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linux/drivers/i3c/master/mipi-i3c-hci/dma.c
Jarkko Nikula 4642f7eddb i3c: mipi-i3c-hci: Round IBI data chunk size to HW supported value 
The dma.c: hci_dma_init() sets the CHUNK_SIZE field in the IBI_SETUP
register incorrectly if the calculated ibi_chunk_sz is not exactly
2^(n+2) bytes, where n is 0..6.

Fix this by rounding the chunk size up to nearest 2^(n+2) bytes.

Signed-off-by: Jarkko Nikula <jarkko.nikula@linux.intel.com>
Link: https://lore.kernel.org/r/20240628131559.502822-4-jarkko.nikula@linux.intel.com
Signed-off-by: Alexandre Belloni <alexandre.belloni@bootlin.com>
2024-07-26 14:21:29 +02:00

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// SPDX-License-Identifier: BSD-3-Clause
/*
* Copyright (c) 2020, MIPI Alliance, Inc.
*
* Author: Nicolas Pitre <npitre@baylibre.com>
*
* Note: The I3C HCI v2.0 spec is still in flux. The IBI support is based on
* v1.x of the spec and v2.0 will likely be split out.
*/
#include <linux/bitfield.h>
#include <linux/device.h>
#include <linux/dma-mapping.h>
#include <linux/errno.h>
#include <linux/i3c/master.h>
#include <linux/io.h>
#include "hci.h"
#include "cmd.h"
#include "ibi.h"
/*
* Software Parameter Values (somewhat arb itrary for now).
* Some of them could be determined at run time eventually.
*/
#define XFER_RINGS 1 /* max: 8 */
#define XFER_RING_ENTRIES 16 /* max: 255 */
#define IBI_RINGS 1 /* max: 8 */
#define IBI_STATUS_RING_ENTRIES 32 /* max: 255 */
#define IBI_CHUNK_CACHELINES 1 /* max: 256 bytes equivalent */
#define IBI_CHUNK_POOL_SIZE 128 /* max: 1023 */
/*
* Ring Header Preamble
*/
#define rhs_reg_read(r) readl(hci->RHS_regs + (RHS_##r))
#define rhs_reg_write(r, v) writel(v, hci->RHS_regs + (RHS_##r))
#define RHS_CONTROL 0x00
#define PREAMBLE_SIZE GENMASK(31, 24) /* Preamble Section Size */
#define HEADER_SIZE GENMASK(23, 16) /* Ring Header Size */
#define MAX_HEADER_COUNT_CAP GENMASK(7, 4) /* HC Max Header Count */
#define MAX_HEADER_COUNT GENMASK(3, 0) /* Driver Max Header Count */
#define RHS_RHn_OFFSET(n) (0x04 + (n)*4)
/*
* Ring Header (Per-Ring Bundle)
*/
#define rh_reg_read(r) readl(rh->regs + (RH_##r))
#define rh_reg_write(r, v) writel(v, rh->regs + (RH_##r))
#define RH_CR_SETUP 0x00 /* Command/Response Ring */
#define CR_XFER_STRUCT_SIZE GENMASK(31, 24)
#define CR_RESP_STRUCT_SIZE GENMASK(23, 16)
#define CR_RING_SIZE GENMASK(8, 0)
#define RH_IBI_SETUP 0x04
#define IBI_STATUS_STRUCT_SIZE GENMASK(31, 24)
#define IBI_STATUS_RING_SIZE GENMASK(23, 16)
#define IBI_DATA_CHUNK_SIZE GENMASK(12, 10)
#define IBI_DATA_CHUNK_COUNT GENMASK(9, 0)
#define RH_CHUNK_CONTROL 0x08
#define RH_INTR_STATUS 0x10
#define RH_INTR_STATUS_ENABLE 0x14
#define RH_INTR_SIGNAL_ENABLE 0x18
#define RH_INTR_FORCE 0x1c
#define INTR_IBI_READY BIT(12)
#define INTR_TRANSFER_COMPLETION BIT(11)
#define INTR_RING_OP BIT(10)
#define INTR_TRANSFER_ERR BIT(9)
#define INTR_WARN_INS_STOP_MODE BIT(7)
#define INTR_IBI_RING_FULL BIT(6)
#define INTR_TRANSFER_ABORT BIT(5)
#define RH_RING_STATUS 0x20
#define RING_STATUS_LOCKED BIT(3)
#define RING_STATUS_ABORTED BIT(2)
#define RING_STATUS_RUNNING BIT(1)
#define RING_STATUS_ENABLED BIT(0)
#define RH_RING_CONTROL 0x24
#define RING_CTRL_ABORT BIT(2)
#define RING_CTRL_RUN_STOP BIT(1)
#define RING_CTRL_ENABLE BIT(0)
#define RH_RING_OPERATION1 0x28
#define RING_OP1_IBI_DEQ_PTR GENMASK(23, 16)
#define RING_OP1_CR_SW_DEQ_PTR GENMASK(15, 8)
#define RING_OP1_CR_ENQ_PTR GENMASK(7, 0)
#define RH_RING_OPERATION2 0x2c
#define RING_OP2_IBI_ENQ_PTR GENMASK(23, 16)
#define RING_OP2_CR_DEQ_PTR GENMASK(7, 0)
#define RH_CMD_RING_BASE_LO 0x30
#define RH_CMD_RING_BASE_HI 0x34
#define RH_RESP_RING_BASE_LO 0x38
#define RH_RESP_RING_BASE_HI 0x3c
#define RH_IBI_STATUS_RING_BASE_LO 0x40
#define RH_IBI_STATUS_RING_BASE_HI 0x44
#define RH_IBI_DATA_RING_BASE_LO 0x48
#define RH_IBI_DATA_RING_BASE_HI 0x4c
#define RH_CMD_RING_SG 0x50 /* Ring Scatter Gather Support */
#define RH_RESP_RING_SG 0x54
#define RH_IBI_STATUS_RING_SG 0x58
#define RH_IBI_DATA_RING_SG 0x5c
#define RING_SG_BLP BIT(31) /* Buffer Vs. List Pointer */
#define RING_SG_LIST_SIZE GENMASK(15, 0)
/*
* Data Buffer Descriptor (in memory)
*/
#define DATA_BUF_BLP BIT(31) /* Buffer Vs. List Pointer */
#define DATA_BUF_IOC BIT(30) /* Interrupt on Completion */
#define DATA_BUF_BLOCK_SIZE GENMASK(15, 0)
struct hci_rh_data {
void __iomem *regs;
void *xfer, *resp, *ibi_status, *ibi_data;
dma_addr_t xfer_dma, resp_dma, ibi_status_dma, ibi_data_dma;
unsigned int xfer_entries, ibi_status_entries, ibi_chunks_total;
unsigned int xfer_struct_sz, resp_struct_sz, ibi_status_sz, ibi_chunk_sz;
unsigned int done_ptr, ibi_chunk_ptr;
struct hci_xfer **src_xfers;
spinlock_t lock;
struct completion op_done;
};
struct hci_rings_data {
unsigned int total;
struct hci_rh_data headers[] __counted_by(total);
};
struct hci_dma_dev_ibi_data {
struct i3c_generic_ibi_pool *pool;
unsigned int max_len;
};
static void hci_dma_cleanup(struct i3c_hci *hci)
{
struct hci_rings_data *rings = hci->io_data;
struct hci_rh_data *rh;
unsigned int i;
if (!rings)
return;
for (i = 0; i < rings->total; i++) {
rh = &rings->headers[i];
rh_reg_write(RING_CONTROL, 0);
rh_reg_write(CR_SETUP, 0);
rh_reg_write(IBI_SETUP, 0);
rh_reg_write(INTR_SIGNAL_ENABLE, 0);
if (rh->xfer)
dma_free_coherent(&hci->master.dev,
rh->xfer_struct_sz * rh->xfer_entries,
rh->xfer, rh->xfer_dma);
if (rh->resp)
dma_free_coherent(&hci->master.dev,
rh->resp_struct_sz * rh->xfer_entries,
rh->resp, rh->resp_dma);
kfree(rh->src_xfers);
if (rh->ibi_status)
dma_free_coherent(&hci->master.dev,
rh->ibi_status_sz * rh->ibi_status_entries,
rh->ibi_status, rh->ibi_status_dma);
if (rh->ibi_data_dma)
dma_unmap_single(&hci->master.dev, rh->ibi_data_dma,
rh->ibi_chunk_sz * rh->ibi_chunks_total,
DMA_FROM_DEVICE);
kfree(rh->ibi_data);
}
rhs_reg_write(CONTROL, 0);
kfree(rings);
hci->io_data = NULL;
}
static int hci_dma_init(struct i3c_hci *hci)
{
struct hci_rings_data *rings;
struct hci_rh_data *rh;
u32 regval;
unsigned int i, nr_rings, xfers_sz, resps_sz;
unsigned int ibi_status_ring_sz, ibi_data_ring_sz;
int ret;
regval = rhs_reg_read(CONTROL);
nr_rings = FIELD_GET(MAX_HEADER_COUNT_CAP, regval);
dev_info(&hci->master.dev, "%d DMA rings available\n", nr_rings);
if (unlikely(nr_rings > 8)) {
dev_err(&hci->master.dev, "number of rings should be <= 8\n");
nr_rings = 8;
}
if (nr_rings > XFER_RINGS)
nr_rings = XFER_RINGS;
rings = kzalloc(struct_size(rings, headers, nr_rings), GFP_KERNEL);
if (!rings)
return -ENOMEM;
hci->io_data = rings;
rings->total = nr_rings;
regval = FIELD_PREP(MAX_HEADER_COUNT, rings->total);
rhs_reg_write(CONTROL, regval);
for (i = 0; i < rings->total; i++) {
u32 offset = rhs_reg_read(RHn_OFFSET(i));
dev_info(&hci->master.dev, "Ring %d at offset %#x\n", i, offset);
ret = -EINVAL;
if (!offset)
goto err_out;
rh = &rings->headers[i];
rh->regs = hci->base_regs + offset;
spin_lock_init(&rh->lock);
init_completion(&rh->op_done);
rh->xfer_entries = XFER_RING_ENTRIES;
regval = rh_reg_read(CR_SETUP);
rh->xfer_struct_sz = FIELD_GET(CR_XFER_STRUCT_SIZE, regval);
rh->resp_struct_sz = FIELD_GET(CR_RESP_STRUCT_SIZE, regval);
DBG("xfer_struct_sz = %d, resp_struct_sz = %d",
rh->xfer_struct_sz, rh->resp_struct_sz);
xfers_sz = rh->xfer_struct_sz * rh->xfer_entries;
resps_sz = rh->resp_struct_sz * rh->xfer_entries;
rh->xfer = dma_alloc_coherent(&hci->master.dev, xfers_sz,
&rh->xfer_dma, GFP_KERNEL);
rh->resp = dma_alloc_coherent(&hci->master.dev, resps_sz,
&rh->resp_dma, GFP_KERNEL);
rh->src_xfers =
kmalloc_array(rh->xfer_entries, sizeof(*rh->src_xfers),
GFP_KERNEL);
ret = -ENOMEM;
if (!rh->xfer || !rh->resp || !rh->src_xfers)
goto err_out;
rh_reg_write(CMD_RING_BASE_LO, lower_32_bits(rh->xfer_dma));
rh_reg_write(CMD_RING_BASE_HI, upper_32_bits(rh->xfer_dma));
rh_reg_write(RESP_RING_BASE_LO, lower_32_bits(rh->resp_dma));
rh_reg_write(RESP_RING_BASE_HI, upper_32_bits(rh->resp_dma));
regval = FIELD_PREP(CR_RING_SIZE, rh->xfer_entries);
rh_reg_write(CR_SETUP, regval);
rh_reg_write(INTR_STATUS_ENABLE, 0xffffffff);
rh_reg_write(INTR_SIGNAL_ENABLE, INTR_IBI_READY |
INTR_TRANSFER_COMPLETION |
INTR_RING_OP |
INTR_TRANSFER_ERR |
INTR_WARN_INS_STOP_MODE |
INTR_IBI_RING_FULL |
INTR_TRANSFER_ABORT);
/* IBIs */
if (i >= IBI_RINGS)
goto ring_ready;
regval = rh_reg_read(IBI_SETUP);
rh->ibi_status_sz = FIELD_GET(IBI_STATUS_STRUCT_SIZE, regval);
rh->ibi_status_entries = IBI_STATUS_RING_ENTRIES;
rh->ibi_chunks_total = IBI_CHUNK_POOL_SIZE;
rh->ibi_chunk_sz = dma_get_cache_alignment();
rh->ibi_chunk_sz *= IBI_CHUNK_CACHELINES;
/*
* Round IBI data chunk size to number of bytes supported by
* the HW. Chunk size can be 2^n number of DWORDs which is the
* same as 2^(n+2) bytes, where n is 0..6.
*/
rh->ibi_chunk_sz = umax(4, rh->ibi_chunk_sz);
rh->ibi_chunk_sz = roundup_pow_of_two(rh->ibi_chunk_sz);
if (rh->ibi_chunk_sz > 256) {
ret = -EINVAL;
goto err_out;
}
ibi_status_ring_sz = rh->ibi_status_sz * rh->ibi_status_entries;
ibi_data_ring_sz = rh->ibi_chunk_sz * rh->ibi_chunks_total;
rh->ibi_status =
dma_alloc_coherent(&hci->master.dev, ibi_status_ring_sz,
&rh->ibi_status_dma, GFP_KERNEL);
rh->ibi_data = kmalloc(ibi_data_ring_sz, GFP_KERNEL);
ret = -ENOMEM;
if (!rh->ibi_status || !rh->ibi_data)
goto err_out;
rh->ibi_data_dma =
dma_map_single(&hci->master.dev, rh->ibi_data,
ibi_data_ring_sz, DMA_FROM_DEVICE);
if (dma_mapping_error(&hci->master.dev, rh->ibi_data_dma)) {
rh->ibi_data_dma = 0;
ret = -ENOMEM;
goto err_out;
}
rh_reg_write(IBI_STATUS_RING_BASE_LO, lower_32_bits(rh->ibi_status_dma));
rh_reg_write(IBI_STATUS_RING_BASE_HI, upper_32_bits(rh->ibi_status_dma));
rh_reg_write(IBI_DATA_RING_BASE_LO, lower_32_bits(rh->ibi_data_dma));
rh_reg_write(IBI_DATA_RING_BASE_HI, upper_32_bits(rh->ibi_data_dma));
regval = FIELD_PREP(IBI_STATUS_RING_SIZE,
rh->ibi_status_entries) |
FIELD_PREP(IBI_DATA_CHUNK_SIZE,
ilog2(rh->ibi_chunk_sz) - 2) |
FIELD_PREP(IBI_DATA_CHUNK_COUNT,
rh->ibi_chunks_total);
rh_reg_write(IBI_SETUP, regval);
regval = rh_reg_read(INTR_SIGNAL_ENABLE);
regval |= INTR_IBI_READY;
rh_reg_write(INTR_SIGNAL_ENABLE, regval);
ring_ready:
rh_reg_write(RING_CONTROL, RING_CTRL_ENABLE |
RING_CTRL_RUN_STOP);
}
return 0;
err_out:
hci_dma_cleanup(hci);
return ret;
}
static void hci_dma_unmap_xfer(struct i3c_hci *hci,
struct hci_xfer *xfer_list, unsigned int n)
{
struct hci_xfer *xfer;
unsigned int i;
for (i = 0; i < n; i++) {
xfer = xfer_list + i;
if (!xfer->data)
continue;
dma_unmap_single(&hci->master.dev,
xfer->data_dma, xfer->data_len,
xfer->rnw ? DMA_FROM_DEVICE : DMA_TO_DEVICE);
}
}
static int hci_dma_queue_xfer(struct i3c_hci *hci,
struct hci_xfer *xfer_list, int n)
{
struct hci_rings_data *rings = hci->io_data;
struct hci_rh_data *rh;
unsigned int i, ring, enqueue_ptr;
u32 op1_val, op2_val;
void *buf;
/* For now we only use ring 0 */
ring = 0;
rh = &rings->headers[ring];
op1_val = rh_reg_read(RING_OPERATION1);
enqueue_ptr = FIELD_GET(RING_OP1_CR_ENQ_PTR, op1_val);
for (i = 0; i < n; i++) {
struct hci_xfer *xfer = xfer_list + i;
u32 *ring_data = rh->xfer + rh->xfer_struct_sz * enqueue_ptr;
/* store cmd descriptor */
*ring_data++ = xfer->cmd_desc[0];
*ring_data++ = xfer->cmd_desc[1];
if (hci->cmd == &mipi_i3c_hci_cmd_v2) {
*ring_data++ = xfer->cmd_desc[2];
*ring_data++ = xfer->cmd_desc[3];
}
/* first word of Data Buffer Descriptor Structure */
if (!xfer->data)
xfer->data_len = 0;
*ring_data++ =
FIELD_PREP(DATA_BUF_BLOCK_SIZE, xfer->data_len) |
((i == n - 1) ? DATA_BUF_IOC : 0);
/* 2nd and 3rd words of Data Buffer Descriptor Structure */
if (xfer->data) {
buf = xfer->bounce_buf ? xfer->bounce_buf : xfer->data;
xfer->data_dma =
dma_map_single(&hci->master.dev,
buf,
xfer->data_len,
xfer->rnw ?
DMA_FROM_DEVICE :
DMA_TO_DEVICE);
if (dma_mapping_error(&hci->master.dev,
xfer->data_dma)) {
hci_dma_unmap_xfer(hci, xfer_list, i);
return -ENOMEM;
}
*ring_data++ = lower_32_bits(xfer->data_dma);
*ring_data++ = upper_32_bits(xfer->data_dma);
} else {
*ring_data++ = 0;
*ring_data++ = 0;
}
/* remember corresponding xfer struct */
rh->src_xfers[enqueue_ptr] = xfer;
/* remember corresponding ring/entry for this xfer structure */
xfer->ring_number = ring;
xfer->ring_entry = enqueue_ptr;
enqueue_ptr = (enqueue_ptr + 1) % rh->xfer_entries;
/*
* We may update the hardware view of the enqueue pointer
* only if we didn't reach its dequeue pointer.
*/
op2_val = rh_reg_read(RING_OPERATION2);
if (enqueue_ptr == FIELD_GET(RING_OP2_CR_DEQ_PTR, op2_val)) {
/* the ring is full */
hci_dma_unmap_xfer(hci, xfer_list, i + 1);
return -EBUSY;
}
}
/* take care to update the hardware enqueue pointer atomically */
spin_lock_irq(&rh->lock);
op1_val = rh_reg_read(RING_OPERATION1);
op1_val &= ~RING_OP1_CR_ENQ_PTR;
op1_val |= FIELD_PREP(RING_OP1_CR_ENQ_PTR, enqueue_ptr);
rh_reg_write(RING_OPERATION1, op1_val);
spin_unlock_irq(&rh->lock);
return 0;
}
static bool hci_dma_dequeue_xfer(struct i3c_hci *hci,
struct hci_xfer *xfer_list, int n)
{
struct hci_rings_data *rings = hci->io_data;
struct hci_rh_data *rh = &rings->headers[xfer_list[0].ring_number];
unsigned int i;
bool did_unqueue = false;
/* stop the ring */
rh_reg_write(RING_CONTROL, RING_CTRL_ABORT);
if (wait_for_completion_timeout(&rh->op_done, HZ) == 0) {
/*
* We're deep in it if ever this condition is ever met.
* Hardware might still be writing to memory, etc.
*/
dev_crit(&hci->master.dev, "unable to abort the ring\n");
WARN_ON(1);
}
for (i = 0; i < n; i++) {
struct hci_xfer *xfer = xfer_list + i;
int idx = xfer->ring_entry;
/*
* At the time the abort happened, the xfer might have
* completed already. If not then replace corresponding
* descriptor entries with a no-op.
*/
if (idx >= 0) {
u32 *ring_data = rh->xfer + rh->xfer_struct_sz * idx;
/* store no-op cmd descriptor */
*ring_data++ = FIELD_PREP(CMD_0_ATTR, 0x7);
*ring_data++ = 0;
if (hci->cmd == &mipi_i3c_hci_cmd_v2) {
*ring_data++ = 0;
*ring_data++ = 0;
}
/* disassociate this xfer struct */
rh->src_xfers[idx] = NULL;
/* and unmap it */
hci_dma_unmap_xfer(hci, xfer, 1);
did_unqueue = true;
}
}
/* restart the ring */
rh_reg_write(RING_CONTROL, RING_CTRL_ENABLE);
return did_unqueue;
}
static void hci_dma_xfer_done(struct i3c_hci *hci, struct hci_rh_data *rh)
{
u32 op1_val, op2_val, resp, *ring_resp;
unsigned int tid, done_ptr = rh->done_ptr;
struct hci_xfer *xfer;
for (;;) {
op2_val = rh_reg_read(RING_OPERATION2);
if (done_ptr == FIELD_GET(RING_OP2_CR_DEQ_PTR, op2_val))
break;
ring_resp = rh->resp + rh->resp_struct_sz * done_ptr;
resp = *ring_resp;
tid = RESP_TID(resp);
DBG("resp = 0x%08x", resp);
xfer = rh->src_xfers[done_ptr];
if (!xfer) {
DBG("orphaned ring entry");
} else {
hci_dma_unmap_xfer(hci, xfer, 1);
xfer->ring_entry = -1;
xfer->response = resp;
if (tid != xfer->cmd_tid) {
dev_err(&hci->master.dev,
"response tid=%d when expecting %d\n",
tid, xfer->cmd_tid);
/* TODO: do something about it? */
}
if (xfer->completion)
complete(xfer->completion);
}
done_ptr = (done_ptr + 1) % rh->xfer_entries;
rh->done_ptr = done_ptr;
}
/* take care to update the software dequeue pointer atomically */
spin_lock(&rh->lock);
op1_val = rh_reg_read(RING_OPERATION1);
op1_val &= ~RING_OP1_CR_SW_DEQ_PTR;
op1_val |= FIELD_PREP(RING_OP1_CR_SW_DEQ_PTR, done_ptr);
rh_reg_write(RING_OPERATION1, op1_val);
spin_unlock(&rh->lock);
}
static int hci_dma_request_ibi(struct i3c_hci *hci, struct i3c_dev_desc *dev,
const struct i3c_ibi_setup *req)
{
struct i3c_hci_dev_data *dev_data = i3c_dev_get_master_data(dev);
struct i3c_generic_ibi_pool *pool;
struct hci_dma_dev_ibi_data *dev_ibi;
dev_ibi = kmalloc(sizeof(*dev_ibi), GFP_KERNEL);
if (!dev_ibi)
return -ENOMEM;
pool = i3c_generic_ibi_alloc_pool(dev, req);
if (IS_ERR(pool)) {
kfree(dev_ibi);
return PTR_ERR(pool);
}
dev_ibi->pool = pool;
dev_ibi->max_len = req->max_payload_len;
dev_data->ibi_data = dev_ibi;
return 0;
}
static void hci_dma_free_ibi(struct i3c_hci *hci, struct i3c_dev_desc *dev)
{
struct i3c_hci_dev_data *dev_data = i3c_dev_get_master_data(dev);
struct hci_dma_dev_ibi_data *dev_ibi = dev_data->ibi_data;
dev_data->ibi_data = NULL;
i3c_generic_ibi_free_pool(dev_ibi->pool);
kfree(dev_ibi);
}
static void hci_dma_recycle_ibi_slot(struct i3c_hci *hci,
struct i3c_dev_desc *dev,
struct i3c_ibi_slot *slot)
{
struct i3c_hci_dev_data *dev_data = i3c_dev_get_master_data(dev);
struct hci_dma_dev_ibi_data *dev_ibi = dev_data->ibi_data;
i3c_generic_ibi_recycle_slot(dev_ibi->pool, slot);
}
static void hci_dma_process_ibi(struct i3c_hci *hci, struct hci_rh_data *rh)
{
struct i3c_dev_desc *dev;
struct i3c_hci_dev_data *dev_data;
struct hci_dma_dev_ibi_data *dev_ibi;
struct i3c_ibi_slot *slot;
u32 op1_val, op2_val, ibi_status_error;
unsigned int ptr, enq_ptr, deq_ptr;
unsigned int ibi_size, ibi_chunks, ibi_data_offset, first_part;
int ibi_addr, last_ptr;
void *ring_ibi_data;
dma_addr_t ring_ibi_data_dma;
op1_val = rh_reg_read(RING_OPERATION1);
deq_ptr = FIELD_GET(RING_OP1_IBI_DEQ_PTR, op1_val);
op2_val = rh_reg_read(RING_OPERATION2);
enq_ptr = FIELD_GET(RING_OP2_IBI_ENQ_PTR, op2_val);
ibi_status_error = 0;
ibi_addr = -1;
ibi_chunks = 0;
ibi_size = 0;
last_ptr = -1;
/* let's find all we can about this IBI */
for (ptr = deq_ptr; ptr != enq_ptr;
ptr = (ptr + 1) % rh->ibi_status_entries) {
u32 ibi_status, *ring_ibi_status;
unsigned int chunks;
ring_ibi_status = rh->ibi_status + rh->ibi_status_sz * ptr;
ibi_status = *ring_ibi_status;
DBG("status = %#x", ibi_status);
if (ibi_status_error) {
/* we no longer care */
} else if (ibi_status & IBI_ERROR) {
ibi_status_error = ibi_status;
} else if (ibi_addr == -1) {
ibi_addr = FIELD_GET(IBI_TARGET_ADDR, ibi_status);
} else if (ibi_addr != FIELD_GET(IBI_TARGET_ADDR, ibi_status)) {
/* the address changed unexpectedly */
ibi_status_error = ibi_status;
}
chunks = FIELD_GET(IBI_CHUNKS, ibi_status);
ibi_chunks += chunks;
if (!(ibi_status & IBI_LAST_STATUS)) {
ibi_size += chunks * rh->ibi_chunk_sz;
} else {
ibi_size += FIELD_GET(IBI_DATA_LENGTH, ibi_status);
last_ptr = ptr;
break;
}
}
/* validate what we've got */
if (last_ptr == -1) {
/* this IBI sequence is not yet complete */
DBG("no LAST_STATUS available (e=%d d=%d)", enq_ptr, deq_ptr);
return;
}
deq_ptr = last_ptr + 1;
deq_ptr %= rh->ibi_status_entries;
if (ibi_status_error) {
dev_err(&hci->master.dev, "IBI error from %#x\n", ibi_addr);
goto done;
}
/* determine who this is for */
dev = i3c_hci_addr_to_dev(hci, ibi_addr);
if (!dev) {
dev_err(&hci->master.dev,
"IBI for unknown device %#x\n", ibi_addr);
goto done;
}
dev_data = i3c_dev_get_master_data(dev);
dev_ibi = dev_data->ibi_data;
if (ibi_size > dev_ibi->max_len) {
dev_err(&hci->master.dev, "IBI payload too big (%d > %d)\n",
ibi_size, dev_ibi->max_len);
goto done;
}
/*
* This ring model is not suitable for zero-copy processing of IBIs.
* We have the data chunk ring wrap-around to deal with, meaning
* that the payload might span multiple chunks beginning at the
* end of the ring and wrap to the start of the ring. Furthermore
* there is no guarantee that those chunks will be released in order
* and in a timely manner by the upper driver. So let's just copy
* them to a discrete buffer. In practice they're supposed to be
* small anyway.
*/
slot = i3c_generic_ibi_get_free_slot(dev_ibi->pool);
if (!slot) {
dev_err(&hci->master.dev, "no free slot for IBI\n");
goto done;
}
/* copy first part of the payload */
ibi_data_offset = rh->ibi_chunk_sz * rh->ibi_chunk_ptr;
ring_ibi_data = rh->ibi_data + ibi_data_offset;
ring_ibi_data_dma = rh->ibi_data_dma + ibi_data_offset;
first_part = (rh->ibi_chunks_total - rh->ibi_chunk_ptr)
* rh->ibi_chunk_sz;
if (first_part > ibi_size)
first_part = ibi_size;
dma_sync_single_for_cpu(&hci->master.dev, ring_ibi_data_dma,
first_part, DMA_FROM_DEVICE);
memcpy(slot->data, ring_ibi_data, first_part);
/* copy second part if any */
if (ibi_size > first_part) {
/* we wrap back to the start and copy remaining data */
ring_ibi_data = rh->ibi_data;
ring_ibi_data_dma = rh->ibi_data_dma;
dma_sync_single_for_cpu(&hci->master.dev, ring_ibi_data_dma,
ibi_size - first_part, DMA_FROM_DEVICE);
memcpy(slot->data + first_part, ring_ibi_data,
ibi_size - first_part);
}
/* submit it */
slot->dev = dev;
slot->len = ibi_size;
i3c_master_queue_ibi(dev, slot);
done:
/* take care to update the ibi dequeue pointer atomically */
spin_lock(&rh->lock);
op1_val = rh_reg_read(RING_OPERATION1);
op1_val &= ~RING_OP1_IBI_DEQ_PTR;
op1_val |= FIELD_PREP(RING_OP1_IBI_DEQ_PTR, deq_ptr);
rh_reg_write(RING_OPERATION1, op1_val);
spin_unlock(&rh->lock);
/* update the chunk pointer */
rh->ibi_chunk_ptr += ibi_chunks;
rh->ibi_chunk_ptr %= rh->ibi_chunks_total;
/* and tell the hardware about freed chunks */
rh_reg_write(CHUNK_CONTROL, rh_reg_read(CHUNK_CONTROL) + ibi_chunks);
}
static bool hci_dma_irq_handler(struct i3c_hci *hci, unsigned int mask)
{
struct hci_rings_data *rings = hci->io_data;
unsigned int i;
bool handled = false;
for (i = 0; mask && i < rings->total; i++) {
struct hci_rh_data *rh;
u32 status;
if (!(mask & BIT(i)))
continue;
mask &= ~BIT(i);
rh = &rings->headers[i];
status = rh_reg_read(INTR_STATUS);
DBG("rh%d status: %#x", i, status);
if (!status)
continue;
rh_reg_write(INTR_STATUS, status);
if (status & INTR_IBI_READY)
hci_dma_process_ibi(hci, rh);
if (status & (INTR_TRANSFER_COMPLETION | INTR_TRANSFER_ERR))
hci_dma_xfer_done(hci, rh);
if (status & INTR_RING_OP)
complete(&rh->op_done);
if (status & INTR_TRANSFER_ABORT) {
dev_notice_ratelimited(&hci->master.dev,
"ring %d: Transfer Aborted\n", i);
mipi_i3c_hci_resume(hci);
}
if (status & INTR_WARN_INS_STOP_MODE)
dev_warn_ratelimited(&hci->master.dev,
"ring %d: Inserted Stop on Mode Change\n", i);
if (status & INTR_IBI_RING_FULL)
dev_err_ratelimited(&hci->master.dev,
"ring %d: IBI Ring Full Condition\n", i);
handled = true;
}
return handled;
}
const struct hci_io_ops mipi_i3c_hci_dma = {
.init = hci_dma_init,
.cleanup = hci_dma_cleanup,
.queue_xfer = hci_dma_queue_xfer,
.dequeue_xfer = hci_dma_dequeue_xfer,
.irq_handler = hci_dma_irq_handler,
.request_ibi = hci_dma_request_ibi,
.free_ibi = hci_dma_free_ibi,
.recycle_ibi_slot = hci_dma_recycle_ibi_slot,
};
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