrq->num_mrq_pairs = num_mrqs;
done:
return sizeof(sli4_cmd_reg_fcfi_mrq_t);
}
/**
* @ingroup sli
* @brief Write a REG_RPI command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param nport_id Remote F/N_Port_ID.
* @param rpi Previously-allocated Remote Port Indicator.
* @param vpi Previously-allocated Virtual Port Indicator.
* @param dma DMA buffer that contains the remote port's service parameters.
* @param update Boolean indicating an update to an existing RPI (TRUE)
* or a new registration (FALSE).
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_reg_rpi(sli4_t *sli4, void *buf, size_t size, uint32_t nport_id, uint16_t rpi,
uint16_t vpi, ocs_dma_t *dma, uint8_t update, uint8_t enable_t10_pi)
{
sli4_cmd_reg_rpi_t *reg_rpi = buf;
ocs_memset(buf, 0, size);
reg_rpi->hdr.command = SLI4_MBOX_COMMAND_REG_RPI;
reg_rpi->rpi = rpi;
reg_rpi->remote_n_port_id = nport_id;
reg_rpi->upd = update;
reg_rpi->etow = enable_t10_pi;
reg_rpi->bde_64.bde_type = SLI4_BDE_TYPE_BDE_64;
reg_rpi->bde_64.buffer_length = SLI4_REG_RPI_BUF_LEN;
reg_rpi->bde_64.u.data.buffer_address_low = ocs_addr32_lo(dma->phys);
reg_rpi->bde_64.u.data.buffer_address_high = ocs_addr32_hi(dma->phys);
reg_rpi->vpi = vpi;
return sizeof(sli4_cmd_reg_rpi_t);
}
/**
* @ingroup sli
* @brief Write a REG_VFI command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param domain Pointer to the domain object.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_reg_vfi(sli4_t *sli4, void *buf, size_t size, ocs_domain_t *domain)
{
sli4_cmd_reg_vfi_t *reg_vfi = buf;
if (!sli4 || !buf || !domain) {
return 0;
}
ocs_memset(buf, 0, size);
reg_vfi->hdr.command = SLI4_MBOX_COMMAND_REG_VFI;
reg_vfi->vfi = domain->indicator;
reg_vfi->fcfi = domain->fcf_indicator;
/* TODO contents of domain->dma only valid if topo == FABRIC */
reg_vfi->sparm.bde_type = SLI4_BDE_TYPE_BDE_64;
reg_vfi->sparm.buffer_length = 0x70;
reg_vfi->sparm.u.data.buffer_address_low = ocs_addr32_lo(domain->dma.phys);
reg_vfi->sparm.u.data.buffer_address_high = ocs_addr32_hi(domain->dma.phys);
reg_vfi->e_d_tov = sli4->config.e_d_tov;
reg_vfi->r_a_tov = sli4->config.r_a_tov;
reg_vfi->vp = TRUE;
reg_vfi->vpi = domain->sport->indicator;
ocs_memcpy(reg_vfi->wwpn, &domain->sport->sli_wwpn, sizeof(reg_vfi->wwpn));
reg_vfi->local_n_port_id = domain->sport->fc_id;
return sizeof(sli4_cmd_reg_vfi_t);
}
/**
* @ingroup sli
* @brief Write a REG_VPI command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param sport Point to SLI Port object.
* @param update Boolean indicating whether to update the existing VPI (true)
* or create a new VPI (false).
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_reg_vpi(sli4_t *sli4, void *buf, size_t size, ocs_sli_port_t *sport, uint8_t update)
{
sli4_cmd_reg_vpi_t *reg_vpi = buf;
if (!sli4 || !buf || !sport) {
return 0;
}
ocs_memset(buf, 0, size);
reg_vpi->hdr.command = SLI4_MBOX_COMMAND_REG_VPI;
reg_vpi->local_n_port_id = sport->fc_id;
reg_vpi->upd = update != 0;
ocs_memcpy(reg_vpi->wwpn, &sport->sli_wwpn, sizeof(reg_vpi->wwpn));
reg_vpi->vpi = sport->indicator;
reg_vpi->vfi = sport->domain->indicator;
return sizeof(sli4_cmd_reg_vpi_t);
}
/**
* @brief Write a REQUEST_FEATURES command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param mask Features to request.
* @param query Use feature query mode (does not change FW).
*
* @return Returns the number of bytes written.
*/
static int32_t
sli_cmd_request_features(sli4_t *sli4, void *buf, size_t size, sli4_features_t mask, uint8_t query)
{
sli4_cmd_request_features_t *features = buf;
ocs_memset(buf, 0, size);
features->hdr.command = SLI4_MBOX_COMMAND_REQUEST_FEATURES;
if (query) {
features->qry = TRUE;
}
features->command.dword = mask.dword;
return sizeof(sli4_cmd_request_features_t);
}
/**
* @ingroup sli
* @brief Write a SLI_CONFIG command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param length Length in bytes of attached command.
* @param dma DMA buffer for non-embedded commands.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_sli_config(sli4_t *sli4, void *buf, size_t size, uint32_t length, ocs_dma_t *dma)
{
sli4_cmd_sli_config_t *sli_config = NULL;
if ((length > sizeof(sli_config->payload.embed)) && (dma == NULL)) {
ocs_log_test(sli4->os, "length(%d) > payload(%ld)\n",
length, sizeof(sli_config->payload.embed));
return -1;
}
sli_config = buf;
ocs_memset(buf, 0, size);
sli_config->hdr.command = SLI4_MBOX_COMMAND_SLI_CONFIG;
if (NULL == dma) {
sli_config->emb = TRUE;
sli_config->payload_length = length;
} else {
sli_config->emb = FALSE;
sli_config->pmd_count = 1;
sli_config->payload.mem.address_low = ocs_addr32_lo(dma->phys);
sli_config->payload.mem.address_high = ocs_addr32_hi(dma->phys);
sli_config->payload.mem.length = dma->size;
sli_config->payload_length = dma->size;
#if defined(OCS_INCLUDE_DEBUG)
/* save pointer to DMA for BMBX dumping purposes */
sli4->bmbx_non_emb_pmd = dma;
#endif
}
return offsetof(sli4_cmd_sli_config_t, payload.embed);
}
/**
* @brief Initialize SLI Port control register.
*
* @param sli4 SLI context pointer.
* @param endian Endian value to write.
*
* @return Returns 0 on success, or a negative error code value on failure.
*/
static int32_t
sli_sliport_control(sli4_t *sli4, uint32_t endian)
{
uint32_t iter;
int32_t rc;
rc = -1;
/* Initialize port, endian */
sli_reg_write(sli4, SLI4_REG_SLIPORT_CONTROL, endian | SLI4_SLIPORT_CONTROL_IP);
for (iter = 0; iter < 3000; iter ++) {
ocs_udelay(SLI4_INIT_PORT_DELAY_US);
if (sli_fw_ready(sli4) == 1) {
rc = 0;
break;
}
}
if (rc != 0) {
ocs_log_crit(sli4->os, "port failed to become ready after initialization\n");
}
return rc;
}
/**
* @ingroup sli
* @brief Write a UNREG_FCFI command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param indicator Indicator value.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_unreg_fcfi(sli4_t *sli4, void *buf, size_t size, uint16_t indicator)
{
sli4_cmd_unreg_fcfi_t *unreg_fcfi = buf;
if (!sli4 || !buf) {
return 0;
}
ocs_memset(buf, 0, size);
unreg_fcfi->hdr.command = SLI4_MBOX_COMMAND_UNREG_FCFI;
unreg_fcfi->fcfi = indicator;
return sizeof(sli4_cmd_unreg_fcfi_t);
}
/**
* @ingroup sli
* @brief Write an UNREG_RPI command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param indicator Indicator value.
* @param which Type of unregister, such as node, port, domain, or FCF.
* @param fc_id FC address.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_unreg_rpi(sli4_t *sli4, void *buf, size_t size, uint16_t indicator, sli4_resource_e which,
uint32_t fc_id)
{
sli4_cmd_unreg_rpi_t *unreg_rpi = buf;
uint8_t index_indicator = 0;
if (!sli4 || !buf) {
return 0;
}
ocs_memset(buf, 0, size);
unreg_rpi->hdr.command = SLI4_MBOX_COMMAND_UNREG_RPI;
switch (which) {
case SLI_RSRC_FCOE_RPI:
index_indicator = SLI4_UNREG_RPI_II_RPI;
if (fc_id != UINT32_MAX) {
unreg_rpi->dp = TRUE;
unreg_rpi->destination_n_port_id = fc_id & 0x00ffffff;
}
break;
case SLI_RSRC_FCOE_VPI:
index_indicator = SLI4_UNREG_RPI_II_VPI;
break;
case SLI_RSRC_FCOE_VFI:
index_indicator = SLI4_UNREG_RPI_II_VFI;
break;
case SLI_RSRC_FCOE_FCFI:
index_indicator = SLI4_UNREG_RPI_II_FCFI;
break;
default:
ocs_log_test(sli4->os, "unknown type %#x\n", which);
return 0;
}
unreg_rpi->ii = index_indicator;
unreg_rpi->index = indicator;
return sizeof(sli4_cmd_unreg_rpi_t);
}
/**
* @ingroup sli
* @brief Write an UNREG_VFI command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param domain Pointer to the domain object
* @param which Type of unregister, such as domain, FCFI, or everything.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_unreg_vfi(sli4_t *sli4, void *buf, size_t size, ocs_domain_t *domain, uint32_t which)
{
sli4_cmd_unreg_vfi_t *unreg_vfi = buf;
if (!sli4 || !buf || !domain) {
return 0;
}
ocs_memset(buf, 0, size);
unreg_vfi->hdr.command = SLI4_MBOX_COMMAND_UNREG_VFI;
switch (which) {
case SLI4_UNREG_TYPE_DOMAIN:
unreg_vfi->index = domain->indicator;
break;
case SLI4_UNREG_TYPE_FCF:
unreg_vfi->index = domain->fcf_indicator;
break;
case SLI4_UNREG_TYPE_ALL:
unreg_vfi->index = UINT16_MAX;
break;
default:
return 0;
}
if (SLI4_UNREG_TYPE_DOMAIN != which) {
unreg_vfi->ii = SLI4_UNREG_VFI_II_FCFI;
}
return sizeof(sli4_cmd_unreg_vfi_t);
}
/**
* @ingroup sli
* @brief Write an UNREG_VPI command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param indicator Indicator value.
* @param which Type of unregister: port, domain, FCFI, everything
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_unreg_vpi(sli4_t *sli4, void *buf, size_t size, uint16_t indicator, uint32_t which)
{
sli4_cmd_unreg_vpi_t *unreg_vpi = buf;
if (!sli4 || !buf) {
return 0;
}
ocs_memset(buf, 0, size);
unreg_vpi->hdr.command = SLI4_MBOX_COMMAND_UNREG_VPI;
unreg_vpi->index = indicator;
switch (which) {
case SLI4_UNREG_TYPE_PORT:
unreg_vpi->ii = SLI4_UNREG_VPI_II_VPI;
break;
case SLI4_UNREG_TYPE_DOMAIN:
unreg_vpi->ii = SLI4_UNREG_VPI_II_VFI;
break;
case SLI4_UNREG_TYPE_FCF:
unreg_vpi->ii = SLI4_UNREG_VPI_II_FCFI;
break;
case SLI4_UNREG_TYPE_ALL:
unreg_vpi->index = UINT16_MAX; /* override indicator */
unreg_vpi->ii = SLI4_UNREG_VPI_II_FCFI;
break;
default:
return 0;
}
return sizeof(sli4_cmd_unreg_vpi_t);
}
/**
* @ingroup sli
* @brief Write an CONFIG_AUTO_XFER_RDY command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param max_burst_len if the write FCP_DL is less than this size,
* then the SLI port will generate the auto XFER_RDY.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_config_auto_xfer_rdy(sli4_t *sli4, void *buf, size_t size, uint32_t max_burst_len)
{
sli4_cmd_config_auto_xfer_rdy_t *req = buf;
if (!sli4 || !buf) {
return 0;
}
ocs_memset(buf, 0, size);
req->hdr.command = SLI4_MBOX_COMMAND_CONFIG_AUTO_XFER_RDY;
req->max_burst_len = max_burst_len;
return sizeof(sli4_cmd_config_auto_xfer_rdy_t);
}
/**
* @ingroup sli
* @brief Write an CONFIG_AUTO_XFER_RDY_HP command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to the destination buffer.
* @param size Buffer size, in bytes.
* @param max_burst_len if the write FCP_DL is less than this size,
* @param esoc enable start offset computation,
* @param block_size block size,
* then the SLI port will generate the auto XFER_RDY.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_config_auto_xfer_rdy_hp(sli4_t *sli4, void *buf, size_t size, uint32_t max_burst_len,
uint32_t esoc, uint32_t block_size )
{
sli4_cmd_config_auto_xfer_rdy_hp_t *req = buf;
if (!sli4 || !buf) {
return 0;
}
ocs_memset(buf, 0, size);
req->hdr.command = SLI4_MBOX_COMMAND_CONFIG_AUTO_XFER_RDY_HP;
req->max_burst_len = max_burst_len;
req->esoc = esoc;
req->block_size = block_size;
return sizeof(sli4_cmd_config_auto_xfer_rdy_hp_t);
}
/**
* @brief Write a COMMON_FUNCTION_RESET command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
*
* @return Returns the number of bytes written.
*/
static int32_t
sli_cmd_common_function_reset(sli4_t *sli4, void *buf, size_t size)
{
sli4_req_common_function_reset_t *reset = NULL;
uint32_t sli_config_off = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
uint32_t payload_size;
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_common_function_reset_t),
sizeof(sli4_res_common_function_reset_t));
sli_config_off = sli_cmd_sli_config(sli4, buf, size, payload_size,
NULL);
}
reset = (sli4_req_common_function_reset_t *)((uint8_t *)buf + sli_config_off);
reset->hdr.opcode = SLI4_OPC_COMMON_FUNCTION_RESET;
reset->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
return(sli_config_off + sizeof(sli4_req_common_function_reset_t));
}
/**
* @brief Write a COMMON_CREATE_CQ command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param qmem DMA memory for the queue.
* @param eq_id Associated EQ_ID
* @param ignored This parameter carries the ULP which is only used for WQ and RQs
*
* @note This creates a Version 0 message.
*
* @return Returns the number of bytes written.
*/
static int32_t
sli_cmd_common_create_cq(sli4_t *sli4, void *buf, size_t size,
ocs_dma_t *qmem, uint16_t eq_id, uint16_t ignored)
{
sli4_req_common_create_cq_v0_t *cqv0 = NULL;
sli4_req_common_create_cq_v2_t *cqv2 = NULL;
uint32_t sli_config_off = 0;
uint32_t p;
uintptr_t addr;
uint32_t if_type = sli4->if_type;
uint32_t page_bytes = 0;
uint32_t num_pages = 0;
uint32_t cmd_size = 0;
uint32_t page_size = 0;
uint32_t n_cqe = 0;
/* First calculate number of pages and the mailbox cmd length */
switch (if_type)
{
case SLI4_IF_TYPE_BE3_SKH_PF:
page_bytes = SLI_PAGE_SIZE;
num_pages = sli_page_count(qmem->size, page_bytes);
cmd_size = sizeof(sli4_req_common_create_cq_v0_t) + (8 * num_pages);
break;
case SLI4_IF_TYPE_LANCER_FC_ETH:
n_cqe = qmem->size / SLI4_CQE_BYTES;
switch (n_cqe) {
case 256:
case 512:
case 1024:
case 2048:
page_size = 1;
break;
case 4096:
page_size = 2;
break;
default:
return 0;
}
page_bytes = page_size * SLI_PAGE_SIZE;
num_pages = sli_page_count(qmem->size, page_bytes);
cmd_size = sizeof(sli4_req_common_create_cq_v2_t) + (8 * num_pages);
break;
default:
ocs_log_test(sli4->os, "unsupported IF_TYPE %d\n", if_type);
return -1;
}
/* now that we have the mailbox command size, we can set SLI_CONFIG fields */
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
uint32_t payload_size;
/* Payload length must accommodate both request and response */
payload_size = max((size_t)cmd_size, sizeof(sli4_res_common_create_queue_t));
sli_config_off = sli_cmd_sli_config(sli4, buf, size, payload_size,
NULL);
}
switch (if_type)
{
case SLI4_IF_TYPE_BE3_SKH_PF:
cqv0 = (sli4_req_common_create_cq_v0_t *)((uint8_t *)buf + sli_config_off);
cqv0->hdr.opcode = SLI4_OPC_COMMON_CREATE_CQ;
cqv0->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
cqv0->hdr.version = 0;
cqv0->hdr.request_length = cmd_size - sizeof(sli4_req_hdr_t);
/* valid values for number of pages: 1, 2, 4 (sec 4.4.3) */
cqv0->num_pages = num_pages;
switch (cqv0->num_pages) {
case 1:
cqv0->cqecnt = SLI4_CQ_CNT_256;
break;
case 2:
cqv0->cqecnt = SLI4_CQ_CNT_512;
break;
case 4:
cqv0->cqecnt = SLI4_CQ_CNT_1024;
break;
default:
ocs_log_test(sli4->os, "num_pages %d not valid\n", cqv0->num_pages);
return -1;
}
cqv0->evt = TRUE;
cqv0->valid = TRUE;
/* TODO cq->nodelay = ???; */
/* TODO cq->clswm = ???; */
cqv0->arm = FALSE;
cqv0->eq_id = eq_id;
for (p = 0, addr = qmem->phys;
p < cqv0->num_pages;
p++, addr += page_bytes) {
cqv0->page_physical_address[p].low = ocs_addr32_lo(addr);
cqv0->page_physical_address[p].high = ocs_addr32_hi(addr);
}
break;
case SLI4_IF_TYPE_LANCER_FC_ETH:
{
cqv2 = (sli4_req_common_create_cq_v2_t *)((uint8_t *)buf + sli_config_off);
cqv2->hdr.opcode = SLI4_OPC_COMMON_CREATE_CQ;
cqv2->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
cqv2->hdr.version = 2;
cqv2->hdr.request_length = cmd_size - sizeof(sli4_req_hdr_t);
cqv2->page_size = page_size;
/* valid values for number of pages: 1, 2, 4, 8 (sec 4.4.3) */
cqv2->num_pages = num_pages;
if (!cqv2->num_pages || (cqv2->num_pages > SLI4_COMMON_CREATE_CQ_V2_MAX_PAGES)) {
return 0;
}
switch (cqv2->num_pages) {
case 1:
cqv2->cqecnt = SLI4_CQ_CNT_256;
break;
case 2:
cqv2->cqecnt = SLI4_CQ_CNT_512;
break;
case 4:
cqv2->cqecnt = SLI4_CQ_CNT_1024;
break;
case 8:
cqv2->cqecnt = SLI4_CQ_CNT_LARGE;
cqv2->cqe_count = n_cqe;
break;
default:
ocs_log_test(sli4->os, "num_pages %d not valid\n", cqv2->num_pages);
return -1;
}
cqv2->evt = TRUE;
cqv2->valid = TRUE;
/* TODO cq->nodelay = ???; */
/* TODO cq->clswm = ???; */
cqv2->arm = FALSE;
cqv2->eq_id = eq_id;
for (p = 0, addr = qmem->phys;
p < cqv2->num_pages;
p++, addr += page_bytes) {
cqv2->page_physical_address[p].low = ocs_addr32_lo(addr);
cqv2->page_physical_address[p].high = ocs_addr32_hi(addr);
}
}
break;
default:
ocs_log_test(sli4->os, "unsupported IF_TYPE %d\n", if_type);
return -1;
}
return (sli_config_off + cmd_size);
}
/**
* @brief Write a COMMON_DESTROY_CQ command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param cq_id CQ ID
*
* @note This creates a Version 0 message.
*
* @return Returns the number of bytes written.
*/
static int32_t
sli_cmd_common_destroy_cq(sli4_t *sli4, void *buf, size_t size, uint16_t cq_id)
{
sli4_req_common_destroy_cq_t *cq = NULL;
uint32_t sli_config_off = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
/* Payload length must accommodate both request and response */
max(sizeof(sli4_req_common_destroy_cq_t),
sizeof(sli4_res_hdr_t)),
NULL);
}
cq = (sli4_req_common_destroy_cq_t *)((uint8_t *)buf + sli_config_off);
cq->hdr.opcode = SLI4_OPC_COMMON_DESTROY_CQ;
cq->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
cq->hdr.request_length = sizeof(sli4_req_common_destroy_cq_t) -
sizeof(sli4_req_hdr_t);
cq->cq_id = cq_id;
return(sli_config_off + sizeof(sli4_req_common_destroy_cq_t));
}
/**
* @brief Write a COMMON_MODIFY_EQ_DELAY command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param q Queue object array.
* @param num_q Queue object array count.
* @param shift Phase shift for staggering interrupts.
* @param delay_mult Delay multiplier for limiting interrupt frequency.
*
* @return Returns the number of bytes written.
*/
static int32_t
sli_cmd_common_modify_eq_delay(sli4_t *sli4, void *buf, size_t size, sli4_queue_t *q, int num_q, uint32_t shift,
uint32_t delay_mult)
{
sli4_req_common_modify_eq_delay_t *modify_delay = NULL;
uint32_t sli_config_off = 0;
int i;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
/* Payload length must accommodate both request and response */
max(sizeof(sli4_req_common_modify_eq_delay_t), sizeof(sli4_res_hdr_t)),
NULL);
}
modify_delay = (sli4_req_common_modify_eq_delay_t *)((uint8_t *)buf + sli_config_off);
modify_delay->hdr.opcode = SLI4_OPC_COMMON_MODIFY_EQ_DELAY;
modify_delay->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
modify_delay->hdr.request_length = sizeof(sli4_req_common_modify_eq_delay_t) -
sizeof(sli4_req_hdr_t);
modify_delay->num_eq = num_q;
for (i = 0; i<num_q; i++) {
modify_delay->eq_delay_record[i].eq_id = q[i].id;
modify_delay->eq_delay_record[i].phase = shift;
modify_delay->eq_delay_record[i].delay_multiplier = delay_mult;
}
return(sli_config_off + sizeof(sli4_req_common_modify_eq_delay_t));
}
/**
* @brief Write a COMMON_CREATE_EQ command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param qmem DMA memory for the queue.
* @param ignored1 Ignored (used for consistency among queue creation functions).
* @param ignored2 Ignored (used for consistency among queue creation functions).
*
* @note Other queue creation routines use the last parameter to pass in
* the associated Q_ID and ULP. EQ doesn't have an associated queue or ULP,
* so these parameters are ignored
*
* @note This creates a Version 0 message
*
* @return Returns the number of bytes written.
*/
static int32_t
sli_cmd_common_create_eq(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *qmem,
uint16_t ignored1, uint16_t ignored2)
{
sli4_req_common_create_eq_t *eq = NULL;
uint32_t sli_config_off = 0;
uint32_t p;
uintptr_t addr;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
uint32_t payload_size;
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_common_create_eq_t),
sizeof(sli4_res_common_create_queue_t));
sli_config_off = sli_cmd_sli_config(sli4, buf, size, payload_size,
NULL);
}
eq = (sli4_req_common_create_eq_t *)((uint8_t *)buf + sli_config_off);
eq->hdr.opcode = SLI4_OPC_COMMON_CREATE_EQ;
eq->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
eq->hdr.request_length = sizeof(sli4_req_common_create_eq_t) -
sizeof(sli4_req_hdr_t);
/* valid values for number of pages: 1, 2, 4 (sec 4.4.3) */
eq->num_pages = qmem->size / SLI_PAGE_SIZE;
switch (eq->num_pages) {
case 1:
eq->eqesz = SLI4_EQE_SIZE_4;
eq->count = SLI4_EQ_CNT_1024;
break;
case 2:
eq->eqesz = SLI4_EQE_SIZE_4;
eq->count = SLI4_EQ_CNT_2048;
break;
case 4:
eq->eqesz = SLI4_EQE_SIZE_4;
eq->count = SLI4_EQ_CNT_4096;
break;
default:
ocs_log_test(sli4->os, "num_pages %d not valid\n", eq->num_pages);
return -1;
}
eq->valid = TRUE;
eq->arm = FALSE;
eq->delay_multiplier = 32;
for (p = 0, addr = qmem->phys;
p < eq->num_pages;
p++, addr += SLI_PAGE_SIZE) {
eq->page_address[p].low = ocs_addr32_lo(addr);
eq->page_address[p].high = ocs_addr32_hi(addr);
}
return(sli_config_off + sizeof(sli4_req_common_create_eq_t));
}
/**
* @brief Write a COMMON_DESTROY_EQ command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param eq_id Queue ID to destroy.
*
* @note Other queue creation routines use the last parameter to pass in
* the associated Q_ID. EQ doesn't have an associated queue so this
* parameter is ignored.
*
* @note This creates a Version 0 message.
*
* @return Returns the number of bytes written.
*/
static int32_t
sli_cmd_common_destroy_eq(sli4_t *sli4, void *buf, size_t size, uint16_t eq_id)
{
sli4_req_common_destroy_eq_t *eq = NULL;
uint32_t sli_config_off = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
/* Payload length must accommodate both request and response */
max(sizeof(sli4_req_common_destroy_eq_t),
sizeof(sli4_res_hdr_t)),
NULL);
}
eq = (sli4_req_common_destroy_eq_t *)((uint8_t *)buf + sli_config_off);
eq->hdr.opcode = SLI4_OPC_COMMON_DESTROY_EQ;
eq->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
eq->hdr.request_length = sizeof(sli4_req_common_destroy_eq_t) -
sizeof(sli4_req_hdr_t);
eq->eq_id = eq_id;
return(sli_config_off + sizeof(sli4_req_common_destroy_eq_t));
}
/**
* @brief Write a LOWLEVEL_SET_WATCHDOG command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param timeout watchdog timer timeout in seconds
*
* @return void
*/
void
sli4_cmd_lowlevel_set_watchdog(sli4_t *sli4, void *buf, size_t size, uint16_t timeout)
{
sli4_req_lowlevel_set_watchdog_t *req = NULL;
uint32_t sli_config_off = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
/* Payload length must accommodate both request and response */
max(sizeof(sli4_req_lowlevel_set_watchdog_t),
sizeof(sli4_res_lowlevel_set_watchdog_t)),
NULL);
}
req = (sli4_req_lowlevel_set_watchdog_t *)((uint8_t *)buf + sli_config_off);
req->hdr.opcode = SLI4_OPC_LOWLEVEL_SET_WATCHDOG;
req->hdr.subsystem = SLI4_SUBSYSTEM_LOWLEVEL;
req->hdr.request_length = sizeof(sli4_req_lowlevel_set_watchdog_t) - sizeof(sli4_req_hdr_t);
req->watchdog_timeout = timeout;
return;
}
static int32_t
sli_cmd_common_get_cntl_attributes(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *dma)
{
sli4_req_hdr_t *hdr = NULL;
uint32_t sli_config_off = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
sizeof(sli4_req_hdr_t),
dma);
}
if (dma == NULL) {
return 0;
}
ocs_memset(dma->virt, 0, dma->size);
hdr = dma->virt;
hdr->opcode = SLI4_OPC_COMMON_GET_CNTL_ATTRIBUTES;
hdr->subsystem = SLI4_SUBSYSTEM_COMMON;
hdr->request_length = dma->size;
return(sli_config_off + sizeof(sli4_req_hdr_t));
}
/**
* @brief Write a COMMON_GET_CNTL_ADDL_ATTRIBUTES command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param dma DMA structure from which the data will be copied.
*
* @note This creates a Version 0 message.
*
* @return Returns the number of bytes written.
*/
static int32_t
sli_cmd_common_get_cntl_addl_attributes(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *dma)
{
sli4_req_hdr_t *hdr = NULL;
uint32_t sli_config_off = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size, sizeof(sli4_req_hdr_t), dma);
}
if (dma == NULL) {
return 0;
}
ocs_memset(dma->virt, 0, dma->size);
hdr = dma->virt;
hdr->opcode = SLI4_OPC_COMMON_GET_CNTL_ADDL_ATTRIBUTES;
hdr->subsystem = SLI4_SUBSYSTEM_COMMON;
hdr->request_length = dma->size;
return(sli_config_off + sizeof(sli4_req_hdr_t));
}
/**
* @brief Write a COMMON_CREATE_MQ_EXT command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param qmem DMA memory for the queue.
* @param cq_id Associated CQ_ID.
* @param ignored This parameter carries the ULP which is only used for WQ and RQs
*
* @note This creates a Version 0 message.
*
* @return Returns the number of bytes written.
*/
static int32_t
sli_cmd_common_create_mq_ext(sli4_t *sli4, void *buf, size_t size,
ocs_dma_t *qmem, uint16_t cq_id, uint16_t ignored)
{
sli4_req_common_create_mq_ext_t *mq = NULL;
uint32_t sli_config_off = 0;
uint32_t p;
uintptr_t addr;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
uint32_t payload_size;
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_common_create_mq_ext_t),
sizeof(sli4_res_common_create_queue_t));
sli_config_off = sli_cmd_sli_config(sli4, buf, size, payload_size,
NULL);
}
mq = (sli4_req_common_create_mq_ext_t *)((uint8_t *)buf + sli_config_off);
mq->hdr.opcode = SLI4_OPC_COMMON_CREATE_MQ_EXT;
mq->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
mq->hdr.request_length = sizeof(sli4_req_common_create_mq_ext_t) -
sizeof(sli4_req_hdr_t);
/* valid values for number of pages: 1, 2, 4, 8 (sec 4.4.12) */
mq->num_pages = qmem->size / SLI_PAGE_SIZE;
switch (mq->num_pages) {
case 1:
mq->ring_size = SLI4_MQE_SIZE_16;
break;
case 2:
mq->ring_size = SLI4_MQE_SIZE_32;
break;
case 4:
mq->ring_size = SLI4_MQE_SIZE_64;
break;
case 8:
mq->ring_size = SLI4_MQE_SIZE_128;
break;
default:
ocs_log_test(sli4->os, "num_pages %d not valid\n", mq->num_pages);
return -1;
}
/* TODO break this down by sli4->config.topology */
mq->async_event_bitmap = SLI4_ASYNC_EVT_FC_FCOE;
if (sli4->config.mq_create_version) {
mq->cq_id_v1 = cq_id;
mq->hdr.version = 1;
}
else {
mq->cq_id_v0 = cq_id;
}
mq->val = TRUE;
for (p = 0, addr = qmem->phys;
p < mq->num_pages;
p++, addr += SLI_PAGE_SIZE) {
mq->page_physical_address[p].low = ocs_addr32_lo(addr);
mq->page_physical_address[p].high = ocs_addr32_hi(addr);
}
return(sli_config_off + sizeof(sli4_req_common_create_mq_ext_t));
}
/**
* @brief Write a COMMON_DESTROY_MQ command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param mq_id MQ ID
*
* @note This creates a Version 0 message.
*
* @return Returns the number of bytes written.
*/
static int32_t
sli_cmd_common_destroy_mq(sli4_t *sli4, void *buf, size_t size, uint16_t mq_id)
{
sli4_req_common_destroy_mq_t *mq = NULL;
uint32_t sli_config_off = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
/* Payload length must accommodate both request and response */
max(sizeof(sli4_req_common_destroy_mq_t),
sizeof(sli4_res_hdr_t)),
NULL);
}
mq = (sli4_req_common_destroy_mq_t *)((uint8_t *)buf + sli_config_off);
mq->hdr.opcode = SLI4_OPC_COMMON_DESTROY_MQ;
mq->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
mq->hdr.request_length = sizeof(sli4_req_common_destroy_mq_t) -
sizeof(sli4_req_hdr_t);
mq->mq_id = mq_id;
return(sli_config_off + sizeof(sli4_req_common_destroy_mq_t));
}
/**
* @ingroup sli
* @brief Write a COMMON_NOP command
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param context NOP context value (passed to response, except on FC/FCoE).
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_common_nop(sli4_t *sli4, void *buf, size_t size, uint64_t context)
{
sli4_req_common_nop_t *nop = NULL;
uint32_t sli_config_off = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
/* Payload length must accommodate both request and response */
max(sizeof(sli4_req_common_nop_t), sizeof(sli4_res_common_nop_t)),
NULL);
}
nop = (sli4_req_common_nop_t *)((uint8_t *)buf + sli_config_off);
nop->hdr.opcode = SLI4_OPC_COMMON_NOP;
nop->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
nop->hdr.request_length = 8;
ocs_memcpy(&nop->context, &context, sizeof(context));
return(sli_config_off + sizeof(sli4_req_common_nop_t));
}
/**
* @ingroup sli
* @brief Write a COMMON_GET_RESOURCE_EXTENT_INFO command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param rtype Resource type (for example, XRI, VFI, VPI, and RPI).
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_common_get_resource_extent_info(sli4_t *sli4, void *buf, size_t size, uint16_t rtype)
{
sli4_req_common_get_resource_extent_info_t *extent = NULL;
uint32_t sli_config_off = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
sizeof(sli4_req_common_get_resource_extent_info_t),
NULL);
}
extent = (sli4_req_common_get_resource_extent_info_t *)((uint8_t *)buf + sli_config_off);
extent->hdr.opcode = SLI4_OPC_COMMON_GET_RESOURCE_EXTENT_INFO;
extent->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
extent->hdr.request_length = 4;
extent->resource_type = rtype;
return(sli_config_off + sizeof(sli4_req_common_get_resource_extent_info_t));
}
/**
* @ingroup sli
* @brief Write a COMMON_GET_SLI4_PARAMETERS command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_common_get_sli4_parameters(sli4_t *sli4, void *buf, size_t size)
{
sli4_req_hdr_t *hdr = NULL;
uint32_t sli_config_off = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
sizeof(sli4_res_common_get_sli4_parameters_t),
NULL);
}
hdr = (sli4_req_hdr_t *)((uint8_t *)buf + sli_config_off);
hdr->opcode = SLI4_OPC_COMMON_GET_SLI4_PARAMETERS;
hdr->subsystem = SLI4_SUBSYSTEM_COMMON;
hdr->request_length = 0x50;
return(sli_config_off + sizeof(sli4_req_hdr_t));
}
/**
* @brief Write a COMMON_QUERY_FW_CONFIG command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to destination buffer.
* @param size Buffer size in bytes.
*
* @return Returns the number of bytes written
*/
static int32_t
sli_cmd_common_query_fw_config(sli4_t *sli4, void *buf, size_t size)
{
sli4_req_common_query_fw_config_t *fw_config;
uint32_t sli_config_off = 0;
uint32_t payload_size;
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_common_query_fw_config_t),
sizeof(sli4_res_common_query_fw_config_t));
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
payload_size,
NULL);
}
fw_config = (sli4_req_common_query_fw_config_t*)((uint8_t*)buf + sli_config_off);
fw_config->hdr.opcode = SLI4_OPC_COMMON_QUERY_FW_CONFIG;
fw_config->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
fw_config->hdr.request_length = payload_size - sizeof(sli4_req_hdr_t);
return sli_config_off + sizeof(sli4_req_common_query_fw_config_t);
}
/**
* @brief Write a COMMON_GET_PORT_NAME command to the provided buffer.
*
* @param sli4 SLI context pointer.
* @param buf Virtual pointer to destination buffer.
* @param size Buffer size in bytes.
*
* @note Function supports both version 0 and 1 forms of this command via
* the IF_TYPE.
*
* @return Returns the number of bytes written.
*/
static int32_t
sli_cmd_common_get_port_name(sli4_t *sli4, void *buf, size_t size)
{
sli4_req_common_get_port_name_t *port_name;
uint32_t sli_config_off = 0;
uint32_t payload_size;
uint8_t version = 0;
uint8_t pt = 0;
/* Select command version according to IF_TYPE */
switch (sli4->if_type) {
case SLI4_IF_TYPE_BE3_SKH_PF:
case SLI4_IF_TYPE_BE3_SKH_VF:
version = 0;
break;
case SLI4_IF_TYPE_LANCER_FC_ETH:
case SLI4_IF_TYPE_LANCER_RDMA:
version = 1;
break;
default:
ocs_log_test(sli4->os, "unsupported IF_TYPE %d\n", sli4->if_type);
return 0;
}
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_common_get_port_name_t),
sizeof(sli4_res_common_get_port_name_t));
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
payload_size,
NULL);
pt = 1;
}
port_name = (sli4_req_common_get_port_name_t *)((uint8_t *)buf + sli_config_off);
port_name->hdr.opcode = SLI4_OPC_COMMON_GET_PORT_NAME;
port_name->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
port_name->hdr.request_length = sizeof(sli4_req_hdr_t) + (version * sizeof(uint32_t));
port_name->hdr.version = version;
/* Set the port type value (ethernet=0, FC=1) for V1 commands */
if (version == 1) {
port_name->pt = pt;
}
return sli_config_off + port_name->hdr.request_length;
}
/**
* @ingroup sli
* @brief Write a COMMON_WRITE_OBJECT command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param noc True if the object should be written but not committed to flash.
* @param eof True if this is the last write for this object.
* @param desired_write_length Number of bytes of data to write to the object.
* @param offset Offset, in bytes, from the start of the object.
* @param object_name Name of the object to write.
* @param dma DMA structure from which the data will be copied.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_common_write_object(sli4_t *sli4, void *buf, size_t size,
uint16_t noc, uint16_t eof, uint32_t desired_write_length,
uint32_t offset,
char *object_name,
ocs_dma_t *dma)
{
sli4_req_common_write_object_t *wr_obj = NULL;
uint32_t sli_config_off = 0;
sli4_bde_t *host_buffer;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
sizeof (sli4_req_common_write_object_t) + sizeof (sli4_bde_t),
NULL);
}
wr_obj = (sli4_req_common_write_object_t *)((uint8_t *)buf + sli_config_off);
wr_obj->hdr.opcode = SLI4_OPC_COMMON_WRITE_OBJECT;
wr_obj->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
wr_obj->hdr.request_length = sizeof(*wr_obj) - 4*sizeof(uint32_t) + sizeof(sli4_bde_t);
wr_obj->hdr.timeout = 0;
wr_obj->hdr.version = 0;
wr_obj->noc = noc;
wr_obj->eof = eof;
wr_obj->desired_write_length = desired_write_length;
wr_obj->write_offset = offset;
ocs_strncpy(wr_obj->object_name, object_name, sizeof(wr_obj->object_name));
wr_obj->host_buffer_descriptor_count = 1;
host_buffer = (sli4_bde_t *)wr_obj->host_buffer_descriptor;
/* Setup to transfer xfer_size bytes to device */
host_buffer->bde_type = SLI4_BDE_TYPE_BDE_64;
host_buffer->buffer_length = desired_write_length;
host_buffer->u.data.buffer_address_low = ocs_addr32_lo(dma->phys);
host_buffer->u.data.buffer_address_high = ocs_addr32_hi(dma->phys);
return(sli_config_off + sizeof(sli4_req_common_write_object_t) + sizeof (sli4_bde_t));
}
/**
* @ingroup sli
* @brief Write a COMMON_DELETE_OBJECT command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param object_name Name of the object to write.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_common_delete_object(sli4_t *sli4, void *buf, size_t size,
char *object_name)
{
sli4_req_common_delete_object_t *del_obj = NULL;
uint32_t sli_config_off = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
sizeof (sli4_req_common_delete_object_t),
NULL);
}
del_obj = (sli4_req_common_delete_object_t *)((uint8_t *)buf + sli_config_off);
del_obj->hdr.opcode = SLI4_OPC_COMMON_DELETE_OBJECT;
del_obj->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
del_obj->hdr.request_length = sizeof(*del_obj);
del_obj->hdr.timeout = 0;
del_obj->hdr.version = 0;
ocs_strncpy(del_obj->object_name, object_name, sizeof(del_obj->object_name));
return(sli_config_off + sizeof(sli4_req_common_delete_object_t));
}
/**
* @ingroup sli
* @brief Write a COMMON_READ_OBJECT command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param desired_read_length Number of bytes of data to read from the object.
* @param offset Offset, in bytes, from the start of the object.
* @param object_name Name of the object to read.
* @param dma DMA structure from which the data will be copied.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_common_read_object(sli4_t *sli4, void *buf, size_t size,
uint32_t desired_read_length,
uint32_t offset,
char *object_name,
ocs_dma_t *dma)
{
sli4_req_common_read_object_t *rd_obj = NULL;
uint32_t sli_config_off = 0;
sli4_bde_t *host_buffer;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
sizeof (sli4_req_common_read_object_t) + sizeof (sli4_bde_t),
NULL);
}
rd_obj = (sli4_req_common_read_object_t *)((uint8_t *)buf + sli_config_off);
rd_obj->hdr.opcode = SLI4_OPC_COMMON_READ_OBJECT;
rd_obj->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
rd_obj->hdr.request_length = sizeof(*rd_obj) - 4*sizeof(uint32_t) + sizeof(sli4_bde_t);
rd_obj->hdr.timeout = 0;
rd_obj->hdr.version = 0;
rd_obj->desired_read_length = desired_read_length;
rd_obj->read_offset = offset;
ocs_strncpy(rd_obj->object_name, object_name, sizeof(rd_obj->object_name));
rd_obj->host_buffer_descriptor_count = 1;
host_buffer = (sli4_bde_t *)rd_obj->host_buffer_descriptor;
/* Setup to transfer xfer_size bytes to device */
host_buffer->bde_type = SLI4_BDE_TYPE_BDE_64;
host_buffer->buffer_length = desired_read_length;
if (dma != NULL) {
host_buffer->u.data.buffer_address_low = ocs_addr32_lo(dma->phys);
host_buffer->u.data.buffer_address_high = ocs_addr32_hi(dma->phys);
} else {
host_buffer->u.data.buffer_address_low = 0;
host_buffer->u.data.buffer_address_high = 0;
}
return(sli_config_off + sizeof(sli4_req_common_read_object_t) + sizeof (sli4_bde_t));
}
/**
* @ingroup sli
* @brief Write a DMTF_EXEC_CLP_CMD command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param cmd DMA structure that describes the buffer for the command.
* @param resp DMA structure that describes the buffer for the response.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_dmtf_exec_clp_cmd(sli4_t *sli4, void *buf, size_t size,
ocs_dma_t *cmd,
ocs_dma_t *resp)
{
sli4_req_dmtf_exec_clp_cmd_t *clp_cmd = NULL;
uint32_t sli_config_off = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
sizeof (sli4_req_dmtf_exec_clp_cmd_t),
NULL);
}
clp_cmd = (sli4_req_dmtf_exec_clp_cmd_t*)((uint8_t *)buf + sli_config_off);
clp_cmd->hdr.opcode = SLI4_OPC_DMTF_EXEC_CLP_CMD;
clp_cmd->hdr.subsystem = SLI4_SUBSYSTEM_DMTF;
clp_cmd->hdr.request_length = sizeof(sli4_req_dmtf_exec_clp_cmd_t) -
sizeof(sli4_req_hdr_t);
clp_cmd->hdr.timeout = 0;
clp_cmd->hdr.version = 0;
clp_cmd->cmd_buf_length = cmd->size;
clp_cmd->cmd_buf_addr_low = ocs_addr32_lo(cmd->phys);
clp_cmd->cmd_buf_addr_high = ocs_addr32_hi(cmd->phys);
clp_cmd->resp_buf_length = resp->size;
clp_cmd->resp_buf_addr_low = ocs_addr32_lo(resp->phys);
clp_cmd->resp_buf_addr_high = ocs_addr32_hi(resp->phys);
return(sli_config_off + sizeof(sli4_req_dmtf_exec_clp_cmd_t));
}
/**
* @ingroup sli
* @brief Write a COMMON_SET_DUMP_LOCATION command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param query Zero to set dump location, non-zero to query dump size
* @param is_buffer_list Set to one if the buffer is a set of buffer descriptors or
* set to 0 if the buffer is a contiguous dump area.
* @param buffer DMA structure to which the dump will be copied.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_common_set_dump_location(sli4_t *sli4, void *buf, size_t size,
uint8_t query, uint8_t is_buffer_list,
ocs_dma_t *buffer, uint8_t fdb)
{
sli4_req_common_set_dump_location_t *set_dump_loc = NULL;
uint32_t sli_config_off = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
sizeof (sli4_req_common_set_dump_location_t),
NULL);
}
set_dump_loc = (sli4_req_common_set_dump_location_t *)((uint8_t *)buf + sli_config_off);
set_dump_loc->hdr.opcode = SLI4_OPC_COMMON_SET_DUMP_LOCATION;
set_dump_loc->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
set_dump_loc->hdr.request_length = sizeof(sli4_req_common_set_dump_location_t) - sizeof(sli4_req_hdr_t);
set_dump_loc->hdr.timeout = 0;
set_dump_loc->hdr.version = 0;
set_dump_loc->blp = is_buffer_list;
set_dump_loc->qry = query;
set_dump_loc->fdb = fdb;
if (buffer) {
set_dump_loc->buf_addr_low = ocs_addr32_lo(buffer->phys);
set_dump_loc->buf_addr_high = ocs_addr32_hi(buffer->phys);
set_dump_loc->buffer_length = buffer->len;
} else {
set_dump_loc->buf_addr_low = 0;
set_dump_loc->buf_addr_high = 0;
set_dump_loc->buffer_length = 0;
}
return(sli_config_off + sizeof(sli4_req_common_set_dump_location_t));
}
/**
* @ingroup sli
* @brief Write a COMMON_SET_FEATURES command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param feature Feature to set.
* @param param_len Length of the parameter (must be a multiple of 4 bytes).
* @param parameter Pointer to the parameter value.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_common_set_features(sli4_t *sli4, void *buf, size_t size,
uint32_t feature,
uint32_t param_len,
void* parameter)
{
sli4_req_common_set_features_t *cmd = NULL;
uint32_t sli_config_off = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
sizeof (sli4_req_common_set_features_t),
NULL);
}
cmd = (sli4_req_common_set_features_t *)((uint8_t *)buf + sli_config_off);
cmd->hdr.opcode = SLI4_OPC_COMMON_SET_FEATURES;
cmd->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
cmd->hdr.request_length = sizeof(sli4_req_common_set_features_t) - sizeof(sli4_req_hdr_t);
cmd->hdr.timeout = 0;
cmd->hdr.version = 0;
cmd->feature = feature;
cmd->param_len = param_len;
ocs_memcpy(cmd->params, parameter, param_len);
return(sli_config_off + sizeof(sli4_req_common_set_features_t));
}
/**
* @ingroup sli
* @brief Write a COMMON_COMMON_GET_PROFILE_CONFIG command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size in bytes.
* @param dma DMA capable memory used to retrieve profile.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_common_get_profile_config(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *dma)
{
sli4_req_common_get_profile_config_t *req = NULL;
uint32_t sli_config_off = 0;
uint32_t payload_size;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
sizeof (sli4_req_common_get_profile_config_t),
dma);
}
if (dma != NULL) {
req = dma->virt;
ocs_memset(req, 0, dma->size);
payload_size = dma->size;
} else {
req = (sli4_req_common_get_profile_config_t *)((uint8_t *)buf + sli_config_off);
payload_size = sizeof(sli4_req_common_get_profile_config_t);
}
req->hdr.opcode = SLI4_OPC_COMMON_GET_PROFILE_CONFIG;
req->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
req->hdr.request_length = payload_size - sizeof(sli4_req_hdr_t);
req->hdr.version = 1;
return(sli_config_off + sizeof(sli4_req_common_get_profile_config_t));
}
/**
* @ingroup sli
* @brief Write a COMMON_COMMON_SET_PROFILE_CONFIG command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param dma DMA capable memory containing profile.
* @param profile_id Profile ID to configure.
* @param descriptor_count Number of descriptors in DMA buffer.
* @param isap Implicit Set Active Profile value to use.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_common_set_profile_config(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *dma,
uint8_t profile_id, uint32_t descriptor_count, uint8_t isap)
{
sli4_req_common_set_profile_config_t *req = NULL;
uint32_t cmd_off = 0;
uint32_t payload_size;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
cmd_off = sli_cmd_sli_config(sli4, buf, size,
sizeof (sli4_req_common_set_profile_config_t),
dma);
}
if (dma != NULL) {
req = dma->virt;
ocs_memset(req, 0, dma->size);
payload_size = dma->size;
} else {
req = (sli4_req_common_set_profile_config_t *)((uint8_t *)buf + cmd_off);
payload_size = sizeof(sli4_req_common_set_profile_config_t);
}
req->hdr.opcode = SLI4_OPC_COMMON_SET_PROFILE_CONFIG;
req->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
req->hdr.request_length = payload_size - sizeof(sli4_req_hdr_t);
req->hdr.version = 1;
req->profile_id = profile_id;
req->desc_count = descriptor_count;
req->isap = isap;
return(cmd_off + sizeof(sli4_req_common_set_profile_config_t));
}
/**
* @ingroup sli
* @brief Write a COMMON_COMMON_GET_PROFILE_LIST command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size in bytes.
* @param start_profile_index First profile index to return.
* @param dma Buffer into which the list will be written.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_common_get_profile_list(sli4_t *sli4, void *buf, size_t size,
uint32_t start_profile_index, ocs_dma_t *dma)
{
sli4_req_common_get_profile_list_t *req = NULL;
uint32_t cmd_off = 0;
uint32_t payload_size;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
cmd_off = sli_cmd_sli_config(sli4, buf, size,
sizeof (sli4_req_common_get_profile_list_t),
dma);
}
if (dma != NULL) {
req = dma->virt;
ocs_memset(req, 0, dma->size);
payload_size = dma->size;
} else {
req = (sli4_req_common_get_profile_list_t *)((uint8_t *)buf + cmd_off);
payload_size = sizeof(sli4_req_common_get_profile_list_t);
}
req->hdr.opcode = SLI4_OPC_COMMON_GET_PROFILE_LIST;
req->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
req->hdr.request_length = payload_size - sizeof(sli4_req_hdr_t);
req->hdr.version = 0;
req->start_profile_index = start_profile_index;
return(cmd_off + sizeof(sli4_req_common_get_profile_list_t));
}
/**
* @ingroup sli
* @brief Write a COMMON_COMMON_GET_ACTIVE_PROFILE command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size in bytes.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_common_get_active_profile(sli4_t *sli4, void *buf, size_t size)
{
sli4_req_common_get_active_profile_t *req = NULL;
uint32_t cmd_off = 0;
uint32_t payload_size;
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_common_get_active_profile_t),
sizeof(sli4_res_common_get_active_profile_t));
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
cmd_off = sli_cmd_sli_config(sli4, buf, size,
payload_size,
NULL);
}
req = (sli4_req_common_get_active_profile_t *)
((uint8_t*)buf + cmd_off);
req->hdr.opcode = SLI4_OPC_COMMON_GET_ACTIVE_PROFILE;
req->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
req->hdr.request_length = payload_size - sizeof(sli4_req_hdr_t);
req->hdr.version = 0;
return(cmd_off + sizeof(sli4_req_common_get_active_profile_t));
}
/**
* @ingroup sli
* @brief Write a COMMON_COMMON_SET_ACTIVE_PROFILE command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size in bytes.
* @param fd If non-zero, set profile to factory default.
* @param active_profile_id ID of new active profile.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_common_set_active_profile(sli4_t *sli4, void *buf, size_t size,
uint32_t fd, uint32_t active_profile_id)
{
sli4_req_common_set_active_profile_t *req = NULL;
uint32_t cmd_off = 0;
uint32_t payload_size;
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_common_set_active_profile_t),
sizeof(sli4_res_common_set_active_profile_t));
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
cmd_off = sli_cmd_sli_config(sli4, buf, size,
payload_size,
NULL);
}
req = (sli4_req_common_set_active_profile_t *)
((uint8_t*)buf + cmd_off);
req->hdr.opcode = SLI4_OPC_COMMON_SET_ACTIVE_PROFILE;
req->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
req->hdr.request_length = payload_size - sizeof(sli4_req_hdr_t);
req->hdr.version = 0;
req->fd = fd;
req->active_profile_id = active_profile_id;
return(cmd_off + sizeof(sli4_req_common_set_active_profile_t));
}
/**
* @ingroup sli
* @brief Write a COMMON_GET_RECONFIG_LINK_INFO command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size in bytes.
* @param dma Buffer to store the supported link configuration modes from the physical device.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_common_get_reconfig_link_info(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *dma)
{
sli4_req_common_get_reconfig_link_info_t *req = NULL;
uint32_t cmd_off = 0;
uint32_t payload_size;
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_common_get_reconfig_link_info_t),
sizeof(sli4_res_common_get_reconfig_link_info_t));
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
cmd_off = sli_cmd_sli_config(sli4, buf, size,
payload_size,
dma);
}
if (dma != NULL) {
req = dma->virt;
ocs_memset(req, 0, dma->size);
payload_size = dma->size;
} else {
req = (sli4_req_common_get_reconfig_link_info_t *)((uint8_t *)buf + cmd_off);
payload_size = sizeof(sli4_req_common_get_reconfig_link_info_t);
}
req->hdr.opcode = SLI4_OPC_COMMON_GET_RECONFIG_LINK_INFO;
req->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
req->hdr.request_length = payload_size - sizeof(sli4_req_hdr_t);
req->hdr.version = 0;
return(cmd_off + sizeof(sli4_req_common_get_reconfig_link_info_t));
}
/**
* @ingroup sli
* @brief Write a COMMON_SET_RECONFIG_LINK_ID command.
*
* @param sli4 SLI context.
* @param buf destination buffer for the command.
* @param size buffer size in bytes.
* @param fd If non-zero, set link config to factory default.
* @param active_link_config_id ID of new active profile.
* @param dma Buffer to assign the link configuration mode that is to become active from the physical device.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_common_set_reconfig_link_id(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *dma,
uint32_t fd, uint32_t active_link_config_id)
{
sli4_req_common_set_reconfig_link_id_t *req = NULL;
uint32_t cmd_off = 0;
uint32_t payload_size;
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_common_set_reconfig_link_id_t),
sizeof(sli4_res_common_set_reconfig_link_id_t));
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
cmd_off = sli_cmd_sli_config(sli4, buf, size,
payload_size,
NULL);
}
if (dma != NULL) {
req = dma->virt;
ocs_memset(req, 0, dma->size);
payload_size = dma->size;
} else {
req = (sli4_req_common_set_reconfig_link_id_t *)((uint8_t *)buf + cmd_off);
payload_size = sizeof(sli4_req_common_set_reconfig_link_id_t);
}
req->hdr.opcode = SLI4_OPC_COMMON_SET_RECONFIG_LINK_ID;
req->hdr.subsystem = SLI4_SUBSYSTEM_COMMON;
req->hdr.request_length = payload_size - sizeof(sli4_req_hdr_t);
req->hdr.version = 0;
req->fd = fd;
req->next_link_config_id = active_link_config_id;
return(cmd_off + sizeof(sli4_req_common_set_reconfig_link_id_t));
}
/**
* @ingroup sli
* @brief Check the mailbox/queue completion entry.
*
* @param buf Pointer to the MCQE.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_cqe_mq(void *buf)
{
sli4_mcqe_t *mcqe = buf;
/*
* Firmware can split mbx completions into two MCQEs: first with only
* the "consumed" bit set and a second with the "complete" bit set.
* Thus, ignore MCQE unless "complete" is set.
*/
if (!mcqe->cmp) {
return -2;
}
if (mcqe->completion_status) {
ocs_log_debug(NULL, "bad status (cmpl=%#x ext=%#x con=%d cmp=%d ae=%d val=%d)\n",
mcqe->completion_status,
mcqe->extended_status,
mcqe->con,
mcqe->cmp,
mcqe->ae,
mcqe->val);
}
return mcqe->completion_status;
}
/**
* @ingroup sli
* @brief Check the asynchronous event completion entry.
*
* @param sli4 SLI context.
* @param buf Pointer to the ACQE.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_cqe_async(sli4_t *sli4, void *buf)
{
sli4_acqe_t *acqe = buf;
int32_t rc = -1;
if (!sli4 || !buf) {
ocs_log_err(NULL, "bad parameter sli4=%p buf=%p\n", sli4, buf);
return -1;
}
switch (acqe->event_code) {
case SLI4_ACQE_EVENT_CODE_LINK_STATE:
rc = sli_fc_process_link_state(sli4, buf);
break;
case SLI4_ACQE_EVENT_CODE_FCOE_FIP:
rc = sli_fc_process_fcoe(sli4, buf);
break;
case SLI4_ACQE_EVENT_CODE_GRP_5:
/*TODO*/ocs_log_debug(sli4->os, "ACQE GRP5\n");
break;
case SLI4_ACQE_EVENT_CODE_SLI_PORT_EVENT:
ocs_log_debug(sli4->os,"ACQE SLI Port, type=0x%x, data1,2=0x%08x,0x%08x\n",
acqe->event_type, acqe->event_data[0], acqe->event_data[1]);
#if defined(OCS_INCLUDE_DEBUG)
ocs_dump32(OCS_DEBUG_ALWAYS, sli4->os, "acq", acqe, sizeof(*acqe));
#endif
break;
case SLI4_ACQE_EVENT_CODE_FC_LINK_EVENT:
rc = sli_fc_process_link_attention(sli4, buf);
break;
default:
/*TODO*/ocs_log_test(sli4->os, "ACQE unknown=%#x\n", acqe->event_code);
}
return rc;
}
/**
* @brief Check the SLI_CONFIG response.
*
* @par Description
* Function checks the SLI_CONFIG response and the payload status.
*
* @param buf Pointer to SLI_CONFIG response.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
static int32_t
sli_res_sli_config(void *buf)
{
sli4_cmd_sli_config_t *sli_config = buf;
if (!buf || (SLI4_MBOX_COMMAND_SLI_CONFIG != sli_config->hdr.command)) {
ocs_log_err(NULL, "bad parameter buf=%p cmd=%#x\n", buf,
buf ? sli_config->hdr.command : -1);
return -1;
}
if (sli_config->hdr.status) {
return sli_config->hdr.status;
}
if (sli_config->emb) {
return sli_config->payload.embed[4];
} else {
ocs_log_test(NULL, "external buffers not supported\n");
return -1;
}
}
/**
* @brief Issue a COMMON_FUNCTION_RESET command.
*
* @param sli4 SLI context.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
static int32_t
sli_common_function_reset(sli4_t *sli4)
{
if (sli_cmd_common_function_reset(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE)) {
if (sli_bmbx_command(sli4)) {
ocs_log_crit(sli4->os, "bootstrap mailbox write fail (COM_FUNC_RESET)\n");
return -1;
}
if (sli_res_sli_config(sli4->bmbx.virt)) {
ocs_log_err(sli4->os, "bad status COM_FUNC_RESET\n");
return -1;
}
} else {
ocs_log_err(sli4->os, "bad COM_FUNC_RESET write\n");
return -1;
}
return 0;
}
/**
* @brief check to see if the FW is ready.
*
* @par Description
* Based on <i>SLI-4 Architecture Specification, Revision 4.x0-13 (2012).</i>.
*
* @param sli4 SLI context.
* @param timeout_ms Time, in milliseconds, to wait for the port to be ready
* before failing.
*
* @return Returns TRUE for ready, or FALSE otherwise.
*/
static int32_t
sli_wait_for_fw_ready(sli4_t *sli4, uint32_t timeout_ms)
{
uint32_t iter = timeout_ms / (SLI4_INIT_PORT_DELAY_US / 1000);
uint32_t ready = FALSE;
do {
iter--;
ocs_udelay(SLI4_INIT_PORT_DELAY_US);
if (sli_fw_ready(sli4) == 1) {
ready = TRUE;
}
} while (!ready && (iter > 0));
return ready;
}
/**
* @brief Initialize the firmware.
*
* @par Description
* Based on <i>SLI-4 Architecture Specification, Revision 4.x0-13 (2012).</i>.
*
* @param sli4 SLI context.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
static int32_t
sli_fw_init(sli4_t *sli4)
{
uint32_t ready;
uint32_t endian;
/*
* Is firmware ready for operation?
*/
ready = sli_wait_for_fw_ready(sli4, SLI4_FW_READY_TIMEOUT_MSEC);
if (!ready) {
ocs_log_crit(sli4->os, "FW status is NOT ready\n");
return -1;
}
/*
* Reset port to a known state
*/
switch (sli4->if_type) {
case SLI4_IF_TYPE_BE3_SKH_PF:
case SLI4_IF_TYPE_BE3_SKH_VF:
/* No SLIPORT_CONTROL register so use command sequence instead */
if (sli_bmbx_wait(sli4, SLI4_BMBX_DELAY_US)) {
ocs_log_crit(sli4->os, "bootstrap mailbox not ready\n");
return -1;
}
if (sli_cmd_fw_initialize(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE)) {
if (sli_bmbx_command(sli4)) {
ocs_log_crit(sli4->os, "bootstrap mailbox write fail (FW_INIT)\n");
return -1;
}
} else {
ocs_log_crit(sli4->os, "bad FW_INIT write\n");
return -1;
}
if (sli_common_function_reset(sli4)) {
ocs_log_err(sli4->os, "bad COM_FUNC_RESET write\n");
return -1;
}
break;
case SLI4_IF_TYPE_LANCER_FC_ETH:
#if BYTE_ORDER == LITTLE_ENDIAN
endian = SLI4_SLIPORT_CONTROL_LITTLE_ENDIAN;
#else
endian = SLI4_SLIPORT_CONTROL_BIG_ENDIAN;
#endif
if (sli_sliport_control(sli4, endian))
return -1;
break;
default:
ocs_log_test(sli4->os, "if_type %d not supported\n", sli4->if_type);
return -1;
}
return 0;
}
/**
* @brief Terminate the firmware.
*
* @param sli4 SLI context.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
static int32_t
sli_fw_term(sli4_t *sli4)
{
uint32_t endian;
if (sli4->if_type == SLI4_IF_TYPE_BE3_SKH_PF ||
sli4->if_type == SLI4_IF_TYPE_BE3_SKH_VF) {
/* No SLIPORT_CONTROL register so use command sequence instead */
if (sli_bmbx_wait(sli4, SLI4_BMBX_DELAY_US)) {
ocs_log_crit(sli4->os, "bootstrap mailbox not ready\n");
return -1;
}
if (sli_common_function_reset(sli4)) {
ocs_log_err(sli4->os, "bad COM_FUNC_RESET write\n");
return -1;
}
if (sli_cmd_fw_deinitialize(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE)) {
if (sli_bmbx_command(sli4)) {
ocs_log_crit(sli4->os, "bootstrap mailbox write fail (FW_DEINIT)\n");
return -1;
}
} else {
ocs_log_test(sli4->os, "bad FW_DEINIT write\n");
return -1;
}
} else {
#if BYTE_ORDER == LITTLE_ENDIAN
endian = SLI4_SLIPORT_CONTROL_LITTLE_ENDIAN;
#else
endian = SLI4_SLIPORT_CONTROL_BIG_ENDIAN;
#endif
/* type 2 etc. use SLIPORT_CONTROL to initialize port */
sli_sliport_control(sli4, endian);
}
return 0;
}
/**
* @brief Write the doorbell register associated with the queue object.
*
* @param sli4 SLI context.
* @param q Queue object.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
static int32_t
sli_queue_doorbell(sli4_t *sli4, sli4_queue_t *q)
{
uint32_t val = 0;
switch (q->type) {
case SLI_QTYPE_EQ:
val = sli_eq_doorbell(q->n_posted, q->id, FALSE);
ocs_reg_write32(sli4->os, q->doorbell_rset, q->doorbell_offset, val);
break;
case SLI_QTYPE_CQ:
val = sli_cq_doorbell(q->n_posted, q->id, FALSE);
ocs_reg_write32(sli4->os, q->doorbell_rset, q->doorbell_offset, val);
break;
case SLI_QTYPE_MQ:
val = SLI4_MQ_DOORBELL(q->n_posted, q->id);
ocs_reg_write32(sli4->os, q->doorbell_rset, q->doorbell_offset, val);
break;
case SLI_QTYPE_RQ:
{
uint32_t n_posted = q->n_posted;
/*
* FC/FCoE has different rules for Receive Queues. The host
* should only update the doorbell of the RQ-pair containing
* the headers since the header / payload RQs are treated
* as a matched unit.
*/
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
/*
* In RQ-pair, an RQ either contains the FC header
* (i.e. is_hdr == TRUE) or the payload.
*
* Don't ring doorbell for payload RQ
*/
if (!q->u.flag.is_hdr) {
break;
}
/*
* Some RQ cannot be incremented one entry at a time. Instead,
* the driver collects a number of entries and updates the
* RQ in batches.
*/
if (q->u.flag.rq_batch) {
if (((q->index + q->n_posted) % SLI4_QUEUE_RQ_BATCH)) {
break;
}
n_posted = SLI4_QUEUE_RQ_BATCH;
}
}
val = SLI4_RQ_DOORBELL(n_posted, q->id);
ocs_reg_write32(sli4->os, q->doorbell_rset, q->doorbell_offset, val);
break;
}
case SLI_QTYPE_WQ:
val = SLI4_WQ_DOORBELL(q->n_posted, q->index, q->id);
ocs_reg_write32(sli4->os, q->doorbell_rset, q->doorbell_offset, val);
break;
default:
ocs_log_test(sli4->os, "bad queue type %d\n", q->type);
return -1;
}
return 0;
}
static int32_t
sli_request_features(sli4_t *sli4, sli4_features_t *features, uint8_t query)
{
if (sli_cmd_request_features(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE,
*features, query)) {
sli4_cmd_request_features_t *req_features = sli4->bmbx.virt;
if (sli_bmbx_command(sli4)) {
ocs_log_crit(sli4->os, "bootstrap mailbox write fail (REQUEST_FEATURES)\n");
return -1;
}
if (req_features->hdr.status) {
ocs_log_err(sli4->os, "REQUEST_FEATURES bad status %#x\n",
req_features->hdr.status);
return -1;
}
features->dword = req_features->response.dword;
} else {
ocs_log_err(sli4->os, "bad REQUEST_FEATURES write\n");
return -1;
}
return 0;
}
/**
* @brief Calculate max queue entries.
*
* @param sli4 SLI context.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
void
sli_calc_max_qentries(sli4_t *sli4)
{
sli4_qtype_e q;
uint32_t alloc_size, qentries, qentry_size;
for (q = SLI_QTYPE_EQ; q < SLI_QTYPE_MAX; q++) {
sli4->config.max_qentries[q] = sli_convert_mask_to_count(sli4->config.count_method[q],
sli4->config.count_mask[q]);
}
/* single, continguous DMA allocations will be called for each queue
* of size (max_qentries * queue entry size); since these can be large,
* check against the OS max DMA allocation size
*/
for (q = SLI_QTYPE_EQ; q < SLI_QTYPE_MAX; q++) {
qentries = sli4->config.max_qentries[q];
qentry_size = sli_get_queue_entry_size(sli4, q);
alloc_size = qentries * qentry_size;
if (alloc_size > ocs_max_dma_alloc(sli4->os, SLI_PAGE_SIZE)) {
while (alloc_size > ocs_max_dma_alloc(sli4->os, SLI_PAGE_SIZE)) {
/* cut the qentries in hwf until alloc_size <= max DMA alloc size */
qentries >>= 1;
alloc_size = qentries * qentry_size;
}
ocs_log_debug(sli4->os, "[%s]: max_qentries from %d to %d (max dma %d)\n",
SLI_QNAME[q], sli4->config.max_qentries[q],
qentries, ocs_max_dma_alloc(sli4->os, SLI_PAGE_SIZE));
sli4->config.max_qentries[q] = qentries;
}
}
}
/**
* @brief Issue a FW_CONFIG mailbox command and store the results.
*
* @param sli4 SLI context.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
static int32_t
sli_query_fw_config(sli4_t *sli4)
{
/*
* Read the device configuration
*
* Note: Only ulp0 fields contain values
*/
if (sli_cmd_common_query_fw_config(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE)) {
sli4_res_common_query_fw_config_t *fw_config =
(sli4_res_common_query_fw_config_t *)
(((uint8_t *)sli4->bmbx.virt) + offsetof(sli4_cmd_sli_config_t, payload.embed));
if (sli_bmbx_command(sli4)) {
ocs_log_crit(sli4->os, "bootstrap mailbox write fail (QUERY_FW_CONFIG)\n");
return -1;
}
if (fw_config->hdr.status) {
ocs_log_err(sli4->os, "COMMON_QUERY_FW_CONFIG bad status %#x\n",
fw_config->hdr.status);
return -1;
}
sli4->physical_port = fw_config->physical_port;
sli4->config.dual_ulp_capable = ((fw_config->function_mode & SLI4_FUNCTION_MODE_DUA_MODE) == 0 ? 0 : 1);
sli4->config.is_ulp_fc[0] = ((fw_config->ulp0_mode &
(SLI4_ULP_MODE_FCOE_INI |
SLI4_ULP_MODE_FCOE_TGT)) == 0 ? 0 : 1);
sli4->config.is_ulp_fc[1] = ((fw_config->ulp1_mode &
(SLI4_ULP_MODE_FCOE_INI |
SLI4_ULP_MODE_FCOE_TGT)) == 0 ? 0 : 1);
if (sli4->config.dual_ulp_capable) {
/*
* Lancer will not support this, so we use the values
* from the READ_CONFIG.
*/
if (sli4->config.is_ulp_fc[0] &&
sli4->config.is_ulp_fc[1]) {
sli4->config.max_qcount[SLI_QTYPE_WQ] = fw_config->ulp0_toe_wq_total + fw_config->ulp1_toe_wq_total;
sli4->config.max_qcount[SLI_QTYPE_RQ] = fw_config->ulp0_toe_defrq_total + fw_config->ulp1_toe_defrq_total;
} else if (sli4->config.is_ulp_fc[0]) {
sli4->config.max_qcount[SLI_QTYPE_WQ] = fw_config->ulp0_toe_wq_total;
sli4->config.max_qcount[SLI_QTYPE_RQ] = fw_config->ulp0_toe_defrq_total;
} else {
sli4->config.max_qcount[SLI_QTYPE_WQ] = fw_config->ulp1_toe_wq_total;
sli4->config.max_qcount[SLI_QTYPE_RQ] = fw_config->ulp1_toe_defrq_total;
}
}
} else {
ocs_log_err(sli4->os, "bad QUERY_FW_CONFIG write\n");
return -1;
}
return 0;
}
static int32_t
sli_get_config(sli4_t *sli4)
{
ocs_dma_t get_cntl_addl_data;
/*
* Read the device configuration
*/
if (sli_cmd_read_config(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE)) {
sli4_res_read_config_t *read_config = sli4->bmbx.virt;
uint32_t i;
uint32_t total;
if (sli_bmbx_command(sli4)) {
ocs_log_crit(sli4->os, "bootstrap mailbox write fail (READ_CONFIG)\n");
return -1;
}
if (read_config->hdr.status) {
ocs_log_err(sli4->os, "READ_CONFIG bad status %#x\n",
read_config->hdr.status);
return -1;
}
sli4->config.has_extents = read_config->ext;
if (FALSE == sli4->config.has_extents) {
uint32_t i = 0;
uint32_t *base = sli4->config.extent[0].base;
if (!base) {
if (NULL == (base = ocs_malloc(sli4->os, SLI_RSRC_MAX * sizeof(uint32_t),
OCS_M_ZERO | OCS_M_NOWAIT))) {
ocs_log_err(sli4->os, "memory allocation failed for sli4_resource_t\n");
return -1;
}
}
for (i = 0; i < SLI_RSRC_MAX; i++) {
sli4->config.extent[i].number = 1;
sli4->config.extent[i].n_alloc = 0;
sli4->config.extent[i].base = &base[i];
}
sli4->config.extent[SLI_RSRC_FCOE_VFI].base[0] = read_config->vfi_base;
sli4->config.extent[SLI_RSRC_FCOE_VFI].size = read_config->vfi_count;
sli4->config.extent[SLI_RSRC_FCOE_VPI].base[0] = read_config->vpi_base;
sli4->config.extent[SLI_RSRC_FCOE_VPI].size = read_config->vpi_count;
sli4->config.extent[SLI_RSRC_FCOE_RPI].base[0] = read_config->rpi_base;
sli4->config.extent[SLI_RSRC_FCOE_RPI].size = read_config->rpi_count;
sli4->config.extent[SLI_RSRC_FCOE_XRI].base[0] = read_config->xri_base;
sli4->config.extent[SLI_RSRC_FCOE_XRI].size = read_config->xri_count;
sli4->config.extent[SLI_RSRC_FCOE_FCFI].base[0] = 0;
sli4->config.extent[SLI_RSRC_FCOE_FCFI].size = read_config->fcfi_count;
} else {
/* TODO extents*/
;
}
for (i = 0; i < SLI_RSRC_MAX; i++) {
total = sli4->config.extent[i].number * sli4->config.extent[i].size;
sli4->config.extent[i].use_map = ocs_bitmap_alloc(total);
if (NULL == sli4->config.extent[i].use_map) {
ocs_log_err(sli4->os, "bitmap memory allocation failed "
"resource %d\n", i);
return -1;
}
sli4->config.extent[i].map_size = total;
}
sli4->config.topology = read_config->topology;
switch (sli4->config.topology) {
case SLI4_READ_CFG_TOPO_FCOE:
ocs_log_debug(sli4->os, "FCoE\n");
break;
case SLI4_READ_CFG_TOPO_FC:
ocs_log_debug(sli4->os, "FC (unknown)\n");
break;
case SLI4_READ_CFG_TOPO_FC_DA:
ocs_log_debug(sli4->os, "FC (direct attach)\n");
break;
case SLI4_READ_CFG_TOPO_FC_AL:
ocs_log_debug(sli4->os, "FC (arbitrated loop)\n");
break;
default:
ocs_log_test(sli4->os, "bad topology %#x\n", sli4->config.topology);
}
sli4->config.e_d_tov = read_config->e_d_tov;
sli4->config.r_a_tov = read_config->r_a_tov;
sli4->config.link_module_type = read_config->lmt;
sli4->config.max_qcount[SLI_QTYPE_EQ] = read_config->eq_count;
sli4->config.max_qcount[SLI_QTYPE_CQ] = read_config->cq_count;
sli4->config.max_qcount[SLI_QTYPE_WQ] = read_config->wq_count;
sli4->config.max_qcount[SLI_QTYPE_RQ] = read_config->rq_count;
/*
* READ_CONFIG doesn't give the max number of MQ. Applications
* will typically want 1, but we may need another at some future
* date. Dummy up a "max" MQ count here.
*/
sli4->config.max_qcount[SLI_QTYPE_MQ] = SLI_USER_MQ_COUNT;
} else {
ocs_log_err(sli4->os, "bad READ_CONFIG write\n");
return -1;
}
if (sli_cmd_common_get_sli4_parameters(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE)) {
sli4_res_common_get_sli4_parameters_t *parms = (sli4_res_common_get_sli4_parameters_t *)
(((uint8_t *)sli4->bmbx.virt) + offsetof(sli4_cmd_sli_config_t, payload.embed));
if (sli_bmbx_command(sli4)) {
ocs_log_crit(sli4->os, "bootstrap mailbox write fail (COMMON_GET_SLI4_PARAMETERS)\n");
return -1;
} else if (parms->hdr.status) {
ocs_log_err(sli4->os, "COMMON_GET_SLI4_PARAMETERS bad status %#x att'l %#x\n",
parms->hdr.status, parms->hdr.additional_status);
return -1;
}
sli4->config.auto_reg = parms->areg;
sli4->config.auto_xfer_rdy = parms->agxf;
sli4->config.hdr_template_req = parms->hdrr;
sli4->config.t10_dif_inline_capable = parms->timm;
sli4->config.t10_dif_separate_capable = parms->tsmm;
sli4->config.mq_create_version = parms->mqv;
sli4->config.cq_create_version = parms->cqv;
sli4->config.rq_min_buf_size = parms->min_rq_buffer_size;
sli4->config.rq_max_buf_size = parms->max_rq_buffer_size;
sli4->config.qpage_count[SLI_QTYPE_EQ] = parms->eq_page_cnt;
sli4->config.qpage_count[SLI_QTYPE_CQ] = parms->cq_page_cnt;
sli4->config.qpage_count[SLI_QTYPE_MQ] = parms->mq_page_cnt;
sli4->config.qpage_count[SLI_QTYPE_WQ] = parms->wq_page_cnt;
sli4->config.qpage_count[SLI_QTYPE_RQ] = parms->rq_page_cnt;
/* save count methods and masks for each queue type */
sli4->config.count_mask[SLI_QTYPE_EQ] = parms->eqe_count_mask;
sli4->config.count_method[SLI_QTYPE_EQ] = parms->eqe_count_method;
sli4->config.count_mask[SLI_QTYPE_CQ] = parms->cqe_count_mask;
sli4->config.count_method[SLI_QTYPE_CQ] = parms->cqe_count_method;
sli4->config.count_mask[SLI_QTYPE_MQ] = parms->mqe_count_mask;
sli4->config.count_method[SLI_QTYPE_MQ] = parms->mqe_count_method;
sli4->config.count_mask[SLI_QTYPE_WQ] = parms->wqe_count_mask;
sli4->config.count_method[SLI_QTYPE_WQ] = parms->wqe_count_method;
sli4->config.count_mask[SLI_QTYPE_RQ] = parms->rqe_count_mask;
sli4->config.count_method[SLI_QTYPE_RQ] = parms->rqe_count_method;
/* now calculate max queue entries */
sli_calc_max_qentries(sli4);
sli4->config.max_sgl_pages = parms->sgl_page_cnt; /* max # of pages */
sli4->config.sgl_page_sizes = parms->sgl_page_sizes; /* bit map of available sizes */
/* ignore HLM here. Use value from REQUEST_FEATURES */
sli4->config.sge_supported_length = parms->sge_supported_length;
if (sli4->config.sge_supported_length > OCS_MAX_SGE_SIZE)
sli4->config.sge_supported_length = OCS_MAX_SGE_SIZE;
sli4->config.sgl_pre_registration_required = parms->sglr;
/* default to using pre-registered SGL's */
sli4->config.sgl_pre_registered = TRUE;
sli4->config.perf_hint = parms->phon;
sli4->config.perf_wq_id_association = parms->phwq;
sli4->config.rq_batch = parms->rq_db_window;
/* save the fields for skyhawk SGL chaining */
sli4->config.sgl_chaining_params.chaining_capable =
(parms->sglc == 1);
sli4->config.sgl_chaining_params.frag_num_field_offset =
parms->frag_num_field_offset;
sli4->config.sgl_chaining_params.frag_num_field_mask =
(1ull << parms->frag_num_field_size) - 1;
sli4->config.sgl_chaining_params.sgl_index_field_offset =
parms->sgl_index_field_offset;
sli4->config.sgl_chaining_params.sgl_index_field_mask =
(1ull << parms->sgl_index_field_size) - 1;
sli4->config.sgl_chaining_params.chain_sge_initial_value_lo =
parms->chain_sge_initial_value_lo;
sli4->config.sgl_chaining_params.chain_sge_initial_value_hi =
parms->chain_sge_initial_value_hi;
/* Use the highest available WQE size. */
if (parms->wqe_sizes & SLI4_128BYTE_WQE_SUPPORT) {
sli4->config.wqe_size = SLI4_WQE_EXT_BYTES;
} else {
sli4->config.wqe_size = SLI4_WQE_BYTES;
}
}
if (sli_query_fw_config(sli4)) {
ocs_log_err(sli4->os, "Error sending QUERY_FW_CONFIG\n");
return -1;
}
sli4->config.port_number = 0;
/*
* Issue COMMON_GET_CNTL_ATTRIBUTES to get port_number. Temporarily
* uses VPD DMA buffer as the response won't fit in the embedded
* buffer.
*/
if (sli_cmd_common_get_cntl_attributes(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE, &sli4->vpd.data)) {
sli4_res_common_get_cntl_attributes_t *attr = sli4->vpd.data.virt;
if (sli_bmbx_command(sli4)) {
ocs_log_crit(sli4->os, "bootstrap mailbox write fail (COMMON_GET_CNTL_ATTRIBUTES)\n");
return -1;
} else if (attr->hdr.status) {
ocs_log_err(sli4->os, "COMMON_GET_CNTL_ATTRIBUTES bad status %#x att'l %#x\n",
attr->hdr.status, attr->hdr.additional_status);
return -1;
}
sli4->config.port_number = attr->port_number;
ocs_memcpy(sli4->config.bios_version_string, attr->bios_version_string,
sizeof(sli4->config.bios_version_string));
} else {
ocs_log_err(sli4->os, "bad COMMON_GET_CNTL_ATTRIBUTES write\n");
return -1;
}
if (ocs_dma_alloc(sli4->os, &get_cntl_addl_data, sizeof(sli4_res_common_get_cntl_addl_attributes_t),
OCS_MIN_DMA_ALIGNMENT)) {
ocs_log_err(sli4->os, "Failed to allocate memory for GET_CNTL_ADDL_ATTR data\n");
} else {
if (sli_cmd_common_get_cntl_addl_attributes(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE,
&get_cntl_addl_data)) {
sli4_res_common_get_cntl_addl_attributes_t *attr = get_cntl_addl_data.virt;
if (sli_bmbx_command(sli4)) {
ocs_log_crit(sli4->os,
"bootstrap mailbox write fail (COMMON_GET_CNTL_ADDL_ATTRIBUTES)\n");
ocs_dma_free(sli4->os, &get_cntl_addl_data);
return -1;
}
if (attr->hdr.status) {
ocs_log_err(sli4->os, "COMMON_GET_CNTL_ADDL_ATTRIBUTES bad status %#x\n",
attr->hdr.status);
ocs_dma_free(sli4->os, &get_cntl_addl_data);
return -1;
}
ocs_memcpy(sli4->config.ipl_name, attr->ipl_file_name, sizeof(sli4->config.ipl_name));
ocs_log_debug(sli4->os, "IPL:%s \n", (char*)sli4->config.ipl_name);
} else {
ocs_log_err(sli4->os, "bad COMMON_GET_CNTL_ADDL_ATTRIBUTES write\n");
ocs_dma_free(sli4->os, &get_cntl_addl_data);
return -1;
}
ocs_dma_free(sli4->os, &get_cntl_addl_data);
}
if (sli_cmd_common_get_port_name(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE)) {
sli4_res_common_get_port_name_t *port_name = (sli4_res_common_get_port_name_t *)(((uint8_t *)sli4->bmbx.virt) +
offsetof(sli4_cmd_sli_config_t, payload.embed));
if (sli_bmbx_command(sli4)) {
ocs_log_crit(sli4->os, "bootstrap mailbox write fail (COMMON_GET_PORT_NAME)\n");
return -1;
}
sli4->config.port_name[0] = port_name->port_name[sli4->config.port_number];
}
sli4->config.port_name[1] = '\0';
if (sli_cmd_read_rev(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE, &sli4->vpd.data)) {
sli4_cmd_read_rev_t *read_rev = sli4->bmbx.virt;
if (sli_bmbx_command(sli4)) {
ocs_log_crit(sli4->os, "bootstrap mailbox write fail (READ_REV)\n");
return -1;
}
if (read_rev->hdr.status) {
ocs_log_err(sli4->os, "READ_REV bad status %#x\n",
read_rev->hdr.status);
return -1;
}
sli4->config.fw_rev[0] = read_rev->first_fw_id;
ocs_memcpy(sli4->config.fw_name[0],read_rev->first_fw_name, sizeof(sli4->config.fw_name[0]));
sli4->config.fw_rev[1] = read_rev->second_fw_id;
ocs_memcpy(sli4->config.fw_name[1],read_rev->second_fw_name, sizeof(sli4->config.fw_name[1]));
sli4->config.hw_rev[0] = read_rev->first_hw_revision;
sli4->config.hw_rev[1] = read_rev->second_hw_revision;
sli4->config.hw_rev[2] = read_rev->third_hw_revision;
ocs_log_debug(sli4->os, "FW1:%s (%08x) / FW2:%s (%08x)\n",
read_rev->first_fw_name, read_rev->first_fw_id,
read_rev->second_fw_name, read_rev->second_fw_id);
ocs_log_debug(sli4->os, "HW1: %08x / HW2: %08x\n", read_rev->first_hw_revision,
read_rev->second_hw_revision);
/* Check that all VPD data was returned */
if (read_rev->returned_vpd_length != read_rev->actual_vpd_length) {
ocs_log_test(sli4->os, "VPD length: available=%d returned=%d actual=%d\n",
read_rev->available_length,
read_rev->returned_vpd_length,
read_rev->actual_vpd_length);
}
sli4->vpd.length = read_rev->returned_vpd_length;
} else {
ocs_log_err(sli4->os, "bad READ_REV write\n");
return -1;
}
if (sli_cmd_read_nvparms(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE)) {
sli4_cmd_read_nvparms_t *read_nvparms = sli4->bmbx.virt;
if (sli_bmbx_command(sli4)) {
ocs_log_crit(sli4->os, "bootstrap mailbox write fail (READ_NVPARMS)\n");
return -1;
}
if (read_nvparms->hdr.status) {
ocs_log_err(sli4->os, "READ_NVPARMS bad status %#x\n",
read_nvparms->hdr.status);
return -1;
}
ocs_memcpy(sli4->config.wwpn, read_nvparms->wwpn, sizeof(sli4->config.wwpn));
ocs_memcpy(sli4->config.wwnn, read_nvparms->wwnn, sizeof(sli4->config.wwnn));
ocs_log_debug(sli4->os, "WWPN %02x:%02x:%02x:%02x:%02x:%02x:%02x:%02x\n",
sli4->config.wwpn[0],
sli4->config.wwpn[1],
sli4->config.wwpn[2],
sli4->config.wwpn[3],
sli4->config.wwpn[4],
sli4->config.wwpn[5],
sli4->config.wwpn[6],
sli4->config.wwpn[7]);
ocs_log_debug(sli4->os, "WWNN %02x:%02x:%02x:%02x:%02x:%02x:%02x:%02x\n",
sli4->config.wwnn[0],
sli4->config.wwnn[1],
sli4->config.wwnn[2],
sli4->config.wwnn[3],
sli4->config.wwnn[4],
sli4->config.wwnn[5],
sli4->config.wwnn[6],
sli4->config.wwnn[7]);
} else {
ocs_log_err(sli4->os, "bad READ_NVPARMS write\n");
return -1;
}
return 0;
}
/****************************************************************************
* Public functions
*/
/**
* @ingroup sli
* @brief Set up the SLI context.
*
* @param sli4 SLI context.
* @param os Device abstraction.
* @param port_type Protocol type of port (for example, FC and NIC).
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_setup(sli4_t *sli4, ocs_os_handle_t os, sli4_port_type_e port_type)
{
uint32_t sli_intf = UINT32_MAX;
uint32_t pci_class_rev = 0;
uint32_t rev_id = 0;
uint32_t family = 0;
uint32_t i;
sli4_asic_entry_t *asic;
ocs_memset(sli4, 0, sizeof(sli4_t));
sli4->os = os;
sli4->port_type = port_type;
/*
* Read the SLI_INTF register to discover the register layout
* and other capability information
*/
sli_intf = ocs_config_read32(os, SLI4_INTF_REG);
if (sli_intf_valid_check(sli_intf)) {
ocs_log_err(os, "SLI_INTF is not valid\n");
return -1;
}
/* driver only support SLI-4 */
sli4->sli_rev = sli_intf_sli_revision(sli_intf);
if (4 != sli4->sli_rev) {
ocs_log_err(os, "Unsupported SLI revision (intf=%#x)\n",
sli_intf);
return -1;
}
sli4->sli_family = sli_intf_sli_family(sli_intf);
sli4->if_type = sli_intf_if_type(sli_intf);
if (SLI4_IF_TYPE_LANCER_FC_ETH == sli4->if_type) {
ocs_log_debug(os, "status=%#x error1=%#x error2=%#x\n",
sli_reg_read(sli4, SLI4_REG_SLIPORT_STATUS),
sli_reg_read(sli4, SLI4_REG_SLIPORT_ERROR1),
sli_reg_read(sli4, SLI4_REG_SLIPORT_ERROR2));
}
/*
* set the ASIC type and revision
*/
pci_class_rev = ocs_config_read32(os, SLI4_PCI_CLASS_REVISION);
rev_id = sli_pci_rev_id(pci_class_rev);
family = sli4->sli_family;
if (family == SLI4_FAMILY_CHECK_ASIC_TYPE) {
uint32_t asic_id = ocs_config_read32(os, SLI4_ASIC_ID_REG);
family = sli_asic_gen(asic_id);
}
for (i = 0, asic = sli4_asic_table; i < ARRAY_SIZE(sli4_asic_table); i++, asic++) {
if ((rev_id == asic->rev_id) && (family == asic->family)) {
sli4->asic_type = asic->type;
sli4->asic_rev = asic->rev;
break;
}
}
/* Fail if no matching asic type/rev was found */
if( (sli4->asic_type == 0) || (sli4->asic_rev == 0)) {
ocs_log_err(os, "no matching asic family/rev found: %02x/%02x\n", family, rev_id);
return -1;
}
/*
* The bootstrap mailbox is equivalent to a MQ with a single 256 byte
* entry, a CQ with a single 16 byte entry, and no event queue.
* Alignment must be 16 bytes as the low order address bits in the
* address register are also control / status.
*/
if (ocs_dma_alloc(sli4->os, &sli4->bmbx, SLI4_BMBX_SIZE +
sizeof(sli4_mcqe_t), 16)) {
ocs_log_err(os, "bootstrap mailbox allocation failed\n");
return -1;
}
if (sli4->bmbx.phys & SLI4_BMBX_MASK_LO) {
ocs_log_err(os, "bad alignment for bootstrap mailbox\n");
return -1;
}
ocs_log_debug(os, "bmbx v=%p p=0x%x %08x s=%zd\n", sli4->bmbx.virt,
ocs_addr32_hi(sli4->bmbx.phys),
ocs_addr32_lo(sli4->bmbx.phys),
sli4->bmbx.size);
/* TODO 4096 is arbitrary. What should this value actually be? */
if (ocs_dma_alloc(sli4->os, &sli4->vpd.data, 4096/*TODO*/, 4096)) {
/* Note that failure isn't fatal in this specific case */
sli4->vpd.data.size = 0;
ocs_log_test(os, "VPD buffer allocation failed\n");
}
if (sli_fw_init(sli4)) {
ocs_log_err(sli4->os, "FW initialization failed\n");
return -1;
}
/*
* Set one of fcpi(initiator), fcpt(target), fcpc(combined) to true
* in addition to any other desired features
*/
sli4->config.features.flag.iaab = TRUE;
sli4->config.features.flag.npiv = TRUE;
sli4->config.features.flag.dif = TRUE;
sli4->config.features.flag.vf = TRUE;
sli4->config.features.flag.fcpc = TRUE;
sli4->config.features.flag.iaar = TRUE;
sli4->config.features.flag.hlm = TRUE;
sli4->config.features.flag.perfh = TRUE;
sli4->config.features.flag.rxseq = TRUE;
sli4->config.features.flag.rxri = TRUE;
sli4->config.features.flag.mrqp = TRUE;
/* use performance hints if available */
if (sli4->config.perf_hint) {
sli4->config.features.flag.perfh = TRUE;
}
if (sli_request_features(sli4, &sli4->config.features, TRUE)) {
return -1;
}
if (sli_get_config(sli4)) {
return -1;
}
return 0;
}
int32_t
sli_init(sli4_t *sli4)
{
if (sli4->config.has_extents) {
/* TODO COMMON_ALLOC_RESOURCE_EXTENTS */;
ocs_log_test(sli4->os, "XXX need to implement extent allocation\n");
return -1;
}
sli4->config.features.flag.hlm = sli4->config.high_login_mode;
sli4->config.features.flag.rxseq = FALSE;
sli4->config.features.flag.rxri = FALSE;
if (sli_request_features(sli4, &sli4->config.features, FALSE)) {
return -1;
}
return 0;
}
int32_t
sli_reset(sli4_t *sli4)
{
uint32_t i;
if (sli_fw_init(sli4)) {
ocs_log_crit(sli4->os, "FW initialization failed\n");
return -1;
}
if (sli4->config.extent[0].base) {
ocs_free(sli4->os, sli4->config.extent[0].base, SLI_RSRC_MAX * sizeof(uint32_t));
sli4->config.extent[0].base = NULL;
}
for (i = 0; i < SLI_RSRC_MAX; i++) {
if (sli4->config.extent[i].use_map) {
ocs_bitmap_free(sli4->config.extent[i].use_map);
sli4->config.extent[i].use_map = NULL;
}
sli4->config.extent[i].base = NULL;
}
if (sli_get_config(sli4)) {
return -1;
}
return 0;
}
/**
* @ingroup sli
* @brief Issue a Firmware Reset.
*
* @par Description
* Issues a Firmware Reset to the chip. This reset affects the entire chip,
* so all PCI function on the same PCI bus and device are affected.
* @n @n This type of reset can be used to activate newly downloaded firmware.
* @n @n The driver should be considered to be in an unknown state after this
* reset and should be reloaded.
*
* @param sli4 SLI context.
*
* @return Returns 0 on success, or -1 otherwise.
*/
int32_t
sli_fw_reset(sli4_t *sli4)
{
uint32_t val;
uint32_t ready;
/*
* Firmware must be ready before issuing the reset.
*/
ready = sli_wait_for_fw_ready(sli4, SLI4_FW_READY_TIMEOUT_MSEC);
if (!ready) {
ocs_log_crit(sli4->os, "FW status is NOT ready\n");
return -1;
}
switch(sli4->if_type) {
case SLI4_IF_TYPE_BE3_SKH_PF:
/* BE3 / Skyhawk use PCICFG_SOFT_RESET_CSR */
val = ocs_config_read32(sli4->os, SLI4_PCI_SOFT_RESET_CSR);
val |= SLI4_PCI_SOFT_RESET_MASK;
ocs_config_write32(sli4->os, SLI4_PCI_SOFT_RESET_CSR, val);
break;
case SLI4_IF_TYPE_LANCER_FC_ETH:
/* Lancer uses PHYDEV_CONTROL */
val = SLI4_PHYDEV_CONTROL_FRST;
sli_reg_write(sli4, SLI4_REG_PHYSDEV_CONTROL, val);
break;
default:
ocs_log_test(sli4->os, "Unexpected iftype %d\n", sli4->if_type);
return -1;
break;
}
/* wait for the FW to become ready after the reset */
ready = sli_wait_for_fw_ready(sli4, SLI4_FW_READY_TIMEOUT_MSEC);
if (!ready) {
ocs_log_crit(sli4->os, "Failed to become ready after firmware reset\n");
return -1;
}
return 0;
}
/**
* @ingroup sli
* @brief Tear down a SLI context.
*
* @param sli4 SLI context.
*
* @return Returns 0 on success, or non-zero otherwise.
*/
int32_t
sli_teardown(sli4_t *sli4)
{
uint32_t i;
if (sli4->config.extent[0].base) {
ocs_free(sli4->os, sli4->config.extent[0].base, SLI_RSRC_MAX * sizeof(uint32_t));
sli4->config.extent[0].base = NULL;
}
for (i = 0; i < SLI_RSRC_MAX; i++) {
if (sli4->config.has_extents) {
/* TODO COMMON_DEALLOC_RESOURCE_EXTENTS */;
}
sli4->config.extent[i].base = NULL;
ocs_bitmap_free(sli4->config.extent[i].use_map);
sli4->config.extent[i].use_map = NULL;
}
if (sli_fw_term(sli4)) {
ocs_log_err(sli4->os, "FW deinitialization failed\n");
}
ocs_dma_free(sli4->os, &sli4->vpd.data);
ocs_dma_free(sli4->os, &sli4->bmbx);
return 0;
}
/**
* @ingroup sli
* @brief Register a callback for the given event.
*
* @param sli4 SLI context.
* @param which Event of interest.
* @param func Function to call when the event occurs.
* @param arg Argument passed to the callback function.
*
* @return Returns 0 on success, or non-zero otherwise.
*/
int32_t
sli_callback(sli4_t *sli4, sli4_callback_e which, void *func, void *arg)
{
if (!sli4 || !func || (which >= SLI4_CB_MAX)) {
ocs_log_err(NULL, "bad parameter sli4=%p which=%#x func=%p\n",
sli4, which, func);
return -1;
}
switch (which) {
case SLI4_CB_LINK:
sli4->link = func;
sli4->link_arg = arg;
break;
case SLI4_CB_FIP:
sli4->fip = func;
sli4->fip_arg = arg;
break;
default:
ocs_log_test(sli4->os, "unknown callback %#x\n", which);
return -1;
}
return 0;
}
/**
* @ingroup sli
* @brief Initialize a queue object.
*
* @par Description
* This initializes the sli4_queue_t object members, including the underlying
* DMA memory.
*
* @param sli4 SLI context.
* @param q Pointer to queue object.
* @param qtype Type of queue to create.
* @param size Size of each entry.
* @param n_entries Number of entries to allocate.
* @param align Starting memory address alignment.
*
* @note Checks if using the existing DMA memory (if any) is possible. If not,
* it frees the existing memory and re-allocates.
*
* @return Returns 0 on success, or non-zero otherwise.
*/
int32_t
__sli_queue_init(sli4_t *sli4, sli4_queue_t *q, uint32_t qtype,
size_t size, uint32_t n_entries, uint32_t align)
{
if ((q->dma.virt == NULL) || (size != q->size) || (n_entries != q->length)) {
if (q->dma.size) {
ocs_dma_free(sli4->os, &q->dma);
}
ocs_memset(q, 0, sizeof(sli4_queue_t));
if (ocs_dma_alloc(sli4->os, &q->dma, size * n_entries, align)) {
ocs_log_err(sli4->os, "%s allocation failed\n", SLI_QNAME[qtype]);
return -1;
}
ocs_memset(q->dma.virt, 0, size * n_entries);
ocs_lock_init(sli4->os, &q->lock, "%s lock[%d:%p]",
SLI_QNAME[qtype], ocs_instance(sli4->os), &q->lock);
q->type = qtype;
q->size = size;
q->length = n_entries;
/* Limit to hwf the queue size per interrupt */
q->proc_limit = n_entries / 2;
switch(q->type) {
case SLI_QTYPE_EQ:
q->posted_limit = q->length / 2;
break;
default:
if ((sli4->if_type == SLI4_IF_TYPE_BE3_SKH_PF) ||
(sli4->if_type == SLI4_IF_TYPE_BE3_SKH_VF)) {
/* For Skyhawk, ring the doorbell more often */
q->posted_limit = 8;
} else {
q->posted_limit = 64;
}
break;
}
}
return 0;
}
/**
* @ingroup sli
* @brief Issue the command to create a queue.
*
* @param sli4 SLI context.
* @param q Pointer to queue object.
*
* @return Returns 0 on success, or non-zero otherwise.
*/
int32_t
__sli_create_queue(sli4_t *sli4, sli4_queue_t *q)
{
sli4_res_common_create_queue_t *res_q = NULL;
if (sli_bmbx_command(sli4)){
ocs_log_crit(sli4->os, "bootstrap mailbox write fail %s\n",
SLI_QNAME[q->type]);
ocs_dma_free(sli4->os, &q->dma);
return -1;
}
if (sli_res_sli_config(sli4->bmbx.virt)) {
ocs_log_err(sli4->os, "bad status create %s\n", SLI_QNAME[q->type]);
ocs_dma_free(sli4->os, &q->dma);
return -1;
}
res_q = (void *)((uint8_t *)sli4->bmbx.virt +
offsetof(sli4_cmd_sli_config_t, payload));
if (res_q->hdr.status) {
ocs_log_err(sli4->os, "bad create %s status=%#x addl=%#x\n",
SLI_QNAME[q->type],
res_q->hdr.status, res_q->hdr.additional_status);
ocs_dma_free(sli4->os, &q->dma);
return -1;
} else {
q->id = res_q->q_id;
q->doorbell_offset = res_q->db_offset;
q->doorbell_rset = res_q->db_rs;
switch (q->type) {
case SLI_QTYPE_EQ:
/* No doorbell information in response for EQs */
q->doorbell_offset = regmap[SLI4_REG_EQCQ_DOORBELL][sli4->if_type].off;
q->doorbell_rset = regmap[SLI4_REG_EQCQ_DOORBELL][sli4->if_type].rset;
break;
case SLI_QTYPE_CQ:
/* No doorbell information in response for CQs */
q->doorbell_offset = regmap[SLI4_REG_EQCQ_DOORBELL][sli4->if_type].off;
q->doorbell_rset = regmap[SLI4_REG_EQCQ_DOORBELL][sli4->if_type].rset;
break;
case SLI_QTYPE_MQ:
/* No doorbell information in response for MQs */
q->doorbell_offset = regmap[SLI4_REG_MQ_DOORBELL][sli4->if_type].off;
q->doorbell_rset = regmap[SLI4_REG_MQ_DOORBELL][sli4->if_type].rset;
break;
case SLI_QTYPE_RQ:
/* set the doorbell for non-skyhawks */
if (!sli4->config.dual_ulp_capable) {
q->doorbell_offset = regmap[SLI4_REG_FCOE_RQ_DOORBELL][sli4->if_type].off;
q->doorbell_rset = regmap[SLI4_REG_FCOE_RQ_DOORBELL][sli4->if_type].rset;
}
break;
case SLI_QTYPE_WQ:
/* set the doorbell for non-skyhawks */
if (!sli4->config.dual_ulp_capable) {
q->doorbell_offset = regmap[SLI4_REG_IO_WQ_DOORBELL][sli4->if_type].off;
q->doorbell_rset = regmap[SLI4_REG_IO_WQ_DOORBELL][sli4->if_type].rset;
}
break;
default:
break;
}
}
return 0;
}
/**
* @ingroup sli
* @brief Get queue entry size.
*
* Get queue entry size given queue type.
*
* @param sli4 SLI context
* @param qtype Type for which the entry size is returned.
*
* @return Returns > 0 on success (queue entry size), or a negative value on failure.
*/
int32_t
sli_get_queue_entry_size(sli4_t *sli4, uint32_t qtype)
{
uint32_t size = 0;
if (!sli4) {
ocs_log_err(NULL, "bad parameter sli4=%p\n", sli4);
return -1;
}
switch (qtype) {
case SLI_QTYPE_EQ:
size = sizeof(uint32_t);
break;
case SLI_QTYPE_CQ:
size = 16;
break;
case SLI_QTYPE_MQ:
size = 256;
break;
case SLI_QTYPE_WQ:
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
size = sli4->config.wqe_size;
} else {
/* TODO */
ocs_log_test(sli4->os, "unsupported queue entry size\n");
return -1;
}
break;
case SLI_QTYPE_RQ:
size = SLI4_FCOE_RQE_SIZE;
break;
default:
ocs_log_test(sli4->os, "unknown queue type %d\n", qtype);
return -1;
}
return size;
}
/**
* @ingroup sli
* @brief Modify the delay timer for all the EQs
*
* @param sli4 SLI context.
* @param eq Array of EQs.
* @param num_eq Count of EQs.
* @param shift Phase shift for staggering interrupts.
* @param delay_mult Delay multiplier for limiting interrupt frequency.
*
* @return Returns 0 on success, or -1 otherwise.
*/
int32_t
sli_eq_modify_delay(sli4_t *sli4, sli4_queue_t *eq, uint32_t num_eq, uint32_t shift, uint32_t delay_mult)
{
sli_cmd_common_modify_eq_delay(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE, eq, num_eq, shift, delay_mult);
if (sli_bmbx_command(sli4)) {
ocs_log_crit(sli4->os, "bootstrap mailbox write fail (MODIFY EQ DELAY)\n");
return -1;
}
if (sli_res_sli_config(sli4->bmbx.virt)) {
ocs_log_err(sli4->os, "bad status MODIFY EQ DELAY\n");
return -1;
}
return 0;
}
/**
* @ingroup sli
* @brief Allocate a queue.
*
* @par Description
* Allocates DMA memory and configures the requested queue type.
*
* @param sli4 SLI context.
* @param qtype Type of queue to create.
* @param q Pointer to the queue object.
* @param n_entries Number of entries to allocate.
* @param assoc Associated queue (that is, the EQ for a CQ, the CQ for a MQ, and so on).
* @param ulp The ULP to bind, which is only used for WQ and RQs
*
* @return Returns 0 on success, or -1 otherwise.
*/
int32_t
sli_queue_alloc(sli4_t *sli4, uint32_t qtype, sli4_queue_t *q, uint32_t n_entries,
sli4_queue_t *assoc, uint16_t ulp)
{
int32_t size;
uint32_t align = 0;
sli4_create_q_fn_t create = NULL;
if (!sli4 || !q) {
ocs_log_err(NULL, "bad parameter sli4=%p q=%p\n", sli4, q);
return -1;
}
/* get queue size */
size = sli_get_queue_entry_size(sli4, qtype);
if (size < 0)
return -1;
align = SLI_PAGE_SIZE;
switch (qtype) {
case SLI_QTYPE_EQ:
create = sli_cmd_common_create_eq;
break;
case SLI_QTYPE_CQ:
create = sli_cmd_common_create_cq;
break;
case SLI_QTYPE_MQ:
/* Validate the number of entries */
switch (n_entries) {
case 16:
case 32:
case 64:
case 128:
break;
default:
ocs_log_test(sli4->os, "illegal n_entries value %d for MQ\n", n_entries);
return -1;
}
assoc->u.flag.is_mq = TRUE;
create = sli_cmd_common_create_mq_ext;
break;
case SLI_QTYPE_WQ:
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
if (sli4->if_type == SLI4_IF_TYPE_BE3_SKH_PF) {
create = sli_cmd_fcoe_wq_create;
} else {
create = sli_cmd_fcoe_wq_create_v1;
}
} else {
/* TODO */
ocs_log_test(sli4->os, "unsupported WQ create\n");
return -1;
}
break;
default:
ocs_log_test(sli4->os, "unknown queue type %d\n", qtype);
return -1;
}
if (__sli_queue_init(sli4, q, qtype, size, n_entries, align)) {
ocs_log_err(sli4->os, "%s allocation failed\n", SLI_QNAME[qtype]);
return -1;
}
if (create(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE, &q->dma, assoc ? assoc->id : 0, ulp)) {
if (__sli_create_queue(sli4, q)) {
ocs_log_err(sli4->os, "create %s failed\n", SLI_QNAME[qtype]);
return -1;
}
q->ulp = ulp;
} else {
ocs_log_err(sli4->os, "cannot create %s\n", SLI_QNAME[qtype]);
return -1;
}
return 0;
}
/**
* @ingroup sli
* @brief Allocate a c queue set.
*
* @param sli4 SLI context.
* @param num_cqs to create
* @param qs Pointers to the queue objects.
* @param n_entries Number of entries to allocate per CQ.
* @param eqs Associated event queues
*
* @return Returns 0 on success, or -1 otherwise.
*/
int32_t
sli_cq_alloc_set(sli4_t *sli4, sli4_queue_t *qs[], uint32_t num_cqs,
uint32_t n_entries, sli4_queue_t *eqs[])
{
uint32_t i, offset = 0, page_bytes = 0, payload_size, cmd_size = 0;
uint32_t p = 0, page_size = 0, n_cqe = 0, num_pages_cq;
uintptr_t addr;
ocs_dma_t dma;
sli4_req_common_create_cq_set_v0_t *req = NULL;
sli4_res_common_create_queue_set_t *res = NULL;
if (!sli4) {
ocs_log_err(NULL, "bad parameter sli4=%p\n", sli4);
return -1;
}
/* Align the queue DMA memory */
for (i = 0; i < num_cqs; i++) {
if (__sli_queue_init(sli4, qs[i], SLI_QTYPE_CQ, SLI4_CQE_BYTES,
n_entries, SLI_PAGE_SIZE)) {
ocs_log_err(sli4->os, "Queue init failed.\n");
goto error;
}
}
n_cqe = qs[0]->dma.size / SLI4_CQE_BYTES;
switch (n_cqe) {
case 256:
case 512:
case 1024:
case 2048:
page_size = 1;
break;
case 4096:
page_size = 2;
break;
default:
return -1;
}
page_bytes = page_size * SLI_PAGE_SIZE;
num_pages_cq = sli_page_count(qs[0]->dma.size, page_bytes);
cmd_size = sizeof(sli4_req_common_create_cq_set_v0_t) + (8 * num_pages_cq * num_cqs);
payload_size = max((size_t)cmd_size, sizeof(sli4_res_common_create_queue_set_t));
if (ocs_dma_alloc(sli4->os, &dma, payload_size, SLI_PAGE_SIZE)) {
ocs_log_err(sli4->os, "DMA allocation failed\n");
goto error;
}
ocs_memset(dma.virt, 0, payload_size);
if (sli_cmd_sli_config(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE,
payload_size, &dma) == -1) {
goto error;
}
/* Fill the request structure */
req = (sli4_req_common_create_cq_set_v0_t *)((uint8_t *)dma.virt);
req->hdr.opcode = SLI4_OPC_COMMON_CREATE_CQ_SET;
req->hdr.subsystem = SLI4_SUBSYSTEM_FCFCOE;
req->hdr.version = 0;
req->hdr.request_length = cmd_size - sizeof(sli4_req_hdr_t);
req->page_size = page_size;
req->num_pages = num_pages_cq;
switch (req->num_pages) {
case 1:
req->cqecnt = SLI4_CQ_CNT_256;
break;
case 2:
req->cqecnt = SLI4_CQ_CNT_512;
break;
case 4:
req->cqecnt = SLI4_CQ_CNT_1024;
break;
case 8:
req->cqecnt = SLI4_CQ_CNT_LARGE;
req->cqe_count = n_cqe;
break;
default:
ocs_log_test(sli4->os, "num_pages %d not valid\n", req->num_pages);
goto error;
}
req->evt = TRUE;
req->valid = TRUE;
req->arm = FALSE;
req->num_cq_req = num_cqs;
/* Fill page addresses of all the CQs. */
for (i = 0; i < num_cqs; i++) {
req->eq_id[i] = eqs[i]->id;
for (p = 0, addr = qs[i]->dma.phys; p < req->num_pages; p++, addr += page_bytes) {
req->page_physical_address[offset].low = ocs_addr32_lo(addr);
req->page_physical_address[offset].high = ocs_addr32_hi(addr);
offset++;
}
}
if (sli_bmbx_command(sli4)) {
ocs_log_crit(sli4->os, "bootstrap mailbox write fail CQSet\n");
goto error;
}
res = (void *)((uint8_t *)dma.virt);
if (res->hdr.status) {
ocs_log_err(sli4->os, "bad create CQSet status=%#x addl=%#x\n",
res->hdr.status, res->hdr.additional_status);
goto error;
} else {
/* Check if we got all requested CQs. */
if (res->num_q_allocated != num_cqs) {
ocs_log_crit(sli4->os, "Requested count CQs doesnt match.\n");
goto error;
}
/* Fill the resp cq ids. */
for (i = 0; i < num_cqs; i++) {
qs[i]->id = res->q_id + i;
qs[i]->doorbell_offset = regmap[SLI4_REG_EQCQ_DOORBELL][sli4->if_type].off;
qs[i]->doorbell_rset = regmap[SLI4_REG_EQCQ_DOORBELL][sli4->if_type].rset;
}
}
ocs_dma_free(sli4->os, &dma);
return 0;
error:
for (i = 0; i < num_cqs; i++) {
if (qs[i]->dma.size) {
ocs_dma_free(sli4->os, &qs[i]->dma);
}
}
if (dma.size) {
ocs_dma_free(sli4->os, &dma);
}
return -1;
}
/**
* @ingroup sli
* @brief Free a queue.
*
* @par Description
* Frees DMA memory and de-registers the requested queue.
*
* @param sli4 SLI context.
* @param q Pointer to the queue object.
* @param destroy_queues Non-zero if the mailbox commands should be sent to destroy the queues.
* @param free_memory Non-zero if the DMA memory associated with the queue should be freed.
*
* @return Returns 0 on success, or -1 otherwise.
*/
int32_t
sli_queue_free(sli4_t *sli4, sli4_queue_t *q, uint32_t destroy_queues, uint32_t free_memory)
{
sli4_destroy_q_fn_t destroy = NULL;
int32_t rc = -1;
if (!sli4 || !q) {
ocs_log_err(NULL, "bad parameter sli4=%p q=%p\n", sli4, q);
return -1;
}
if (destroy_queues) {
switch (q->type) {
case SLI_QTYPE_EQ:
destroy = sli_cmd_common_destroy_eq;
break;
case SLI_QTYPE_CQ:
destroy = sli_cmd_common_destroy_cq;
break;
case SLI_QTYPE_MQ:
destroy = sli_cmd_common_destroy_mq;
break;
case SLI_QTYPE_WQ:
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
destroy = sli_cmd_fcoe_wq_destroy;
} else {
/* TODO */
ocs_log_test(sli4->os, "unsupported WQ destroy\n");
return -1;
}
break;
case SLI_QTYPE_RQ:
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
destroy = sli_cmd_fcoe_rq_destroy;
} else {
/* TODO */
ocs_log_test(sli4->os, "unsupported RQ destroy\n");
return -1;
}
break;
default:
ocs_log_test(sli4->os, "bad queue type %d\n",
q->type);
return -1;
}
/*
* Destroying queues makes BE3 sad (version 0 interface type). Rely
* on COMMON_FUNCTION_RESET to free host allocated queue resources
* inside the SLI Port.
*/
if (SLI4_IF_TYPE_BE3_SKH_PF == sli4->if_type) {
destroy = NULL;
}
/* Destroy the queue if the operation is defined */
if (destroy && destroy(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE, q->id)) {
sli4_res_hdr_t *res = NULL;
if (sli_bmbx_command(sli4)){
ocs_log_crit(sli4->os, "bootstrap mailbox write fail destroy %s\n",
SLI_QNAME[q->type]);
} else if (sli_res_sli_config(sli4->bmbx.virt)) {
ocs_log_err(sli4->os, "bad status destroy %s\n", SLI_QNAME[q->type]);
} else {
res = (void *)((uint8_t *)sli4->bmbx.virt +
offsetof(sli4_cmd_sli_config_t, payload));
if (res->status) {
ocs_log_err(sli4->os, "bad destroy %s status=%#x addl=%#x\n",
SLI_QNAME[q->type],
res->status, res->additional_status);
} else {
rc = 0;
}
}
}
}
if (free_memory) {
ocs_lock_free(&q->lock);
if (ocs_dma_free(sli4->os, &q->dma)) {
ocs_log_err(sli4->os, "%s queue ID %d free failed\n",
SLI_QNAME[q->type], q->id);
rc = -1;
}
}
return rc;
}
int32_t
sli_queue_reset(sli4_t *sli4, sli4_queue_t *q)
{
ocs_lock(&q->lock);
q->index = 0;
q->n_posted = 0;
if (SLI_QTYPE_MQ == q->type) {
q->u.r_idx = 0;
}
if (q->dma.virt != NULL) {
ocs_memset(q->dma.virt, 0, (q->size * q->length));
}
ocs_unlock(&q->lock);
return 0;
}
/**
* @ingroup sli
* @brief Check if the given queue is empty.
*
* @par Description
* If the valid bit of the current entry is unset, the queue is empty.
*
* @param sli4 SLI context.
* @param q Pointer to the queue object.
*
* @return Returns TRUE if empty, or FALSE otherwise.
*/
int32_t
sli_queue_is_empty(sli4_t *sli4, sli4_queue_t *q)
{
int32_t rc = TRUE;
uint8_t *qe = q->dma.virt;
ocs_lock(&q->lock);
ocs_dma_sync(&q->dma, OCS_DMASYNC_POSTREAD);
qe += q->index * q->size;
rc = !sli_queue_entry_is_valid(q, qe, FALSE);
ocs_unlock(&q->lock);
return rc;
}
/**
* @ingroup sli
* @brief Arm an EQ.
*
* @param sli4 SLI context.
* @param q Pointer to queue object.
* @param arm If TRUE, arm the EQ.
*
* @return Returns 0 on success, or non-zero otherwise.
*/
int32_t
sli_queue_eq_arm(sli4_t *sli4, sli4_queue_t *q, uint8_t arm)
{
uint32_t val = 0;
ocs_lock(&q->lock);
val = sli_eq_doorbell(q->n_posted, q->id, arm);
ocs_reg_write32(sli4->os, q->doorbell_rset, q->doorbell_offset, val);
q->n_posted = 0;
ocs_unlock(&q->lock);
return 0;
}
/**
* @ingroup sli
* @brief Arm a queue.
*
* @param sli4 SLI context.
* @param q Pointer to queue object.
* @param arm If TRUE, arm the queue.
*
* @return Returns 0 on success, or non-zero otherwise.
*/
int32_t
sli_queue_arm(sli4_t *sli4, sli4_queue_t *q, uint8_t arm)
{
uint32_t val = 0;
ocs_lock(&q->lock);
switch (q->type) {
case SLI_QTYPE_EQ:
val = sli_eq_doorbell(q->n_posted, q->id, arm);
ocs_reg_write32(sli4->os, q->doorbell_rset, q->doorbell_offset, val);
q->n_posted = 0;
break;
case SLI_QTYPE_CQ:
val = sli_cq_doorbell(q->n_posted, q->id, arm);
ocs_reg_write32(sli4->os, q->doorbell_rset, q->doorbell_offset, val);
q->n_posted = 0;
break;
default:
ocs_log_test(sli4->os, "should only be used for EQ/CQ, not %s\n",
SLI_QNAME[q->type]);
}
ocs_unlock(&q->lock);
return 0;
}
/**
* @ingroup sli
* @brief Write an entry to the queue object.
*
* Note: Assumes the q->lock will be locked and released by the caller.
*
* @param sli4 SLI context.
* @param q Pointer to the queue object.
* @param entry Pointer to the entry contents.
*
* @return Returns queue index on success, or negative error value otherwise.
*/
int32_t
_sli_queue_write(sli4_t *sli4, sli4_queue_t *q, uint8_t *entry)
{
int32_t rc = 0;
uint8_t *qe = q->dma.virt;
uint32_t qindex;
qindex = q->index;
qe += q->index * q->size;
if (entry) {
if ((SLI_QTYPE_WQ == q->type) && sli4->config.perf_wq_id_association) {
sli_set_wq_id_association(entry, q->id);
}
#if defined(OCS_INCLUDE_DEBUG)
switch (q->type) {
case SLI_QTYPE_WQ: {
ocs_dump32(OCS_DEBUG_ENABLE_WQ_DUMP, sli4->os, "wqe", entry, q->size);
break;
}
case SLI_QTYPE_MQ:
/* Note: we don't really need to dump the whole
* 256 bytes, just do 64 */
ocs_dump32(OCS_DEBUG_ENABLE_MQ_DUMP, sli4->os, "mqe outbound", entry, 64);
break;
default:
break;
}
#endif
ocs_memcpy(qe, entry, q->size);
q->n_posted = 1;
}
ocs_dma_sync(&q->dma, OCS_DMASYNC_PREWRITE);
rc = sli_queue_doorbell(sli4, q);
q->index = (q->index + q->n_posted) & (q->length - 1);
q->n_posted = 0;
if (rc < 0) {
/* failure */
return rc;
} else if (rc > 0) {
/* failure, but we need to return a negative value on failure */
return -rc;
} else {
return qindex;
}
}
/**
* @ingroup sli
* @brief Write an entry to the queue object.
*
* Note: Assumes the q->lock will be locked and released by the caller.
*
* @param sli4 SLI context.
* @param q Pointer to the queue object.
* @param entry Pointer to the entry contents.
*
* @return Returns queue index on success, or negative error value otherwise.
*/
int32_t
sli_queue_write(sli4_t *sli4, sli4_queue_t *q, uint8_t *entry)
{
int32_t rc;
ocs_lock(&q->lock);
rc = _sli_queue_write(sli4, q, entry);
ocs_unlock(&q->lock);
return rc;
}
/**
* @brief Check if the current queue entry is valid.
*
* @param q Pointer to the queue object.
* @param qe Pointer to the queue entry.
* @param clear Boolean to clear valid bit.
*
* @return Returns TRUE if the entry is valid, or FALSE otherwise.
*/
static uint8_t
sli_queue_entry_is_valid(sli4_queue_t *q, uint8_t *qe, uint8_t clear)
{
uint8_t valid = FALSE;
switch (q->type) {
case SLI_QTYPE_EQ:
valid = ((sli4_eqe_t *)qe)->vld;
if (valid && clear) {
((sli4_eqe_t *)qe)->vld = 0;
}
break;
case SLI_QTYPE_CQ:
/*
* For both MCQE and WCQE/RCQE, the valid bit
* is bit 31 of dword 3 (0 based)
*/
valid = (qe[15] & 0x80) != 0;
if (valid & clear) {
qe[15] &= ~0x80;
}
break;
case SLI_QTYPE_MQ:
valid = q->index != q->u.r_idx;
break;
case SLI_QTYPE_RQ:
valid = TRUE;
clear = FALSE;
break;
default:
ocs_log_test(NULL, "doesn't handle type=%#x\n", q->type);
}
if (clear) {
ocs_dma_sync(&q->dma, OCS_DMASYNC_PREWRITE);
}
return valid;
}
/**
* @ingroup sli
* @brief Read an entry from the queue object.
*
* @param sli4 SLI context.
* @param q Pointer to the queue object.
* @param entry Destination pointer for the queue entry contents.
*
* @return Returns 0 on success, or non-zero otherwise.
*/
int32_t
sli_queue_read(sli4_t *sli4, sli4_queue_t *q, uint8_t *entry)
{
int32_t rc = 0;
uint8_t *qe = q->dma.virt;
uint32_t *qindex = NULL;
if (SLI_QTYPE_MQ == q->type) {
qindex = &q->u.r_idx;
} else {
qindex = &q->index;
}
ocs_lock(&q->lock);
ocs_dma_sync(&q->dma, OCS_DMASYNC_POSTREAD);
qe += *qindex * q->size;
if (!sli_queue_entry_is_valid(q, qe, TRUE)) {
ocs_unlock(&q->lock);
return -1;
}
if (entry) {
ocs_memcpy(entry, qe, q->size);
#if defined(OCS_INCLUDE_DEBUG)
switch(q->type) {
case SLI_QTYPE_CQ:
ocs_dump32(OCS_DEBUG_ENABLE_CQ_DUMP, sli4->os, "cq", entry, q->size);
break;
case SLI_QTYPE_MQ:
ocs_dump32(OCS_DEBUG_ENABLE_MQ_DUMP, sli4->os, "mq Compl", entry, 64);
break;
case SLI_QTYPE_EQ:
ocs_dump32(OCS_DEBUG_ENABLE_EQ_DUMP, sli4->os, "eq Compl", entry, q->size);
break;
default:
break;
}
#endif
}
switch (q->type) {
case SLI_QTYPE_EQ:
case SLI_QTYPE_CQ:
case SLI_QTYPE_MQ:
*qindex = (*qindex + 1) & (q->length - 1);
if (SLI_QTYPE_MQ != q->type) {
q->n_posted++;
}
break;
default:
/* reads don't update the index */
break;
}
ocs_unlock(&q->lock);
return rc;
}
int32_t
sli_queue_index(sli4_t *sli4, sli4_queue_t *q)
{
if (q) {
return q->index;
} else {
return -1;
}
}
int32_t
sli_queue_poke(sli4_t *sli4, sli4_queue_t *q, uint32_t index, uint8_t *entry)
{
int32_t rc;
ocs_lock(&q->lock);
rc = _sli_queue_poke(sli4, q, index, entry);
ocs_unlock(&q->lock);
return rc;
}
int32_t
_sli_queue_poke(sli4_t *sli4, sli4_queue_t *q, uint32_t index, uint8_t *entry)
{
int32_t rc = 0;
uint8_t *qe = q->dma.virt;
if (index >= q->length) {
return -1;
}
qe += index * q->size;
if (entry) {
ocs_memcpy(qe, entry, q->size);
}
ocs_dma_sync(&q->dma, OCS_DMASYNC_PREWRITE);
return rc;
}
/**
* @ingroup sli
* @brief Allocate SLI Port resources.
*
* @par Description
* Allocate port-related resources, such as VFI, RPI, XRI, and so on.
* Resources are modeled using extents, regardless of whether the underlying
* device implements resource extents. If the device does not implement
* extents, the SLI layer models this as a single (albeit large) extent.
*
* @param sli4 SLI context.
* @param rtype Resource type (for example, RPI or XRI)
* @param rid Allocated resource ID.
* @param index Index into the bitmap.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_resource_alloc(sli4_t *sli4, sli4_resource_e rtype, uint32_t *rid, uint32_t *index)
{
int32_t rc = 0;
uint32_t size;
uint32_t extent_idx;
uint32_t item_idx;
int status;
*rid = UINT32_MAX;
*index = UINT32_MAX;
switch (rtype) {
case SLI_RSRC_FCOE_VFI:
case SLI_RSRC_FCOE_VPI:
case SLI_RSRC_FCOE_RPI:
case SLI_RSRC_FCOE_XRI:
status = ocs_bitmap_find(sli4->config.extent[rtype].use_map,
sli4->config.extent[rtype].map_size);
if (status < 0) {
ocs_log_err(sli4->os, "out of resource %d (alloc=%d)\n",
rtype, sli4->config.extent[rtype].n_alloc);
rc = -1;
break;
} else {
*index = status;
}
size = sli4->config.extent[rtype].size;
extent_idx = *index / size;
item_idx = *index % size;
*rid = sli4->config.extent[rtype].base[extent_idx] + item_idx;
sli4->config.extent[rtype].n_alloc++;
break;
default:
rc = -1;
}
return rc;
}
/**
* @ingroup sli
* @brief Free the SLI Port resources.
*
* @par Description
* Free port-related resources, such as VFI, RPI, XRI, and so. See discussion of
* "extent" usage in sli_resource_alloc.
*
* @param sli4 SLI context.
* @param rtype Resource type (for example, RPI or XRI).
* @param rid Allocated resource ID.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_resource_free(sli4_t *sli4, sli4_resource_e rtype, uint32_t rid)
{
int32_t rc = -1;
uint32_t x;
uint32_t size, *base;
switch (rtype) {
case SLI_RSRC_FCOE_VFI:
case SLI_RSRC_FCOE_VPI:
case SLI_RSRC_FCOE_RPI:
case SLI_RSRC_FCOE_XRI:
/*
* Figure out which extent contains the resource ID. I.e. find
* the extent such that
* extent->base <= resource ID < extent->base + extent->size
*/
base = sli4->config.extent[rtype].base;
size = sli4->config.extent[rtype].size;
/*
* In the case of FW reset, this may be cleared but the force_free path will
* still attempt to free the resource. Prevent a NULL pointer access.
*/
if (base != NULL) {
for (x = 0; x < sli4->config.extent[rtype].number; x++) {
if ((rid >= base[x]) && (rid < (base[x] + size))) {
rid -= base[x];
ocs_bitmap_clear(sli4->config.extent[rtype].use_map,
(x * size) + rid);
rc = 0;
break;
}
}
}
break;
default:
;
}
return rc;
}
int32_t
sli_resource_reset(sli4_t *sli4, sli4_resource_e rtype)
{
int32_t rc = -1;
uint32_t i;
switch (rtype) {
case SLI_RSRC_FCOE_VFI:
case SLI_RSRC_FCOE_VPI:
case SLI_RSRC_FCOE_RPI:
case SLI_RSRC_FCOE_XRI:
for (i = 0; i < sli4->config.extent[rtype].map_size; i++) {
ocs_bitmap_clear(sli4->config.extent[rtype].use_map, i);
}
rc = 0;
break;
default:
;
}
return rc;
}
/**
* @ingroup sli
* @brief Parse an EQ entry to retrieve the CQ_ID for this event.
*
* @param sli4 SLI context.
* @param buf Pointer to the EQ entry.
* @param cq_id CQ_ID for this entry (only valid on success).
*
* @return
* - 0 if success.
* - < 0 if error.
* - > 0 if firmware detects EQ overflow.
*/
int32_t
sli_eq_parse(sli4_t *sli4, uint8_t *buf, uint16_t *cq_id)
{
sli4_eqe_t *eqe = (void *)buf;
int32_t rc = 0;
if (!sli4 || !buf || !cq_id) {
ocs_log_err(NULL, "bad parameters sli4=%p buf=%p cq_id=%p\n",
sli4, buf, cq_id);
return -1;
}
switch (eqe->major_code) {
case SLI4_MAJOR_CODE_STANDARD:
*cq_id = eqe->resource_id;
break;
case SLI4_MAJOR_CODE_SENTINEL:
ocs_log_debug(sli4->os, "sentinel EQE\n");
rc = 1;
break;
default:
ocs_log_test(sli4->os, "Unsupported EQE: major %x minor %x\n",
eqe->major_code, eqe->minor_code);
rc = -1;
}
return rc;
}
/**
* @ingroup sli
* @brief Parse a CQ entry to retrieve the event type and the associated queue.
*
* @param sli4 SLI context.
* @param cq CQ to process.
* @param cqe Pointer to the CQ entry.
* @param etype CQ event type.
* @param q_id Queue ID associated with this completion message
* (that is, MQ_ID, RQ_ID, and so on).
*
* @return
* - 0 if call completed correctly and CQE status is SUCCESS.
* - -1 if call failed (no CQE status).
* - Other value if call completed correctly and return value is a CQE status value.
*/
int32_t
sli_cq_parse(sli4_t *sli4, sli4_queue_t *cq, uint8_t *cqe, sli4_qentry_e *etype,
uint16_t *q_id)
{
int32_t rc = 0;
if (!sli4 || !cq || !cqe || !etype) {
ocs_log_err(NULL, "bad parameters sli4=%p cq=%p cqe=%p etype=%p q_id=%p\n",
sli4, cq, cqe, etype, q_id);
return -1;
}
if (cq->u.flag.is_mq) {
sli4_mcqe_t *mcqe = (void *)cqe;
if (mcqe->ae) {
*etype = SLI_QENTRY_ASYNC;
} else {
*etype = SLI_QENTRY_MQ;
rc = sli_cqe_mq(mcqe);
}
*q_id = -1;
} else if (SLI4_PORT_TYPE_FC == sli4->port_type) {
rc = sli_fc_cqe_parse(sli4, cq, cqe, etype, q_id);
} else {
ocs_log_test(sli4->os, "implement CQE parsing type = %#x\n",
sli4->port_type);
rc = -1;
}
return rc;
}
/**
* @ingroup sli
* @brief Cause chip to enter an unrecoverable error state.
*
* @par Description
* Cause chip to enter an unrecoverable error state. This is
* used when detecting unexpected FW behavior so FW can be
* hwted from the driver as soon as error is detected.
*
* @param sli4 SLI context.
* @param dump Generate dump as part of reset.
*
* @return Returns 0 if call completed correctly, or -1 if call failed (unsupported chip).
*/
int32_t sli_raise_ue(sli4_t *sli4, uint8_t dump)
{
#define FDD 2
if (SLI4_IF_TYPE_BE3_SKH_PF == sli_get_if_type(sli4)) {
switch(sli_get_asic_type(sli4)) {
case SLI4_ASIC_TYPE_BE3: {
sli_reg_write(sli4, SLI4_REG_SW_UE_CSR1, 0xffffffff);
sli_reg_write(sli4, SLI4_REG_SW_UE_CSR2, 0);
break;
}
case SLI4_ASIC_TYPE_SKYHAWK: {
uint32_t value;
value = ocs_config_read32(sli4->os, SLI4_SW_UE_REG);
ocs_config_write32(sli4->os, SLI4_SW_UE_REG, (value | (1U << 24)));
break;
}
default:
ocs_log_test(sli4->os, "invalid asic type %d\n", sli_get_asic_type(sli4));
return -1;
}
} else if (SLI4_IF_TYPE_LANCER_FC_ETH == sli_get_if_type(sli4)) {
if (dump == FDD) {
sli_reg_write(sli4, SLI4_REG_SLIPORT_CONTROL, SLI4_SLIPORT_CONTROL_FDD | SLI4_SLIPORT_CONTROL_IP);
} else {
uint32_t value = SLI4_PHYDEV_CONTROL_FRST;
if (dump == 1) {
value |= SLI4_PHYDEV_CONTROL_DD;
}
sli_reg_write(sli4, SLI4_REG_PHYSDEV_CONTROL, value);
}
} else {
ocs_log_test(sli4->os, "invalid iftype=%d\n", sli_get_if_type(sli4));
return -1;
}
return 0;
}
/**
* @ingroup sli
* @brief Read the SLIPORT_STATUS register to to check if a dump is present.
*
* @param sli4 SLI context.
*
* @return Returns 1 if the chip is ready, or 0 if the chip is not ready, 2 if fdp is present.
*/
int32_t sli_dump_is_ready(sli4_t *sli4)
{
int32_t rc = 0;
uint32_t port_val;
uint32_t bmbx_val;
uint32_t uerr_lo;
uint32_t uerr_hi;
uint32_t uerr_mask_lo;
uint32_t uerr_mask_hi;
if (SLI4_IF_TYPE_BE3_SKH_PF == sli_get_if_type(sli4)) {
/* for iftype=0, dump ready when UE is encountered */
uerr_lo = sli_reg_read(sli4, SLI4_REG_UERR_STATUS_LO);
uerr_hi = sli_reg_read(sli4, SLI4_REG_UERR_STATUS_HI);
uerr_mask_lo = sli_reg_read(sli4, SLI4_REG_UERR_MASK_LO);
uerr_mask_hi = sli_reg_read(sli4, SLI4_REG_UERR_MASK_HI);
if ((uerr_lo & ~uerr_mask_lo) || (uerr_hi & ~uerr_mask_hi)) {
rc = 1;
}
} else if (SLI4_IF_TYPE_LANCER_FC_ETH == sli_get_if_type(sli4)) {
/*
* Ensure that the port is ready AND the mailbox is
* ready before signaling that the dump is ready to go.
*/
port_val = sli_reg_read(sli4, SLI4_REG_SLIPORT_STATUS);
bmbx_val = sli_reg_read(sli4, SLI4_REG_BMBX);
if ((bmbx_val & SLI4_BMBX_RDY) &&
SLI4_PORT_STATUS_READY(port_val)) {
if(SLI4_PORT_STATUS_DUMP_PRESENT(port_val)) {
rc = 1;
}else if( SLI4_PORT_STATUS_FDP_PRESENT(port_val)) {
rc = 2;
}
}
} else {
ocs_log_test(sli4->os, "invalid iftype=%d\n", sli_get_if_type(sli4));
return -1;
}
return rc;
}
/**
* @ingroup sli
* @brief Read the SLIPORT_STATUS register to check if a dump is present.
*
* @param sli4 SLI context.
*
* @return
* - 0 if call completed correctly and no dump is present.
* - 1 if call completed and dump is present.
* - -1 if call failed (unsupported chip).
*/
int32_t sli_dump_is_present(sli4_t *sli4)
{
uint32_t val;
uint32_t ready;
if (SLI4_IF_TYPE_LANCER_FC_ETH != sli_get_if_type(sli4)) {
ocs_log_test(sli4->os, "Function only supported for I/F type 2");
return -1;
}
/* If the chip is not ready, then there cannot be a dump */
ready = sli_wait_for_fw_ready(sli4, SLI4_INIT_PORT_DELAY_US);
if (!ready) {
return 0;
}
val = sli_reg_read(sli4, SLI4_REG_SLIPORT_STATUS);
if (UINT32_MAX == val) {
ocs_log_err(sli4->os, "error reading SLIPORT_STATUS\n");
return -1;
} else {
return ((val & SLI4_PORT_STATUS_DIP) ? 1 : 0);
}
}
/**
* @ingroup sli
* @brief Read the SLIPORT_STATUS register to check if the reset required is set.
*
* @param sli4 SLI context.
*
* @return
* - 0 if call completed correctly and reset is not required.
* - 1 if call completed and reset is required.
* - -1 if call failed.
*/
int32_t sli_reset_required(sli4_t *sli4)
{
uint32_t val;
if (SLI4_IF_TYPE_BE3_SKH_PF == sli_get_if_type(sli4)) {
ocs_log_test(sli4->os, "reset required N/A for iftype 0\n");
return 0;
}
val = sli_reg_read(sli4, SLI4_REG_SLIPORT_STATUS);
if (UINT32_MAX == val) {
ocs_log_err(sli4->os, "error reading SLIPORT_STATUS\n");
return -1;
} else {
return ((val & SLI4_PORT_STATUS_RN) ? 1 : 0);
}
}
/**
* @ingroup sli
* @brief Read the SLIPORT_SEMAPHORE and SLIPORT_STATUS registers to check if
* the port status indicates that a FW error has occurred.
*
* @param sli4 SLI context.
*
* @return
* - 0 if call completed correctly and no FW error occurred.
* - > 0 which indicates that a FW error has occurred.
* - -1 if call failed.
*/
int32_t sli_fw_error_status(sli4_t *sli4)
{
uint32_t sliport_semaphore;
int32_t rc = 0;
sliport_semaphore = sli_reg_read(sli4, SLI4_REG_SLIPORT_SEMAPHORE);
if (UINT32_MAX == sliport_semaphore) {
ocs_log_err(sli4->os, "error reading SLIPORT_SEMAPHORE register\n");
return 1;
}
rc = (SLI4_PORT_SEMAPHORE_IN_ERR(sliport_semaphore) ? 1 : 0);
if (rc == 0) {
if (SLI4_IF_TYPE_BE3_SKH_PF == sli4->if_type ||
(SLI4_IF_TYPE_BE3_SKH_VF == sli4->if_type)) {
uint32_t uerr_mask_lo, uerr_mask_hi;
uint32_t uerr_status_lo, uerr_status_hi;
uerr_mask_lo = sli_reg_read(sli4, SLI4_REG_UERR_MASK_LO);
uerr_mask_hi = sli_reg_read(sli4, SLI4_REG_UERR_MASK_HI);
uerr_status_lo = sli_reg_read(sli4, SLI4_REG_UERR_STATUS_LO);
uerr_status_hi = sli_reg_read(sli4, SLI4_REG_UERR_STATUS_HI);
if ((uerr_mask_lo & uerr_status_lo) != 0 ||
(uerr_mask_hi & uerr_status_hi) != 0) {
rc = 1;
}
} else if ((SLI4_IF_TYPE_LANCER_FC_ETH == sli4->if_type)) {
uint32_t sliport_status;
sliport_status = sli_reg_read(sli4, SLI4_REG_SLIPORT_STATUS);
rc = (SLI4_PORT_STATUS_ERROR(sliport_status) ? 1 : 0);
}
}
return rc;
}
/**
* @ingroup sli
* @brief Determine if the chip FW is in a ready state
*
* @param sli4 SLI context.
*
* @return
* - 0 if call completed correctly and FW is not ready.
* - 1 if call completed correctly and FW is ready.
* - -1 if call failed.
*/
int32_t
sli_fw_ready(sli4_t *sli4)
{
uint32_t val;
int32_t rc = -1;
/*
* Is firmware ready for operation? Check needed depends on IF_TYPE
*/
if (SLI4_IF_TYPE_BE3_SKH_PF == sli4->if_type ||
SLI4_IF_TYPE_BE3_SKH_VF == sli4->if_type) {
val = sli_reg_read(sli4, SLI4_REG_SLIPORT_SEMAPHORE);
rc = ((SLI4_PORT_SEMAPHORE_STATUS_POST_READY ==
SLI4_PORT_SEMAPHORE_PORT(val)) &&
(!SLI4_PORT_SEMAPHORE_IN_ERR(val)) ? 1 : 0);
} else if (SLI4_IF_TYPE_LANCER_FC_ETH == sli4->if_type) {
val = sli_reg_read(sli4, SLI4_REG_SLIPORT_STATUS);
rc = (SLI4_PORT_STATUS_READY(val) ? 1 : 0);
}
return rc;
}
/**
* @ingroup sli
* @brief Determine if the link can be configured
*
* @param sli4 SLI context.
*
* @return
* - 0 if link is not configurable.
* - 1 if link is configurable.
*/
int32_t sli_link_is_configurable(sli4_t *sli)
{
int32_t rc = 0;
/*
* Link config works on: Skyhawk and Lancer
* Link config does not work on: LancerG6
*/
switch (sli_get_asic_type(sli)) {
case SLI4_ASIC_TYPE_SKYHAWK:
case SLI4_ASIC_TYPE_LANCER:
case SLI4_ASIC_TYPE_CORSAIR:
rc = 1;
break;
case SLI4_ASIC_TYPE_LANCERG6:
case SLI4_ASIC_TYPE_BE3:
default:
rc = 0;
break;
}
return rc;
}
/* vim: set noexpandtab textwidth=120: */
/**
* @ingroup sli_fc
* @brief Write an FCOE_WQ_CREATE command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param qmem DMA memory for the queue.
* @param cq_id Associated CQ_ID.
* @param ulp The ULP to bind
*
* @note This creates a Version 0 message.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_fcoe_wq_create(sli4_t *sli4, void *buf, size_t size,
ocs_dma_t *qmem, uint16_t cq_id, uint16_t ulp)
{
sli4_req_fcoe_wq_create_t *wq = NULL;
uint32_t sli_config_off = 0;
uint32_t p;
uintptr_t addr;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
uint32_t payload_size;
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_fcoe_wq_create_t),
sizeof(sli4_res_common_create_queue_t));
sli_config_off = sli_cmd_sli_config(sli4, buf, size, payload_size,
NULL);
}
wq = (sli4_req_fcoe_wq_create_t *)((uint8_t *)buf + sli_config_off);
wq->hdr.opcode = SLI4_OPC_FCOE_WQ_CREATE;
wq->hdr.subsystem = SLI4_SUBSYSTEM_FCFCOE;
wq->hdr.request_length = sizeof(sli4_req_fcoe_wq_create_t) -
sizeof(sli4_req_hdr_t);
/* valid values for number of pages: 1-4 (sec 4.5.1) */
wq->num_pages = sli_page_count(qmem->size, SLI_PAGE_SIZE);
if (!wq->num_pages || (wq->num_pages > SLI4_FCOE_WQ_CREATE_V0_MAX_PAGES)) {
return 0;
}
wq->cq_id = cq_id;
if (sli4->config.dual_ulp_capable) {
wq->dua = 1;
wq->bqu = 1;
wq->ulp = ulp;
}
for (p = 0, addr = qmem->phys;
p < wq->num_pages;
p++, addr += SLI_PAGE_SIZE) {
wq->page_physical_address[p].low = ocs_addr32_lo(addr);
wq->page_physical_address[p].high = ocs_addr32_hi(addr);
}
return(sli_config_off + sizeof(sli4_req_fcoe_wq_create_t));
}
/**
* @ingroup sli_fc
* @brief Write an FCOE_WQ_CREATE_V1 command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param qmem DMA memory for the queue.
* @param cq_id Associated CQ_ID.
* @param ignored This parameter carries the ULP for WQ (ignored for V1)
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_fcoe_wq_create_v1(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *qmem,
uint16_t cq_id, uint16_t ignored)
{
sli4_req_fcoe_wq_create_v1_t *wq = NULL;
uint32_t sli_config_off = 0;
uint32_t p;
uintptr_t addr;
uint32_t page_size = 0;
uint32_t page_bytes = 0;
uint32_t n_wqe = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
uint32_t payload_size;
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_fcoe_wq_create_v1_t),
sizeof(sli4_res_common_create_queue_t));
sli_config_off = sli_cmd_sli_config(sli4, buf, size, payload_size,
NULL);
}
wq = (sli4_req_fcoe_wq_create_v1_t *)((uint8_t *)buf + sli_config_off);
wq->hdr.opcode = SLI4_OPC_FCOE_WQ_CREATE;
wq->hdr.subsystem = SLI4_SUBSYSTEM_FCFCOE;
wq->hdr.request_length = sizeof(sli4_req_fcoe_wq_create_v1_t) -
sizeof(sli4_req_hdr_t);
wq->hdr.version = 1;
n_wqe = qmem->size / sli4->config.wqe_size;
/* This heuristic to determine the page size is simplistic
* but could be made more sophisticated
*/
switch (qmem->size) {
case 4096:
case 8192:
case 16384:
case 32768:
page_size = 1;
break;
case 65536:
page_size = 2;
break;
case 131072:
page_size = 4;
break;
case 262144:
page_size = 8;
break;
case 524288:
page_size = 10;
break;
default:
return 0;
}
page_bytes = page_size * SLI_PAGE_SIZE;
/* valid values for number of pages: 1-8 */
wq->num_pages = sli_page_count(qmem->size, page_bytes);
if (!wq->num_pages || (wq->num_pages > SLI4_FCOE_WQ_CREATE_V1_MAX_PAGES)) {
return 0;
}
wq->cq_id = cq_id;
wq->page_size = page_size;
if (sli4->config.wqe_size == SLI4_WQE_EXT_BYTES) {
wq->wqe_size = SLI4_WQE_EXT_SIZE;
} else {
wq->wqe_size = SLI4_WQE_SIZE;
}
wq->wqe_count = n_wqe;
for (p = 0, addr = qmem->phys;
p < wq->num_pages;
p++, addr += page_bytes) {
wq->page_physical_address[p].low = ocs_addr32_lo(addr);
wq->page_physical_address[p].high = ocs_addr32_hi(addr);
}
return(sli_config_off + sizeof(sli4_req_fcoe_wq_create_v1_t));
}
/**
* @ingroup sli_fc
* @brief Write an FCOE_WQ_DESTROY command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param wq_id WQ_ID.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_fcoe_wq_destroy(sli4_t *sli4, void *buf, size_t size, uint16_t wq_id)
{
sli4_req_fcoe_wq_destroy_t *wq = NULL;
uint32_t sli_config_off = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
uint32_t payload_size;
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_fcoe_wq_destroy_t),
sizeof(sli4_res_hdr_t));
sli_config_off = sli_cmd_sli_config(sli4, buf, size, payload_size,
NULL);
}
wq = (sli4_req_fcoe_wq_destroy_t *)((uint8_t *)buf + sli_config_off);
wq->hdr.opcode = SLI4_OPC_FCOE_WQ_DESTROY;
wq->hdr.subsystem = SLI4_SUBSYSTEM_FCFCOE;
wq->hdr.request_length = sizeof(sli4_req_fcoe_wq_destroy_t) -
sizeof(sli4_req_hdr_t);
wq->wq_id = wq_id;
return(sli_config_off + sizeof(sli4_req_fcoe_wq_destroy_t));
}
/**
* @ingroup sli_fc
* @brief Write an FCOE_POST_SGL_PAGES command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param xri starting XRI
* @param xri_count XRI
* @param page0 First SGL memory page.
* @param page1 Second SGL memory page (optional).
* @param dma DMA buffer for non-embedded mailbox command (options)
*
* if non-embedded mbx command is used, dma buffer must be at least (32 + xri_count*16) in length
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_fcoe_post_sgl_pages(sli4_t *sli4, void *buf, size_t size,
uint16_t xri, uint32_t xri_count, ocs_dma_t *page0[], ocs_dma_t *page1[], ocs_dma_t *dma)
{
sli4_req_fcoe_post_sgl_pages_t *post = NULL;
uint32_t sli_config_off = 0;
uint32_t i;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
uint32_t payload_size;
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_fcoe_post_sgl_pages_t),
sizeof(sli4_res_hdr_t));
sli_config_off = sli_cmd_sli_config(sli4, buf, size, payload_size,
dma);
}
if (dma) {
post = dma->virt;
ocs_memset(post, 0, dma->size);
} else {
post = (sli4_req_fcoe_post_sgl_pages_t *)((uint8_t *)buf + sli_config_off);
}
post->hdr.opcode = SLI4_OPC_FCOE_POST_SGL_PAGES;
post->hdr.subsystem = SLI4_SUBSYSTEM_FCFCOE;
/* payload size calculation
* 4 = xri_start + xri_count
* xri_count = # of XRI's registered
* sizeof(uint64_t) = physical address size
* 2 = # of physical addresses per page set
*/
post->hdr.request_length = 4 + (xri_count * (sizeof(uint64_t) * 2));
post->xri_start = xri;
post->xri_count = xri_count;
for (i = 0; i < xri_count; i++) {
post->page_set[i].page0_low = ocs_addr32_lo(page0[i]->phys);
post->page_set[i].page0_high = ocs_addr32_hi(page0[i]->phys);
}
if (page1) {
for (i = 0; i < xri_count; i++) {
post->page_set[i].page1_low = ocs_addr32_lo(page1[i]->phys);
post->page_set[i].page1_high = ocs_addr32_hi(page1[i]->phys);
}
}
return dma ? sli_config_off : (sli_config_off + sizeof(sli4_req_fcoe_post_sgl_pages_t));
}
/**
* @ingroup sli_fc
* @brief Write an FCOE_RQ_CREATE command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param qmem DMA memory for the queue.
* @param cq_id Associated CQ_ID.
* @param ulp This parameter carries the ULP for the RQ
* @param buffer_size Buffer size pointed to by each RQE.
*
* @note This creates a Version 0 message.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_fcoe_rq_create(sli4_t *sli4, void *buf, size_t size,
ocs_dma_t *qmem, uint16_t cq_id, uint16_t ulp, uint16_t buffer_size)
{
sli4_req_fcoe_rq_create_t *rq = NULL;
uint32_t sli_config_off = 0;
uint32_t p;
uintptr_t addr;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
uint32_t payload_size;
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_fcoe_rq_create_t),
sizeof(sli4_res_common_create_queue_t));
sli_config_off = sli_cmd_sli_config(sli4, buf, size, payload_size,
NULL);
}
rq = (sli4_req_fcoe_rq_create_t *)((uint8_t *)buf + sli_config_off);
rq->hdr.opcode = SLI4_OPC_FCOE_RQ_CREATE;
rq->hdr.subsystem = SLI4_SUBSYSTEM_FCFCOE;
rq->hdr.request_length = sizeof(sli4_req_fcoe_rq_create_t) -
sizeof(sli4_req_hdr_t);
/* valid values for number of pages: 1-8 (sec 4.5.6) */
rq->num_pages = sli_page_count(qmem->size, SLI_PAGE_SIZE);
if (!rq->num_pages || (rq->num_pages > SLI4_FCOE_RQ_CREATE_V0_MAX_PAGES)) {
ocs_log_test(sli4->os, "num_pages %d not valid\n", rq->num_pages);
return 0;
}
/*
* RQE count is the log base 2 of the total number of entries
*/
rq->rqe_count = ocs_lg2(qmem->size / SLI4_FCOE_RQE_SIZE);
if ((buffer_size < SLI4_FCOE_RQ_CREATE_V0_MIN_BUF_SIZE) ||
(buffer_size > SLI4_FCOE_RQ_CREATE_V0_MAX_BUF_SIZE)) {
ocs_log_err(sli4->os, "buffer_size %d out of range (%d-%d)\n",
buffer_size,
SLI4_FCOE_RQ_CREATE_V0_MIN_BUF_SIZE,
SLI4_FCOE_RQ_CREATE_V0_MAX_BUF_SIZE);
return -1;
}
rq->buffer_size = buffer_size;
rq->cq_id = cq_id;
if (sli4->config.dual_ulp_capable) {
rq->dua = 1;
rq->bqu = 1;
rq->ulp = ulp;
}
for (p = 0, addr = qmem->phys;
p < rq->num_pages;
p++, addr += SLI_PAGE_SIZE) {
rq->page_physical_address[p].low = ocs_addr32_lo(addr);
rq->page_physical_address[p].high = ocs_addr32_hi(addr);
}
return(sli_config_off + sizeof(sli4_req_fcoe_rq_create_t));
}
/**
* @ingroup sli_fc
* @brief Write an FCOE_RQ_CREATE_V1 command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param qmem DMA memory for the queue.
* @param cq_id Associated CQ_ID.
* @param ulp This parameter carries the ULP for RQ (ignored for V1)
* @param buffer_size Buffer size pointed to by each RQE.
*
* @note This creates a Version 0 message
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_fcoe_rq_create_v1(sli4_t *sli4, void *buf, size_t size,
ocs_dma_t *qmem, uint16_t cq_id, uint16_t ulp,
uint16_t buffer_size)
{
sli4_req_fcoe_rq_create_v1_t *rq = NULL;
uint32_t sli_config_off = 0;
uint32_t p;
uintptr_t addr;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
uint32_t payload_size;
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_fcoe_rq_create_v1_t),
sizeof(sli4_res_common_create_queue_t));
sli_config_off = sli_cmd_sli_config(sli4, buf, size, payload_size,
NULL);
}
rq = (sli4_req_fcoe_rq_create_v1_t *)((uint8_t *)buf + sli_config_off);
rq->hdr.opcode = SLI4_OPC_FCOE_RQ_CREATE;
rq->hdr.subsystem = SLI4_SUBSYSTEM_FCFCOE;
rq->hdr.request_length = sizeof(sli4_req_fcoe_rq_create_v1_t) -
sizeof(sli4_req_hdr_t);
rq->hdr.version = 1;
/* Disable "no buffer warnings" to avoid Lancer bug */
rq->dnb = TRUE;
/* valid values for number of pages: 1-8 (sec 4.5.6) */
rq->num_pages = sli_page_count(qmem->size, SLI_PAGE_SIZE);
if (!rq->num_pages || (rq->num_pages > SLI4_FCOE_RQ_CREATE_V1_MAX_PAGES)) {
ocs_log_test(sli4->os, "num_pages %d not valid, max %d\n",
rq->num_pages, SLI4_FCOE_RQ_CREATE_V1_MAX_PAGES);
return 0;
}
/*
* RQE count is the total number of entries (note not lg2(# entries))
*/
rq->rqe_count = qmem->size / SLI4_FCOE_RQE_SIZE;
rq->rqe_size = SLI4_FCOE_RQE_SIZE_8;
rq->page_size = SLI4_FCOE_RQ_PAGE_SIZE_4096;
if ((buffer_size < sli4->config.rq_min_buf_size) ||
(buffer_size > sli4->config.rq_max_buf_size)) {
ocs_log_err(sli4->os, "buffer_size %d out of range (%d-%d)\n",
buffer_size,
sli4->config.rq_min_buf_size,
sli4->config.rq_max_buf_size);
return -1;
}
rq->buffer_size = buffer_size;
rq->cq_id = cq_id;
for (p = 0, addr = qmem->phys;
p < rq->num_pages;
p++, addr += SLI_PAGE_SIZE) {
rq->page_physical_address[p].low = ocs_addr32_lo(addr);
rq->page_physical_address[p].high = ocs_addr32_hi(addr);
}
return(sli_config_off + sizeof(sli4_req_fcoe_rq_create_v1_t));
}
/**
* @ingroup sli_fc
* @brief Write an FCOE_RQ_DESTROY command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param rq_id RQ_ID.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_fcoe_rq_destroy(sli4_t *sli4, void *buf, size_t size, uint16_t rq_id)
{
sli4_req_fcoe_rq_destroy_t *rq = NULL;
uint32_t sli_config_off = 0;
if (SLI4_PORT_TYPE_FC == sli4->port_type) {
uint32_t payload_size;
/* Payload length must accommodate both request and response */
payload_size = max(sizeof(sli4_req_fcoe_rq_destroy_t),
sizeof(sli4_res_hdr_t));
sli_config_off = sli_cmd_sli_config(sli4, buf, size, payload_size,
NULL);
}
rq = (sli4_req_fcoe_rq_destroy_t *)((uint8_t *)buf + sli_config_off);
rq->hdr.opcode = SLI4_OPC_FCOE_RQ_DESTROY;
rq->hdr.subsystem = SLI4_SUBSYSTEM_FCFCOE;
rq->hdr.request_length = sizeof(sli4_req_fcoe_rq_destroy_t) -
sizeof(sli4_req_hdr_t);
rq->rq_id = rq_id;
return(sli_config_off + sizeof(sli4_req_fcoe_rq_destroy_t));
}
/**
* @ingroup sli_fc
* @brief Write an FCOE_READ_FCF_TABLE command.
*
* @note
* The response of this command exceeds the size of an embedded
* command and requires an external buffer with DMA capability to hold the results.
* The caller should allocate the ocs_dma_t structure / memory.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param dma Pointer to DMA memory structure. This is allocated by the caller.
* @param index FCF table index to retrieve.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_fcoe_read_fcf_table(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *dma, uint16_t index)
{
sli4_req_fcoe_read_fcf_table_t *read_fcf = NULL;
if (SLI4_PORT_TYPE_FC != sli4->port_type) {
ocs_log_test(sli4->os, "FCOE_READ_FCF_TABLE only supported on FC\n");
return -1;
}
read_fcf = dma->virt;
ocs_memset(read_fcf, 0, sizeof(sli4_req_fcoe_read_fcf_table_t));
read_fcf->hdr.opcode = SLI4_OPC_FCOE_READ_FCF_TABLE;
read_fcf->hdr.subsystem = SLI4_SUBSYSTEM_FCFCOE;
read_fcf->hdr.request_length = dma->size -
sizeof(sli4_req_fcoe_read_fcf_table_t);
read_fcf->fcf_index = index;
return sli_cmd_sli_config(sli4, buf, size, 0, dma);
}
/**
* @ingroup sli_fc
* @brief Write an FCOE_POST_HDR_TEMPLATES command.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the command.
* @param size Buffer size, in bytes.
* @param dma Pointer to DMA memory structure. This is allocated by the caller.
* @param rpi Starting RPI index for the header templates.
* @param payload_dma Pointer to DMA memory used to hold larger descriptor counts.
*
* @return Returns the number of bytes written.
*/
int32_t
sli_cmd_fcoe_post_hdr_templates(sli4_t *sli4, void *buf, size_t size,
ocs_dma_t *dma, uint16_t rpi, ocs_dma_t *payload_dma)
{
sli4_req_fcoe_post_hdr_templates_t *template = NULL;
uint32_t sli_config_off = 0;
uintptr_t phys = 0;
uint32_t i = 0;
uint32_t page_count;
uint32_t payload_size;
page_count = sli_page_count(dma->size, SLI_PAGE_SIZE);
payload_size = sizeof(sli4_req_fcoe_post_hdr_templates_t) +
page_count * sizeof(sli4_physical_page_descriptor_t);
if (page_count > 16) {
/* We can't fit more than 16 descriptors into an embedded mailbox
command, it has to be non-embedded */
if (ocs_dma_alloc(sli4->os, payload_dma, payload_size, 4)) {
ocs_log_err(sli4->os, "mailbox payload memory allocation fail\n");
return 0;
}
sli_config_off = sli_cmd_sli_config(sli4, buf, size, payload_size, payload_dma);
template = (sli4_req_fcoe_post_hdr_templates_t *)payload_dma->virt;
} else {
sli_config_off = sli_cmd_sli_config(sli4, buf, size, payload_size, NULL);
template = (sli4_req_fcoe_post_hdr_templates_t *)((uint8_t *)buf + sli_config_off);
}
if (UINT16_MAX == rpi) {
rpi = sli4->config.extent[SLI_RSRC_FCOE_RPI].base[0];
}
template->hdr.opcode = SLI4_OPC_FCOE_POST_HDR_TEMPLATES;
template->hdr.subsystem = SLI4_SUBSYSTEM_FCFCOE;
template->hdr.request_length = sizeof(sli4_req_fcoe_post_hdr_templates_t) -
sizeof(sli4_req_hdr_t);
template->rpi_offset = rpi;
template->page_count = page_count;
phys = dma->phys;
for (i = 0; i < template->page_count; i++) {
template->page_descriptor[i].low = ocs_addr32_lo(phys);
template->page_descriptor[i].high = ocs_addr32_hi(phys);
phys += SLI_PAGE_SIZE;
}
return(sli_config_off + payload_size);
}
int32_t
sli_cmd_fcoe_rediscover_fcf(sli4_t *sli4, void *buf, size_t size, uint16_t index)
{
sli4_req_fcoe_rediscover_fcf_t *redisc = NULL;
uint32_t sli_config_off = 0;
sli_config_off = sli_cmd_sli_config(sli4, buf, size,
sizeof(sli4_req_fcoe_rediscover_fcf_t),
NULL);
redisc = (sli4_req_fcoe_rediscover_fcf_t *)((uint8_t *)buf + sli_config_off);
redisc->hdr.opcode = SLI4_OPC_FCOE_REDISCOVER_FCF;
redisc->hdr.subsystem = SLI4_SUBSYSTEM_FCFCOE;
redisc->hdr.request_length = sizeof(sli4_req_fcoe_rediscover_fcf_t) -
sizeof(sli4_req_hdr_t);
if (index == UINT16_MAX) {
redisc->fcf_count = 0;
} else {
redisc->fcf_count = 1;
redisc->fcf_index[0] = index;
}
return(sli_config_off + sizeof(sli4_req_fcoe_rediscover_fcf_t));
}
/**
* @ingroup sli_fc
* @brief Write an ABORT_WQE work queue entry.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the WQE.
* @param size Buffer size, in bytes.
* @param type Abort type, such as XRI, abort tag, and request tag.
* @param send_abts Boolean to cause the hardware to automatically generate an ABTS.
* @param ids ID of IOs to abort.
* @param mask Mask applied to the ID values to abort.
* @param tag Tag value associated with this abort.
* @param cq_id The id of the completion queue where the WQE response is sent.
* @param dnrx When set to 1, this field indicates that the SLI Port must not return the associated XRI to the SLI
* Port's optimized write XRI pool.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_abort_wqe(sli4_t *sli4, void *buf, size_t size, sli4_abort_type_e type, uint32_t send_abts,
uint32_t ids, uint32_t mask, uint16_t tag, uint16_t cq_id)
{
sli4_abort_wqe_t *abort = buf;
ocs_memset(buf, 0, size);
switch (type) {
case SLI_ABORT_XRI:
abort->criteria = SLI4_ABORT_CRITERIA_XRI_TAG;
if (mask) {
ocs_log_warn(sli4->os, "warning non-zero mask %#x when aborting XRI %#x\n", mask, ids);
mask = 0;
}
break;
case SLI_ABORT_ABORT_ID:
abort->criteria = SLI4_ABORT_CRITERIA_ABORT_TAG;
break;
case SLI_ABORT_REQUEST_ID:
abort->criteria = SLI4_ABORT_CRITERIA_REQUEST_TAG;
break;
default:
ocs_log_test(sli4->os, "unsupported type %#x\n", type);
return -1;
}
abort->ia = send_abts ? 0 : 1;
/* Suppress ABTS retries */
abort->ir = 1;
abort->t_mask = mask;
abort->t_tag = ids;
abort->command = SLI4_WQE_ABORT;
abort->request_tag = tag;
abort->qosd = TRUE;
abort->cq_id = cq_id;
abort->cmd_type = SLI4_CMD_ABORT_WQE;
return 0;
}
/**
* @ingroup sli_fc
* @brief Write an ELS_REQUEST64_WQE work queue entry.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the WQE.
* @param size Buffer size, in bytes.
* @param sgl DMA memory for the ELS request.
* @param req_type ELS request type.
* @param req_len Length of ELS request in bytes.
* @param max_rsp_len Max length of ELS response in bytes.
* @param timeout Time, in seconds, before an IO times out. Zero means 2 * R_A_TOV.
* @param xri XRI for this exchange.
* @param tag IO tag value.
* @param cq_id The id of the completion queue where the WQE response is sent.
* @param rnode Destination of ELS request (that is, the remote node).
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_els_request64_wqe(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *sgl, uint8_t req_type,
uint32_t req_len, uint32_t max_rsp_len, uint8_t timeout,
uint16_t xri, uint16_t tag, uint16_t cq_id, ocs_remote_node_t *rnode)
{
sli4_els_request64_wqe_t *els = buf;
sli4_sge_t *sge = sgl->virt;
uint8_t is_fabric = FALSE;
ocs_memset(buf, 0, size);
if (sli4->config.sgl_pre_registered) {
els->xbl = FALSE;
els->dbde = TRUE;
els->els_request_payload.bde_type = SLI4_BDE_TYPE_BDE_64;
els->els_request_payload.buffer_length = req_len;
els->els_request_payload.u.data.buffer_address_low = sge[0].buffer_address_low;
els->els_request_payload.u.data.buffer_address_high = sge[0].buffer_address_high;
} else {
els->xbl = TRUE;
els->els_request_payload.bde_type = SLI4_BDE_TYPE_BLP;
els->els_request_payload.buffer_length = 2 * sizeof(sli4_sge_t);
els->els_request_payload.u.blp.sgl_segment_address_low = ocs_addr32_lo(sgl->phys);
els->els_request_payload.u.blp.sgl_segment_address_high = ocs_addr32_hi(sgl->phys);
}
els->els_request_payload_length = req_len;
els->max_response_payload_length = max_rsp_len;
els->xri_tag = xri;
els->timer = timeout;
els->class = SLI4_ELS_REQUEST64_CLASS_3;
els->command = SLI4_WQE_ELS_REQUEST64;
els->request_tag = tag;
if (rnode->node_group) {
els->hlm = TRUE;
els->remote_id = rnode->fc_id & 0x00ffffff;
}
els->iod = SLI4_ELS_REQUEST64_DIR_READ;
els->qosd = TRUE;
/* figure out the ELS_ID value from the request buffer */
switch (req_type) {
case FC_ELS_CMD_LOGO:
els->els_id = SLI4_ELS_REQUEST64_LOGO;
if (rnode->attached) {
els->ct = SLI4_ELS_REQUEST64_CONTEXT_RPI;
els->context_tag = rnode->indicator;
} else {
els->ct = SLI4_ELS_REQUEST64_CONTEXT_VPI;
els->context_tag = rnode->sport->indicator;
}
if (FC_ADDR_FABRIC == rnode->fc_id) {
is_fabric = TRUE;
}
break;
case FC_ELS_CMD_FDISC:
if (FC_ADDR_FABRIC == rnode->fc_id) {
is_fabric = TRUE;
}
if (0 == rnode->sport->fc_id) {
els->els_id = SLI4_ELS_REQUEST64_FDISC;
is_fabric = TRUE;
} else {
els->els_id = SLI4_ELS_REQUEST64_OTHER;
}
els->ct = SLI4_ELS_REQUEST64_CONTEXT_VPI;
els->context_tag = rnode->sport->indicator;
els->sp = TRUE;
break;
case FC_ELS_CMD_FLOGI:
els->els_id = SLI4_ELS_REQUEST64_FLOGIN;
is_fabric = TRUE;
if (SLI4_IF_TYPE_BE3_SKH_PF == sli4->if_type) {
if (!rnode->sport->domain) {
ocs_log_test(sli4->os, "invalid domain handle\n");
return -1;
}
/*
* IF_TYPE 0 skips INIT_VFI/INIT_VPI and therefore must use the
* FCFI here
*/
els->ct = SLI4_ELS_REQUEST64_CONTEXT_FCFI;
els->context_tag = rnode->sport->domain->fcf_indicator;
els->sp = TRUE;
} else {
els->ct = SLI4_ELS_REQUEST64_CONTEXT_VPI;
els->context_tag = rnode->sport->indicator;
/*
* Set SP here ... we haven't done a REG_VPI yet
* TODO: need to maybe not set this when we have
* completed VFI/VPI registrations ...
*
* Use the FC_ID of the SPORT if it has been allocated, otherwise
* use an S_ID of zero.
*/
els->sp = TRUE;
if (rnode->sport->fc_id != UINT32_MAX) {
els->sid = rnode->sport->fc_id;
}
}
break;
case FC_ELS_CMD_PLOGI:
els->els_id = SLI4_ELS_REQUEST64_PLOGI;
els->ct = SLI4_ELS_REQUEST64_CONTEXT_VPI;
els->context_tag = rnode->sport->indicator;
break;
case FC_ELS_CMD_SCR:
els->els_id = SLI4_ELS_REQUEST64_OTHER;
els->ct = SLI4_ELS_REQUEST64_CONTEXT_VPI;
els->context_tag = rnode->sport->indicator;
break;
default:
els->els_id = SLI4_ELS_REQUEST64_OTHER;
if (rnode->attached) {
els->ct = SLI4_ELS_REQUEST64_CONTEXT_RPI;
els->context_tag = rnode->indicator;
} else {
els->ct = SLI4_ELS_REQUEST64_CONTEXT_VPI;
els->context_tag = rnode->sport->indicator;
}
break;
}
if (is_fabric) {
els->cmd_type = SLI4_ELS_REQUEST64_CMD_FABRIC;
} else {
els->cmd_type = SLI4_ELS_REQUEST64_CMD_NON_FABRIC;
}
els->cq_id = cq_id;
if (SLI4_ELS_REQUEST64_CONTEXT_RPI != els->ct) {
els->remote_id = rnode->fc_id;
}
if (SLI4_ELS_REQUEST64_CONTEXT_VPI == els->ct) {
els->temporary_rpi = rnode->indicator;
}
return 0;
}
/**
* @ingroup sli_fc
* @brief Write an FCP_ICMND64_WQE work queue entry.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the WQE.
* @param size Buffer size, in bytes.
* @param sgl DMA memory for the scatter gather list.
* @param xri XRI for this exchange.
* @param tag IO tag value.
* @param cq_id The id of the completion queue where the WQE response is sent.
* @param rpi remote node indicator (RPI)
* @param rnode Destination request (that is, the remote node).
* @param timeout Time, in seconds, before an IO times out. Zero means no timeout.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_fcp_icmnd64_wqe(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *sgl,
uint16_t xri, uint16_t tag, uint16_t cq_id,
uint32_t rpi, ocs_remote_node_t *rnode, uint8_t timeout)
{
sli4_fcp_icmnd64_wqe_t *icmnd = buf;
sli4_sge_t *sge = NULL;
ocs_memset(buf, 0, size);
if (!sgl || !sgl->virt) {
ocs_log_err(sli4->os, "bad parameter sgl=%p virt=%p\n",
sgl, sgl ? sgl->virt : NULL);
return -1;
}
sge = sgl->virt;
if (sli4->config.sgl_pre_registered) {
icmnd->xbl = FALSE;
icmnd->dbde = TRUE;
icmnd->bde.bde_type = SLI4_BDE_TYPE_BDE_64;
icmnd->bde.buffer_length = sge[0].buffer_length;
icmnd->bde.u.data.buffer_address_low = sge[0].buffer_address_low;
icmnd->bde.u.data.buffer_address_high = sge[0].buffer_address_high;
} else {
icmnd->xbl = TRUE;
icmnd->bde.bde_type = SLI4_BDE_TYPE_BLP;
icmnd->bde.buffer_length = sgl->size;
icmnd->bde.u.blp.sgl_segment_address_low = ocs_addr32_lo(sgl->phys);
icmnd->bde.u.blp.sgl_segment_address_high = ocs_addr32_hi(sgl->phys);
}
icmnd->payload_offset_length = sge[0].buffer_length + sge[1].buffer_length;
icmnd->xri_tag = xri;
icmnd->context_tag = rpi;
icmnd->timer = timeout;
icmnd->pu = 2; /* WQE word 4 contains read transfer length */
icmnd->class = SLI4_ELS_REQUEST64_CLASS_3;
icmnd->command = SLI4_WQE_FCP_ICMND64;
icmnd->ct = SLI4_ELS_REQUEST64_CONTEXT_RPI;
icmnd->abort_tag = xri;
icmnd->request_tag = tag;
icmnd->len_loc = 3;
if (rnode->node_group) {
icmnd->hlm = TRUE;
icmnd->remote_n_port_id = rnode->fc_id & 0x00ffffff;
}
if (((ocs_node_t *)rnode->node)->fcp2device) {
icmnd->erp = TRUE;
}
icmnd->cmd_type = SLI4_CMD_FCP_ICMND64_WQE;
icmnd->cq_id = cq_id;
return 0;
}
/**
* @ingroup sli_fc
* @brief Write an FCP_IREAD64_WQE work queue entry.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the WQE.
* @param size Buffer size, in bytes.
* @param sgl DMA memory for the scatter gather list.
* @param first_data_sge Index of first data sge (used if perf hints are enabled)
* @param xfer_len Data transfer length.
* @param xri XRI for this exchange.
* @param tag IO tag value.
* @param cq_id The id of the completion queue where the WQE response is sent.
* @param rpi remote node indicator (RPI)
* @param rnode Destination request (i.e. remote node).
* @param dif T10 DIF operation, or 0 to disable.
* @param bs T10 DIF block size, or 0 if DIF is disabled.
* @param timeout Time, in seconds, before an IO times out. Zero means no timeout.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_fcp_iread64_wqe(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *sgl, uint32_t first_data_sge,
uint32_t xfer_len, uint16_t xri, uint16_t tag, uint16_t cq_id,
uint32_t rpi, ocs_remote_node_t *rnode,
uint8_t dif, uint8_t bs, uint8_t timeout)
{
sli4_fcp_iread64_wqe_t *iread = buf;
sli4_sge_t *sge = NULL;
ocs_memset(buf, 0, size);
if (!sgl || !sgl->virt) {
ocs_log_err(sli4->os, "bad parameter sgl=%p virt=%p\n",
sgl, sgl ? sgl->virt : NULL);
return -1;
}
sge = sgl->virt;
if (sli4->config.sgl_pre_registered) {
iread->xbl = FALSE;
iread->dbde = TRUE;
iread->bde.bde_type = SLI4_BDE_TYPE_BDE_64;
iread->bde.buffer_length = sge[0].buffer_length;
iread->bde.u.data.buffer_address_low = sge[0].buffer_address_low;
iread->bde.u.data.buffer_address_high = sge[0].buffer_address_high;
} else {
iread->xbl = TRUE;
iread->bde.bde_type = SLI4_BDE_TYPE_BLP;
iread->bde.buffer_length = sgl->size;
iread->bde.u.blp.sgl_segment_address_low = ocs_addr32_lo(sgl->phys);
iread->bde.u.blp.sgl_segment_address_high = ocs_addr32_hi(sgl->phys);
/* fill out fcp_cmnd buffer len and change resp buffer to be of type
* "skip" (note: response will still be written to sge[1] if necessary) */
iread->fcp_cmd_buffer_length = sge[0].buffer_length;
sge[1].sge_type = SLI4_SGE_TYPE_SKIP;
}
iread->payload_offset_length = sge[0].buffer_length + sge[1].buffer_length;
iread->total_transfer_length = xfer_len;
iread->xri_tag = xri;
iread->context_tag = rpi;
iread->timer = timeout;
iread->pu = 2; /* WQE word 4 contains read transfer length */
iread->class = SLI4_ELS_REQUEST64_CLASS_3;
iread->command = SLI4_WQE_FCP_IREAD64;
iread->ct = SLI4_ELS_REQUEST64_CONTEXT_RPI;
iread->dif = dif;
iread->bs = bs;
iread->abort_tag = xri;
iread->request_tag = tag;
iread->len_loc = 3;
if (rnode->node_group) {
iread->hlm = TRUE;
iread->remote_n_port_id = rnode->fc_id & 0x00ffffff;
}
if (((ocs_node_t *)rnode->node)->fcp2device) {
iread->erp = TRUE;
}
iread->iod = 1;
iread->cmd_type = SLI4_CMD_FCP_IREAD64_WQE;
iread->cq_id = cq_id;
if (sli4->config.perf_hint) {
iread->first_data_bde.bde_type = SLI4_BDE_TYPE_BDE_64;
iread->first_data_bde.buffer_length = sge[first_data_sge].buffer_length;
iread->first_data_bde.u.data.buffer_address_low = sge[first_data_sge].buffer_address_low;
iread->first_data_bde.u.data.buffer_address_high = sge[first_data_sge].buffer_address_high;
}
return 0;
}
/**
* @ingroup sli_fc
* @brief Write an FCP_IWRITE64_WQE work queue entry.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the WQE.
* @param size Buffer size, in bytes.
* @param sgl DMA memory for the scatter gather list.
* @param first_data_sge Index of first data sge (used if perf hints are enabled)
* @param xfer_len Data transfer length.
* @param first_burst The number of first burst bytes
* @param xri XRI for this exchange.
* @param tag IO tag value.
* @param cq_id The id of the completion queue where the WQE response is sent.
* @param rpi remote node indicator (RPI)
* @param rnode Destination request (i.e. remote node)
* @param dif T10 DIF operation, or 0 to disable
* @param bs T10 DIF block size, or 0 if DIF is disabled
* @param timeout Time, in seconds, before an IO times out. Zero means no timeout.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_fcp_iwrite64_wqe(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *sgl, uint32_t first_data_sge,
uint32_t xfer_len, uint32_t first_burst, uint16_t xri, uint16_t tag, uint16_t cq_id,
uint32_t rpi, ocs_remote_node_t *rnode,
uint8_t dif, uint8_t bs, uint8_t timeout)
{
sli4_fcp_iwrite64_wqe_t *iwrite = buf;
sli4_sge_t *sge = NULL;
ocs_memset(buf, 0, size);
if (!sgl || !sgl->virt) {
ocs_log_err(sli4->os, "bad parameter sgl=%p virt=%p\n",
sgl, sgl ? sgl->virt : NULL);
return -1;
}
sge = sgl->virt;
if (sli4->config.sgl_pre_registered) {
iwrite->xbl = FALSE;
iwrite->dbde = TRUE;
iwrite->bde.bde_type = SLI4_BDE_TYPE_BDE_64;
iwrite->bde.buffer_length = sge[0].buffer_length;
iwrite->bde.u.data.buffer_address_low = sge[0].buffer_address_low;
iwrite->bde.u.data.buffer_address_high = sge[0].buffer_address_high;
} else {
iwrite->xbl = TRUE;
iwrite->bde.bde_type = SLI4_BDE_TYPE_BLP;
iwrite->bde.buffer_length = sgl->size;
iwrite->bde.u.blp.sgl_segment_address_low = ocs_addr32_lo(sgl->phys);
iwrite->bde.u.blp.sgl_segment_address_high = ocs_addr32_hi(sgl->phys);
/* fill out fcp_cmnd buffer len and change resp buffer to be of type
* "skip" (note: response will still be written to sge[1] if necessary) */
iwrite->fcp_cmd_buffer_length = sge[0].buffer_length;
sge[1].sge_type = SLI4_SGE_TYPE_SKIP;
}
iwrite->payload_offset_length = sge[0].buffer_length + sge[1].buffer_length;
iwrite->total_transfer_length = xfer_len;
iwrite->initial_transfer_length = MIN(xfer_len, first_burst);
iwrite->xri_tag = xri;
iwrite->context_tag = rpi;
iwrite->timer = timeout;
iwrite->pu = 2; /* WQE word 4 contains read transfer length */
iwrite->class = SLI4_ELS_REQUEST64_CLASS_3;
iwrite->command = SLI4_WQE_FCP_IWRITE64;
iwrite->ct = SLI4_ELS_REQUEST64_CONTEXT_RPI;
iwrite->dif = dif;
iwrite->bs = bs;
iwrite->abort_tag = xri;
iwrite->request_tag = tag;
iwrite->len_loc = 3;
if (rnode->node_group) {
iwrite->hlm = TRUE;
iwrite->remote_n_port_id = rnode->fc_id & 0x00ffffff;
}
if (((ocs_node_t *)rnode->node)->fcp2device) {
iwrite->erp = TRUE;
}
iwrite->cmd_type = SLI4_CMD_FCP_IWRITE64_WQE;
iwrite->cq_id = cq_id;
if (sli4->config.perf_hint) {
iwrite->first_data_bde.bde_type = SLI4_BDE_TYPE_BDE_64;
iwrite->first_data_bde.buffer_length = sge[first_data_sge].buffer_length;
iwrite->first_data_bde.u.data.buffer_address_low = sge[first_data_sge].buffer_address_low;
iwrite->first_data_bde.u.data.buffer_address_high = sge[first_data_sge].buffer_address_high;
}
return 0;
}
/**
* @ingroup sli_fc
* @brief Write an FCP_TRECEIVE64_WQE work queue entry.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the WQE.
* @param size Buffer size, in bytes.
* @param sgl DMA memory for the Scatter-Gather List.
* @param first_data_sge Index of first data sge (used if perf hints are enabled)
* @param relative_off Relative offset of the IO (if any).
* @param xfer_len Data transfer length.
* @param xri XRI for this exchange.
* @param tag IO tag value.
* @param xid OX_ID for the exchange.
* @param cq_id The id of the completion queue where the WQE response is sent.
* @param rpi remote node indicator (RPI)
* @param rnode Destination request (i.e. remote node).
* @param flags Optional attributes, including:
* - ACTIVE - IO is already active.
* - AUTO RSP - Automatically generate a good FCP_RSP.
* @param dif T10 DIF operation, or 0 to disable.
* @param bs T10 DIF block size, or 0 if DIF is disabled.
* @param csctl value of csctl field.
* @param app_id value for VM application header.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_fcp_treceive64_wqe(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *sgl, uint32_t first_data_sge,
uint32_t relative_off, uint32_t xfer_len, uint16_t xri, uint16_t tag, uint16_t cq_id,
uint16_t xid, uint32_t rpi, ocs_remote_node_t *rnode, uint32_t flags, uint8_t dif, uint8_t bs,
uint8_t csctl, uint32_t app_id)
{
sli4_fcp_treceive64_wqe_t *trecv = buf;
sli4_fcp_128byte_wqe_t *trecv_128 = buf;
sli4_sge_t *sge = NULL;
ocs_memset(buf, 0, size);
if (!sgl || !sgl->virt) {
ocs_log_err(sli4->os, "bad parameter sgl=%p virt=%p\n",
sgl, sgl ? sgl->virt : NULL);
return -1;
}
sge = sgl->virt;
if (sli4->config.sgl_pre_registered) {
trecv->xbl = FALSE;
trecv->dbde = TRUE;
trecv->bde.bde_type = SLI4_BDE_TYPE_BDE_64;
trecv->bde.buffer_length = sge[0].buffer_length;
trecv->bde.u.data.buffer_address_low = sge[0].buffer_address_low;
trecv->bde.u.data.buffer_address_high = sge[0].buffer_address_high;
trecv->payload_offset_length = sge[0].buffer_length;
} else {
trecv->xbl = TRUE;
/* if data is a single physical address, use a BDE */
if (!dif && (xfer_len <= sge[2].buffer_length)) {
trecv->dbde = TRUE;
trecv->bde.bde_type = SLI4_BDE_TYPE_BDE_64;
trecv->bde.buffer_length = sge[2].buffer_length;
trecv->bde.u.data.buffer_address_low = sge[2].buffer_address_low;
trecv->bde.u.data.buffer_address_high = sge[2].buffer_address_high;
} else {
trecv->bde.bde_type = SLI4_BDE_TYPE_BLP;
trecv->bde.buffer_length = sgl->size;
trecv->bde.u.blp.sgl_segment_address_low = ocs_addr32_lo(sgl->phys);
trecv->bde.u.blp.sgl_segment_address_high = ocs_addr32_hi(sgl->phys);
}
}
trecv->relative_offset = relative_off;
if (flags & SLI4_IO_CONTINUATION) {
trecv->xc = TRUE;
}
trecv->xri_tag = xri;
trecv->context_tag = rpi;
trecv->pu = TRUE; /* WQE uses relative offset */
if (flags & SLI4_IO_AUTO_GOOD_RESPONSE) {
trecv->ar = TRUE;
}
trecv->command = SLI4_WQE_FCP_TRECEIVE64;
trecv->class = SLI4_ELS_REQUEST64_CLASS_3;
trecv->ct = SLI4_ELS_REQUEST64_CONTEXT_RPI;
trecv->dif = dif;
trecv->bs = bs;
trecv->remote_xid = xid;
trecv->request_tag = tag;
trecv->iod = 1;
trecv->len_loc = 0x2;
if (rnode->node_group) {
trecv->hlm = TRUE;
trecv->dword5.dword = rnode->fc_id & 0x00ffffff;
}
trecv->cmd_type = SLI4_CMD_FCP_TRECEIVE64_WQE;
trecv->cq_id = cq_id;
trecv->fcp_data_receive_length = xfer_len;
if (sli4->config.perf_hint) {
trecv->first_data_bde.bde_type = SLI4_BDE_TYPE_BDE_64;
trecv->first_data_bde.buffer_length = sge[first_data_sge].buffer_length;
trecv->first_data_bde.u.data.buffer_address_low = sge[first_data_sge].buffer_address_low;
trecv->first_data_bde.u.data.buffer_address_high = sge[first_data_sge].buffer_address_high;
}
/* The upper 7 bits of csctl is the priority */
if (csctl & SLI4_MASK_CCP) {
trecv->ccpe = 1;
trecv->ccp = (csctl & SLI4_MASK_CCP);
}
if (app_id && (sli4->config.wqe_size == SLI4_WQE_EXT_BYTES) && !trecv->eat) {
trecv->app_id_valid = 1;
trecv->wqes = 1;
trecv_128->dw[31] = app_id;
}
return 0;
}
/**
* @ingroup sli_fc
* @brief Write an FCP_CONT_TRECEIVE64_WQE work queue entry.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the WQE.
* @param size Buffer size, in bytes.
* @param sgl DMA memory for the Scatter-Gather List.
* @param first_data_sge Index of first data sge (used if perf hints are enabled)
* @param relative_off Relative offset of the IO (if any).
* @param xfer_len Data transfer length.
* @param xri XRI for this exchange.
* @param sec_xri Secondary XRI for this exchange. (BZ 161832 workaround)
* @param tag IO tag value.
* @param xid OX_ID for the exchange.
* @param cq_id The id of the completion queue where the WQE response is sent.
* @param rpi remote node indicator (RPI)
* @param rnode Destination request (i.e. remote node).
* @param flags Optional attributes, including:
* - ACTIVE - IO is already active.
* - AUTO RSP - Automatically generate a good FCP_RSP.
* @param dif T10 DIF operation, or 0 to disable.
* @param bs T10 DIF block size, or 0 if DIF is disabled.
* @param csctl value of csctl field.
* @param app_id value for VM application header.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_fcp_cont_treceive64_wqe(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *sgl, uint32_t first_data_sge,
uint32_t relative_off, uint32_t xfer_len, uint16_t xri, uint16_t sec_xri, uint16_t tag,
uint16_t cq_id, uint16_t xid, uint32_t rpi, ocs_remote_node_t *rnode, uint32_t flags,
uint8_t dif, uint8_t bs, uint8_t csctl, uint32_t app_id)
{
int32_t rc;
rc = sli_fcp_treceive64_wqe(sli4, buf, size, sgl, first_data_sge, relative_off, xfer_len, xri, tag,
cq_id, xid, rpi, rnode, flags, dif, bs, csctl, app_id);
if (rc == 0) {
sli4_fcp_treceive64_wqe_t *trecv = buf;
trecv->command = SLI4_WQE_FCP_CONT_TRECEIVE64;
trecv->dword5.sec_xri_tag = sec_xri;
}
return rc;
}
/**
* @ingroup sli_fc
* @brief Write an FCP_TRSP64_WQE work queue entry.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the WQE.
* @param size Buffer size, in bytes.
* @param sgl DMA memory for the Scatter-Gather List.
* @param rsp_len Response data length.
* @param xri XRI for this exchange.
* @param tag IO tag value.
* @param cq_id The id of the completion queue where the WQE response is sent.
* @param xid OX_ID for the exchange.
* @param rpi remote node indicator (RPI)
* @param rnode Destination request (i.e. remote node).
* @param flags Optional attributes, including:
* - ACTIVE - IO is already active
* - AUTO RSP - Automatically generate a good FCP_RSP.
* @param csctl value of csctl field.
* @param port_owned 0/1 to indicate if the XRI is port owned (used to set XBL=0)
* @param app_id value for VM application header.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_fcp_trsp64_wqe(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *sgl, uint32_t rsp_len,
uint16_t xri, uint16_t tag, uint16_t cq_id, uint16_t xid, uint32_t rpi, ocs_remote_node_t *rnode,
uint32_t flags, uint8_t csctl, uint8_t port_owned, uint32_t app_id)
{
sli4_fcp_trsp64_wqe_t *trsp = buf;
sli4_fcp_128byte_wqe_t *trsp_128 = buf;
ocs_memset(buf, 0, size);
if (flags & SLI4_IO_AUTO_GOOD_RESPONSE) {
trsp->ag = TRUE;
/*
* The SLI-4 documentation states that the BDE is ignored when
* using auto-good response, but, at least for IF_TYPE 0 devices,
* this does not appear to be true.
*/
if (SLI4_IF_TYPE_BE3_SKH_PF == sli4->if_type) {
trsp->bde.buffer_length = 12; /* byte size of RSP */
}
} else {
sli4_sge_t *sge = sgl->virt;
if (sli4->config.sgl_pre_registered || port_owned) {
trsp->dbde = TRUE;
} else {
trsp->xbl = TRUE;
}
trsp->bde.bde_type = SLI4_BDE_TYPE_BDE_64;
trsp->bde.buffer_length = sge[0].buffer_length;
trsp->bde.u.data.buffer_address_low = sge[0].buffer_address_low;
trsp->bde.u.data.buffer_address_high = sge[0].buffer_address_high;
trsp->fcp_response_length = rsp_len;
}
if (flags & SLI4_IO_CONTINUATION) {
trsp->xc = TRUE;
}
if (rnode->node_group) {
trsp->hlm = TRUE;
trsp->dword5 = rnode->fc_id & 0x00ffffff;
}
trsp->xri_tag = xri;
trsp->rpi = rpi;
trsp->command = SLI4_WQE_FCP_TRSP64;
trsp->class = SLI4_ELS_REQUEST64_CLASS_3;
trsp->remote_xid = xid;
trsp->request_tag = tag;
trsp->dnrx = ((flags & SLI4_IO_DNRX) == 0 ? 0 : 1);
trsp->len_loc = 0x1;
trsp->cq_id = cq_id;
trsp->cmd_type = SLI4_CMD_FCP_TRSP64_WQE;
/* The upper 7 bits of csctl is the priority */
if (csctl & SLI4_MASK_CCP) {
trsp->ccpe = 1;
trsp->ccp = (csctl & SLI4_MASK_CCP);
}
if (app_id && (sli4->config.wqe_size == SLI4_WQE_EXT_BYTES) && !trsp->eat) {
trsp->app_id_valid = 1;
trsp->wqes = 1;
trsp_128->dw[31] = app_id;
}
return 0;
}
/**
* @ingroup sli_fc
* @brief Write an FCP_TSEND64_WQE work queue entry.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the WQE.
* @param size Buffer size, in bytes.
* @param sgl DMA memory for the scatter gather list.
* @param first_data_sge Index of first data sge (used if perf hints are enabled)
* @param relative_off Relative offset of the IO (if any).
* @param xfer_len Data transfer length.
* @param xri XRI for this exchange.
* @param tag IO tag value.
* @param cq_id The id of the completion queue where the WQE response is sent.
* @param xid OX_ID for the exchange.
* @param rpi remote node indicator (RPI)
* @param rnode Destination request (i.e. remote node).
* @param flags Optional attributes, including:
* - ACTIVE - IO is already active.
* - AUTO RSP - Automatically generate a good FCP_RSP.
* @param dif T10 DIF operation, or 0 to disable.
* @param bs T10 DIF block size, or 0 if DIF is disabled.
* @param csctl value of csctl field.
* @param app_id value for VM application header.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_fcp_tsend64_wqe(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *sgl, uint32_t first_data_sge,
uint32_t relative_off, uint32_t xfer_len,
uint16_t xri, uint16_t tag, uint16_t cq_id, uint16_t xid, uint32_t rpi, ocs_remote_node_t *rnode,
uint32_t flags, uint8_t dif, uint8_t bs, uint8_t csctl, uint32_t app_id)
{
sli4_fcp_tsend64_wqe_t *tsend = buf;
sli4_fcp_128byte_wqe_t *tsend_128 = buf;
sli4_sge_t *sge = NULL;
ocs_memset(buf, 0, size);
if (!sgl || !sgl->virt) {
ocs_log_err(sli4->os, "bad parameter sgl=%p virt=%p\n",
sgl, sgl ? sgl->virt : NULL);
return -1;
}
sge = sgl->virt;
if (sli4->config.sgl_pre_registered) {
tsend->xbl = FALSE;
tsend->dbde = TRUE;
tsend->bde.bde_type = SLI4_BDE_TYPE_BDE_64;
/* TSEND64_WQE specifies first two SGE are skipped
* (i.e. 3rd is valid) */
tsend->bde.buffer_length = sge[2].buffer_length;
tsend->bde.u.data.buffer_address_low = sge[2].buffer_address_low;
tsend->bde.u.data.buffer_address_high = sge[2].buffer_address_high;
} else {
tsend->xbl = TRUE;
/* if data is a single physical address, use a BDE */
if (!dif && (xfer_len <= sge[2].buffer_length)) {
tsend->dbde = TRUE;
tsend->bde.bde_type = SLI4_BDE_TYPE_BDE_64;
/* TSEND64_WQE specifies first two SGE are skipped
* (i.e. 3rd is valid) */
tsend->bde.buffer_length = sge[2].buffer_length;
tsend->bde.u.data.buffer_address_low = sge[2].buffer_address_low;
tsend->bde.u.data.buffer_address_high = sge[2].buffer_address_high;
} else {
tsend->bde.bde_type = SLI4_BDE_TYPE_BLP;
tsend->bde.buffer_length = sgl->size;
tsend->bde.u.blp.sgl_segment_address_low = ocs_addr32_lo(sgl->phys);
tsend->bde.u.blp.sgl_segment_address_high = ocs_addr32_hi(sgl->phys);
}
}
tsend->relative_offset = relative_off;
if (flags & SLI4_IO_CONTINUATION) {
tsend->xc = TRUE;
}
tsend->xri_tag = xri;
tsend->rpi = rpi;
tsend->pu = TRUE; /* WQE uses relative offset */
if (flags & SLI4_IO_AUTO_GOOD_RESPONSE) {
tsend->ar = TRUE;
}
tsend->command = SLI4_WQE_FCP_TSEND64;
tsend->class = SLI4_ELS_REQUEST64_CLASS_3;
tsend->ct = SLI4_ELS_REQUEST64_CONTEXT_RPI;
tsend->dif = dif;
tsend->bs = bs;
tsend->remote_xid = xid;
tsend->request_tag = tag;
tsend->len_loc = 0x2;
if (rnode->node_group) {
tsend->hlm = TRUE;
tsend->dword5 = rnode->fc_id & 0x00ffffff;
}
tsend->cq_id = cq_id;
tsend->cmd_type = SLI4_CMD_FCP_TSEND64_WQE;
tsend->fcp_data_transmit_length = xfer_len;
if (sli4->config.perf_hint) {
tsend->first_data_bde.bde_type = SLI4_BDE_TYPE_BDE_64;
tsend->first_data_bde.buffer_length = sge[first_data_sge].buffer_length;
tsend->first_data_bde.u.data.buffer_address_low = sge[first_data_sge].buffer_address_low;
tsend->first_data_bde.u.data.buffer_address_high = sge[first_data_sge].buffer_address_high;
}
/* The upper 7 bits of csctl is the priority */
if (csctl & SLI4_MASK_CCP) {
tsend->ccpe = 1;
tsend->ccp = (csctl & SLI4_MASK_CCP);
}
if (app_id && (sli4->config.wqe_size == SLI4_WQE_EXT_BYTES) && !tsend->eat) {
tsend->app_id_valid = 1;
tsend->wqes = 1;
tsend_128->dw[31] = app_id;
}
return 0;
}
/**
* @ingroup sli_fc
* @brief Write a GEN_REQUEST64 work queue entry.
*
* @note This WQE is only used to send FC-CT commands.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the WQE.
* @param size Buffer size, in bytes.
* @param sgl DMA memory for the request.
* @param req_len Length of request.
* @param max_rsp_len Max length of response.
* @param timeout Time, in seconds, before an IO times out. Zero means infinite.
* @param xri XRI for this exchange.
* @param tag IO tag value.
* @param cq_id The id of the completion queue where the WQE response is sent.
* @param rnode Destination of request (that is, the remote node).
* @param r_ctl R_CTL value for sequence.
* @param type TYPE value for sequence.
* @param df_ctl DF_CTL value for sequence.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_gen_request64_wqe(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *sgl,
uint32_t req_len, uint32_t max_rsp_len, uint8_t timeout,
uint16_t xri, uint16_t tag, uint16_t cq_id, ocs_remote_node_t *rnode,
uint8_t r_ctl, uint8_t type, uint8_t df_ctl)
{
sli4_gen_request64_wqe_t *gen = buf;
sli4_sge_t *sge = NULL;
ocs_memset(buf, 0, size);
if (!sgl || !sgl->virt) {
ocs_log_err(sli4->os, "bad parameter sgl=%p virt=%p\n",
sgl, sgl ? sgl->virt : NULL);
return -1;
}
sge = sgl->virt;
if (sli4->config.sgl_pre_registered) {
gen->xbl = FALSE;
gen->dbde = TRUE;
gen->bde.bde_type = SLI4_BDE_TYPE_BDE_64;
gen->bde.buffer_length = req_len;
gen->bde.u.data.buffer_address_low = sge[0].buffer_address_low;
gen->bde.u.data.buffer_address_high = sge[0].buffer_address_high;
} else {
gen->xbl = TRUE;
gen->bde.bde_type = SLI4_BDE_TYPE_BLP;
gen->bde.buffer_length = 2 * sizeof(sli4_sge_t);
gen->bde.u.blp.sgl_segment_address_low = ocs_addr32_lo(sgl->phys);
gen->bde.u.blp.sgl_segment_address_high = ocs_addr32_hi(sgl->phys);
}
gen->request_payload_length = req_len;
gen->max_response_payload_length = max_rsp_len;
gen->df_ctl = df_ctl;
gen->type = type;
gen->r_ctl = r_ctl;
gen->xri_tag = xri;
gen->ct = SLI4_ELS_REQUEST64_CONTEXT_RPI;
gen->context_tag = rnode->indicator;
gen->class = SLI4_ELS_REQUEST64_CLASS_3;
gen->command = SLI4_WQE_GEN_REQUEST64;
gen->timer = timeout;
gen->request_tag = tag;
gen->iod = SLI4_ELS_REQUEST64_DIR_READ;
gen->qosd = TRUE;
if (rnode->node_group) {
gen->hlm = TRUE;
gen->remote_n_port_id = rnode->fc_id & 0x00ffffff;
}
gen->cmd_type = SLI4_CMD_GEN_REQUEST64_WQE;
gen->cq_id = cq_id;
return 0;
}
/**
* @ingroup sli_fc
* @brief Write a SEND_FRAME work queue entry
*
* @param sli4 SLI context.
* @param buf Destination buffer for the WQE.
* @param size Buffer size, in bytes.
* @param sof Start of frame value
* @param eof End of frame value
* @param hdr Pointer to FC header data
* @param payload DMA memory for the payload.
* @param req_len Length of payload.
* @param timeout Time, in seconds, before an IO times out. Zero means infinite.
* @param xri XRI for this exchange.
* @param req_tag IO tag value.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_send_frame_wqe(sli4_t *sli4, void *buf, size_t size, uint8_t sof, uint8_t eof, uint32_t *hdr,
ocs_dma_t *payload, uint32_t req_len, uint8_t timeout,
uint16_t xri, uint16_t req_tag)
{
sli4_send_frame_wqe_t *sf = buf;
ocs_memset(buf, 0, size);
sf->dbde = TRUE;
sf->bde.buffer_length = req_len;
sf->bde.u.data.buffer_address_low = ocs_addr32_lo(payload->phys);
sf->bde.u.data.buffer_address_high = ocs_addr32_hi(payload->phys);
/* Copy FC header */
sf->fc_header_0_1[0] = hdr[0];
sf->fc_header_0_1[1] = hdr[1];
sf->fc_header_2_5[0] = hdr[2];
sf->fc_header_2_5[1] = hdr[3];
sf->fc_header_2_5[2] = hdr[4];
sf->fc_header_2_5[3] = hdr[5];
sf->frame_length = req_len;
sf->xri_tag = xri;
sf->pu = 0;
sf->context_tag = 0;
sf->ct = 0;
sf->command = SLI4_WQE_SEND_FRAME;
sf->class = SLI4_ELS_REQUEST64_CLASS_3;
sf->timer = timeout;
sf->request_tag = req_tag;
sf->eof = eof;
sf->sof = sof;
sf->qosd = 0;
sf->lenloc = 1;
sf->xc = 0;
sf->xbl = 1;
sf->cmd_type = SLI4_CMD_SEND_FRAME_WQE;
sf->cq_id = 0xffff;
return 0;
}
/**
* @ingroup sli_fc
* @brief Write a XMIT_SEQUENCE64 work queue entry.
*
* This WQE is used to send FC-CT response frames.
*
* @note This API implements a restricted use for this WQE, a TODO: would
* include passing in sequence initiative, and full SGL's
*
* @param sli4 SLI context.
* @param buf Destination buffer for the WQE.
* @param size Buffer size, in bytes.
* @param payload DMA memory for the request.
* @param payload_len Length of request.
* @param timeout Time, in seconds, before an IO times out. Zero means infinite.
* @param ox_id originator exchange ID
* @param xri XRI for this exchange.
* @param tag IO tag value.
* @param rnode Destination of request (that is, the remote node).
* @param r_ctl R_CTL value for sequence.
* @param type TYPE value for sequence.
* @param df_ctl DF_CTL value for sequence.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_xmit_sequence64_wqe(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *payload,
uint32_t payload_len, uint8_t timeout, uint16_t ox_id,
uint16_t xri, uint16_t tag, ocs_remote_node_t *rnode,
uint8_t r_ctl, uint8_t type, uint8_t df_ctl)
{
sli4_xmit_sequence64_wqe_t *xmit = buf;
ocs_memset(buf, 0, size);
if ((payload == NULL) || (payload->virt == NULL)) {
ocs_log_err(sli4->os, "bad parameter sgl=%p virt=%p\n",
payload, payload ? payload->virt : NULL);
return -1;
}
if (sli4->config.sgl_pre_registered) {
xmit->dbde = TRUE;
} else {
xmit->xbl = TRUE;
}
xmit->bde.bde_type = SLI4_BDE_TYPE_BDE_64;
xmit->bde.buffer_length = payload_len;
xmit->bde.u.data.buffer_address_low = ocs_addr32_lo(payload->phys);
xmit->bde.u.data.buffer_address_high = ocs_addr32_hi(payload->phys);
xmit->sequence_payload_len = payload_len;
xmit->remote_n_port_id = rnode->fc_id & 0x00ffffff;
xmit->relative_offset = 0;
xmit->si = 0; /* sequence initiative - this matches what is seen from
* FC switches in response to FCGS commands */
xmit->ft = 0; /* force transmit */
xmit->xo = 0; /* exchange responder */
xmit->ls = 1; /* last in seqence */
xmit->df_ctl = df_ctl;
xmit->type = type;
xmit->r_ctl = r_ctl;
xmit->xri_tag = xri;
xmit->context_tag = rnode->indicator;
xmit->dif = 0;
xmit->ct = SLI4_ELS_REQUEST64_CONTEXT_RPI;
xmit->bs = 0;
xmit->command = SLI4_WQE_XMIT_SEQUENCE64;
xmit->class = SLI4_ELS_REQUEST64_CLASS_3;
xmit->pu = 0;
xmit->timer = timeout;
xmit->abort_tag = 0;
xmit->request_tag = tag;
xmit->remote_xid = ox_id;
xmit->iod = SLI4_ELS_REQUEST64_DIR_READ;
if (rnode->node_group) {
xmit->hlm = TRUE;
xmit->remote_n_port_id = rnode->fc_id & 0x00ffffff;
}
xmit->cmd_type = SLI4_CMD_XMIT_SEQUENCE64_WQE;
xmit->len_loc = 2;
xmit->cq_id = 0xFFFF;
return 0;
}
/**
* @ingroup sli_fc
* @brief Write a REQUEUE_XRI_WQE work queue entry.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the WQE.
* @param size Buffer size, in bytes.
* @param xri XRI for this exchange.
* @param tag IO tag value.
* @param cq_id The id of the completion queue where the WQE response is sent.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_requeue_xri_wqe(sli4_t *sli4, void *buf, size_t size, uint16_t xri, uint16_t tag, uint16_t cq_id)
{
sli4_requeue_xri_wqe_t *requeue = buf;
ocs_memset(buf, 0, size);
requeue->command = SLI4_WQE_REQUEUE_XRI;
requeue->xri_tag = xri;
requeue->request_tag = tag;
requeue->xc = 1;
requeue->qosd = 1;
requeue->cq_id = cq_id;
requeue->cmd_type = SLI4_CMD_REQUEUE_XRI_WQE;
return 0;
}
int32_t
sli_xmit_bcast64_wqe(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *payload,
uint32_t payload_len, uint8_t timeout, uint16_t xri, uint16_t tag,
uint16_t cq_id, ocs_remote_node_t *rnode,
uint8_t r_ctl, uint8_t type, uint8_t df_ctl)
{
sli4_xmit_bcast64_wqe_t *bcast = buf;
/* Command requires a temporary RPI (i.e. unused remote node) */
if (rnode->attached) {
ocs_log_test(sli4->os, "remote node %d in use\n", rnode->indicator);
return -1;
}
ocs_memset(buf, 0, size);
bcast->dbde = TRUE;
bcast->sequence_payload.bde_type = SLI4_BDE_TYPE_BDE_64;
bcast->sequence_payload.buffer_length = payload_len;
bcast->sequence_payload.u.data.buffer_address_low = ocs_addr32_lo(payload->phys);
bcast->sequence_payload.u.data.buffer_address_high = ocs_addr32_hi(payload->phys);
bcast->sequence_payload_length = payload_len;
bcast->df_ctl = df_ctl;
bcast->type = type;
bcast->r_ctl = r_ctl;
bcast->xri_tag = xri;
bcast->ct = SLI4_ELS_REQUEST64_CONTEXT_VPI;
bcast->context_tag = rnode->sport->indicator;
bcast->class = SLI4_ELS_REQUEST64_CLASS_3;
bcast->command = SLI4_WQE_XMIT_BCAST64;
bcast->timer = timeout;
bcast->request_tag = tag;
bcast->temporary_rpi = rnode->indicator;
bcast->len_loc = 0x1;
bcast->iod = SLI4_ELS_REQUEST64_DIR_WRITE;
bcast->cmd_type = SLI4_CMD_XMIT_BCAST64_WQE;
bcast->cq_id = cq_id;
return 0;
}
/**
* @ingroup sli_fc
* @brief Write an XMIT_BLS_RSP64_WQE work queue entry.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the WQE.
* @param size Buffer size, in bytes.
* @param payload Contents of the BLS payload to be sent.
* @param xri XRI for this exchange.
* @param tag IO tag value.
* @param cq_id The id of the completion queue where the WQE response is sent.
* @param rnode Destination of request (that is, the remote node).
* @param s_id Source ID to use in the response. If UINT32_MAX, use SLI Port's ID.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_xmit_bls_rsp64_wqe(sli4_t *sli4, void *buf, size_t size, sli_bls_payload_t *payload,
uint16_t xri, uint16_t tag, uint16_t cq_id, ocs_remote_node_t *rnode, uint32_t s_id)
{
sli4_xmit_bls_rsp_wqe_t *bls = buf;
/*
* Callers can either specify RPI or S_ID, but not both
*/
if (rnode->attached && (s_id != UINT32_MAX)) {
ocs_log_test(sli4->os, "S_ID specified for attached remote node %d\n",
rnode->indicator);
return -1;
}
ocs_memset(buf, 0, size);
if (SLI_BLS_ACC == payload->type) {
bls->payload_word0 = (payload->u.acc.seq_id_last << 16) |
(payload->u.acc.seq_id_validity << 24);
bls->high_seq_cnt = payload->u.acc.high_seq_cnt;
bls->low_seq_cnt = payload->u.acc.low_seq_cnt;
} else if (SLI_BLS_RJT == payload->type) {
bls->payload_word0 = *((uint32_t *)&payload->u.rjt);
bls->ar = TRUE;
} else {
ocs_log_test(sli4->os, "bad BLS type %#x\n",
payload->type);
return -1;
}
bls->ox_id = payload->ox_id;
bls->rx_id = payload->rx_id;
if (rnode->attached) {
bls->ct = SLI4_ELS_REQUEST64_CONTEXT_RPI;
bls->context_tag = rnode->indicator;
} else {
bls->ct = SLI4_ELS_REQUEST64_CONTEXT_VPI;
bls->context_tag = rnode->sport->indicator;
if (UINT32_MAX != s_id) {
bls->local_n_port_id = s_id & 0x00ffffff;
} else {
bls->local_n_port_id = rnode->sport->fc_id & 0x00ffffff;
}
bls->remote_id = rnode->fc_id & 0x00ffffff;
bls->temporary_rpi = rnode->indicator;
}
bls->xri_tag = xri;
bls->class = SLI4_ELS_REQUEST64_CLASS_3;
bls->command = SLI4_WQE_XMIT_BLS_RSP;
bls->request_tag = tag;
bls->qosd = TRUE;
if (rnode->node_group) {
bls->hlm = TRUE;
bls->remote_id = rnode->fc_id & 0x00ffffff;
}
bls->cq_id = cq_id;
bls->cmd_type = SLI4_CMD_XMIT_BLS_RSP64_WQE;
return 0;
}
/**
* @ingroup sli_fc
* @brief Write a XMIT_ELS_RSP64_WQE work queue entry.
*
* @param sli4 SLI context.
* @param buf Destination buffer for the WQE.
* @param size Buffer size, in bytes.
* @param rsp DMA memory for the ELS response.
* @param rsp_len Length of ELS response, in bytes.
* @param xri XRI for this exchange.
* @param tag IO tag value.
* @param cq_id The id of the completion queue where the WQE response is sent.
* @param ox_id OX_ID of the exchange containing the request.
* @param rnode Destination of the ELS response (that is, the remote node).
* @param flags Optional attributes, including:
* - SLI4_IO_CONTINUATION - IO is already active.
* @param s_id S_ID used for special responses.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_xmit_els_rsp64_wqe(sli4_t *sli4, void *buf, size_t size, ocs_dma_t *rsp,
uint32_t rsp_len, uint16_t xri, uint16_t tag, uint16_t cq_id,
uint16_t ox_id, ocs_remote_node_t *rnode, uint32_t flags, uint32_t s_id)
{
sli4_xmit_els_rsp64_wqe_t *els = buf;
ocs_memset(buf, 0, size);
if (sli4->config.sgl_pre_registered) {
els->dbde = TRUE;
} else {
els->xbl = TRUE;
}
els->els_response_payload.bde_type = SLI4_BDE_TYPE_BDE_64;
els->els_response_payload.buffer_length = rsp_len;
els->els_response_payload.u.data.buffer_address_low = ocs_addr32_lo(rsp->phys);
els->els_response_payload.u.data.buffer_address_high = ocs_addr32_hi(rsp->phys);
els->els_response_payload_length = rsp_len;
els->xri_tag = xri;
els->class = SLI4_ELS_REQUEST64_CLASS_3;
els->command = SLI4_WQE_ELS_RSP64;
els->request_tag = tag;
els->ox_id = ox_id;
els->iod = SLI4_ELS_REQUEST64_DIR_WRITE;
els->qosd = TRUE;
if (flags & SLI4_IO_CONTINUATION) {
els->xc = TRUE;
}
if (rnode->attached) {
els->ct = SLI4_ELS_REQUEST64_CONTEXT_RPI;
els->context_tag = rnode->indicator;
} else {
els->ct = SLI4_ELS_REQUEST64_CONTEXT_VPI;
els->context_tag = rnode->sport->indicator;
els->remote_id = rnode->fc_id & 0x00ffffff;
els->temporary_rpi = rnode->indicator;
if (UINT32_MAX != s_id) {
els->sp = TRUE;
els->s_id = s_id & 0x00ffffff;
}
}
if (rnode->node_group) {
els->hlm = TRUE;
els->remote_id = rnode->fc_id & 0x00ffffff;
}
els->cmd_type = SLI4_ELS_REQUEST64_CMD_GEN;
els->cq_id = cq_id;
return 0;
}
/**
* @ingroup sli_fc
* @brief Process an asynchronous Link State event entry.
*
* @par Description
* Parses Asynchronous Completion Queue Entry (ACQE),
* creates an abstracted event, and calls registered callback functions.
*
* @param sli4 SLI context.
* @param acqe Pointer to the ACQE.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_fc_process_link_state(sli4_t *sli4, void *acqe)
{
sli4_link_state_t *link_state = acqe;
sli4_link_event_t event = { 0 };
int32_t rc = 0;
if (!sli4->link) {
/* bail if there is no callback */
return 0;
}
if (SLI4_LINK_TYPE_ETHERNET == link_state->link_type) {
event.topology = SLI_LINK_TOPO_NPORT;
event.medium = SLI_LINK_MEDIUM_ETHERNET;
} else {
/* TODO is this supported for anything other than FCoE? */
ocs_log_test(sli4->os, "unsupported link type %#x\n",
link_state->link_type);
event.topology = SLI_LINK_TOPO_MAX;
event.medium = SLI_LINK_MEDIUM_MAX;
rc = -1;
}
switch (link_state->port_link_status) {
case SLI4_PORT_LINK_STATUS_PHYSICAL_DOWN:
case SLI4_PORT_LINK_STATUS_LOGICAL_DOWN:
event.status = SLI_LINK_STATUS_DOWN;
break;
case SLI4_PORT_LINK_STATUS_PHYSICAL_UP:
case SLI4_PORT_LINK_STATUS_LOGICAL_UP:
event.status = SLI_LINK_STATUS_UP;
break;
default:
ocs_log_test(sli4->os, "unsupported link status %#x\n",
link_state->port_link_status);
event.status = SLI_LINK_STATUS_MAX;
rc = -1;
}
switch (link_state->port_speed) {
case 0:
event.speed = 0;
break;
case 1:
event.speed = 10;
break;
case 2:
event.speed = 100;
break;
case 3:
event.speed = 1000;
break;
case 4:
event.speed = 10000;
break;
case 5:
event.speed = 20000;
break;
case 6:
event.speed = 25000;
break;
case 7:
event.speed = 40000;
break;
case 8:
event.speed = 100000;
break;
default:
ocs_log_test(sli4->os, "unsupported port_speed %#x\n",
link_state->port_speed);
rc = -1;
}
sli4->link(sli4->link_arg, (void *)&event);
return rc;
}
/**
* @ingroup sli_fc
* @brief Process an asynchronous Link Attention event entry.
*
* @par Description
* Parses Asynchronous Completion Queue Entry (ACQE),
* creates an abstracted event, and calls the registered callback functions.
*
* @param sli4 SLI context.
* @param acqe Pointer to the ACQE.
*
* @todo XXX all events return LINK_UP.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_fc_process_link_attention(sli4_t *sli4, void *acqe)
{
sli4_link_attention_t *link_attn = acqe;
sli4_link_event_t event = { 0 };
ocs_log_debug(sli4->os, "link_number=%d attn_type=%#x topology=%#x port_speed=%#x "
"port_fault=%#x shared_link_status=%#x logical_link_speed=%#x "
"event_tag=%#x\n", link_attn->link_number, link_attn->attn_type,
link_attn->topology, link_attn->port_speed, link_attn->port_fault,
link_attn->shared_link_status, link_attn->logical_link_speed,
link_attn->event_tag);
if (!sli4->link) {
return 0;
}
event.medium = SLI_LINK_MEDIUM_FC;
switch (link_attn->attn_type) {
case SLI4_LINK_ATTN_TYPE_LINK_UP:
event.status = SLI_LINK_STATUS_UP;
break;
case SLI4_LINK_ATTN_TYPE_LINK_DOWN:
event.status = SLI_LINK_STATUS_DOWN;
break;
case SLI4_LINK_ATTN_TYPE_NO_HARD_ALPA:
ocs_log_debug(sli4->os, "attn_type: no hard alpa\n");
event.status = SLI_LINK_STATUS_NO_ALPA;
break;
default:
ocs_log_test(sli4->os, "attn_type: unknown\n");
break;
}
switch (link_attn->event_type) {
case SLI4_FC_EVENT_LINK_ATTENTION:
break;
case SLI4_FC_EVENT_SHARED_LINK_ATTENTION:
ocs_log_debug(sli4->os, "event_type: FC shared link event \n");
break;
default:
ocs_log_test(sli4->os, "event_type: unknown\n");
break;
}
switch (link_attn->topology) {
case SLI4_LINK_ATTN_P2P:
event.topology = SLI_LINK_TOPO_NPORT;
break;
case SLI4_LINK_ATTN_FC_AL:
event.topology = SLI_LINK_TOPO_LOOP;
break;
case SLI4_LINK_ATTN_INTERNAL_LOOPBACK:
ocs_log_debug(sli4->os, "topology Internal loopback\n");
event.topology = SLI_LINK_TOPO_LOOPBACK_INTERNAL;
break;
case SLI4_LINK_ATTN_SERDES_LOOPBACK:
ocs_log_debug(sli4->os, "topology serdes loopback\n");
event.topology = SLI_LINK_TOPO_LOOPBACK_EXTERNAL;
break;
default:
ocs_log_test(sli4->os, "topology: unknown\n");
break;
}
event.speed = link_attn->port_speed * 1000;
sli4->link(sli4->link_arg, (void *)&event);
return 0;
}
/**
* @ingroup sli_fc
* @brief Parse an FC/FCoE work queue CQ entry.
*
* @param sli4 SLI context.
* @param cq CQ to process.
* @param cqe Pointer to the CQ entry.
* @param etype CQ event type.
* @param r_id Resource ID associated with this completion message (such as the IO tag).
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_fc_cqe_parse(sli4_t *sli4, sli4_queue_t *cq, uint8_t *cqe, sli4_qentry_e *etype,
uint16_t *r_id)
{
uint8_t code = cqe[SLI4_CQE_CODE_OFFSET];
int32_t rc = -1;
switch (code) {
case SLI4_CQE_CODE_WORK_REQUEST_COMPLETION:
{
sli4_fc_wcqe_t *wcqe = (void *)cqe;
*etype = SLI_QENTRY_WQ;
*r_id = wcqe->request_tag;
rc = wcqe->status;
/* Flag errors except for FCP_RSP_FAILURE */
if (rc && (rc != SLI4_FC_WCQE_STATUS_FCP_RSP_FAILURE)) {
ocs_log_test(sli4->os, "WCQE: status=%#x hw_status=%#x tag=%#x w1=%#x w2=%#x xb=%d\n",
wcqe->status, wcqe->hw_status,
wcqe->request_tag, wcqe->wqe_specific_1,
wcqe->wqe_specific_2, wcqe->xb);
ocs_log_test(sli4->os, " %08X %08X %08X %08X\n", ((uint32_t*) cqe)[0], ((uint32_t*) cqe)[1],
((uint32_t*) cqe)[2], ((uint32_t*) cqe)[3]);
}
/* TODO: need to pass additional status back out of here as well
* as status (could overload rc as status/addlstatus are only 8 bits each)
*/
break;
}
case SLI4_CQE_CODE_RQ_ASYNC:
{
sli4_fc_async_rcqe_t *rcqe = (void *)cqe;
*etype = SLI_QENTRY_RQ;
*r_id = rcqe->rq_id;
rc = rcqe->status;
break;
}
case SLI4_CQE_CODE_RQ_ASYNC_V1:
{
sli4_fc_async_rcqe_v1_t *rcqe = (void *)cqe;
*etype = SLI_QENTRY_RQ;
*r_id = rcqe->rq_id;
rc = rcqe->status;
break;
}
case SLI4_CQE_CODE_OPTIMIZED_WRITE_CMD:
{
sli4_fc_optimized_write_cmd_cqe_t *optcqe = (void *)cqe;
*etype = SLI_QENTRY_OPT_WRITE_CMD;
*r_id = optcqe->rq_id;
rc = optcqe->status;
break;
}
case SLI4_CQE_CODE_OPTIMIZED_WRITE_DATA:
{
sli4_fc_optimized_write_data_cqe_t *dcqe = (void *)cqe;
*etype = SLI_QENTRY_OPT_WRITE_DATA;
*r_id = dcqe->xri;
rc = dcqe->status;
/* Flag errors */
if (rc != SLI4_FC_WCQE_STATUS_SUCCESS) {
ocs_log_test(sli4->os, "Optimized DATA CQE: status=%#x hw_status=%#x xri=%#x dpl=%#x w3=%#x xb=%d\n",
dcqe->status, dcqe->hw_status,
dcqe->xri, dcqe->total_data_placed,
((uint32_t*) cqe)[3], dcqe->xb);
}
break;
}
case SLI4_CQE_CODE_RQ_COALESCING:
{
sli4_fc_coalescing_rcqe_t *rcqe = (void *)cqe;
*etype = SLI_QENTRY_RQ;
*r_id = rcqe->rq_id;
rc = rcqe->status;
break;
}
case SLI4_CQE_CODE_XRI_ABORTED:
{
sli4_fc_xri_aborted_cqe_t *xa = (void *)cqe;
*etype = SLI_QENTRY_XABT;
*r_id = xa->xri;
rc = 0;
break;
}
case SLI4_CQE_CODE_RELEASE_WQE: {
sli4_fc_wqec_t *wqec = (void*) cqe;
*etype = SLI_QENTRY_WQ_RELEASE;
*r_id = wqec->wq_id;
rc = 0;
break;
}
default:
ocs_log_test(sli4->os, "CQE completion code %d not handled\n", code);
*etype = SLI_QENTRY_MAX;
*r_id = UINT16_MAX;
}
return rc;
}
/**
* @ingroup sli_fc
* @brief Return the ELS/CT response length.
*
* @param sli4 SLI context.
* @param cqe Pointer to the CQ entry.
*
* @return Returns the length, in bytes.
*/
uint32_t
sli_fc_response_length(sli4_t *sli4, uint8_t *cqe)
{
sli4_fc_wcqe_t *wcqe = (void *)cqe;
return wcqe->wqe_specific_1;
}
/**
* @ingroup sli_fc
* @brief Return the FCP IO length.
*
* @param sli4 SLI context.
* @param cqe Pointer to the CQ entry.
*
* @return Returns the length, in bytes.
*/
uint32_t
sli_fc_io_length(sli4_t *sli4, uint8_t *cqe)
{
sli4_fc_wcqe_t *wcqe = (void *)cqe;
return wcqe->wqe_specific_1;
}
/**
* @ingroup sli_fc
* @brief Retrieve the D_ID from the completion.
*
* @param sli4 SLI context.
* @param cqe Pointer to the CQ entry.
* @param d_id Pointer where the D_ID is written.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_fc_els_did(sli4_t *sli4, uint8_t *cqe, uint32_t *d_id)
{
sli4_fc_wcqe_t *wcqe = (void *)cqe;
*d_id = 0;
if (wcqe->status) {
return -1;
} else {
*d_id = wcqe->wqe_specific_2 & 0x00ffffff;
return 0;
}
}
uint32_t
sli_fc_ext_status(sli4_t *sli4, uint8_t *cqe)
{
sli4_fc_wcqe_t *wcqe = (void *)cqe;
uint32_t mask;
switch (wcqe->status) {
case SLI4_FC_WCQE_STATUS_FCP_RSP_FAILURE:
mask = UINT32_MAX;
break;
case SLI4_FC_WCQE_STATUS_LOCAL_REJECT:
case SLI4_FC_WCQE_STATUS_CMD_REJECT:
mask = 0xff;
break;
case SLI4_FC_WCQE_STATUS_NPORT_RJT:
case SLI4_FC_WCQE_STATUS_FABRIC_RJT:
case SLI4_FC_WCQE_STATUS_NPORT_BSY:
case SLI4_FC_WCQE_STATUS_FABRIC_BSY:
case SLI4_FC_WCQE_STATUS_LS_RJT:
mask = UINT32_MAX;
break;
case SLI4_FC_WCQE_STATUS_DI_ERROR:
mask = UINT32_MAX;
break;
default:
mask = 0;
}
return wcqe->wqe_specific_2 & mask;
}
/**
* @ingroup sli_fc
* @brief Retrieve the RQ index from the completion.
*
* @param sli4 SLI context.
* @param cqe Pointer to the CQ entry.
* @param rq_id Pointer where the rq_id is written.
* @param index Pointer where the index is written.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_fc_rqe_rqid_and_index(sli4_t *sli4, uint8_t *cqe, uint16_t *rq_id, uint32_t *index)
{
sli4_fc_async_rcqe_t *rcqe = (void *)cqe;
sli4_fc_async_rcqe_v1_t *rcqe_v1 = (void *)cqe;
int32_t rc = -1;
uint8_t code = 0;
*rq_id = 0;
*index = UINT32_MAX;
code = cqe[SLI4_CQE_CODE_OFFSET];
if (code == SLI4_CQE_CODE_RQ_ASYNC) {
*rq_id = rcqe->rq_id;
if (SLI4_FC_ASYNC_RQ_SUCCESS == rcqe->status) {
*index = rcqe->rq_element_index;
rc = 0;
} else {
*index = rcqe->rq_element_index;
rc = rcqe->status;
ocs_log_test(sli4->os, "status=%02x (%s) rq_id=%d, index=%x pdpl=%x sof=%02x eof=%02x hdpl=%x\n",
rcqe->status, sli_fc_get_status_string(rcqe->status), rcqe->rq_id,
rcqe->rq_element_index, rcqe->payload_data_placement_length, rcqe->sof_byte,
rcqe->eof_byte, rcqe->header_data_placement_length);
}
} else if (code == SLI4_CQE_CODE_RQ_ASYNC_V1) {
*rq_id = rcqe_v1->rq_id;
if (SLI4_FC_ASYNC_RQ_SUCCESS == rcqe_v1->status) {
*index = rcqe_v1->rq_element_index;
rc = 0;
} else {
*index = rcqe_v1->rq_element_index;
rc = rcqe_v1->status;
ocs_log_test(sli4->os, "status=%02x (%s) rq_id=%d, index=%x pdpl=%x sof=%02x eof=%02x hdpl=%x\n",
rcqe_v1->status, sli_fc_get_status_string(rcqe_v1->status),
rcqe_v1->rq_id, rcqe_v1->rq_element_index,
rcqe_v1->payload_data_placement_length, rcqe_v1->sof_byte,
rcqe_v1->eof_byte, rcqe_v1->header_data_placement_length);
}
} else if (code == SLI4_CQE_CODE_OPTIMIZED_WRITE_CMD) {
sli4_fc_optimized_write_cmd_cqe_t *optcqe = (void *)cqe;
*rq_id = optcqe->rq_id;
if (SLI4_FC_ASYNC_RQ_SUCCESS == optcqe->status) {
*index = optcqe->rq_element_index;
rc = 0;
} else {
*index = optcqe->rq_element_index;
rc = optcqe->status;
ocs_log_test(sli4->os, "status=%02x (%s) rq_id=%d, index=%x pdpl=%x hdpl=%x oox=%d agxr=%d xri=0x%x rpi=0x%x\n",
optcqe->status, sli_fc_get_status_string(optcqe->status), optcqe->rq_id,
optcqe->rq_element_index, optcqe->payload_data_placement_length,
optcqe->header_data_placement_length, optcqe->oox, optcqe->agxr, optcqe->xri,
optcqe->rpi);
}
} else if (code == SLI4_CQE_CODE_RQ_COALESCING) {
sli4_fc_coalescing_rcqe_t *rcqe = (void *)cqe;
*rq_id = rcqe->rq_id;
if (SLI4_FC_COALESCE_RQ_SUCCESS == rcqe->status) {
*index = rcqe->rq_element_index;
rc = 0;
} else {
*index = UINT32_MAX;
rc = rcqe->status;
ocs_log_test(sli4->os, "status=%02x (%s) rq_id=%d, index=%x rq_id=%#x sdpl=%x\n",
rcqe->status, sli_fc_get_status_string(rcqe->status), rcqe->rq_id,
rcqe->rq_element_index, rcqe->rq_id, rcqe->sequence_reporting_placement_length);
}
} else {
*index = UINT32_MAX;
rc = rcqe->status;
ocs_log_debug(sli4->os, "status=%02x rq_id=%d, index=%x pdpl=%x sof=%02x eof=%02x hdpl=%x\n",
rcqe->status, rcqe->rq_id, rcqe->rq_element_index, rcqe->payload_data_placement_length,
rcqe->sof_byte, rcqe->eof_byte, rcqe->header_data_placement_length);
}
return rc;
}
/**
* @ingroup sli_fc
* @brief Process an asynchronous FCoE event entry.
*
* @par Description
* Parses Asynchronous Completion Queue Entry (ACQE),
* creates an abstracted event, and calls the registered callback functions.
*
* @param sli4 SLI context.
* @param acqe Pointer to the ACQE.
*
* @return Returns 0 on success, or a non-zero value on failure.
*/
int32_t
sli_fc_process_fcoe(sli4_t *sli4, void *acqe)
{
sli4_fcoe_fip_t *fcoe = acqe;
sli4_fip_event_t event = { 0 };
uint32_t mask = UINT32_MAX;
ocs_log_debug(sli4->os, "ACQE FCoE FIP type=%02x count=%d tag=%#x\n",
fcoe->event_type,
fcoe->fcf_count,
fcoe->event_tag);
if (!sli4->fip) {
return 0;
}
event.type = fcoe->event_type;
event.index = UINT32_MAX;
switch (fcoe->event_type) {
case SLI4_FCOE_FIP_FCF_DISCOVERED:
ocs_log_debug(sli4->os, "FCF Discovered index=%d\n", fcoe->event_information);
break;
case SLI4_FCOE_FIP_FCF_TABLE_FULL:
ocs_log_debug(sli4->os, "FCF Table Full\n");
mask = 0;
break;
case SLI4_FCOE_FIP_FCF_DEAD:
ocs_log_debug(sli4->os, "FCF Dead/Gone index=%d\n", fcoe->event_information);
break;
case SLI4_FCOE_FIP_FCF_CLEAR_VLINK:
mask = UINT16_MAX;
ocs_log_debug(sli4->os, "Clear VLINK Received VPI=%#x\n", fcoe->event_information & mask);
break;
case SLI4_FCOE_FIP_FCF_MODIFIED:
ocs_log_debug(sli4->os, "FCF Modified\n");
break;
default:
ocs_log_test(sli4->os, "bad FCoE type %#x", fcoe->event_type);
mask = 0;
}
if (mask != 0) {
event.index = fcoe->event_information & mask;
}
sli4->fip(sli4->fip_arg, &event);
return 0;
}
/**
* @ingroup sli_fc
* @brief Allocate a receive queue.
*
* @par Description
* Allocates DMA memory and configures the requested queue type.
*
* @param sli4 SLI context.
* @param q Pointer to the queue object for the header.
* @param n_entries Number of entries to allocate.
* @param buffer_size buffer size for the queue.
* @param cq Associated CQ.
* @param ulp The ULP to bind
* @param is_hdr Used to validate the rq_id and set the type of queue
*
* @return Returns 0 on success, or -1 on failure.
*/
int32_t
sli_fc_rq_alloc(sli4_t *sli4, sli4_queue_t *q,
uint32_t n_entries, uint32_t buffer_size,
sli4_queue_t *cq, uint16_t ulp, uint8_t is_hdr)
{
int32_t (*rq_create)(sli4_t *, void *, size_t, ocs_dma_t *, uint16_t, uint16_t, uint16_t);
if ((sli4 == NULL) || (q == NULL)) {
void *os = sli4 != NULL ? sli4->os : NULL;
ocs_log_err(os, "bad parameter sli4=%p q=%p\n", sli4, q);
return -1;
}
if (__sli_queue_init(sli4, q, SLI_QTYPE_RQ, SLI4_FCOE_RQE_SIZE,
n_entries, SLI_PAGE_SIZE)) {
return -1;
}
if (sli4->if_type == SLI4_IF_TYPE_BE3_SKH_PF) {
rq_create = sli_cmd_fcoe_rq_create;
} else {
rq_create = sli_cmd_fcoe_rq_create_v1;
}
if (rq_create(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE, &q->dma,
cq->id, ulp, buffer_size)) {
if (__sli_create_queue(sli4, q)) {
ocs_dma_free(sli4->os, &q->dma);
return -1;
}
if (is_hdr && q->id & 1) {
ocs_log_test(sli4->os, "bad header RQ_ID %d\n", q->id);
ocs_dma_free(sli4->os, &q->dma);
return -1;
} else if (!is_hdr && (q->id & 1) == 0) {
ocs_log_test(sli4->os, "bad data RQ_ID %d\n", q->id);
ocs_dma_free(sli4->os, &q->dma);
return -1;
}
} else {
return -1;
}
q->u.flag.is_hdr = is_hdr;
if (SLI4_IF_TYPE_BE3_SKH_PF == sli4->if_type) {
q->u.flag.rq_batch = TRUE;
}
return 0;
}
/**
* @ingroup sli_fc
* @brief Allocate a receive queue set.
*
* @param sli4 SLI context.
* @param num_rq_pairs to create
* @param qs Pointers to the queue objects for both header and data.
* Length of this arrays should be 2 * num_rq_pairs
* @param base_cq_id. Assumes base_cq_id : (base_cq_id + num_rq_pairs) cqs as allotted.
* @param n_entries number of entries in each RQ queue.
* @param header_buffer_size
* @param payload_buffer_size
* @param ulp The ULP to bind
*
* @return Returns 0 on success, or -1 on failure.
*/
int32_t
sli_fc_rq_set_alloc(sli4_t *sli4, uint32_t num_rq_pairs,
sli4_queue_t *qs[], uint32_t base_cq_id,
uint32_t n_entries, uint32_t header_buffer_size,
uint32_t payload_buffer_size, uint16_t ulp)
{
uint32_t i, p, offset = 0;
uint32_t payload_size, total_page_count = 0;
uintptr_t addr;
ocs_dma_t dma;
sli4_res_common_create_queue_set_t *rsp = NULL;
sli4_req_fcoe_rq_create_v2_t *req = NULL;
for (i = 0; i < (num_rq_pairs * 2); i++) {
if (__sli_queue_init(sli4, qs[i], SLI_QTYPE_RQ, SLI4_FCOE_RQE_SIZE,
n_entries, SLI_PAGE_SIZE)) {
goto error;
}
}
total_page_count = sli_page_count(qs[0]->dma.size, SLI_PAGE_SIZE) * num_rq_pairs * 2;
/* Payload length must accommodate both request and response */
payload_size = max((sizeof(sli4_req_fcoe_rq_create_v1_t) + (8 * total_page_count)),
sizeof(sli4_res_common_create_queue_set_t));
if (ocs_dma_alloc(sli4->os, &dma, payload_size, SLI_PAGE_SIZE)) {
ocs_log_err(sli4->os, "DMA allocation failed\n");
goto error;
}
ocs_memset(dma.virt, 0, payload_size);
if (sli_cmd_sli_config(sli4, sli4->bmbx.virt, SLI4_BMBX_SIZE,
payload_size, &dma) == -1) {
goto error;
}
req = (sli4_req_fcoe_rq_create_v2_t *)((uint8_t *)dma.virt);
/* Fill Header fields */
req->hdr.opcode = SLI4_OPC_FCOE_RQ_CREATE;
req->hdr.subsystem = SLI4_SUBSYSTEM_FCFCOE;
req->hdr.version = 2;
req->hdr.request_length = sizeof(sli4_req_fcoe_rq_create_v2_t) - sizeof(sli4_req_hdr_t)
+ (8 * total_page_count);
/* Fill Payload fields */
req->dnb = TRUE;
req->num_pages = sli_page_count(qs[0]->dma.size, SLI_PAGE_SIZE);
req->rqe_count = qs[0]->dma.size / SLI4_FCOE_RQE_SIZE;
req->rqe_size = SLI4_FCOE_RQE_SIZE_8;
req->page_size = SLI4_FCOE_RQ_PAGE_SIZE_4096;
req->rq_count = num_rq_pairs * 2;
req->base_cq_id = base_cq_id;
req->hdr_buffer_size = header_buffer_size;
req->payload_buffer_size = payload_buffer_size;
for (i = 0; i < (num_rq_pairs * 2); i++) {
for (p = 0, addr = qs[i]->dma.phys; p < req->num_pages; p++, addr += SLI_PAGE_SIZE) {
req->page_physical_address[offset].low = ocs_addr32_lo(addr);
req->page_physical_address[offset].high = ocs_addr32_hi(addr);
offset++;
}
}
if (sli_bmbx_command(sli4)){
ocs_log_crit(sli4->os, "bootstrap mailbox write faild RQSet\n");
goto error;
}
rsp = (void *)((uint8_t *)dma.virt);
if (rsp->hdr.status) {
ocs_log_err(sli4->os, "bad create RQSet status=%#x addl=%#x\n",
rsp->hdr.status, rsp->hdr.additional_status);
goto error;
} else {
for (i = 0; i < (num_rq_pairs * 2); i++) {
qs[i]->id = i + rsp->q_id;
if ((qs[i]->id & 1) == 0) {
qs[i]->u.flag.is_hdr = TRUE;
} else {
qs[i]->u.flag.is_hdr = FALSE;
}
qs[i]->doorbell_offset = regmap[SLI4_REG_FCOE_RQ_DOORBELL][sli4->if_type].off;
qs[i]->doorbell_rset = regmap[SLI4_REG_FCOE_RQ_DOORBELL][sli4->if_type].rset;
}
}
ocs_dma_free(sli4->os, &dma);
return 0;
error:
for (i = 0; i < (num_rq_pairs * 2); i++) {
if (qs[i]->dma.size) {
ocs_dma_free(sli4->os, &qs[i]->dma);
}
}
if (dma.size) {
ocs_dma_free(sli4->os, &dma);
}
return -1;
}
/**
* @ingroup sli_fc
* @brief Get the RPI resource requirements.
*
* @param sli4 SLI context.
* @param n_rpi Number of RPIs desired.
*
* @return Returns the number of bytes needed. This value may be zero.
*/
uint32_t
sli_fc_get_rpi_requirements(sli4_t *sli4, uint32_t n_rpi)
{
uint32_t bytes = 0;
/* Check if header templates needed */
if (sli4->config.hdr_template_req) {
/* round up to a page */
bytes = SLI_ROUND_PAGE(n_rpi * SLI4_FCOE_HDR_TEMPLATE_SIZE);
}
return bytes;
}
/**
* @ingroup sli_fc
* @brief Return a text string corresponding to a CQE status value
*
* @param status Status value
*
* @return Returns corresponding string, otherwise "unknown"
*/
const char *
sli_fc_get_status_string(uint32_t status)
{
static struct {
uint32_t code;
const char *label;
} lookup[] = {
{SLI4_FC_WCQE_STATUS_SUCCESS, "SUCCESS"},
{SLI4_FC_WCQE_STATUS_FCP_RSP_FAILURE, "FCP_RSP_FAILURE"},
{SLI4_FC_WCQE_STATUS_REMOTE_STOP, "REMOTE_STOP"},
{SLI4_FC_WCQE_STATUS_LOCAL_REJECT, "LOCAL_REJECT"},
{SLI4_FC_WCQE_STATUS_NPORT_RJT, "NPORT_RJT"},
{SLI4_FC_WCQE_STATUS_FABRIC_RJT, "FABRIC_RJT"},
{SLI4_FC_WCQE_STATUS_NPORT_BSY, "NPORT_BSY"},
{SLI4_FC_WCQE_STATUS_FABRIC_BSY, "FABRIC_BSY"},
{SLI4_FC_WCQE_STATUS_LS_RJT, "LS_RJT"},
{SLI4_FC_WCQE_STATUS_CMD_REJECT, "CMD_REJECT"},
{SLI4_FC_WCQE_STATUS_FCP_TGT_LENCHECK, "FCP_TGT_LENCHECK"},
{SLI4_FC_WCQE_STATUS_RQ_BUF_LEN_EXCEEDED, "BUF_LEN_EXCEEDED"},
{SLI4_FC_WCQE_STATUS_RQ_INSUFF_BUF_NEEDED, "RQ_INSUFF_BUF_NEEDED"},
{SLI4_FC_WCQE_STATUS_RQ_INSUFF_FRM_DISC, "RQ_INSUFF_FRM_DESC"},
{SLI4_FC_WCQE_STATUS_RQ_DMA_FAILURE, "RQ_DMA_FAILURE"},
{SLI4_FC_WCQE_STATUS_FCP_RSP_TRUNCATE, "FCP_RSP_TRUNCATE"},
{SLI4_FC_WCQE_STATUS_DI_ERROR, "DI_ERROR"},
{SLI4_FC_WCQE_STATUS_BA_RJT, "BA_RJT"},
{SLI4_FC_WCQE_STATUS_RQ_INSUFF_XRI_NEEDED, "RQ_INSUFF_XRI_NEEDED"},
{SLI4_FC_WCQE_STATUS_RQ_INSUFF_XRI_DISC, "INSUFF_XRI_DISC"},
{SLI4_FC_WCQE_STATUS_RX_ERROR_DETECT, "RX_ERROR_DETECT"},
{SLI4_FC_WCQE_STATUS_RX_ABORT_REQUEST, "RX_ABORT_REQUEST"},
};
uint32_t i;
for (i = 0; i < ARRAY_SIZE(lookup); i++) {
if (status == lookup[i].code) {
return lookup[i].label;
}
}
return "unknown";
}