On Thu, Feb 04, 2021 at 07:15:39PM +0530, Kishon Vijay Abraham I wrote:
> Hi Lorenzo,
>
> On 04/02/21 3:28 pm, Lorenzo Pieralisi wrote:
> > On Tue, Feb 02, 2021 at 12:12:55PM -0800, Randy Dunlap wrote:
> >> The pci-epf-ntb driver uses configfs APIs, so it should depend on
> >> CONFIGFS_FS to prevent build errors.
> >>
> >> ld: drivers/pci/endpoint/functions/pci-epf-ntb.o: in function
> >> `epf_ntb_add_cfs':
> >> pci-epf-ntb.c:(.text+0x1b): undefined reference to
> >> `config_group_init_type_name'
> >>
> >> Fixes: 7dc64244f9e9 ("PCI: endpoint: Add EP function driver to provide NTB
> >> functionality")
> >>
> >> Signed-off-by: Randy Dunlap <rdun...@infradead.org>
> >> Cc: Kishon Vijay Abraham I <kis...@ti.com>
> >> Cc: Lorenzo Pieralisi <lorenzo.pieral...@arm.com>
> >> Cc: linux-...@vger.kernel.org
> >> ---
> >> You may switch to 'select CONFIG_FS_FS' if you feel strongly about it.
> >
> > Kishon ?
>
> There seems to be some issue in the version that got merged. The v11
> patch series had this fixed [1] by using select CONFIGFS_FS. However
> whatever was merged seems to be v10 which didn't have select CONFIGFS_FS
> [2]. I had sent a private mail to you pointing the same (attached for
> reference, not sure if it was delivered).
I think that Bjorn has not pulled my pci/ntb branch yet (so the one
in -next is v10 indeed, my one should be v11, please check).
Thanks,
Lorenzo
> Thanks
> Kishon
>
> [1] ->
> https://lore.kernel.org/linux-doc/20210201195809.7342-14-kis...@ti.com/
>
> [2] ->
> https://git.kernel.org/pub/scm/linux/kernel/git/next/linux-next.git/tree/drivers/pci/endpoint/functions/Kconfig
> >
> > Thanks,
> > Lorenzo
> >
> >> drivers/pci/endpoint/functions/Kconfig | 1 +
> >> 1 file changed, 1 insertion(+)
> >>
> >> --- linux-next-20210202.orig/drivers/pci/endpoint/functions/Kconfig
> >> +++ linux-next-20210202/drivers/pci/endpoint/functions/Kconfig
> >> @@ -16,6 +16,7 @@ config PCI_EPF_TEST
> >> config PCI_EPF_NTB
> >> tristate "PCI Endpoint NTB driver"
> >> depends on PCI_ENDPOINT
> >> + depends on CONFIGFS_FS
> >> help
> >> Select this configuration option to enable the NTB driver
> >> for PCI Endpoint. NTB driver implements NTB controller
> Date: Tue, 2 Feb 2021 21:57:37 +0530
> From: Kishon Vijay Abraham I <kis...@ti.com>
> To: Lorenzo Pieralisi <lorenzo.pieral...@arm.com>
> Subject: Re: [PATCH v11 13/17] PCI: endpoint: Add EP function driver to
> provide NTB functionality
> User-Agent: Mozilla/5.0 (X11; Linux x86_64; rv:68.0) Gecko/20100101
> Thunderbird/68.10.0
>
> Hi Lorenzo,
>
> On 02/02/21 1:28 am, Kishon Vijay Abraham I wrote:
> > Add a new endpoint function driver to provide NTB functionality
> > using multiple PCIe endpoint instances.
> >
> > Signed-off-by: Kishon Vijay Abraham I <kis...@ti.com>
> > [a...@arndb.de: Select configfs dependency]
> > Signed-off-by: Arnd Bergmann <a...@arndb.de>
> > [yebi...@huawei.com: Fix unused but set variables]
> > Signed-off-by: Ye Bin <yebi...@huawei.com>
> > [geert+rene...@glider.be: Explain NTB in PCI_EPF_NTB help text]
> > Signed-off-by: Geert Uytterhoeven <geert+rene...@glider.be>
> > ---
> > drivers/pci/endpoint/functions/Kconfig | 13 +
> > drivers/pci/endpoint/functions/Makefile | 1 +
> > drivers/pci/endpoint/functions/pci-epf-ntb.c | 2128 ++++++++++++++++++
> > 3 files changed, 2142 insertions(+)
> > create mode 100644 drivers/pci/endpoint/functions/pci-epf-ntb.c
> >
> > diff --git a/drivers/pci/endpoint/functions/Kconfig
> > b/drivers/pci/endpoint/functions/Kconfig
> > index 8820d0f7ec77..5f1242ca2f4e 100644
> > --- a/drivers/pci/endpoint/functions/Kconfig
> > +++ b/drivers/pci/endpoint/functions/Kconfig
> > @@ -12,3 +12,16 @@ config PCI_EPF_TEST
> > for PCI Endpoint.
> >
> > If in doubt, say "N" to disable Endpoint test driver.
> > +
> > +config PCI_EPF_NTB
> > + tristate "PCI Endpoint NTB driver"
> > + depends on PCI_ENDPOINT
> > + select CONFIGFS_FS
>
> I'm seeing some difference between here and linux-next.
> https://git.kernel.org/pub/scm/linux/kernel/git/next/linux-next.git/tree/drivers/pci/endpoint/functions/Kconfig
>
> I see "select CONFIGFS_FS" missing in linux-next.
>
> Thank You,
> Kishon
>
> > + help
> > + Select this configuration option to enable the Non-Transparent
> > + Bridge (NTB) driver for PCI Endpoint. NTB driver implements NTB
> > + controller functionality using multiple PCIe endpoint instances.
> > + It can support NTB endpoint function devices created using
> > + device tree.
> > +
> > + If in doubt, say "N" to disable Endpoint NTB driver.
> > diff --git a/drivers/pci/endpoint/functions/Makefile
> > b/drivers/pci/endpoint/functions/Makefile
> > index d6fafff080e2..96ab932a537a 100644
> > --- a/drivers/pci/endpoint/functions/Makefile
> > +++ b/drivers/pci/endpoint/functions/Makefile
> > @@ -4,3 +4,4 @@
> > #
> >
> > obj-$(CONFIG_PCI_EPF_TEST) += pci-epf-test.o
> > +obj-$(CONFIG_PCI_EPF_NTB) += pci-epf-ntb.o
> > diff --git a/drivers/pci/endpoint/functions/pci-epf-ntb.c
> > b/drivers/pci/endpoint/functions/pci-epf-ntb.c
> > new file mode 100644
> > index 000000000000..338148cf56f5
> > --- /dev/null
> > +++ b/drivers/pci/endpoint/functions/pci-epf-ntb.c
> > @@ -0,0 +1,2128 @@
> > +// SPDX-License-Identifier: GPL-2.0
> > +/**
> > + * Endpoint Function Driver to implement Non-Transparent Bridge
> > functionality
> > + *
> > + * Copyright (C) 2020 Texas Instruments
> > + * Author: Kishon Vijay Abraham I <kis...@ti.com>
> > + */
> > +
> > +/*
> > + * The PCI NTB function driver configures the SoC with multiple PCIe
> > Endpoint
> > + * (EP) controller instances (see diagram below) in such a way that
> > + * transactions from one EP controller are routed to the other EP
> > controller.
> > + * Once PCI NTB function driver configures the SoC with multiple EP
> > instances,
> > + * HOST1 and HOST2 can communicate with each other using SoC as a bridge.
> > + *
> > + * +-------------+ +-------------+
> > + * | | | |
> > + * | HOST1 | | HOST2 |
> > + * | | | |
> > + * +------^------+ +------^------+
> > + * | |
> > + * | |
> > + * +---------|-------------------------------------------------|---------+
> > + * | +------v------+ +------v------+ |
> > + * | | | | | |
> > + * | | EP | | EP | |
> > + * | | CONTROLLER1 | | CONTROLLER2 | |
> > + * | | <-----------------------------------> | |
> > + * | | | | | |
> > + * | | | | | |
> > + * | | | SoC With Multiple EP Instances | | |
> > + * | | | (Configured using NTB Function) | | |
> > + * | +-------------+ +-------------+ |
> > + * +---------------------------------------------------------------------+
> > + */
> > +
> > +#include <linux/delay.h>
> > +#include <linux/io.h>
> > +#include <linux/module.h>
> > +#include <linux/slab.h>
> > +
> > +#include <linux/pci-epc.h>
> > +#include <linux/pci-epf.h>
> > +
> > +static struct workqueue_struct *kpcintb_workqueue;
> > +
> > +#define COMMAND_CONFIGURE_DOORBELL 1
> > +#define COMMAND_TEARDOWN_DOORBELL 2
> > +#define COMMAND_CONFIGURE_MW 3
> > +#define COMMAND_TEARDOWN_MW 4
> > +#define COMMAND_LINK_UP 5
> > +#define COMMAND_LINK_DOWN 6
> > +
> > +#define COMMAND_STATUS_OK 1
> > +#define COMMAND_STATUS_ERROR 2
> > +
> > +#define LINK_STATUS_UP BIT(0)
> > +
> > +#define SPAD_COUNT 64
> > +#define DB_COUNT 4
> > +#define NTB_MW_OFFSET 2
> > +#define DB_COUNT_MASK GENMASK(15, 0)
> > +#define MSIX_ENABLE BIT(16)
> > +#define MAX_DB_COUNT 32
> > +#define MAX_MW 4
> > +
> > +enum epf_ntb_bar {
> > + BAR_CONFIG,
> > + BAR_PEER_SPAD,
> > + BAR_DB_MW1,
> > + BAR_MW2,
> > + BAR_MW3,
> > + BAR_MW4,
> > +};
> > +
> > +struct epf_ntb {
> > + u32 num_mws;
> > + u32 db_count;
> > + u32 spad_count;
> > + struct pci_epf *epf;
> > + u64 mws_size[MAX_MW];
> > + struct config_group group;
> > + struct epf_ntb_epc *epc[2];
> > +};
> > +
> > +#define to_epf_ntb(epf_group) container_of((epf_group), struct epf_ntb,
> > group)
> > +
> > +struct epf_ntb_epc {
> > + u8 func_no;
> > + bool linkup;
> > + bool is_msix;
> > + int msix_bar;
> > + u32 spad_size;
> > + struct pci_epc *epc;
> > + struct epf_ntb *epf_ntb;
> > + void __iomem *mw_addr[6];
> > + size_t msix_table_offset;
> > + struct epf_ntb_ctrl *reg;
> > + struct pci_epf_bar *epf_bar;
> > + enum pci_barno epf_ntb_bar[6];
> > + struct delayed_work cmd_handler;
> > + enum pci_epc_interface_type type;
> > + const struct pci_epc_features *epc_features;
> > +};
> > +
> > +struct epf_ntb_ctrl {
> > + u32 command;
> > + u32 argument;
> > + u16 command_status;
> > + u16 link_status;
> > + u32 topology;
> > + u64 addr;
> > + u64 size;
> > + u32 num_mws;
> > + u32 mw1_offset;
> > + u32 spad_offset;
> > + u32 spad_count;
> > + u32 db_entry_size;
> > + u32 db_data[MAX_DB_COUNT];
> > + u32 db_offset[MAX_DB_COUNT];
> > +} __packed;
> > +
> > +static struct pci_epf_header epf_ntb_header = {
> > + .vendorid = PCI_ANY_ID,
> > + .deviceid = PCI_ANY_ID,
> > + .baseclass_code = PCI_BASE_CLASS_MEMORY,
> > + .interrupt_pin = PCI_INTERRUPT_INTA,
> > +};
> > +
> > +/**
> > + * epf_ntb_link_up() - Raise link_up interrupt to both the hosts
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @link_up: true or false indicating Link is UP or Down
> > + *
> > + * Once NTB function in HOST1 and the NTB function in HOST2 invoke
> > + * ntb_link_enable(), this NTB function driver will trigger a link event to
> > + * the NTB client in both the hosts.
> > + */
> > +static int epf_ntb_link_up(struct epf_ntb *ntb, bool link_up)
> > +{
> > + enum pci_epc_interface_type type;
> > + enum pci_epc_irq_type irq_type;
> > + struct epf_ntb_epc *ntb_epc;
> > + struct epf_ntb_ctrl *ctrl;
> > + struct pci_epc *epc;
> > + bool is_msix;
> > + u8 func_no;
> > + int ret;
> > +
> > + for (type = PRIMARY_INTERFACE; type <= SECONDARY_INTERFACE; type++) {
> > + ntb_epc = ntb->epc[type];
> > + epc = ntb_epc->epc;
> > + func_no = ntb_epc->func_no;
> > + is_msix = ntb_epc->is_msix;
> > + ctrl = ntb_epc->reg;
> > + if (link_up)
> > + ctrl->link_status |= LINK_STATUS_UP;
> > + else
> > + ctrl->link_status &= ~LINK_STATUS_UP;
> > + irq_type = is_msix ? PCI_EPC_IRQ_MSIX : PCI_EPC_IRQ_MSI;
> > + ret = pci_epc_raise_irq(epc, func_no, irq_type, 1);
> > + if (ret) {
> > + dev_err(&epc->dev,
> > + "%s intf: Failed to raise Link Up IRQ\n",
> > + pci_epc_interface_string(type));
> > + return ret;
> > + }
> > + }
> > +
> > + return 0;
> > +}
> > +
> > +/**
> > + * epf_ntb_configure_mw() - Configure the Outbound Address Space for one
> > host
> > + * to access the memory window of other host
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @type: PRIMARY interface or SECONDARY interface
> > + * @mw: Index of the memory window (either 0, 1, 2 or 3)
> > + *
> > + * +-----------------+
> > +---->+----------------+-----------+-----------------+
> > + * | BAR0 | | | Doorbell 1 +-----------> MSI|X
> > ADDRESS 1 |
> > + * +-----------------+ | +----------------+
> > +-----------------+
> > + * | BAR1 | | | Doorbell 2 +---------+ |
> > |
> > + * +-----------------+----+ +----------------+ | |
> > |
> > + * | BAR2 | | Doorbell 3 +-------+ |
> > +-----------------+
> > + * +-----------------+----+ +----------------+ | +-> MSI|X
> > ADDRESS 2 |
> > + * | BAR3 | | | Doorbell 4 +-----+ |
> > +-----------------+
> > + * +-----------------+ | |----------------+ | | |
> > |
> > + * | BAR4 | | | | | |
> > +-----------------+
> > + * +-----------------+ | | MW1 +---+ | +-->+ MSI|X
> > ADDRESS 3||
> > + * | BAR5 | | | | | |
> > +-----------------+
> > + * +-----------------+ +---->-----------------+ | | |
> > |
> > + * EP CONTROLLER 1 | | | |
> > +-----------------+
> > + * | | | +---->+ MSI|X
> > ADDRESS 4 |
> > + * +----------------+ |
> > +-----------------+
> > + * (A) EP CONTROLLER 2 | |
> > |
> > + * (OB SPACE) | |
> > |
> > + * +-------> MW1
> > |
> > + * |
> > |
> > + * |
> > |
> > + * (B)
> > +-----------------+
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + *
> > +-----------------+
> > + * PCI Address
> > Space
> > + * (Managed by
> > HOST2)
> > + *
> > + * This function performs stage (B) in the above diagram (see MW1) i.e.,
> > map OB
> > + * address space of memory window to PCI address space.
> > + *
> > + * This operation requires 3 parameters
> > + * 1) Address in the outbound address space
> > + * 2) Address in the PCI Address space
> > + * 3) Size of the address region to be mapped
> > + *
> > + * The address in the outbound address space (for MW1, MW2, MW3 and MW4) is
> > + * stored in epf_bar corresponding to BAR_DB_MW1 for MW1 and BAR_MW2,
> > BAR_MW3
> > + * BAR_MW4 for rest of the BARs of epf_ntb_epc that is connected to HOST1.
> > This
> > + * is populated in epf_ntb_alloc_peer_mem() in this driver.
> > + *
> > + * The address and size of the PCI address region that has to be mapped
> > would
> > + * be provided by HOST2 in ctrl->addr and ctrl->size of epf_ntb_epc that is
> > + * connected to HOST2.
> > + *
> > + * Please note Memory window1 (MW1) and Doorbell registers together will be
> > + * mapped to a single BAR (BAR2) above for 32-bit BARs. The exact BAR
> > that's
> > + * used for Memory window (MW) can be obtained from
> > epf_ntb_bar[BAR_DB_MW1],
> > + * epf_ntb_bar[BAR_MW2], epf_ntb_bar[BAR_MW2], epf_ntb_bar[BAR_MW2].
> > + */
> > +static int epf_ntb_configure_mw(struct epf_ntb *ntb,
> > + enum pci_epc_interface_type type, u32 mw)
> > +{
> > + struct epf_ntb_epc *peer_ntb_epc, *ntb_epc;
> > + struct pci_epf_bar *peer_epf_bar;
> > + enum pci_barno peer_barno;
> > + struct epf_ntb_ctrl *ctrl;
> > + phys_addr_t phys_addr;
> > + struct pci_epc *epc;
> > + u64 addr, size;
> > + int ret = 0;
> > + u8 func_no;
> > +
> > + ntb_epc = ntb->epc[type];
> > + epc = ntb_epc->epc;
> > +
> > + peer_ntb_epc = ntb->epc[!type];
> > + peer_barno = peer_ntb_epc->epf_ntb_bar[mw + NTB_MW_OFFSET];
> > + peer_epf_bar = &peer_ntb_epc->epf_bar[peer_barno];
> > +
> > + phys_addr = peer_epf_bar->phys_addr;
> > + ctrl = ntb_epc->reg;
> > + addr = ctrl->addr;
> > + size = ctrl->size;
> > + if (mw + NTB_MW_OFFSET == BAR_DB_MW1)
> > + phys_addr += ctrl->mw1_offset;
> > +
> > + if (size > ntb->mws_size[mw]) {
> > + dev_err(&epc->dev,
> > + "%s intf: MW: %d Req Sz:%llxx > Supported Sz:%llx\n",
> > + pci_epc_interface_string(type), mw, size,
> > + ntb->mws_size[mw]);
> > + ret = -EINVAL;
> > + goto err_invalid_size;
> > + }
> > +
> > + func_no = ntb_epc->func_no;
> > +
> > + ret = pci_epc_map_addr(epc, func_no, phys_addr, addr, size);
> > + if (ret)
> > + dev_err(&epc->dev,
> > + "%s intf: Failed to map memory window %d address\n",
> > + pci_epc_interface_string(type), mw);
> > +
> > +err_invalid_size:
> > +
> > + return ret;
> > +}
> > +
> > +/**
> > + * epf_ntb_teardown_mw() - Teardown the configured OB ATU
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @type: PRIMARY interface or SECONDARY interface
> > + * @mw: Index of the memory window (either 0, 1, 2 or 3)
> > + *
> > + * Teardown the configured OB ATU configured in epf_ntb_configure_mw()
> > using
> > + * pci_epc_unmap_addr()
> > + */
> > +static void epf_ntb_teardown_mw(struct epf_ntb *ntb,
> > + enum pci_epc_interface_type type, u32 mw)
> > +{
> > + struct epf_ntb_epc *peer_ntb_epc, *ntb_epc;
> > + struct pci_epf_bar *peer_epf_bar;
> > + enum pci_barno peer_barno;
> > + struct epf_ntb_ctrl *ctrl;
> > + phys_addr_t phys_addr;
> > + struct pci_epc *epc;
> > + u8 func_no;
> > +
> > + ntb_epc = ntb->epc[type];
> > + epc = ntb_epc->epc;
> > +
> > + peer_ntb_epc = ntb->epc[!type];
> > + peer_barno = peer_ntb_epc->epf_ntb_bar[mw + NTB_MW_OFFSET];
> > + peer_epf_bar = &peer_ntb_epc->epf_bar[peer_barno];
> > +
> > + phys_addr = peer_epf_bar->phys_addr;
> > + ctrl = ntb_epc->reg;
> > + if (mw + NTB_MW_OFFSET == BAR_DB_MW1)
> > + phys_addr += ctrl->mw1_offset;
> > + func_no = ntb_epc->func_no;
> > +
> > + pci_epc_unmap_addr(epc, func_no, phys_addr);
> > +}
> > +
> > +/**
> > + * epf_ntb_configure_msi() - Map OB address space to MSI address
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @type: PRIMARY interface or SECONDARY interface
> > + * @db_count: Number of doorbell interrupts to map
> > + *
> > + *+-----------------+
> > +----->+----------------+-----------+-----------------+
> > + *| BAR0 | | | Doorbell 1 +---+-------> MSI
> > ADDRESS |
> > + *+-----------------+ | +----------------+ |
> > +-----------------+
> > + *| BAR1 | | | Doorbell 2 +---+ |
> > |
> > + *+-----------------+----+ +----------------+ | |
> > |
> > + *| BAR2 | | Doorbell 3 +---+ |
> > |
> > + *+-----------------+----+ +----------------+ | |
> > |
> > + *| BAR3 | | | Doorbell 4 +---+ |
> > |
> > + *+-----------------+ | |----------------+ |
> > |
> > + *| BAR4 | | | | |
> > |
> > + *+-----------------+ | | MW1 | |
> > |
> > + *| BAR5 | | | | |
> > |
> > + *+-----------------+ +----->-----------------+ |
> > |
> > + * EP CONTROLLER 1 | | |
> > |
> > + * | | |
> > |
> > + * +----------------+
> > +-----------------+
> > + * (A) EP CONTROLLER 2 |
> > |
> > + * (OB SPACE) |
> > |
> > + * | MW1
> > |
> > + * |
> > |
> > + * |
> > |
> > + * (B)
> > +-----------------+
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + *
> > +-----------------+
> > + * PCI Address
> > Space
> > + * (Managed by
> > HOST2)
> > + *
> > + *
> > + * This function performs stage (B) in the above diagram (see Doorbell 1,
> > + * Doorbell 2, Doorbell 3, Doorbell 4) i.e map OB address space
> > corresponding to
> > + * doorbell to MSI address in PCI address space.
> > + *
> > + * This operation requires 3 parameters
> > + * 1) Address reserved for doorbell in the outbound address space
> > + * 2) MSI-X address in the PCIe Address space
> > + * 3) Number of MSI-X interrupts that has to be configured
> > + *
> > + * The address in the outbound address space (for the Doorbell) is stored
> > in
> > + * epf_bar corresponding to BAR_DB_MW1 of epf_ntb_epc that is connected to
> > + * HOST1. This is populated in epf_ntb_alloc_peer_mem() in this driver
> > along
> > + * with address for MW1.
> > + *
> > + * pci_epc_map_msi_irq() takes the MSI address from MSI capability register
> > + * and maps the OB address (obtained in epf_ntb_alloc_peer_mem()) to the
> > MSI
> > + * address.
> > + *
> > + * epf_ntb_configure_msi() also stores the MSI data to raise each interrupt
> > + * in db_data of the peer's control region. This helps the peer to raise
> > + * doorbell of the other host by writing db_data to the BAR corresponding
> > to
> > + * BAR_DB_MW1.
> > + */
> > +static int epf_ntb_configure_msi(struct epf_ntb *ntb,
> > + enum pci_epc_interface_type type, u16 db_count)
> > +{
> > + struct epf_ntb_epc *peer_ntb_epc, *ntb_epc;
> > + u32 db_entry_size, db_data, db_offset;
> > + struct pci_epf_bar *peer_epf_bar;
> > + struct epf_ntb_ctrl *peer_ctrl;
> > + enum pci_barno peer_barno;
> > + phys_addr_t phys_addr;
> > + struct pci_epc *epc;
> > + u8 func_no;
> > + int ret, i;
> > +
> > + ntb_epc = ntb->epc[type];
> > + epc = ntb_epc->epc;
> > +
> > + peer_ntb_epc = ntb->epc[!type];
> > + peer_barno = peer_ntb_epc->epf_ntb_bar[BAR_DB_MW1];
> > + peer_epf_bar = &peer_ntb_epc->epf_bar[peer_barno];
> > + peer_ctrl = peer_ntb_epc->reg;
> > + db_entry_size = peer_ctrl->db_entry_size;
> > +
> > + phys_addr = peer_epf_bar->phys_addr;
> > + func_no = ntb_epc->func_no;
> > +
> > + ret = pci_epc_map_msi_irq(epc, func_no, phys_addr, db_count,
> > + db_entry_size, &db_data, &db_offset);
> > + if (ret) {
> > + dev_err(&epc->dev, "%s intf: Failed to map MSI IRQ\n",
> > + pci_epc_interface_string(type));
> > + return ret;
> > + }
> > +
> > + for (i = 0; i < db_count; i++) {
> > + peer_ctrl->db_data[i] = db_data | i;
> > + peer_ctrl->db_offset[i] = db_offset;
> > + }
> > +
> > + return 0;
> > +}
> > +
> > +/**
> > + * epf_ntb_configure_msix() - Map OB address space to MSI-X address
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @type: PRIMARY interface or SECONDARY interface
> > + * @db_count: Number of doorbell interrupts to map
> > + *
> > + *+-----------------+
> > +----->+----------------+-----------+-----------------+
> > + *| BAR0 | | | Doorbell 1 +-----------> MSI-X
> > ADDRESS 1 |
> > + *+-----------------+ | +----------------+
> > +-----------------+
> > + *| BAR1 | | | Doorbell 2 +---------+ |
> > |
> > + *+-----------------+----+ +----------------+ | |
> > |
> > + *| BAR2 | | Doorbell 3 +-------+ |
> > +-----------------+
> > + *+-----------------+----+ +----------------+ | +-> MSI-X
> > ADDRESS 2 |
> > + *| BAR3 | | | Doorbell 4 +-----+ |
> > +-----------------+
> > + *+-----------------+ | |----------------+ | | |
> > |
> > + *| BAR4 | | | | | |
> > +-----------------+
> > + *+-----------------+ | | MW1 + | +-->+ MSI-X
> > ADDRESS 3||
> > + *| BAR5 | | | | |
> > +-----------------+
> > + *+-----------------+ +----->-----------------+ | |
> > |
> > + * EP CONTROLLER 1 | | |
> > +-----------------+
> > + * | | +---->+ MSI-X
> > ADDRESS 4 |
> > + * +----------------+
> > +-----------------+
> > + * (A) EP CONTROLLER 2 |
> > |
> > + * (OB SPACE) |
> > |
> > + * | MW1
> > |
> > + * |
> > |
> > + * |
> > |
> > + * (B)
> > +-----------------+
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + *
> > +-----------------+
> > + * PCI Address
> > Space
> > + * (Managed by
> > HOST2)
> > + *
> > + * This function performs stage (B) in the above diagram (see Doorbell 1,
> > + * Doorbell 2, Doorbell 3, Doorbell 4) i.e map OB address space
> > corresponding to
> > + * doorbell to MSI-X address in PCI address space.
> > + *
> > + * This operation requires 3 parameters
> > + * 1) Address reserved for doorbell in the outbound address space
> > + * 2) MSI-X address in the PCIe Address space
> > + * 3) Number of MSI-X interrupts that has to be configured
> > + *
> > + * The address in the outbound address space (for the Doorbell) is stored
> > in
> > + * epf_bar corresponding to BAR_DB_MW1 of epf_ntb_epc that is connected to
> > + * HOST1. This is populated in epf_ntb_alloc_peer_mem() in this driver
> > along
> > + * with address for MW1.
> > + *
> > + * The MSI-X address is in the MSI-X table of EP CONTROLLER 2 and
> > + * the count of doorbell is in ctrl->argument of epf_ntb_epc that is
> > connected
> > + * to HOST2. MSI-X table is stored memory mapped to ntb_epc->msix_bar and
> > the
> > + * offset is in ntb_epc->msix_table_offset. From this
> > epf_ntb_configure_msix()
> > + * gets the MSI-X address and data.
> > + *
> > + * epf_ntb_configure_msix() also stores the MSI-X data to raise each
> > interrupt
> > + * in db_data of the peer's control region. This helps the peer to raise
> > + * doorbell of the other host by writing db_data to the BAR corresponding
> > to
> > + * BAR_DB_MW1.
> > + */
> > +static int epf_ntb_configure_msix(struct epf_ntb *ntb,
> > + enum pci_epc_interface_type type,
> > + u16 db_count)
> > +{
> > + const struct pci_epc_features *epc_features;
> > + struct epf_ntb_epc *peer_ntb_epc, *ntb_epc;
> > + struct pci_epf_bar *peer_epf_bar, *epf_bar;
> > + struct pci_epf_msix_tbl *msix_tbl;
> > + struct epf_ntb_ctrl *peer_ctrl;
> > + u32 db_entry_size, msg_data;
> > + enum pci_barno peer_barno;
> > + phys_addr_t phys_addr;
> > + struct pci_epc *epc;
> > + size_t align;
> > + u64 msg_addr;
> > + u8 func_no;
> > + int ret, i;
> > +
> > + ntb_epc = ntb->epc[type];
> > + epc = ntb_epc->epc;
> > +
> > + epf_bar = &ntb_epc->epf_bar[ntb_epc->msix_bar];
> > + msix_tbl = epf_bar->addr + ntb_epc->msix_table_offset;
> > +
> > + peer_ntb_epc = ntb->epc[!type];
> > + peer_barno = peer_ntb_epc->epf_ntb_bar[BAR_DB_MW1];
> > + peer_epf_bar = &peer_ntb_epc->epf_bar[peer_barno];
> > + phys_addr = peer_epf_bar->phys_addr;
> > + peer_ctrl = peer_ntb_epc->reg;
> > + epc_features = ntb_epc->epc_features;
> > + align = epc_features->align;
> > +
> > + func_no = ntb_epc->func_no;
> > + db_entry_size = peer_ctrl->db_entry_size;
> > +
> > + for (i = 0; i < db_count; i++) {
> > + msg_addr = ALIGN_DOWN(msix_tbl[i].msg_addr, align);
> > + msg_data = msix_tbl[i].msg_data;
> > + ret = pci_epc_map_addr(epc, func_no, phys_addr, msg_addr,
> > + db_entry_size);
> > + if (ret) {
> > + dev_err(&epc->dev,
> > + "%s intf: Failed to configure MSI-X IRQ\n",
> > + pci_epc_interface_string(type));
> > + return ret;
> > + }
> > + phys_addr = phys_addr + db_entry_size;
> > + peer_ctrl->db_data[i] = msg_data;
> > + peer_ctrl->db_offset[i] = msix_tbl[i].msg_addr & (align - 1);
> > + }
> > + ntb_epc->is_msix = true;
> > +
> > + return 0;
> > +}
> > +
> > +/**
> > + * epf_ntb_configure_db() - Configure the Outbound Address Space for one
> > host
> > + * to ring the doorbell of other host
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @type: PRIMARY interface or SECONDARY interface
> > + * @db_count: Count of the number of doorbells that has to be configured
> > + * @msix: Indicates whether MSI-X or MSI should be used
> > + *
> > + * Invokes epf_ntb_configure_msix() or epf_ntb_configure_msi() required for
> > + * one HOST to ring the doorbell of other HOST.
> > + */
> > +static int epf_ntb_configure_db(struct epf_ntb *ntb,
> > + enum pci_epc_interface_type type,
> > + u16 db_count, bool msix)
> > +{
> > + struct epf_ntb_epc *ntb_epc;
> > + struct pci_epc *epc;
> > + int ret;
> > +
> > + if (db_count > MAX_DB_COUNT)
> > + return -EINVAL;
> > +
> > + ntb_epc = ntb->epc[type];
> > + epc = ntb_epc->epc;
> > +
> > + if (msix)
> > + ret = epf_ntb_configure_msix(ntb, type, db_count);
> > + else
> > + ret = epf_ntb_configure_msi(ntb, type, db_count);
> > +
> > + if (ret)
> > + dev_err(&epc->dev, "%s intf: Failed to configure DB\n",
> > + pci_epc_interface_string(type));
> > +
> > + return ret;
> > +}
> > +
> > +/**
> > + * epf_ntb_teardown_db() - Unmap address in OB address space to MSI/MSI-X
> > + * address
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @type: PRIMARY interface or SECONDARY interface
> > + *
> > + * Invoke pci_epc_unmap_addr() to unmap OB address to MSI/MSI-X address.
> > + */
> > +static void
> > +epf_ntb_teardown_db(struct epf_ntb *ntb, enum pci_epc_interface_type type)
> > +{
> > + struct epf_ntb_epc *peer_ntb_epc, *ntb_epc;
> > + struct pci_epf_bar *peer_epf_bar;
> > + enum pci_barno peer_barno;
> > + phys_addr_t phys_addr;
> > + struct pci_epc *epc;
> > + u8 func_no;
> > +
> > + ntb_epc = ntb->epc[type];
> > + epc = ntb_epc->epc;
> > +
> > + peer_ntb_epc = ntb->epc[!type];
> > + peer_barno = peer_ntb_epc->epf_ntb_bar[BAR_DB_MW1];
> > + peer_epf_bar = &peer_ntb_epc->epf_bar[peer_barno];
> > + phys_addr = peer_epf_bar->phys_addr;
> > + func_no = ntb_epc->func_no;
> > +
> > + pci_epc_unmap_addr(epc, func_no, phys_addr);
> > +}
> > +
> > +/**
> > + * epf_ntb_cmd_handler() - Handle commands provided by the NTB Host
> > + * @work: work_struct for the two epf_ntb_epc (PRIMARY and SECONDARY)
> > + *
> > + * Workqueue function that gets invoked for the two epf_ntb_epc
> > + * periodically (once every 5ms) to see if it has received any commands
> > + * from NTB host. The host can send commands to configure doorbell or
> > + * configure memory window or to update link status.
> > + */
> > +static void epf_ntb_cmd_handler(struct work_struct *work)
> > +{
> > + enum pci_epc_interface_type type;
> > + struct epf_ntb_epc *ntb_epc;
> > + struct epf_ntb_ctrl *ctrl;
> > + u32 command, argument;
> > + struct epf_ntb *ntb;
> > + struct device *dev;
> > + u16 db_count;
> > + bool is_msix;
> > + int ret;
> > +
> > + ntb_epc = container_of(work, struct epf_ntb_epc, cmd_handler.work);
> > + ctrl = ntb_epc->reg;
> > + command = ctrl->command;
> > + if (!command)
> > + goto reset_handler;
> > + argument = ctrl->argument;
> > +
> > + ctrl->command = 0;
> > + ctrl->argument = 0;
> > +
> > + ctrl = ntb_epc->reg;
> > + type = ntb_epc->type;
> > + ntb = ntb_epc->epf_ntb;
> > + dev = &ntb->epf->dev;
> > +
> > + switch (command) {
> > + case COMMAND_CONFIGURE_DOORBELL:
> > + db_count = argument & DB_COUNT_MASK;
> > + is_msix = argument & MSIX_ENABLE;
> > + ret = epf_ntb_configure_db(ntb, type, db_count, is_msix);
> > + if (ret < 0)
> > + ctrl->command_status = COMMAND_STATUS_ERROR;
> > + else
> > + ctrl->command_status = COMMAND_STATUS_OK;
> > + break;
> > + case COMMAND_TEARDOWN_DOORBELL:
> > + epf_ntb_teardown_db(ntb, type);
> > + ctrl->command_status = COMMAND_STATUS_OK;
> > + break;
> > + case COMMAND_CONFIGURE_MW:
> > + ret = epf_ntb_configure_mw(ntb, type, argument);
> > + if (ret < 0)
> > + ctrl->command_status = COMMAND_STATUS_ERROR;
> > + else
> > + ctrl->command_status = COMMAND_STATUS_OK;
> > + break;
> > + case COMMAND_TEARDOWN_MW:
> > + epf_ntb_teardown_mw(ntb, type, argument);
> > + ctrl->command_status = COMMAND_STATUS_OK;
> > + break;
> > + case COMMAND_LINK_UP:
> > + ntb_epc->linkup = true;
> > + if (ntb->epc[PRIMARY_INTERFACE]->linkup &&
> > + ntb->epc[SECONDARY_INTERFACE]->linkup) {
> > + ret = epf_ntb_link_up(ntb, true);
> > + if (ret < 0)
> > + ctrl->command_status = COMMAND_STATUS_ERROR;
> > + else
> > + ctrl->command_status = COMMAND_STATUS_OK;
> > + goto reset_handler;
> > + }
> > + ctrl->command_status = COMMAND_STATUS_OK;
> > + break;
> > + case COMMAND_LINK_DOWN:
> > + ntb_epc->linkup = false;
> > + ret = epf_ntb_link_up(ntb, false);
> > + if (ret < 0)
> > + ctrl->command_status = COMMAND_STATUS_ERROR;
> > + else
> > + ctrl->command_status = COMMAND_STATUS_OK;
> > + break;
> > + default:
> > + dev_err(dev, "%s intf UNKNOWN command: %d\n",
> > + pci_epc_interface_string(type), command);
> > + break;
> > + }
> > +
> > +reset_handler:
> > + queue_delayed_work(kpcintb_workqueue, &ntb_epc->cmd_handler,
> > + msecs_to_jiffies(5));
> > +}
> > +
> > +/**
> > + * epf_ntb_peer_spad_bar_clear() - Clear Peer Scratchpad BAR
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + *
> > + *+-----------------+------->+------------------+
> > +-----------------+
> > + *| BAR0 | | CONFIG REGION | | BAR0
> > |
> > + *+-----------------+----+
> > +------------------+<-------+-----------------+
> > + *| BAR1 | | |SCRATCHPAD REGION | | BAR1
> > |
> > + *+-----------------+
> > +-->+------------------+<-------+-----------------+
> > + *| BAR2 | Local Memory | BAR2
> > |
> > + *+-----------------+
> > +-----------------+
> > + *| BAR3 | | BAR3
> > |
> > + *+-----------------+
> > +-----------------+
> > + *| BAR4 | | BAR4
> > |
> > + *+-----------------+
> > +-----------------+
> > + *| BAR5 | | BAR5
> > |
> > + *+-----------------+
> > +-----------------+
> > + * EP CONTROLLER 1 EP CONTROLLER 2
> > + *
> > + * Clear BAR1 of EP CONTROLLER 2 which contains the HOST2's peer scratchpad
> > + * region. While BAR1 is the default peer scratchpad BAR, an NTB could have
> > + * other BARs for peer scratchpad (because of 64-bit BARs or reserved
> > BARs).
> > + * This function can get the exact BAR used for peer scratchpad from
> > + * epf_ntb_bar[BAR_PEER_SPAD].
> > + *
> > + * Since HOST2's peer scratchpad is also HOST1's self scratchpad, this
> > function
> > + * gets the address of peer scratchpad from
> > + * peer_ntb_epc->epf_ntb_bar[BAR_CONFIG].
> > + */
> > +static void epf_ntb_peer_spad_bar_clear(struct epf_ntb_epc *ntb_epc)
> > +{
> > + struct pci_epf_bar *epf_bar;
> > + enum pci_barno barno;
> > + struct pci_epc *epc;
> > + u8 func_no;
> > +
> > + epc = ntb_epc->epc;
> > + func_no = ntb_epc->func_no;
> > + barno = ntb_epc->epf_ntb_bar[BAR_PEER_SPAD];
> > + epf_bar = &ntb_epc->epf_bar[barno];
> > + pci_epc_clear_bar(epc, func_no, epf_bar);
> > +}
> > +
> > +/**
> > + * epf_ntb_peer_spad_bar_set() - Set peer scratchpad BAR
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + *
> > + *+-----------------+------->+------------------+
> > +-----------------+
> > + *| BAR0 | | CONFIG REGION | | BAR0
> > |
> > + *+-----------------+----+
> > +------------------+<-------+-----------------+
> > + *| BAR1 | | |SCRATCHPAD REGION | | BAR1
> > |
> > + *+-----------------+
> > +-->+------------------+<-------+-----------------+
> > + *| BAR2 | Local Memory | BAR2
> > |
> > + *+-----------------+
> > +-----------------+
> > + *| BAR3 | | BAR3
> > |
> > + *+-----------------+
> > +-----------------+
> > + *| BAR4 | | BAR4
> > |
> > + *+-----------------+
> > +-----------------+
> > + *| BAR5 | | BAR5
> > |
> > + *+-----------------+
> > +-----------------+
> > + * EP CONTROLLER 1 EP CONTROLLER 2
> > + *
> > + * Set BAR1 of EP CONTROLLER 2 which contains the HOST2's peer scratchpad
> > + * region. While BAR1 is the default peer scratchpad BAR, an NTB could have
> > + * other BARs for peer scratchpad (because of 64-bit BARs or reserved
> > BARs).
> > + * This function can get the exact BAR used for peer scratchpad from
> > + * epf_ntb_bar[BAR_PEER_SPAD].
> > + *
> > + * Since HOST2's peer scratchpad is also HOST1's self scratchpad, this
> > function
> > + * gets the address of peer scratchpad from
> > + * peer_ntb_epc->epf_ntb_bar[BAR_CONFIG].
> > + */
> > +static int epf_ntb_peer_spad_bar_set(struct epf_ntb *ntb,
> > + enum pci_epc_interface_type type)
> > +{
> > + struct epf_ntb_epc *peer_ntb_epc, *ntb_epc;
> > + struct pci_epf_bar *peer_epf_bar, *epf_bar;
> > + enum pci_barno peer_barno, barno;
> > + u32 peer_spad_offset;
> > + struct pci_epc *epc;
> > + struct device *dev;
> > + u8 func_no;
> > + int ret;
> > +
> > + dev = &ntb->epf->dev;
> > +
> > + peer_ntb_epc = ntb->epc[!type];
> > + peer_barno = peer_ntb_epc->epf_ntb_bar[BAR_CONFIG];
> > + peer_epf_bar = &peer_ntb_epc->epf_bar[peer_barno];
> > +
> > + ntb_epc = ntb->epc[type];
> > + barno = ntb_epc->epf_ntb_bar[BAR_PEER_SPAD];
> > + epf_bar = &ntb_epc->epf_bar[barno];
> > + func_no = ntb_epc->func_no;
> > + epc = ntb_epc->epc;
> > +
> > + peer_spad_offset = peer_ntb_epc->reg->spad_offset;
> > + epf_bar->phys_addr = peer_epf_bar->phys_addr + peer_spad_offset;
> > + epf_bar->size = peer_ntb_epc->spad_size;
> > + epf_bar->barno = barno;
> > + epf_bar->flags = PCI_BASE_ADDRESS_MEM_TYPE_32;
> > +
> > + ret = pci_epc_set_bar(epc, func_no, epf_bar);
> > + if (ret) {
> > + dev_err(dev, "%s intf: peer SPAD BAR set failed\n",
> > + pci_epc_interface_string(type));
> > + return ret;
> > + }
> > +
> > + return 0;
> > +}
> > +
> > +/**
> > + * epf_ntb_config_sspad_bar_clear() - Clear Config + Self scratchpad BAR
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + *
> > + * +-----------------+------->+------------------+
> > +-----------------+
> > + * | BAR0 | | CONFIG REGION | | BAR0
> > |
> > + * +-----------------+----+
> > +------------------+<-------+-----------------+
> > + * | BAR1 | | |SCRATCHPAD REGION | | BAR1
> > |
> > + * +-----------------+
> > +-->+------------------+<-------+-----------------+
> > + * | BAR2 | Local Memory | BAR2
> > |
> > + * +-----------------+
> > +-----------------+
> > + * | BAR3 | | BAR3
> > |
> > + * +-----------------+
> > +-----------------+
> > + * | BAR4 | | BAR4
> > |
> > + * +-----------------+
> > +-----------------+
> > + * | BAR5 | | BAR5
> > |
> > + * +-----------------+
> > +-----------------+
> > + * EP CONTROLLER 1 EP CONTROLLER 2
> > + *
> > + * Clear BAR0 of EP CONTROLLER 1 which contains the HOST1's config and
> > + * self scratchpad region (removes inbound ATU configuration). While BAR0
> > is
> > + * the default self scratchpad BAR, an NTB could have other BARs for self
> > + * scratchpad (because of reserved BARs). This function can get the exact
> > BAR
> > + * used for self scratchpad from epf_ntb_bar[BAR_CONFIG].
> > + *
> > + * Please note the self scratchpad region and config region is combined to
> > + * a single region and mapped using the same BAR. Also note HOST2's peer
> > + * scratchpad is HOST1's self scratchpad.
> > + */
> > +static void epf_ntb_config_sspad_bar_clear(struct epf_ntb_epc *ntb_epc)
> > +{
> > + struct pci_epf_bar *epf_bar;
> > + enum pci_barno barno;
> > + struct pci_epc *epc;
> > + u8 func_no;
> > +
> > + epc = ntb_epc->epc;
> > + func_no = ntb_epc->func_no;
> > + barno = ntb_epc->epf_ntb_bar[BAR_CONFIG];
> > + epf_bar = &ntb_epc->epf_bar[barno];
> > + pci_epc_clear_bar(epc, func_no, epf_bar);
> > +}
> > +
> > +/**
> > + * epf_ntb_config_sspad_bar_set() - Set Config + Self scratchpad BAR
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + *
> > + * +-----------------+------->+------------------+
> > +-----------------+
> > + * | BAR0 | | CONFIG REGION | | BAR0
> > |
> > + * +-----------------+----+
> > +------------------+<-------+-----------------+
> > + * | BAR1 | | |SCRATCHPAD REGION | | BAR1
> > |
> > + * +-----------------+
> > +-->+------------------+<-------+-----------------+
> > + * | BAR2 | Local Memory | BAR2
> > |
> > + * +-----------------+
> > +-----------------+
> > + * | BAR3 | | BAR3
> > |
> > + * +-----------------+
> > +-----------------+
> > + * | BAR4 | | BAR4
> > |
> > + * +-----------------+
> > +-----------------+
> > + * | BAR5 | | BAR5
> > |
> > + * +-----------------+
> > +-----------------+
> > + * EP CONTROLLER 1 EP CONTROLLER 2
> > + *
> > + * Map BAR0 of EP CONTROLLER 1 which contains the HOST1's config and
> > + * self scratchpad region. While BAR0 is the default self scratchpad BAR,
> > an
> > + * NTB could have other BARs for self scratchpad (because of reserved
> > BARs).
> > + * This function can get the exact BAR used for self scratchpad from
> > + * epf_ntb_bar[BAR_CONFIG].
> > + *
> > + * Please note the self scratchpad region and config region is combined to
> > + * a single region and mapped using the same BAR. Also note HOST2's peer
> > + * scratchpad is HOST1's self scratchpad.
> > + */
> > +static int epf_ntb_config_sspad_bar_set(struct epf_ntb_epc *ntb_epc)
> > +{
> > + struct pci_epf_bar *epf_bar;
> > + enum pci_barno barno;
> > + struct epf_ntb *ntb;
> > + struct pci_epc *epc;
> > + struct device *dev;
> > + u8 func_no;
> > + int ret;
> > +
> > + ntb = ntb_epc->epf_ntb;
> > + dev = &ntb->epf->dev;
> > +
> > + epc = ntb_epc->epc;
> > + func_no = ntb_epc->func_no;
> > + barno = ntb_epc->epf_ntb_bar[BAR_CONFIG];
> > + epf_bar = &ntb_epc->epf_bar[barno];
> > +
> > + ret = pci_epc_set_bar(epc, func_no, epf_bar);
> > + if (ret) {
> > + dev_err(dev, "%s inft: Config/Status/SPAD BAR set failed\n",
> > + pci_epc_interface_string(ntb_epc->type));
> > + return ret;
> > + }
> > +
> > + return 0;
> > +}
> > +
> > +/**
> > + * epf_ntb_config_spad_bar_free() - Free the physical memory associated
> > with
> > + * config + scratchpad region
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + *
> > + * +-----------------+------->+------------------+
> > +-----------------+
> > + * | BAR0 | | CONFIG REGION | | BAR0
> > |
> > + * +-----------------+----+
> > +------------------+<-------+-----------------+
> > + * | BAR1 | | |SCRATCHPAD REGION | | BAR1
> > |
> > + * +-----------------+
> > +-->+------------------+<-------+-----------------+
> > + * | BAR2 | Local Memory | BAR2
> > |
> > + * +-----------------+
> > +-----------------+
> > + * | BAR3 | | BAR3
> > |
> > + * +-----------------+
> > +-----------------+
> > + * | BAR4 | | BAR4
> > |
> > + * +-----------------+
> > +-----------------+
> > + * | BAR5 | | BAR5
> > |
> > + * +-----------------+
> > +-----------------+
> > + * EP CONTROLLER 1 EP CONTROLLER 2
> > + *
> > + * Free the Local Memory mentioned in the above diagram. After invoking
> > this
> > + * function, any of config + self scratchpad region of HOST1 or peer
> > scratchpad
> > + * region of HOST2 should not be accessed.
> > + */
> > +static void epf_ntb_config_spad_bar_free(struct epf_ntb *ntb)
> > +{
> > + enum pci_epc_interface_type type;
> > + struct epf_ntb_epc *ntb_epc;
> > + enum pci_barno barno;
> > + struct pci_epf *epf;
> > +
> > + epf = ntb->epf;
> > + for (type = PRIMARY_INTERFACE; type <= SECONDARY_INTERFACE; type++) {
> > + ntb_epc = ntb->epc[type];
> > + barno = ntb_epc->epf_ntb_bar[BAR_CONFIG];
> > + if (ntb_epc->reg)
> > + pci_epf_free_space(epf, ntb_epc->reg, barno, type);
> > + }
> > +}
> > +
> > +/**
> > + * epf_ntb_config_spad_bar_alloc() - Allocate memory for config +
> > scratchpad
> > + * region
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @type: PRIMARY interface or SECONDARY interface
> > + *
> > + * +-----------------+------->+------------------+
> > +-----------------+
> > + * | BAR0 | | CONFIG REGION | | BAR0
> > |
> > + * +-----------------+----+
> > +------------------+<-------+-----------------+
> > + * | BAR1 | | |SCRATCHPAD REGION | | BAR1
> > |
> > + * +-----------------+
> > +-->+------------------+<-------+-----------------+
> > + * | BAR2 | Local Memory | BAR2
> > |
> > + * +-----------------+
> > +-----------------+
> > + * | BAR3 | | BAR3
> > |
> > + * +-----------------+
> > +-----------------+
> > + * | BAR4 | | BAR4
> > |
> > + * +-----------------+
> > +-----------------+
> > + * | BAR5 | | BAR5
> > |
> > + * +-----------------+
> > +-----------------+
> > + * EP CONTROLLER 1 EP CONTROLLER 2
> > + *
> > + * Allocate the Local Memory mentioned in the above diagram. The size of
> > + * CONFIG REGION is sizeof(struct epf_ntb_ctrl) and size of SCRATCHPAD
> > REGION
> > + * is obtained from "spad-count" configfs entry.
> > + *
> > + * The size of both config region and scratchpad region has to be aligned,
> > + * since the scratchpad region will also be mapped as PEER SCRATCHPAD of
> > + * other host using a separate BAR.
> > + */
> > +static int epf_ntb_config_spad_bar_alloc(struct epf_ntb *ntb,
> > + enum pci_epc_interface_type type)
> > +{
> > + const struct pci_epc_features *peer_epc_features, *epc_features;
> > + struct epf_ntb_epc *peer_ntb_epc, *ntb_epc;
> > + size_t msix_table_size, pba_size, align;
> > + enum pci_barno peer_barno, barno;
> > + struct epf_ntb_ctrl *ctrl;
> > + u32 spad_size, ctrl_size;
> > + u64 size, peer_size;
> > + struct pci_epf *epf;
> > + struct device *dev;
> > + bool msix_capable;
> > + u32 spad_count;
> > + void *base;
> > +
> > + epf = ntb->epf;
> > + dev = &epf->dev;
> > + ntb_epc = ntb->epc[type];
> > +
> > + epc_features = ntb_epc->epc_features;
> > + barno = ntb_epc->epf_ntb_bar[BAR_CONFIG];
> > + size = epc_features->bar_fixed_size[barno];
> > + align = epc_features->align;
> > +
> > + peer_ntb_epc = ntb->epc[!type];
> > + peer_epc_features = peer_ntb_epc->epc_features;
> > + peer_barno = ntb_epc->epf_ntb_bar[BAR_PEER_SPAD];
> > + peer_size = peer_epc_features->bar_fixed_size[peer_barno];
> > +
> > + /* Check if epc_features is populated incorrectly */
> > + if ((!IS_ALIGNED(size, align)))
> > + return -EINVAL;
> > +
> > + spad_count = ntb->spad_count;
> > +
> > + ctrl_size = sizeof(struct epf_ntb_ctrl);
> > + spad_size = spad_count * 4;
> > +
> > + msix_capable = epc_features->msix_capable;
> > + if (msix_capable) {
> > + msix_table_size = PCI_MSIX_ENTRY_SIZE * ntb->db_count;
> > + ctrl_size = ALIGN(ctrl_size, 8);
> > + ntb_epc->msix_table_offset = ctrl_size;
> > + ntb_epc->msix_bar = barno;
> > + /* Align to QWORD or 8 Bytes */
> > + pba_size = ALIGN(DIV_ROUND_UP(ntb->db_count, 8), 8);
> > + ctrl_size = ctrl_size + msix_table_size + pba_size;
> > + }
> > +
> > + if (!align) {
> > + ctrl_size = roundup_pow_of_two(ctrl_size);
> > + spad_size = roundup_pow_of_two(spad_size);
> > + } else {
> > + ctrl_size = ALIGN(ctrl_size, align);
> > + spad_size = ALIGN(spad_size, align);
> > + }
> > +
> > + if (peer_size) {
> > + if (peer_size < spad_size)
> > + spad_count = peer_size / 4;
> > + spad_size = peer_size;
> > + }
> > +
> > + /*
> > + * In order to make sure SPAD offset is aligned to its size,
> > + * expand control region size to the size of SPAD if SPAD size
> > + * is greater than control region size.
> > + */
> > + if (spad_size > ctrl_size)
> > + ctrl_size = spad_size;
> > +
> > + if (!size)
> > + size = ctrl_size + spad_size;
> > + else if (size < ctrl_size + spad_size)
> > + return -EINVAL;
> > +
> > + base = pci_epf_alloc_space(epf, size, barno, align, type);
> > + if (!base) {
> > + dev_err(dev, "%s intf: Config/Status/SPAD alloc region fail\n",
> > + pci_epc_interface_string(type));
> > + return -ENOMEM;
> > + }
> > +
> > + ntb_epc->reg = base;
> > +
> > + ctrl = ntb_epc->reg;
> > + ctrl->spad_offset = ctrl_size;
> > + ctrl->spad_count = spad_count;
> > + ctrl->num_mws = ntb->num_mws;
> > + ctrl->db_entry_size = align ? align : 4;
> > + ntb_epc->spad_size = spad_size;
> > +
> > + return 0;
> > +}
> > +
> > +/**
> > + * epf_ntb_config_spad_bar_alloc_interface() - Allocate memory for config +
> > + * scratchpad region for each of PRIMARY and SECONDARY interface
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + *
> > + * Wrapper for epf_ntb_config_spad_bar_alloc() which allocates memory for
> > + * config + scratchpad region for a specific interface
> > + */
> > +static int epf_ntb_config_spad_bar_alloc_interface(struct epf_ntb *ntb)
> > +{
> > + enum pci_epc_interface_type type;
> > + struct device *dev;
> > + int ret;
> > +
> > + dev = &ntb->epf->dev;
> > +
> > + for (type = PRIMARY_INTERFACE; type <= SECONDARY_INTERFACE; type++) {
> > + ret = epf_ntb_config_spad_bar_alloc(ntb, type);
> > + if (ret) {
> > + dev_err(dev, "%s intf: Config/SPAD BAR alloc failed\n",
> > + pci_epc_interface_string(type));
> > + return ret;
> > + }
> > + }
> > +
> > + return 0;
> > +}
> > +
> > +/**
> > + * epf_ntb_free_peer_mem() - Free memory allocated in peers outbound
> > address
> > + * space
> > + * @ntb_epc: EPC associated with one of the HOST which holds peers outbound
> > + * address regions
> > + *
> > + * +-----------------+
> > +---->+----------------+-----------+-----------------+
> > + * | BAR0 | | | Doorbell 1 +-----------> MSI|X
> > ADDRESS 1 |
> > + * +-----------------+ | +----------------+
> > +-----------------+
> > + * | BAR1 | | | Doorbell 2 +---------+ |
> > |
> > + * +-----------------+----+ +----------------+ | |
> > |
> > + * | BAR2 | | Doorbell 3 +-------+ |
> > +-----------------+
> > + * +-----------------+----+ +----------------+ | +-> MSI|X
> > ADDRESS 2 |
> > + * | BAR3 | | | Doorbell 4 +-----+ |
> > +-----------------+
> > + * +-----------------+ | |----------------+ | | |
> > |
> > + * | BAR4 | | | | | |
> > +-----------------+
> > + * +-----------------+ | | MW1 +---+ | +-->+ MSI|X
> > ADDRESS 3||
> > + * | BAR5 | | | | | |
> > +-----------------+
> > + * +-----------------+ +---->-----------------+ | | |
> > |
> > + * EP CONTROLLER 1 | | | |
> > +-----------------+
> > + * | | | +---->+ MSI|X
> > ADDRESS 4 |
> > + * +----------------+ |
> > +-----------------+
> > + * (A) EP CONTROLLER 2 | |
> > |
> > + * (OB SPACE) | |
> > |
> > + * +-------> MW1
> > |
> > + * |
> > |
> > + * |
> > |
> > + * (B)
> > +-----------------+
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + *
> > +-----------------+
> > + * PCI Address
> > Space
> > + * (Managed by
> > HOST2)
> > + *
> > + * Free memory allocated in EP CONTROLLER 2 (OB SPACE) in the above
> > diagram.
> > + * It'll free Doorbell 1, Doorbell 2, Doorbell 3, Doorbell 4, MW1 (and
> > MW2, MW3,
> > + * MW4).
> > + */
> > +static void epf_ntb_free_peer_mem(struct epf_ntb_epc *ntb_epc)
> > +{
> > + struct pci_epf_bar *epf_bar;
> > + void __iomem *mw_addr;
> > + phys_addr_t phys_addr;
> > + enum epf_ntb_bar bar;
> > + enum pci_barno barno;
> > + struct pci_epc *epc;
> > + size_t size;
> > +
> > + epc = ntb_epc->epc;
> > +
> > + for (bar = BAR_DB_MW1; bar < BAR_MW4; bar++) {
> > + barno = ntb_epc->epf_ntb_bar[bar];
> > + mw_addr = ntb_epc->mw_addr[barno];
> > + epf_bar = &ntb_epc->epf_bar[barno];
> > + phys_addr = epf_bar->phys_addr;
> > + size = epf_bar->size;
> > + if (mw_addr) {
> > + pci_epc_mem_free_addr(epc, phys_addr, mw_addr, size);
> > + ntb_epc->mw_addr[barno] = NULL;
> > + }
> > + }
> > +}
> > +
> > +/**
> > + * epf_ntb_db_mw_bar_clear() - Clear doorbell and memory BAR
> > + * @ntb_epc: EPC associated with one of the HOST which holds peer's
> > outbound
> > + * address
> > + *
> > + * +-----------------+
> > +---->+----------------+-----------+-----------------+
> > + * | BAR0 | | | Doorbell 1 +-----------> MSI|X
> > ADDRESS 1 |
> > + * +-----------------+ | +----------------+
> > +-----------------+
> > + * | BAR1 | | | Doorbell 2 +---------+ |
> > |
> > + * +-----------------+----+ +----------------+ | |
> > |
> > + * | BAR2 | | Doorbell 3 +-------+ |
> > +-----------------+
> > + * +-----------------+----+ +----------------+ | +-> MSI|X
> > ADDRESS 2 |
> > + * | BAR3 | | | Doorbell 4 +-----+ |
> > +-----------------+
> > + * +-----------------+ | |----------------+ | | |
> > |
> > + * | BAR4 | | | | | |
> > +-----------------+
> > + * +-----------------+ | | MW1 +---+ | +-->+ MSI|X
> > ADDRESS 3||
> > + * | BAR5 | | | | | |
> > +-----------------+
> > + * +-----------------+ +---->-----------------+ | | |
> > |
> > + * EP CONTROLLER 1 | | | |
> > +-----------------+
> > + * | | | +---->+ MSI|X
> > ADDRESS 4 |
> > + * +----------------+ |
> > +-----------------+
> > + * (A) EP CONTROLLER 2 | |
> > |
> > + * (OB SPACE) | |
> > |
> > + * +-------> MW1
> > |
> > + * |
> > |
> > + * |
> > |
> > + * (B)
> > +-----------------+
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + *
> > +-----------------+
> > + * PCI Address
> > Space
> > + * (Managed by
> > HOST2)
> > + *
> > + * Clear doorbell and memory BARs (remove inbound ATU configuration). In
> > the above
> > + * diagram it clears BAR2 TO BAR5 of EP CONTROLLER 1 (Doorbell BAR, MW1
> > BAR, MW2
> > + * BAR, MW3 BAR and MW4 BAR).
> > + */
> > +static void epf_ntb_db_mw_bar_clear(struct epf_ntb_epc *ntb_epc)
> > +{
> > + struct pci_epf_bar *epf_bar;
> > + enum epf_ntb_bar bar;
> > + enum pci_barno barno;
> > + struct pci_epc *epc;
> > + u8 func_no;
> > +
> > + epc = ntb_epc->epc;
> > +
> > + func_no = ntb_epc->func_no;
> > +
> > + for (bar = BAR_DB_MW1; bar < BAR_MW4; bar++) {
> > + barno = ntb_epc->epf_ntb_bar[bar];
> > + epf_bar = &ntb_epc->epf_bar[barno];
> > + pci_epc_clear_bar(epc, func_no, epf_bar);
> > + }
> > +}
> > +
> > +/**
> > + * epf_ntb_db_mw_bar_cleanup() - Clear doorbell/memory BAR and free memory
> > + * allocated in peers outbound address space
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @type: PRIMARY interface or SECONDARY interface
> > + *
> > + * Wrapper for epf_ntb_db_mw_bar_clear() to clear HOST1's BAR and
> > + * epf_ntb_free_peer_mem() which frees up HOST2 outbound memory.
> > + */
> > +static void epf_ntb_db_mw_bar_cleanup(struct epf_ntb *ntb,
> > + enum pci_epc_interface_type type)
> > +{
> > + struct epf_ntb_epc *peer_ntb_epc, *ntb_epc;
> > +
> > + ntb_epc = ntb->epc[type];
> > + peer_ntb_epc = ntb->epc[!type];
> > +
> > + epf_ntb_db_mw_bar_clear(ntb_epc);
> > + epf_ntb_free_peer_mem(peer_ntb_epc);
> > +}
> > +
> > +/**
> > + * epf_ntb_configure_interrupt() - Configure MSI/MSI-X capaiblity
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @type: PRIMARY interface or SECONDARY interface
> > + *
> > + * Configure MSI/MSI-X capability for each interface with number of
> > + * interrupts equal to "db_count" configfs entry.
> > + */
> > +static int epf_ntb_configure_interrupt(struct epf_ntb *ntb,
> > + enum pci_epc_interface_type type)
> > +{
> > + const struct pci_epc_features *epc_features;
> > + bool msix_capable, msi_capable;
> > + struct epf_ntb_epc *ntb_epc;
> > + struct pci_epc *epc;
> > + struct device *dev;
> > + u32 db_count;
> > + u8 func_no;
> > + int ret;
> > +
> > + ntb_epc = ntb->epc[type];
> > + dev = &ntb->epf->dev;
> > +
> > + epc_features = ntb_epc->epc_features;
> > + msix_capable = epc_features->msix_capable;
> > + msi_capable = epc_features->msi_capable;
> > +
> > + if (!(msix_capable || msi_capable)) {
> > + dev_err(dev, "MSI or MSI-X is required for doorbell\n");
> > + return -EINVAL;
> > + }
> > +
> > + func_no = ntb_epc->func_no;
> > +
> > + db_count = ntb->db_count;
> > + if (db_count > MAX_DB_COUNT) {
> > + dev_err(dev, "DB count cannot be more than %d\n", MAX_DB_COUNT);
> > + return -EINVAL;
> > + }
> > +
> > + ntb->db_count = db_count;
> > + epc = ntb_epc->epc;
> > +
> > + if (msi_capable) {
> > + ret = pci_epc_set_msi(epc, func_no, db_count);
> > + if (ret) {
> > + dev_err(dev, "%s intf: MSI configuration failed\n",
> > + pci_epc_interface_string(type));
> > + return ret;
> > + }
> > + }
> > +
> > + if (msix_capable) {
> > + ret = pci_epc_set_msix(epc, func_no, db_count,
> > + ntb_epc->msix_bar,
> > + ntb_epc->msix_table_offset);
> > + if (ret) {
> > + dev_err(dev, "MSI configuration failed\n");
> > + return ret;
> > + }
> > + }
> > +
> > + return 0;
> > +}
> > +
> > +/**
> > + * epf_ntb_alloc_peer_mem() - Allocate memory in peer's outbound address
> > space
> > + * @ntb_epc: EPC associated with one of the HOST whose BAR holds peer's
> > outbound
> > + * address
> > + * @bar: BAR of @ntb_epc in for which memory has to be allocated (could be
> > + * BAR_DB_MW1, BAR_MW2, BAR_MW3, BAR_MW4)
> > + * @peer_ntb_epc: EPC associated with HOST whose outbound address space is
> > + * used by @ntb_epc
> > + * @size: Size of the address region that has to be allocated in peers OB
> > SPACE
> > + *
> > + *
> > + * +-----------------+
> > +---->+----------------+-----------+-----------------+
> > + * | BAR0 | | | Doorbell 1 +-----------> MSI|X
> > ADDRESS 1 |
> > + * +-----------------+ | +----------------+
> > +-----------------+
> > + * | BAR1 | | | Doorbell 2 +---------+ |
> > |
> > + * +-----------------+----+ +----------------+ | |
> > |
> > + * | BAR2 | | Doorbell 3 +-------+ |
> > +-----------------+
> > + * +-----------------+----+ +----------------+ | +-> MSI|X
> > ADDRESS 2 |
> > + * | BAR3 | | | Doorbell 4 +-----+ |
> > +-----------------+
> > + * +-----------------+ | |----------------+ | | |
> > |
> > + * | BAR4 | | | | | |
> > +-----------------+
> > + * +-----------------+ | | MW1 +---+ | +-->+ MSI|X
> > ADDRESS 3||
> > + * | BAR5 | | | | | |
> > +-----------------+
> > + * +-----------------+ +---->-----------------+ | | |
> > |
> > + * EP CONTROLLER 1 | | | |
> > +-----------------+
> > + * | | | +---->+ MSI|X
> > ADDRESS 4 |
> > + * +----------------+ |
> > +-----------------+
> > + * (A) EP CONTROLLER 2 | |
> > |
> > + * (OB SPACE) | |
> > |
> > + * +-------> MW1
> > |
> > + * |
> > |
> > + * |
> > |
> > + * (B)
> > +-----------------+
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + * |
> > |
> > + *
> > +-----------------+
> > + * PCI Address
> > Space
> > + * (Managed by
> > HOST2)
> > + *
> > + * Allocate memory in OB space of EP CONTROLLER 2 in the above diagram.
> > Allocate
> > + * for Doorbell 1, Doorbell 2, Doorbell 3, Doorbell 4, MW1 (and MW2, MW3,
> > MW4).
> > + */
> > +static int epf_ntb_alloc_peer_mem(struct device *dev,
> > + struct epf_ntb_epc *ntb_epc,
> > + enum epf_ntb_bar bar,
> > + struct epf_ntb_epc *peer_ntb_epc,
> > + size_t size)
> > +{
> > + const struct pci_epc_features *epc_features;
> > + struct pci_epf_bar *epf_bar;
> > + struct pci_epc *peer_epc;
> > + phys_addr_t phys_addr;
> > + void __iomem *mw_addr;
> > + enum pci_barno barno;
> > + size_t align;
> > +
> > + epc_features = ntb_epc->epc_features;
> > + align = epc_features->align;
> > +
> > + if (size < 128)
> > + size = 128;
> > +
> > + if (align)
> > + size = ALIGN(size, align);
> > + else
> > + size = roundup_pow_of_two(size);
> > +
> > + peer_epc = peer_ntb_epc->epc;
> > + mw_addr = pci_epc_mem_alloc_addr(peer_epc, &phys_addr, size);
> > + if (!mw_addr) {
> > + dev_err(dev, "%s intf: Failed to allocate OB address\n",
> > + pci_epc_interface_string(peer_ntb_epc->type));
> > + return -ENOMEM;
> > + }
> > +
> > + barno = ntb_epc->epf_ntb_bar[bar];
> > + epf_bar = &ntb_epc->epf_bar[barno];
> > + ntb_epc->mw_addr[barno] = mw_addr;
> > +
> > + epf_bar->phys_addr = phys_addr;
> > + epf_bar->size = size;
> > + epf_bar->barno = barno;
> > + epf_bar->flags = PCI_BASE_ADDRESS_MEM_TYPE_32;
> > +
> > + return 0;
> > +}
> > +
> > +/**
> > + * epf_ntb_db_mw_bar_init() - Configure Doorbell and Memory window BARs
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @type: PRIMARY interface or SECONDARY interface
> > + *
> > + * Wrapper for epf_ntb_alloc_peer_mem() and pci_epc_set_bar() that
> > allocates
> > + * memory in OB address space of HOST2 and configures BAR of HOST1
> > + */
> > +static int epf_ntb_db_mw_bar_init(struct epf_ntb *ntb,
> > + enum pci_epc_interface_type type)
> > +{
> > + const struct pci_epc_features *epc_features;
> > + struct epf_ntb_epc *peer_ntb_epc, *ntb_epc;
> > + struct pci_epf_bar *epf_bar;
> > + struct epf_ntb_ctrl *ctrl;
> > + u32 num_mws, db_count;
> > + enum epf_ntb_bar bar;
> > + enum pci_barno barno;
> > + struct pci_epc *epc;
> > + struct device *dev;
> > + size_t align;
> > + int ret, i;
> > + u8 func_no;
> > + u64 size;
> > +
> > + ntb_epc = ntb->epc[type];
> > + peer_ntb_epc = ntb->epc[!type];
> > +
> > + dev = &ntb->epf->dev;
> > + epc_features = ntb_epc->epc_features;
> > + align = epc_features->align;
> > + func_no = ntb_epc->func_no;
> > + epc = ntb_epc->epc;
> > + num_mws = ntb->num_mws;
> > + db_count = ntb->db_count;
> > +
> > + for (bar = BAR_DB_MW1, i = 0; i < num_mws; bar++, i++) {
> > + if (bar == BAR_DB_MW1) {
> > + align = align ? align : 4;
> > + size = db_count * align;
> > + size = ALIGN(size, ntb->mws_size[i]);
> > + ctrl = ntb_epc->reg;
> > + ctrl->mw1_offset = size;
> > + size += ntb->mws_size[i];
> > + } else {
> > + size = ntb->mws_size[i];
> > + }
> > +
> > + ret = epf_ntb_alloc_peer_mem(dev, ntb_epc, bar,
> > + peer_ntb_epc, size);
> > + if (ret) {
> > + dev_err(dev, "%s intf: DoorBell mem alloc failed\n",
> > + pci_epc_interface_string(type));
> > + goto err_alloc_peer_mem;
> > + }
> > +
> > + barno = ntb_epc->epf_ntb_bar[bar];
> > + epf_bar = &ntb_epc->epf_bar[barno];
> > +
> > + ret = pci_epc_set_bar(epc, func_no, epf_bar);
> > + if (ret) {
> > + dev_err(dev, "%s intf: DoorBell BAR set failed\n",
> > + pci_epc_interface_string(type));
> > + goto err_alloc_peer_mem;
> > + }
> > + }
> > +
> > + return 0;
> > +
> > +err_alloc_peer_mem:
> > + epf_ntb_db_mw_bar_cleanup(ntb, type);
> > +
> > + return ret;
> > +}
> > +
> > +/**
> > + * epf_ntb_epc_destroy_interface() - Cleanup NTB EPC interface
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @type: PRIMARY interface or SECONDARY interface
> > + *
> > + * Unbind NTB function device from EPC and relinquish reference to pci_epc
> > + * for each of the interface.
> > + */
> > +static void epf_ntb_epc_destroy_interface(struct epf_ntb *ntb,
> > + enum pci_epc_interface_type type)
> > +{
> > + struct epf_ntb_epc *ntb_epc;
> > + struct pci_epc *epc;
> > + struct pci_epf *epf;
> > +
> > + if (type < 0)
> > + return;
> > +
> > + epf = ntb->epf;
> > + ntb_epc = ntb->epc[type];
> > + if (!ntb_epc)
> > + return;
> > + epc = ntb_epc->epc;
> > + pci_epc_remove_epf(epc, epf, type);
> > + pci_epc_put(epc);
> > +}
> > +
> > +/**
> > + * epf_ntb_epc_destroy() - Cleanup NTB EPC interface
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + *
> > + * Wrapper for epf_ntb_epc_destroy_interface() to cleanup all the NTB
> > interfaces
> > + */
> > +static void epf_ntb_epc_destroy(struct epf_ntb *ntb)
> > +{
> > + enum pci_epc_interface_type type;
> > +
> > + for (type = PRIMARY_INTERFACE; type <= SECONDARY_INTERFACE; type++)
> > + epf_ntb_epc_destroy_interface(ntb, type);
> > +}
> > +
> > +/**
> > + * epf_ntb_epc_create_interface() - Create and initialize NTB EPC interface
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @epc: struct pci_epc to which a particular NTB interface should be
> > associated
> > + * @type: PRIMARY interface or SECONDARY interface
> > + *
> > + * Allocate memory for NTB EPC interface and initialize it.
> > + */
> > +static int epf_ntb_epc_create_interface(struct epf_ntb *ntb,
> > + struct pci_epc *epc,
> > + enum pci_epc_interface_type type)
> > +{
> > + const struct pci_epc_features *epc_features;
> > + struct pci_epf_bar *epf_bar;
> > + struct epf_ntb_epc *ntb_epc;
> > + struct pci_epf *epf;
> > + struct device *dev;
> > + u8 func_no;
> > +
> > + dev = &ntb->epf->dev;
> > +
> > + ntb_epc = devm_kzalloc(dev, sizeof(*ntb_epc), GFP_KERNEL);
> > + if (!ntb_epc)
> > + return -ENOMEM;
> > +
> > + epf = ntb->epf;
> > + if (type == PRIMARY_INTERFACE) {
> > + func_no = epf->func_no;
> > + epf_bar = epf->bar;
> > + } else {
> > + func_no = epf->sec_epc_func_no;
> > + epf_bar = epf->sec_epc_bar;
> > + }
> > +
> > + ntb_epc->linkup = false;
> > + ntb_epc->epc = epc;
> > + ntb_epc->func_no = func_no;
> > + ntb_epc->type = type;
> > + ntb_epc->epf_bar = epf_bar;
> > + ntb_epc->epf_ntb = ntb;
> > +
> > + epc_features = pci_epc_get_features(epc, func_no);
> > + if (!epc_features)
> > + return -EINVAL;
> > + ntb_epc->epc_features = epc_features;
> > +
> > + ntb->epc[type] = ntb_epc;
> > +
> > + return 0;
> > +}
> > +
> > +/**
> > + * epf_ntb_epc_create() - Create and initialize NTB EPC interface
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + *
> > + * Get a reference to EPC device and bind NTB function device to that EPC
> > + * for each of the interface. It is also a wrapper to
> > + * epf_ntb_epc_create_interface() to allocate memory for NTB EPC interface
> > + * and initialize it
> > + */
> > +static int epf_ntb_epc_create(struct epf_ntb *ntb)
> > +{
> > + struct pci_epf *epf;
> > + struct device *dev;
> > + int ret;
> > +
> > + epf = ntb->epf;
> > + dev = &epf->dev;
> > +
> > + ret = epf_ntb_epc_create_interface(ntb, epf->epc, PRIMARY_INTERFACE);
> > + if (ret) {
> > + dev_err(dev, "PRIMARY intf: Fail to create NTB EPC\n");
> > + return ret;
> > + }
> > +
> > + ret = epf_ntb_epc_create_interface(ntb, epf->sec_epc,
> > + SECONDARY_INTERFACE);
> > + if (ret) {
> > + dev_err(dev, "SECONDARY intf: Fail to create NTB EPC\n");
> > + goto err_epc_create;
> > + }
> > +
> > + return 0;
> > +
> > +err_epc_create:
> > + epf_ntb_epc_destroy_interface(ntb, PRIMARY_INTERFACE);
> > +
> > + return ret;
> > +}
> > +
> > +/**
> > + * epf_ntb_init_epc_bar_interface() - Identify BARs to be used for each of
> > + * the NTB constructs (scratchpad region, doorbell, memorywindow)
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @type: PRIMARY interface or SECONDARY interface
> > + *
> > + * Identify the free BARs to be used for each of BAR_CONFIG, BAR_PEER_SPAD,
> > + * BAR_DB_MW1, BAR_MW2, BAR_MW3 and BAR_MW4.
> > + */
> > +static int epf_ntb_init_epc_bar_interface(struct epf_ntb *ntb,
> > + enum pci_epc_interface_type type)
> > +{
> > + const struct pci_epc_features *epc_features;
> > + struct epf_ntb_epc *ntb_epc;
> > + enum pci_barno barno;
> > + enum epf_ntb_bar bar;
> > + struct device *dev;
> > + u32 num_mws;
> > + int i;
> > +
> > + barno = BAR_0;
> > + ntb_epc = ntb->epc[type];
> > + num_mws = ntb->num_mws;
> > + dev = &ntb->epf->dev;
> > + epc_features = ntb_epc->epc_features;
> > +
> > + /* These are required BARs which are mandatory for NTB functionality */
> > + for (bar = BAR_CONFIG; bar <= BAR_DB_MW1; bar++, barno++) {
> > + barno = pci_epc_get_next_free_bar(epc_features, barno);
> > + if (barno < 0) {
> > + dev_err(dev, "%s intf: Fail to get NTB function BAR\n",
> > + pci_epc_interface_string(type));
> > + return barno;
> > + }
> > + ntb_epc->epf_ntb_bar[bar] = barno;
> > + }
> > +
> > + /* These are optional BARs which don't impact NTB functionality */
> > + for (bar = BAR_MW2, i = 1; i < num_mws; bar++, barno++, i++) {
> > + barno = pci_epc_get_next_free_bar(epc_features, barno);
> > + if (barno < 0) {
> > + ntb->num_mws = i;
> > + dev_dbg(dev, "BAR not available for > MW%d\n", i + 1);
> > + }
> > + ntb_epc->epf_ntb_bar[bar] = barno;
> > + }
> > +
> > + return 0;
> > +}
> > +
> > +/**
> > + * epf_ntb_init_epc_bar() - Identify BARs to be used for each of the NTB
> > + * constructs (scratchpad region, doorbell, memorywindow)
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @type: PRIMARY interface or SECONDARY interface
> > + *
> > + * Wrapper to epf_ntb_init_epc_bar_interface() to identify the free BARs
> > + * to be used for each of BAR_CONFIG, BAR_PEER_SPAD, BAR_DB_MW1, BAR_MW2,
> > + * BAR_MW3 and BAR_MW4 for all the interfaces.
> > + */
> > +static int epf_ntb_init_epc_bar(struct epf_ntb *ntb)
> > +{
> > + enum pci_epc_interface_type type;
> > + struct device *dev;
> > + int ret;
> > +
> > + dev = &ntb->epf->dev;
> > + for (type = PRIMARY_INTERFACE; type <= SECONDARY_INTERFACE; type++) {
> > + ret = epf_ntb_init_epc_bar_interface(ntb, type);
> > + if (ret) {
> > + dev_err(dev, "Fail to init EPC bar for %s interface\n",
> > + pci_epc_interface_string(type));
> > + return ret;
> > + }
> > + }
> > +
> > + return 0;
> > +}
> > +
> > +/**
> > + * epf_ntb_epc_init_interface() - Initialize NTB interface
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @type: PRIMARY interface or SECONDARY interface
> > + *
> > + * Wrapper to initialize a particular EPC interface and start the workqueue
> > + * to check for commands from host. This function will write to the
> > + * EP controller HW for configuring it.
> > + */
> > +static int epf_ntb_epc_init_interface(struct epf_ntb *ntb,
> > + enum pci_epc_interface_type type)
> > +{
> > + struct epf_ntb_epc *ntb_epc;
> > + struct pci_epc *epc;
> > + struct pci_epf *epf;
> > + struct device *dev;
> > + u8 func_no;
> > + int ret;
> > +
> > + ntb_epc = ntb->epc[type];
> > + epf = ntb->epf;
> > + dev = &epf->dev;
> > + epc = ntb_epc->epc;
> > + func_no = ntb_epc->func_no;
> > +
> > + ret = epf_ntb_config_sspad_bar_set(ntb->epc[type]);
> > + if (ret) {
> > + dev_err(dev, "%s intf: Config/self SPAD BAR init failed\n",
> > + pci_epc_interface_string(type));
> > + return ret;
> > + }
> > +
> > + ret = epf_ntb_peer_spad_bar_set(ntb, type);
> > + if (ret) {
> > + dev_err(dev, "%s intf: Peer SPAD BAR init failed\n",
> > + pci_epc_interface_string(type));
> > + goto err_peer_spad_bar_init;
> > + }
> > +
> > + ret = epf_ntb_configure_interrupt(ntb, type);
> > + if (ret) {
> > + dev_err(dev, "%s intf: Interrupt configuration failed\n",
> > + pci_epc_interface_string(type));
> > + goto err_peer_spad_bar_init;
> > + }
> > +
> > + ret = epf_ntb_db_mw_bar_init(ntb, type);
> > + if (ret) {
> > + dev_err(dev, "%s intf: DB/MW BAR init failed\n",
> > + pci_epc_interface_string(type));
> > + goto err_db_mw_bar_init;
> > + }
> > +
> > + ret = pci_epc_write_header(epc, func_no, epf->header);
> > + if (ret) {
> > + dev_err(dev, "%s intf: Configuration header write failed\n",
> > + pci_epc_interface_string(type));
> > + goto err_write_header;
> > + }
> > +
> > + INIT_DELAYED_WORK(&ntb->epc[type]->cmd_handler, epf_ntb_cmd_handler);
> > + queue_work(kpcintb_workqueue, &ntb->epc[type]->cmd_handler.work);
> > +
> > + return 0;
> > +
> > +err_write_header:
> > + epf_ntb_db_mw_bar_cleanup(ntb, type);
> > +
> > +err_db_mw_bar_init:
> > + epf_ntb_peer_spad_bar_clear(ntb->epc[type]);
> > +
> > +err_peer_spad_bar_init:
> > + epf_ntb_config_sspad_bar_clear(ntb->epc[type]);
> > +
> > + return ret;
> > +}
> > +
> > +/**
> > + * epf_ntb_epc_cleanup_interface() - Cleanup NTB interface
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + * @type: PRIMARY interface or SECONDARY interface
> > + *
> > + * Wrapper to cleanup a particular NTB interface.
> > + */
> > +static void epf_ntb_epc_cleanup_interface(struct epf_ntb *ntb,
> > + enum pci_epc_interface_type type)
> > +{
> > + struct epf_ntb_epc *ntb_epc;
> > +
> > + if (type < 0)
> > + return;
> > +
> > + ntb_epc = ntb->epc[type];
> > + cancel_delayed_work(&ntb_epc->cmd_handler);
> > + epf_ntb_db_mw_bar_cleanup(ntb, type);
> > + epf_ntb_peer_spad_bar_clear(ntb_epc);
> > + epf_ntb_config_sspad_bar_clear(ntb_epc);
> > +}
> > +
> > +/**
> > + * epf_ntb_epc_cleanup() - Cleanup all NTB interfaces
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + *
> > + * Wrapper to cleanup all NTB interfaces.
> > + */
> > +static void epf_ntb_epc_cleanup(struct epf_ntb *ntb)
> > +{
> > + enum pci_epc_interface_type type;
> > +
> > + for (type = PRIMARY_INTERFACE; type <= SECONDARY_INTERFACE; type++)
> > + epf_ntb_epc_cleanup_interface(ntb, type);
> > +}
> > +
> > +/**
> > + * epf_ntb_epc_init() - Initialize all NTB interfaces
> > + * @ntb: NTB device that facilitates communication between HOST1 and HOST2
> > + *
> > + * Wrapper to initialize all NTB interface and start the workqueue
> > + * to check for commands from host.
> > + */
> > +static int epf_ntb_epc_init(struct epf_ntb *ntb)
> > +{
> > + enum pci_epc_interface_type type;
> > + struct device *dev;
> > + int ret;
> > +
> > + dev = &ntb->epf->dev;
> > +
> > + for (type = PRIMARY_INTERFACE; type <= SECONDARY_INTERFACE; type++) {
> > + ret = epf_ntb_epc_init_interface(ntb, type);
> > + if (ret) {
> > + dev_err(dev, "%s intf: Failed to initialize\n",
> > + pci_epc_interface_string(type));
> > + goto err_init_type;
> > + }
> > + }
> > +
> > + return 0;
> > +
> > +err_init_type:
> > + epf_ntb_epc_cleanup_interface(ntb, type - 1);
> > +
> > + return ret;
> > +}
> > +
> > +/**
> > + * epf_ntb_bind() - Initialize endpoint controller to provide NTB
> > functionality
> > + * @epf: NTB endpoint function device
> > + *
> > + * Initialize both the endpoint controllers associated with NTB function
> > device.
> > + * Invoked when a primary interface or secondary interface is bound to EPC
> > + * device. This function will succeed only when EPC is bound to both the
> > + * interfaces.
> > + */
> > +static int epf_ntb_bind(struct pci_epf *epf)
> > +{
> > + struct epf_ntb *ntb = epf_get_drvdata(epf);
> > + struct device *dev = &epf->dev;
> > + int ret;
> > +
> > + if (!epf->epc) {
> > + dev_dbg(dev, "PRIMARY EPC interface not yet bound\n");
> > + return 0;
> > + }
> > +
> > + if (!epf->sec_epc) {
> > + dev_dbg(dev, "SECONDARY EPC interface not yet bound\n");
> > + return 0;
> > + }
> > +
> > + ret = epf_ntb_epc_create(ntb);
> > + if (ret) {
> > + dev_err(dev, "Failed to create NTB EPC\n");
> > + return ret;
> > + }
> > +
> > + ret = epf_ntb_init_epc_bar(ntb);
> > + if (ret) {
> > + dev_err(dev, "Failed to create NTB EPC\n");
> > + goto err_bar_init;
> > + }
> > +
> > + ret = epf_ntb_config_spad_bar_alloc_interface(ntb);
> > + if (ret) {
> > + dev_err(dev, "Failed to allocate BAR memory\n");
> > + goto err_bar_alloc;
> > + }
> > +
> > + ret = epf_ntb_epc_init(ntb);
> > + if (ret) {
> > + dev_err(dev, "Failed to initialize EPC\n");
> > + goto err_bar_alloc;
> > + }
> > +
> > + epf_set_drvdata(epf, ntb);
> > +
> > + return 0;
> > +
> > +err_bar_alloc:
> > + epf_ntb_config_spad_bar_free(ntb);
> > +
> > +err_bar_init:
> > + epf_ntb_epc_destroy(ntb);
> > +
> > + return ret;
> > +}
> > +
> > +/**
> > + * epf_ntb_unbind() - Cleanup the initialization from epf_ntb_bind()
> > + * @epf: NTB endpoint function device
> > + *
> > + * Cleanup the initialization from epf_ntb_bind()
> > + */
> > +static void epf_ntb_unbind(struct pci_epf *epf)
> > +{
> > + struct epf_ntb *ntb = epf_get_drvdata(epf);
> > +
> > + epf_ntb_epc_cleanup(ntb);
> > + epf_ntb_config_spad_bar_free(ntb);
> > + epf_ntb_epc_destroy(ntb);
> > +}
> > +
> > +#define EPF_NTB_R(_name) \
> > +static ssize_t epf_ntb_##_name##_show(struct config_item *item,
> > \
> > + char *page) \
> > +{ \
> > + struct config_group *group = to_config_group(item); \
> > + struct epf_ntb *ntb = to_epf_ntb(group); \
> > + \
> > + return sprintf(page, "%d\n", ntb->_name); \
> > +}
> > +
> > +#define EPF_NTB_W(_name) \
> > +static ssize_t epf_ntb_##_name##_store(struct config_item *item, \
> > + const char *page, size_t len) \
> > +{ \
> > + struct config_group *group = to_config_group(item); \
> > + struct epf_ntb *ntb = to_epf_ntb(group); \
> > + u32 val; \
> > + int ret; \
> > + \
> > + ret = kstrtou32(page, 0, &val); \
> > + if (ret) \
> > + return ret; \
> > + \
> > + ntb->_name = val; \
> > + \
> > + return len; \
> > +}
> > +
> > +#define EPF_NTB_MW_R(_name)
> > \
> > +static ssize_t epf_ntb_##_name##_show(struct config_item *item,
> > \
> > + char *page) \
> > +{ \
> > + struct config_group *group = to_config_group(item); \
> > + struct epf_ntb *ntb = to_epf_ntb(group); \
> > + int win_no; \
> > + \
> > + sscanf(#_name, "mw%d", &win_no); \
> > + \
> > + return sprintf(page, "%lld\n", ntb->mws_size[win_no - 1]); \
> > +}
> > +
> > +#define EPF_NTB_MW_W(_name)
> > \
> > +static ssize_t epf_ntb_##_name##_store(struct config_item *item, \
> > + const char *page, size_t len) \
> > +{ \
> > + struct config_group *group = to_config_group(item); \
> > + struct epf_ntb *ntb = to_epf_ntb(group); \
> > + struct device *dev = &ntb->epf->dev; \
> > + int win_no; \
> > + u64 val; \
> > + int ret; \
> > + \
> > + ret = kstrtou64(page, 0, &val); \
> > + if (ret) \
> > + return ret; \
> > + \
> > + if (sscanf(#_name, "mw%d", &win_no) != 1) \
> > + return -EINVAL; \
> > + \
> > + if (ntb->num_mws < win_no) { \
> > + dev_err(dev, "Invalid num_nws: %d value\n", ntb->num_mws); \
> > + return -EINVAL; \
> > + } \
> > + \
> > + ntb->mws_size[win_no - 1] = val; \
> > + \
> > + return len; \
> > +}
> > +
> > +static ssize_t epf_ntb_num_mws_store(struct config_item *item,
> > + const char *page, size_t len)
> > +{
> > + struct config_group *group = to_config_group(item);
> > + struct epf_ntb *ntb = to_epf_ntb(group);
> > + u32 val;
> > + int ret;
> > +
> > + ret = kstrtou32(page, 0, &val);
> > + if (ret)
> > + return ret;
> > +
> > + if (val > MAX_MW)
> > + return -EINVAL;
> > +
> > + ntb->num_mws = val;
> > +
> > + return len;
> > +}
> > +
> > +EPF_NTB_R(spad_count)
> > +EPF_NTB_W(spad_count)
> > +EPF_NTB_R(db_count)
> > +EPF_NTB_W(db_count)
> > +EPF_NTB_R(num_mws)
> > +EPF_NTB_MW_R(mw1)
> > +EPF_NTB_MW_W(mw1)
> > +EPF_NTB_MW_R(mw2)
> > +EPF_NTB_MW_W(mw2)
> > +EPF_NTB_MW_R(mw3)
> > +EPF_NTB_MW_W(mw3)
> > +EPF_NTB_MW_R(mw4)
> > +EPF_NTB_MW_W(mw4)
> > +
> > +CONFIGFS_ATTR(epf_ntb_, spad_count);
> > +CONFIGFS_ATTR(epf_ntb_, db_count);
> > +CONFIGFS_ATTR(epf_ntb_, num_mws);
> > +CONFIGFS_ATTR(epf_ntb_, mw1);
> > +CONFIGFS_ATTR(epf_ntb_, mw2);
> > +CONFIGFS_ATTR(epf_ntb_, mw3);
> > +CONFIGFS_ATTR(epf_ntb_, mw4);
> > +
> > +static struct configfs_attribute *epf_ntb_attrs[] = {
> > + &epf_ntb_attr_spad_count,
> > + &epf_ntb_attr_db_count,
> > + &epf_ntb_attr_num_mws,
> > + &epf_ntb_attr_mw1,
> > + &epf_ntb_attr_mw2,
> > + &epf_ntb_attr_mw3,
> > + &epf_ntb_attr_mw4,
> > + NULL,
> > +};
> > +
> > +static const struct config_item_type ntb_group_type = {
> > + .ct_attrs = epf_ntb_attrs,
> > + .ct_owner = THIS_MODULE,
> > +};
> > +
> > +/**
> > + * epf_ntb_add_cfs() - Add configfs directory specific to NTB
> > + * @epf: NTB endpoint function device
> > + *
> > + * Add configfs directory specific to NTB. This directory will hold
> > + * NTB specific properties like db_count, spad_count, num_mws etc.,
> > + */
> > +static struct config_group *epf_ntb_add_cfs(struct pci_epf *epf,
> > + struct config_group *group)
> > +{
> > + struct epf_ntb *ntb = epf_get_drvdata(epf);
> > + struct config_group *ntb_group = &ntb->group;
> > + struct device *dev = &epf->dev;
> > +
> > + config_group_init_type_name(ntb_group, dev_name(dev), &ntb_group_type);
> > +
> > + return ntb_group;
> > +}
> > +
> > +/**
> > + * epf_ntb_probe() - Probe NTB function driver
> > + * @epf: NTB endpoint function device
> > + *
> > + * Probe NTB function driver when endpoint function bus detects a NTB
> > + * endpoint function.
> > + */
> > +static int epf_ntb_probe(struct pci_epf *epf)
> > +{
> > + struct epf_ntb *ntb;
> > + struct device *dev;
> > +
> > + dev = &epf->dev;
> > +
> > + ntb = devm_kzalloc(dev, sizeof(*ntb), GFP_KERNEL);
> > + if (!ntb)
> > + return -ENOMEM;
> > +
> > + epf->header = &epf_ntb_header;
> > + ntb->epf = epf;
> > + epf_set_drvdata(epf, ntb);
> > +
> > + return 0;
> > +}
> > +
> > +static struct pci_epf_ops epf_ntb_ops = {
> > + .bind = epf_ntb_bind,
> > + .unbind = epf_ntb_unbind,
> > + .add_cfs = epf_ntb_add_cfs,
> > +};
> > +
> > +static const struct pci_epf_device_id epf_ntb_ids[] = {
> > + {
> > + .name = "pci_epf_ntb",
> > + },
> > + {},
> > +};
> > +
> > +static struct pci_epf_driver epf_ntb_driver = {
> > + .driver.name = "pci_epf_ntb",
> > + .probe = epf_ntb_probe,
> > + .id_table = epf_ntb_ids,
> > + .ops = &epf_ntb_ops,
> > + .owner = THIS_MODULE,
> > +};
> > +
> > +static int __init epf_ntb_init(void)
> > +{
> > + int ret;
> > +
> > + kpcintb_workqueue = alloc_workqueue("kpcintb", WQ_MEM_RECLAIM |
> > + WQ_HIGHPRI, 0);
> > + ret = pci_epf_register_driver(&epf_ntb_driver);
> > + if (ret) {
> > + destroy_workqueue(kpcintb_workqueue);
> > + pr_err("Failed to register pci epf ntb driver --> %d\n", ret);
> > + return ret;
> > + }
> > +
> > + return 0;
> > +}
> > +module_init(epf_ntb_init);
> > +
> > +static void __exit epf_ntb_exit(void)
> > +{
> > + pci_epf_unregister_driver(&epf_ntb_driver);
> > + destroy_workqueue(kpcintb_workqueue);
> > +}
> > +module_exit(epf_ntb_exit);
> > +
> > +MODULE_DESCRIPTION("PCI EPF NTB DRIVER");
> > +MODULE_AUTHOR("Kishon Vijay Abraham I <kis...@ti.com>");
> > +MODULE_LICENSE("GPL v2");
> >
