@@ -557,6 +557,11 @@ _base_sas_ioc_info(struct MPT3SAS_ADAPTER *ioc, MPI2DefaultReply_t *mpi_reply,
frame_sz = sizeof(Mpi2SmpPassthroughRequest_t) + ioc->sge_size;
func_str = "smp_passthru";
break;
+ case MPI2_FUNCTION_NVME_ENCAPSULATED:
+ frame_sz = sizeof(Mpi26NVMeEncapsulatedRequest_t) +
+ ioc->sge_size;
+ func_str = "nvme_encapsulated";
+ break;
default:
frame_sz = 32;
func_str = "unknown";
@@ -985,7 +990,9 @@ _base_interrupt(int irq, void *bus_id)
if (request_desript_type ==
MPI25_RPY_DESCRIPT_FLAGS_FAST_PATH_SCSI_IO_SUCCESS ||
request_desript_type ==
- MPI2_RPY_DESCRIPT_FLAGS_SCSI_IO_SUCCESS) {
+ MPI2_RPY_DESCRIPT_FLAGS_SCSI_IO_SUCCESS ||
+ request_desript_type ==
+ MPI26_RPY_DESCRIPT_FLAGS_PCIE_ENCAPSULATED_SUCCESS) {
cb_idx = _base_get_cb_idx(ioc, smid);
if ((likely(cb_idx < MPT_MAX_CALLBACKS)) &&
(likely(mpt_callbacks[cb_idx] != NULL))) {
@@ -1345,6 +1352,225 @@ _base_build_sg(struct MPT3SAS_ADAPTER *ioc, void *psge,
}
}
+/* IEEE format sgls */
+
+/**
+ * _base_build_nvme_prp - This function is called for NVMe end devices to build
+ * a native SGL (NVMe PRP). The native SGL is built starting in the first PRP
+ * entry of the NVMe message (PRP1). If the data buffer is small enough to be
+ * described entirely using PRP1, then PRP2 is not used. If needed, PRP2 is
+ * used to describe a larger data buffer. If the data buffer is too large to
+ * describe using the two PRP entriess inside the NVMe message, then PRP1
+ * describes the first data memory segment, and PRP2 contains a pointer to a PRP
+ * list located elsewhere in memory to describe the remaining data memory
+ * segments. The PRP list will be contiguous.
+
+ * The native SGL for NVMe devices is a Physical Region Page (PRP). A PRP
+ * consists of a list of PRP entries to describe a number of noncontigous
+ * physical memory segments as a single memory buffer, just as a SGL does. Note
+ * however, that this function is only used by the IOCTL call, so the memory
+ * given will be guaranteed to be contiguous. There is no need to translate
+ * non-contiguous SGL into a PRP in this case. All PRPs will describe
+ * contiguous space that is one page size each.
+ *
+ * Each NVMe message contains two PRP entries. The first (PRP1) either contains
+ * a PRP list pointer or a PRP element, depending upon the command. PRP2
+ * contains the second PRP element if the memory being described fits within 2
+ * PRP entries, or a PRP list pointer if the PRP spans more than two entries.
+ *
+ * A PRP list pointer contains the address of a PRP list, structured as a linear
+ * array of PRP entries. Each PRP entry in this list describes a segment of
+ * physical memory.
+ *
+ * Each 64-bit PRP entry comprises an address and an offset field. The address
+ * always points at the beginning of a 4KB physical memory page, and the offset
+ * describes where within that 4KB page the memory segment begins. Only the
+ * first element in a PRP list may contain a non-zero offest, implying that all
+ * memory segments following the first begin at the start of a 4KB page.
+ *
+ * Each PRP element normally describes 4KB of physical memory, with exceptions
+ * for the first and last elements in the list. If the memory being described
+ * by the list begins at a non-zero offset within the first 4KB page, then the
+ * first PRP element will contain a non-zero offset indicating where the region
+ * begins within the 4KB page. The last memory segment may end before the end
+ * of the 4KB segment, depending upon the overall size of the memory being
+ * described by the PRP list.
+ *
+ * Since PRP entries lack any indication of size, the overall data buffer length
+ * is used to determine where the end of the data memory buffer is located, and
+ * how many PRP entries are required to describe it.
+ *
+ * @ioc: per adapter object
+ * @smid: system request message index for getting asscociated SGL
+ * @nvme_encap_request: the NVMe request msg frame pointer
+ * @data_out_dma: physical address for WRITES
+ * @data_out_sz: data xfer size for WRITES
+ * @data_in_dma: physical address for READS
+ * @data_in_sz: data xfer size for READS
+ *
+ * Returns nothing.
+ */
+static void
+_base_build_nvme_prp(struct MPT3SAS_ADAPTER *ioc, u16 smid,
+ Mpi26NVMeEncapsulatedRequest_t *nvme_encap_request,
+ dma_addr_t data_out_dma, size_t data_out_sz, dma_addr_t data_in_dma,
+ size_t data_in_sz)
+{
+ int prp_size = NVME_PRP_SIZE;
+ u64 *prp_entry, *prp1_entry, *prp2_entry, *prp_entry_phys;
+ u64 *prp_page, *prp_page_phys;
+ u32 offset, entry_len;
+ u32 page_mask_result, page_mask;
+ dma_addr_t paddr;
+ size_t length;
+
+ /*
+ * Not all commands require a data transfer. If no data, just return
+ * without constructing any PRP.
+ */
+ if (!data_in_sz && !data_out_sz)
+ return;
+ /*
+ * Set pointers to PRP1 and PRP2, which are in the NVMe command.
+ * PRP1 is located at a 24 byte offset from the start of the NVMe
+ * command. Then set the current PRP entry pointer to PRP1.
+ */
+ prp1_entry = (u64 *)(nvme_encap_request->NVMe_Command +
+ NVME_CMD_PRP1_OFFSET);
+ prp2_entry = (u64 *)(nvme_encap_request->NVMe_Command +
+ NVME_CMD_PRP2_OFFSET);
+ prp_entry = prp1_entry;
+ /*
+ * For the PRP entries, use the specially allocated buffer of
+ * contiguous memory.
+ */
+ prp_page = (u64 *)mpt3sas_base_get_pcie_sgl(ioc, smid);
+ prp_page_phys = (u64 *)mpt3sas_base_get_pcie_sgl_dma(ioc, smid);
+
+ /*
+ * Check if we are within 1 entry of a page boundary we don't
+ * want our first entry to be a PRP List entry.
+ */
+ page_mask = ioc->page_size - 1;
+ page_mask_result = (uintptr_t)((u8 *)prp_page + prp_size) & page_mask;
+ if (!page_mask_result) {
+ /* Bump up to next page boundary. */
+ prp_page = (u64 *)((u8 *)prp_page + prp_size);
+ prp_page_phys = (u64 *)((u8 *)prp_page_phys + prp_size);
+ }
+
+ /*
+ * Set PRP physical pointer, which initially points to the current PRP
+ * DMA memory page.
+ */
+ prp_entry_phys = prp_page_phys;
+
+ /* Get physical address and length of the data buffer. */
+ if (data_in_sz) {
+ paddr = data_in_dma;
+ length = data_in_sz;
+ } else {
+ paddr = data_out_dma;
+ length = data_out_sz;
+ }
+
+ /* Loop while the length is not zero. */
+ while (length) {
+ /*
+ * Check if we need to put a list pointer here if we are at
+ * page boundary - prp_size (8 bytes).
+ */
+ page_mask_result =
+ (uintptr_t)((u8 *)prp_entry_phys + prp_size) & page_mask;
+ if (!page_mask_result) {
+ /*
+ * This is the last entry in a PRP List, so we need to
+ * put a PRP list pointer here. What this does is:
+ * - bump the current memory pointer to the next
+ * address, which will be the next full page.
+ * - set the PRP Entry to point to that page. This
+ * is now the PRP List pointer.
+ * - bump the PRP Entry pointer the start of the
+ * next page. Since all of this PRP memory is
+ * contiguous, no need to get a new page - it's
+ * just the next address.
+ */
+ prp_entry_phys++;
+ *prp_entry = cpu_to_le64((uintptr_t)prp_entry_phys);
+ prp_entry++;
+ }
+
+ /* Need to handle if entry will be part of a page. */
+ offset = (u32)paddr & page_mask;
+ entry_len = ioc->page_size - offset;
+
+ if (prp_entry == prp1_entry) {
+ /*
+ * Must fill in the first PRP pointer (PRP1) before
+ * moving on.
+ */
+ *prp1_entry = cpu_to_le64((u64)paddr);
+
+ /*
+ * Now point to the second PRP entry within the
+ * command (PRP2).
+ */
+ prp_entry = prp2_entry;
+ } else if (prp_entry == prp2_entry) {
+ /*
+ * Should the PRP2 entry be a PRP List pointer or just
+ * a regular PRP pointer? If there is more than one
+ * more page of data, must use a PRP List pointer.
+ */
+ if (length > ioc->page_size) {
+ /*
+ * PRP2 will contain a PRP List pointer because
+ * more PRP's are needed with this command. The
+ * list will start at the beginning of the
+ * contiguous buffer.
+ */
+ *prp2_entry =
+ cpu_to_le64((uintptr_t)prp_entry_phys);
+
+ /*
+ * The next PRP Entry will be the start of the
+ * first PRP List.
+ */
+ prp_entry = prp_page;
+ } else {
+ /*
+ * After this, the PRP Entries are complete.
+ * This command uses 2 PRP's and no PRP list.
+ */
+ *prp2_entry = cpu_to_le64((u64)paddr);
+ }
+ } else {
+ /*
+ * Put entry in list and bump the addresses.
+ *
+ * After PRP1 and PRP2 are filled in, this will fill in
+ * all remaining PRP entries in a PRP List, one per
+ * each time through the loop.
+ */
+ *prp_entry = cpu_to_le64((u64)paddr);
+ prp_entry++;
+ prp_entry_phys++;
+ }
+
+ /*
+ * Bump the phys address of the command's data buffer by the
+ * entry_len.
+ */
+ paddr += entry_len;
+
+ /* Decrement length accounting for last partial page. */
+ if (entry_len > length)
+ length = 0;
+ else
+ length -= entry_len;
+ }
+}
+
/**
* base_make_prp_nvme -
* Prepare PRPs(Physical Region Page)- SGLs specific to NVMe drives only
@@ -2794,6 +3020,30 @@ _base_put_smid_hi_priority(struct MPT3SAS_ADAPTER *ioc, u16 smid,
}
/**
+ * _base_put_smid_nvme_encap - send NVMe encapsulated request to
+ * firmware
+ * @ioc: per adapter object
+ * @smid: system request message index
+ *
+ * Return nothing.
+ */
+static void
+_base_put_smid_nvme_encap(struct MPT3SAS_ADAPTER *ioc, u16 smid)
+{
+ Mpi2RequestDescriptorUnion_t descriptor;
+ u64 *request = (u64 *)&descriptor;
+
+ descriptor.Default.RequestFlags =
+ MPI26_REQ_DESCRIPT_FLAGS_PCIE_ENCAPSULATED;
+ descriptor.Default.MSIxIndex = _base_get_msix_index(ioc);
+ descriptor.Default.SMID = cpu_to_le16(smid);
+ descriptor.Default.LMID = 0;
+ descriptor.Default.DescriptorTypeDependent = 0;
+ _base_writeq(*request, &ioc->chip->RequestDescriptorPostLow,
+ &ioc->scsi_lookup_lock);
+}
+
+/**
* _base_put_smid_default - Default, primarily used for config pages
* @ioc: per adapter object
* @smid: system request message index
@@ -2884,6 +3134,27 @@ _base_put_smid_hi_priority_atomic(struct MPT3SAS_ADAPTER *ioc, u16 smid,
}
/**
+ * _base_put_smid_nvme_encap_atomic - send NVMe encapsulated request to
+ * firmware using Atomic Request Descriptor
+ * @ioc: per adapter object
+ * @smid: system request message index
+ *
+ * Return nothing.
+ */
+static void
+_base_put_smid_nvme_encap_atomic(struct MPT3SAS_ADAPTER *ioc, u16 smid)
+{
+ Mpi26AtomicRequestDescriptor_t descriptor;
+ u32 *request = (u32 *)&descriptor;
+
+ descriptor.RequestFlags = MPI26_REQ_DESCRIPT_FLAGS_PCIE_ENCAPSULATED;
+ descriptor.MSIxIndex = _base_get_msix_index(ioc);
+ descriptor.SMID = cpu_to_le16(smid);
+
+ writel(cpu_to_le32(*request), &ioc->chip->AtomicRequestDescriptorPost);
+}
+
+/**
* _base_put_smid_default - Default, primarily used for config pages
* use Atomic Request Descriptor
* @ioc: per adapter object
@@ -5707,6 +5978,7 @@ mpt3sas_base_attach(struct MPT3SAS_ADAPTER *ioc)
*/
ioc->build_sg_scmd = &_base_build_sg_scmd_ieee;
ioc->build_sg = &_base_build_sg_ieee;
+ ioc->build_nvme_prp = &_base_build_nvme_prp;
ioc->build_zero_len_sge = &_base_build_zero_len_sge_ieee;
ioc->sge_size_ieee = sizeof(Mpi2IeeeSgeSimple64_t);
@@ -5718,11 +5990,13 @@ mpt3sas_base_attach(struct MPT3SAS_ADAPTER *ioc)
ioc->put_smid_scsi_io = &_base_put_smid_scsi_io_atomic;
ioc->put_smid_fast_path = &_base_put_smid_fast_path_atomic;
ioc->put_smid_hi_priority = &_base_put_smid_hi_priority_atomic;
+ ioc->put_smid_nvme_encap = &_base_put_smid_nvme_encap_atomic;
} else {
ioc->put_smid_default = &_base_put_smid_default;
ioc->put_smid_scsi_io = &_base_put_smid_scsi_io;
ioc->put_smid_fast_path = &_base_put_smid_fast_path;
ioc->put_smid_hi_priority = &_base_put_smid_hi_priority;
+ ioc->put_smid_nvme_encap = &_base_put_smid_nvme_encap;
}
@@ -1184,6 +1184,9 @@ struct MPT3SAS_ADAPTER {
MPT_BUILD_SG build_sg_mpi;
MPT_BUILD_ZERO_LEN_SGE build_zero_len_sge_mpi;
+ /* function ptr for NVMe PRP elements only */
+ NVME_BUILD_PRP build_nvme_prp;
+
/* event log */
u32 event_type[MPI2_EVENT_NOTIFY_EVENTMASK_WORDS];
u32 event_context;
@@ -1354,6 +1357,7 @@ struct MPT3SAS_ADAPTER {
PUT_SMID_IO_FP_HIP put_smid_fast_path;
PUT_SMID_IO_FP_HIP put_smid_hi_priority;
PUT_SMID_DEFAULT put_smid_default;
+ PUT_SMID_DEFAULT put_smid_nvme_encap;
};
@@ -272,6 +272,7 @@ mpt3sas_ctl_done(struct MPT3SAS_ADAPTER *ioc, u16 smid, u8 msix_index,
{
MPI2DefaultReply_t *mpi_reply;
Mpi2SCSIIOReply_t *scsiio_reply;
+ Mpi26NVMeEncapsulatedErrorReply_t *nvme_error_reply;
const void *sense_data;
u32 sz;
@@ -298,6 +299,18 @@ mpt3sas_ctl_done(struct MPT3SAS_ADAPTER *ioc, u16 smid, u8 msix_index,
memcpy(ioc->ctl_cmds.sense, sense_data, sz);
}
}
+ /*
+ * Get Error Response data for NVMe device. The ctl_cmds.sense
+ * buffer is used to store the Error Response data.
+ */
+ if (mpi_reply->Function == MPI2_FUNCTION_NVME_ENCAPSULATED) {
+ nvme_error_reply =
+ (Mpi26NVMeEncapsulatedErrorReply_t *)mpi_reply;
+ sz = min_t(u32, NVME_ERROR_RESPONSE_SIZE,
+ le32_to_cpu(nvme_error_reply->ErrorResponseCount));
+ sense_data = mpt3sas_base_get_sense_buffer(ioc, smid);
+ memcpy(ioc->ctl_cmds.sense, sense_data, sz);
+ }
}
_ctl_display_some_debug(ioc, smid, "ctl_done", mpi_reply);
@@ -641,11 +654,12 @@ _ctl_do_mpt_command(struct MPT3SAS_ADAPTER *ioc, struct mpt3_ioctl_command karg,
{
MPI2RequestHeader_t *mpi_request = NULL, *request;
MPI2DefaultReply_t *mpi_reply;
+ Mpi26NVMeEncapsulatedRequest_t *nvme_encap_request = NULL;
u32 ioc_state;
u16 smid;
unsigned long timeout;
u8 issue_reset;
- u32 sz;
+ u32 sz, sz_arg;
void *psge;
void *data_out = NULL;
dma_addr_t data_out_dma = 0;
@@ -742,7 +756,8 @@ _ctl_do_mpt_command(struct MPT3SAS_ADAPTER *ioc, struct mpt3_ioctl_command karg,
if (mpi_request->Function == MPI2_FUNCTION_SCSI_IO_REQUEST ||
mpi_request->Function == MPI2_FUNCTION_RAID_SCSI_IO_PASSTHROUGH ||
mpi_request->Function == MPI2_FUNCTION_SCSI_TASK_MGMT ||
- mpi_request->Function == MPI2_FUNCTION_SATA_PASSTHROUGH) {
+ mpi_request->Function == MPI2_FUNCTION_SATA_PASSTHROUGH ||
+ mpi_request->Function == MPI2_FUNCTION_NVME_ENCAPSULATED) {
device_handle = le16_to_cpu(mpi_request->FunctionDependent1);
if (!device_handle || (device_handle >
@@ -793,6 +808,38 @@ _ctl_do_mpt_command(struct MPT3SAS_ADAPTER *ioc, struct mpt3_ioctl_command karg,
init_completion(&ioc->ctl_cmds.done);
switch (mpi_request->Function) {
+ case MPI2_FUNCTION_NVME_ENCAPSULATED:
+ {
+ nvme_encap_request = (Mpi26NVMeEncapsulatedRequest_t *)request;
+ /*
+ * Get the Physical Address of the sense buffer.
+ * Use Error Response buffer address field to hold the sense
+ * buffer address.
+ * Clear the internal sense buffer, which will potentially hold
+ * the Completion Queue Entry on return, or 0 if no Entry.
+ * Build the PRPs and set direction bits.
+ * Send the request.
+ */
+ nvme_encap_request->ErrorResponseBaseAddress = ioc->sense_dma &
+ 0xFFFFFFFF00000000;
+ nvme_encap_request->ErrorResponseBaseAddress |=
+ (U64)mpt3sas_base_get_sense_buffer_dma(ioc, smid);
+ nvme_encap_request->ErrorResponseAllocationLength =
+ NVME_ERROR_RESPONSE_SIZE;
+ memset(ioc->ctl_cmds.sense, 0, NVME_ERROR_RESPONSE_SIZE);
+ ioc->build_nvme_prp(ioc, smid, nvme_encap_request,
+ data_out_dma, data_out_sz, data_in_dma, data_in_sz);
+ if (test_bit(device_handle, ioc->device_remove_in_progress)) {
+ dtmprintk(ioc, pr_info(MPT3SAS_FMT "handle(0x%04x) :"
+ "ioctl failed due to device removal in progress\n",
+ ioc->name, device_handle));
+ mpt3sas_base_free_smid(ioc, smid);
+ ret = -EINVAL;
+ goto out;
+ }
+ ioc->put_smid_nvme_encap(ioc, smid);
+ break;
+ }
case MPI2_FUNCTION_SCSI_IO_REQUEST:
case MPI2_FUNCTION_RAID_SCSI_IO_PASSTHROUGH:
{
@@ -1008,15 +1055,25 @@ _ctl_do_mpt_command(struct MPT3SAS_ADAPTER *ioc, struct mpt3_ioctl_command karg,
}
}
- /* copy out sense to user */
+ /* copy out sense/NVMe Error Response to user */
if (karg.max_sense_bytes && (mpi_request->Function ==
MPI2_FUNCTION_SCSI_IO_REQUEST || mpi_request->Function ==
- MPI2_FUNCTION_RAID_SCSI_IO_PASSTHROUGH)) {
- sz = min_t(u32, karg.max_sense_bytes, SCSI_SENSE_BUFFERSIZE);
+ MPI2_FUNCTION_RAID_SCSI_IO_PASSTHROUGH || mpi_request->Function ==
+ MPI2_FUNCTION_NVME_ENCAPSULATED)) {
+ if (karg.sense_data_ptr == NULL) {
+ pr_info(MPT3SAS_FMT "Response buffer provided"
+ " by application is NULL; Response data will"
+ " not be returned.\n", ioc->name);
+ goto out;
+ }
+ sz_arg = (mpi_request->Function ==
+ MPI2_FUNCTION_NVME_ENCAPSULATED) ? NVME_ERROR_RESPONSE_SIZE :
+ SCSI_SENSE_BUFFERSIZE;
+ sz = min_t(u32, karg.max_sense_bytes, sz_arg);
if (copy_to_user(karg.sense_data_ptr, ioc->ctl_cmds.sense,
sz)) {
pr_err("failure at %s:%d/%s()!\n", __FILE__,
- __LINE__, __func__);
+ __LINE__, __func__);
ret = -ENODATA;
goto out;
}