blob: 0f1679ebad96babdcf5ba9a92910feaf77e4e22c [file] [log] [blame]
// SPDX-License-Identifier: GPL-2.0 OR BSD-3-Clause
/* Copyright (c) 2021, Microsoft Corporation. */
#include <linux/delay.h>
#include <linux/device.h>
#include <linux/io.h>
#include <linux/mm.h>
#include <net/mana/gdma.h>
#include <net/mana/shm_channel.h>
#define PAGE_FRAME_L48_WIDTH_BYTES 6
#define PAGE_FRAME_L48_WIDTH_BITS (PAGE_FRAME_L48_WIDTH_BYTES * 8)
#define PAGE_FRAME_L48_MASK 0x0000FFFFFFFFFFFF
#define PAGE_FRAME_H4_WIDTH_BITS 4
#define VECTOR_MASK 0xFFFF
#define SHMEM_VF_RESET_STATE ((u32)-1)
#define SMC_MSG_TYPE_ESTABLISH_HWC 1
#define SMC_MSG_TYPE_ESTABLISH_HWC_VERSION 0
#define SMC_MSG_TYPE_DESTROY_HWC 2
#define SMC_MSG_TYPE_DESTROY_HWC_VERSION 0
#define SMC_MSG_DIRECTION_REQUEST 0
#define SMC_MSG_DIRECTION_RESPONSE 1
/* Structures labeled with "HW DATA" are exchanged with the hardware. All of
* them are naturally aligned and hence don't need __packed.
*/
/* Shared memory channel protocol header
*
* msg_type: set on request and response; response matches request.
* msg_version: newer PF writes back older response (matching request)
* older PF acts on latest version known and sets that version in result
* (less than request).
* direction: 0 for request, VF->PF; 1 for response, PF->VF.
* status: 0 on request,
* operation result on response (success = 0, failure = 1 or greater).
* reset_vf: If set on either establish or destroy request, indicates perform
* FLR before/after the operation.
* owner_is_pf: 1 indicates PF owned, 0 indicates VF owned.
*/
union smc_proto_hdr {
u32 as_uint32;
struct {
u8 msg_type : 3;
u8 msg_version : 3;
u8 reserved_1 : 1;
u8 direction : 1;
u8 status;
u8 reserved_2;
u8 reset_vf : 1;
u8 reserved_3 : 6;
u8 owner_is_pf : 1;
};
}; /* HW DATA */
#define SMC_APERTURE_BITS 256
#define SMC_BASIC_UNIT (sizeof(u32))
#define SMC_APERTURE_DWORDS (SMC_APERTURE_BITS / (SMC_BASIC_UNIT * 8))
#define SMC_LAST_DWORD (SMC_APERTURE_DWORDS - 1)
static int mana_smc_poll_register(void __iomem *base, bool reset)
{
void __iomem *ptr = base + SMC_LAST_DWORD * SMC_BASIC_UNIT;
u32 last_dword;
int i;
/* Poll the hardware for the ownership bit. This should be pretty fast,
* but let's do it in a loop just in case the hardware or the PF
* driver are temporarily busy.
*/
for (i = 0; i < 20 * 1000; i++) {
last_dword = readl(ptr);
/* shmem reads as 0xFFFFFFFF in the reset case */
if (reset && last_dword == SHMEM_VF_RESET_STATE)
return 0;
/* If bit_31 is set, the PF currently owns the SMC. */
if (!(last_dword & BIT(31)))
return 0;
usleep_range(1000, 2000);
}
return -ETIMEDOUT;
}
static int mana_smc_read_response(struct shm_channel *sc, u32 msg_type,
u32 msg_version, bool reset_vf)
{
void __iomem *base = sc->base;
union smc_proto_hdr hdr;
int err;
/* Wait for PF to respond. */
err = mana_smc_poll_register(base, reset_vf);
if (err)
return err;
hdr.as_uint32 = readl(base + SMC_LAST_DWORD * SMC_BASIC_UNIT);
if (reset_vf && hdr.as_uint32 == SHMEM_VF_RESET_STATE)
return 0;
/* Validate protocol fields from the PF driver */
if (hdr.msg_type != msg_type || hdr.msg_version > msg_version ||
hdr.direction != SMC_MSG_DIRECTION_RESPONSE) {
dev_err(sc->dev, "Wrong SMC response 0x%x, type=%d, ver=%d\n",
hdr.as_uint32, msg_type, msg_version);
return -EPROTO;
}
/* Validate the operation result */
if (hdr.status != 0) {
dev_err(sc->dev, "SMC operation failed: 0x%x\n", hdr.status);
return -EPROTO;
}
return 0;
}
void mana_smc_init(struct shm_channel *sc, struct device *dev,
void __iomem *base)
{
sc->dev = dev;
sc->base = base;
}
int mana_smc_setup_hwc(struct shm_channel *sc, bool reset_vf, u64 eq_addr,
u64 cq_addr, u64 rq_addr, u64 sq_addr,
u32 eq_msix_index)
{
union smc_proto_hdr *hdr;
u16 all_addr_h4bits = 0;
u16 frame_addr_seq = 0;
u64 frame_addr = 0;
u8 shm_buf[32];
u64 *shmem;
u32 *dword;
u8 *ptr;
int err;
int i;
/* Ensure VF already has possession of shared memory */
err = mana_smc_poll_register(sc->base, false);
if (err) {
dev_err(sc->dev, "Timeout when setting up HWC: %d\n", err);
return err;
}
if (!MANA_PAGE_ALIGNED(eq_addr) || !MANA_PAGE_ALIGNED(cq_addr) ||
!MANA_PAGE_ALIGNED(rq_addr) || !MANA_PAGE_ALIGNED(sq_addr))
return -EINVAL;
if ((eq_msix_index & VECTOR_MASK) != eq_msix_index)
return -EINVAL;
/* Scheme for packing four addresses and extra info into 256 bits.
*
* Addresses must be page frame aligned, so only frame address bits
* are transferred.
*
* 52-bit frame addresses are split into the lower 48 bits and upper
* 4 bits. Lower 48 bits of 4 address are written sequentially from
* the start of the 256-bit shared memory region followed by 16 bits
* containing the upper 4 bits of the 4 addresses in sequence.
*
* A 16 bit EQ vector number fills out the next-to-last 32-bit dword.
*
* The final 32-bit dword is used for protocol control information as
* defined in smc_proto_hdr.
*/
memset(shm_buf, 0, sizeof(shm_buf));
ptr = shm_buf;
/* EQ addr: low 48 bits of frame address */
shmem = (u64 *)ptr;
frame_addr = MANA_PFN(eq_addr);
*shmem = frame_addr & PAGE_FRAME_L48_MASK;
all_addr_h4bits |= (frame_addr >> PAGE_FRAME_L48_WIDTH_BITS) <<
(frame_addr_seq++ * PAGE_FRAME_H4_WIDTH_BITS);
ptr += PAGE_FRAME_L48_WIDTH_BYTES;
/* CQ addr: low 48 bits of frame address */
shmem = (u64 *)ptr;
frame_addr = MANA_PFN(cq_addr);
*shmem = frame_addr & PAGE_FRAME_L48_MASK;
all_addr_h4bits |= (frame_addr >> PAGE_FRAME_L48_WIDTH_BITS) <<
(frame_addr_seq++ * PAGE_FRAME_H4_WIDTH_BITS);
ptr += PAGE_FRAME_L48_WIDTH_BYTES;
/* RQ addr: low 48 bits of frame address */
shmem = (u64 *)ptr;
frame_addr = MANA_PFN(rq_addr);
*shmem = frame_addr & PAGE_FRAME_L48_MASK;
all_addr_h4bits |= (frame_addr >> PAGE_FRAME_L48_WIDTH_BITS) <<
(frame_addr_seq++ * PAGE_FRAME_H4_WIDTH_BITS);
ptr += PAGE_FRAME_L48_WIDTH_BYTES;
/* SQ addr: low 48 bits of frame address */
shmem = (u64 *)ptr;
frame_addr = MANA_PFN(sq_addr);
*shmem = frame_addr & PAGE_FRAME_L48_MASK;
all_addr_h4bits |= (frame_addr >> PAGE_FRAME_L48_WIDTH_BITS) <<
(frame_addr_seq++ * PAGE_FRAME_H4_WIDTH_BITS);
ptr += PAGE_FRAME_L48_WIDTH_BYTES;
/* High 4 bits of the four frame addresses */
*((u16 *)ptr) = all_addr_h4bits;
ptr += sizeof(u16);
/* EQ MSIX vector number */
*((u16 *)ptr) = (u16)eq_msix_index;
ptr += sizeof(u16);
/* 32-bit protocol header in final dword */
*((u32 *)ptr) = 0;
hdr = (union smc_proto_hdr *)ptr;
hdr->msg_type = SMC_MSG_TYPE_ESTABLISH_HWC;
hdr->msg_version = SMC_MSG_TYPE_ESTABLISH_HWC_VERSION;
hdr->direction = SMC_MSG_DIRECTION_REQUEST;
hdr->reset_vf = reset_vf;
/* Write 256-message buffer to shared memory (final 32-bit write
* triggers HW to set possession bit to PF).
*/
dword = (u32 *)shm_buf;
for (i = 0; i < SMC_APERTURE_DWORDS; i++)
writel(*dword++, sc->base + i * SMC_BASIC_UNIT);
/* Read shmem response (polling for VF possession) and validate.
* For setup, waiting for response on shared memory is not strictly
* necessary, since wait occurs later for results to appear in EQE's.
*/
err = mana_smc_read_response(sc, SMC_MSG_TYPE_ESTABLISH_HWC,
SMC_MSG_TYPE_ESTABLISH_HWC_VERSION,
reset_vf);
if (err) {
dev_err(sc->dev, "Error when setting up HWC: %d\n", err);
return err;
}
return 0;
}
int mana_smc_teardown_hwc(struct shm_channel *sc, bool reset_vf)
{
union smc_proto_hdr hdr = {};
int err;
/* Ensure already has possession of shared memory */
err = mana_smc_poll_register(sc->base, false);
if (err) {
dev_err(sc->dev, "Timeout when tearing down HWC\n");
return err;
}
/* Set up protocol header for HWC destroy message */
hdr.msg_type = SMC_MSG_TYPE_DESTROY_HWC;
hdr.msg_version = SMC_MSG_TYPE_DESTROY_HWC_VERSION;
hdr.direction = SMC_MSG_DIRECTION_REQUEST;
hdr.reset_vf = reset_vf;
/* Write message in high 32 bits of 256-bit shared memory, causing HW
* to set possession bit to PF.
*/
writel(hdr.as_uint32, sc->base + SMC_LAST_DWORD * SMC_BASIC_UNIT);
/* Read shmem response (polling for VF possession) and validate.
* For teardown, waiting for response is required to ensure hardware
* invalidates MST entries before software frees memory.
*/
err = mana_smc_read_response(sc, SMC_MSG_TYPE_DESTROY_HWC,
SMC_MSG_TYPE_DESTROY_HWC_VERSION,
reset_vf);
if (err) {
dev_err(sc->dev, "Error when tearing down HWC: %d\n", err);
return err;
}
return 0;
}