OpenCloudOS-Kernel/drivers/i3c/master/mipi-i3c-hci/cmd_v2.c

317 lines
8.4 KiB
C

// SPDX-License-Identifier: BSD-3-Clause
/*
* Copyright (c) 2020, MIPI Alliance, Inc.
*
* Author: Nicolas Pitre <npitre@baylibre.com>
*
* I3C HCI v2.0 Command Descriptor Handling
*
* Note: The I3C HCI v2.0 spec is still in flux. The code here will change.
*/
#include <linux/bitfield.h>
#include <linux/i3c/master.h>
#include "hci.h"
#include "cmd.h"
#include "xfer_mode_rate.h"
/*
* Unified Data Transfer Command
*/
#define CMD_0_ATTR_U FIELD_PREP(CMD_0_ATTR, 0x4)
#define CMD_U3_HDR_TSP_ML_CTRL(v) FIELD_PREP(W3_MASK(107, 104), v)
#define CMD_U3_IDB4(v) FIELD_PREP(W3_MASK(103, 96), v)
#define CMD_U3_HDR_CMD(v) FIELD_PREP(W3_MASK(103, 96), v)
#define CMD_U2_IDB3(v) FIELD_PREP(W2_MASK( 95, 88), v)
#define CMD_U2_HDR_BT(v) FIELD_PREP(W2_MASK( 95, 88), v)
#define CMD_U2_IDB2(v) FIELD_PREP(W2_MASK( 87, 80), v)
#define CMD_U2_BT_CMD2(v) FIELD_PREP(W2_MASK( 87, 80), v)
#define CMD_U2_IDB1(v) FIELD_PREP(W2_MASK( 79, 72), v)
#define CMD_U2_BT_CMD1(v) FIELD_PREP(W2_MASK( 79, 72), v)
#define CMD_U2_IDB0(v) FIELD_PREP(W2_MASK( 71, 64), v)
#define CMD_U2_BT_CMD0(v) FIELD_PREP(W2_MASK( 71, 64), v)
#define CMD_U1_ERR_HANDLING(v) FIELD_PREP(W1_MASK( 63, 62), v)
#define CMD_U1_ADD_FUNC(v) FIELD_PREP(W1_MASK( 61, 56), v)
#define CMD_U1_COMBO_XFER W1_BIT_( 55)
#define CMD_U1_DATA_LENGTH(v) FIELD_PREP(W1_MASK( 53, 32), v)
#define CMD_U0_TOC W0_BIT_( 31)
#define CMD_U0_ROC W0_BIT_( 30)
#define CMD_U0_MAY_YIELD W0_BIT_( 29)
#define CMD_U0_NACK_RCNT(v) FIELD_PREP(W0_MASK( 28, 27), v)
#define CMD_U0_IDB_COUNT(v) FIELD_PREP(W0_MASK( 26, 24), v)
#define CMD_U0_MODE_INDEX(v) FIELD_PREP(W0_MASK( 22, 18), v)
#define CMD_U0_XFER_RATE(v) FIELD_PREP(W0_MASK( 17, 15), v)
#define CMD_U0_DEV_ADDRESS(v) FIELD_PREP(W0_MASK( 14, 8), v)
#define CMD_U0_RnW W0_BIT_( 7)
#define CMD_U0_TID(v) FIELD_PREP(W0_MASK( 6, 3), v)
/*
* Address Assignment Command
*/
#define CMD_0_ATTR_A FIELD_PREP(CMD_0_ATTR, 0x2)
#define CMD_A1_DATA_LENGTH(v) FIELD_PREP(W1_MASK( 53, 32), v)
#define CMD_A0_TOC W0_BIT_( 31)
#define CMD_A0_ROC W0_BIT_( 30)
#define CMD_A0_XFER_RATE(v) FIELD_PREP(W0_MASK( 17, 15), v)
#define CMD_A0_ASSIGN_ADDRESS(v) FIELD_PREP(W0_MASK( 14, 8), v)
#define CMD_A0_TID(v) FIELD_PREP(W0_MASK( 6, 3), v)
static unsigned int get_i3c_rate_idx(struct i3c_hci *hci)
{
struct i3c_bus *bus = i3c_master_get_bus(&hci->master);
if (bus->scl_rate.i3c >= 12000000)
return XFERRATE_I3C_SDR0;
if (bus->scl_rate.i3c > 8000000)
return XFERRATE_I3C_SDR1;
if (bus->scl_rate.i3c > 6000000)
return XFERRATE_I3C_SDR2;
if (bus->scl_rate.i3c > 4000000)
return XFERRATE_I3C_SDR3;
if (bus->scl_rate.i3c > 2000000)
return XFERRATE_I3C_SDR4;
return XFERRATE_I3C_SDR_FM_FMP;
}
static unsigned int get_i2c_rate_idx(struct i3c_hci *hci)
{
struct i3c_bus *bus = i3c_master_get_bus(&hci->master);
if (bus->scl_rate.i2c >= 1000000)
return XFERRATE_I2C_FMP;
return XFERRATE_I2C_FM;
}
static void hci_cmd_v2_prep_private_xfer(struct i3c_hci *hci,
struct hci_xfer *xfer,
u8 addr, unsigned int mode,
unsigned int rate)
{
u8 *data = xfer->data;
unsigned int data_len = xfer->data_len;
bool rnw = xfer->rnw;
xfer->cmd_tid = hci_get_tid();
if (!rnw && data_len <= 5) {
xfer->cmd_desc[0] =
CMD_0_ATTR_U |
CMD_U0_TID(xfer->cmd_tid) |
CMD_U0_DEV_ADDRESS(addr) |
CMD_U0_XFER_RATE(rate) |
CMD_U0_MODE_INDEX(mode) |
CMD_U0_IDB_COUNT(data_len);
xfer->cmd_desc[1] =
CMD_U1_DATA_LENGTH(0);
xfer->cmd_desc[2] = 0;
xfer->cmd_desc[3] = 0;
switch (data_len) {
case 5:
xfer->cmd_desc[3] |= CMD_U3_IDB4(data[4]);
fallthrough;
case 4:
xfer->cmd_desc[2] |= CMD_U2_IDB3(data[3]);
fallthrough;
case 3:
xfer->cmd_desc[2] |= CMD_U2_IDB2(data[2]);
fallthrough;
case 2:
xfer->cmd_desc[2] |= CMD_U2_IDB1(data[1]);
fallthrough;
case 1:
xfer->cmd_desc[2] |= CMD_U2_IDB0(data[0]);
fallthrough;
case 0:
break;
}
/* we consumed all the data with the cmd descriptor */
xfer->data = NULL;
} else {
xfer->cmd_desc[0] =
CMD_0_ATTR_U |
CMD_U0_TID(xfer->cmd_tid) |
(rnw ? CMD_U0_RnW : 0) |
CMD_U0_DEV_ADDRESS(addr) |
CMD_U0_XFER_RATE(rate) |
CMD_U0_MODE_INDEX(mode);
xfer->cmd_desc[1] =
CMD_U1_DATA_LENGTH(data_len);
xfer->cmd_desc[2] = 0;
xfer->cmd_desc[3] = 0;
}
}
static int hci_cmd_v2_prep_ccc(struct i3c_hci *hci, struct hci_xfer *xfer,
u8 ccc_addr, u8 ccc_cmd, bool raw)
{
unsigned int mode = XFERMODE_IDX_I3C_SDR;
unsigned int rate = get_i3c_rate_idx(hci);
u8 *data = xfer->data;
unsigned int data_len = xfer->data_len;
bool rnw = xfer->rnw;
if (raw && ccc_addr != I3C_BROADCAST_ADDR) {
hci_cmd_v2_prep_private_xfer(hci, xfer, ccc_addr, mode, rate);
return 0;
}
xfer->cmd_tid = hci_get_tid();
if (!rnw && data_len <= 4) {
xfer->cmd_desc[0] =
CMD_0_ATTR_U |
CMD_U0_TID(xfer->cmd_tid) |
CMD_U0_DEV_ADDRESS(ccc_addr) |
CMD_U0_XFER_RATE(rate) |
CMD_U0_MODE_INDEX(mode) |
CMD_U0_IDB_COUNT(data_len + (!raw ? 0 : 1));
xfer->cmd_desc[1] =
CMD_U1_DATA_LENGTH(0);
xfer->cmd_desc[2] =
CMD_U2_IDB0(ccc_cmd);
xfer->cmd_desc[3] = 0;
switch (data_len) {
case 4:
xfer->cmd_desc[3] |= CMD_U3_IDB4(data[3]);
fallthrough;
case 3:
xfer->cmd_desc[2] |= CMD_U2_IDB3(data[2]);
fallthrough;
case 2:
xfer->cmd_desc[2] |= CMD_U2_IDB2(data[1]);
fallthrough;
case 1:
xfer->cmd_desc[2] |= CMD_U2_IDB1(data[0]);
fallthrough;
case 0:
break;
}
/* we consumed all the data with the cmd descriptor */
xfer->data = NULL;
} else {
xfer->cmd_desc[0] =
CMD_0_ATTR_U |
CMD_U0_TID(xfer->cmd_tid) |
(rnw ? CMD_U0_RnW : 0) |
CMD_U0_DEV_ADDRESS(ccc_addr) |
CMD_U0_XFER_RATE(rate) |
CMD_U0_MODE_INDEX(mode) |
CMD_U0_IDB_COUNT(!raw ? 0 : 1);
xfer->cmd_desc[1] =
CMD_U1_DATA_LENGTH(data_len);
xfer->cmd_desc[2] =
CMD_U2_IDB0(ccc_cmd);
xfer->cmd_desc[3] = 0;
}
return 0;
}
static void hci_cmd_v2_prep_i3c_xfer(struct i3c_hci *hci,
struct i3c_dev_desc *dev,
struct hci_xfer *xfer)
{
unsigned int mode = XFERMODE_IDX_I3C_SDR;
unsigned int rate = get_i3c_rate_idx(hci);
u8 addr = dev->info.dyn_addr;
hci_cmd_v2_prep_private_xfer(hci, xfer, addr, mode, rate);
}
static void hci_cmd_v2_prep_i2c_xfer(struct i3c_hci *hci,
struct i2c_dev_desc *dev,
struct hci_xfer *xfer)
{
unsigned int mode = XFERMODE_IDX_I2C;
unsigned int rate = get_i2c_rate_idx(hci);
u8 addr = dev->addr;
hci_cmd_v2_prep_private_xfer(hci, xfer, addr, mode, rate);
}
static int hci_cmd_v2_daa(struct i3c_hci *hci)
{
struct hci_xfer *xfer;
int ret;
u8 next_addr = 0;
u32 device_id[2];
u64 pid;
unsigned int dcr, bcr;
DECLARE_COMPLETION_ONSTACK(done);
xfer = hci_alloc_xfer(2);
if (!xfer)
return -ENOMEM;
xfer[0].data = &device_id;
xfer[0].data_len = 8;
xfer[0].rnw = true;
xfer[0].cmd_desc[1] = CMD_A1_DATA_LENGTH(8);
xfer[1].completion = &done;
for (;;) {
ret = i3c_master_get_free_addr(&hci->master, next_addr);
if (ret < 0)
break;
next_addr = ret;
DBG("next_addr = 0x%02x", next_addr);
xfer[0].cmd_tid = hci_get_tid();
xfer[0].cmd_desc[0] =
CMD_0_ATTR_A |
CMD_A0_TID(xfer[0].cmd_tid) |
CMD_A0_ROC;
xfer[1].cmd_tid = hci_get_tid();
xfer[1].cmd_desc[0] =
CMD_0_ATTR_A |
CMD_A0_TID(xfer[1].cmd_tid) |
CMD_A0_ASSIGN_ADDRESS(next_addr) |
CMD_A0_ROC |
CMD_A0_TOC;
hci->io->queue_xfer(hci, xfer, 2);
if (!wait_for_completion_timeout(&done, HZ) &&
hci->io->dequeue_xfer(hci, xfer, 2)) {
ret = -ETIME;
break;
}
if (RESP_STATUS(xfer[0].response) != RESP_SUCCESS) {
ret = 0; /* no more devices to be assigned */
break;
}
if (RESP_STATUS(xfer[1].response) != RESP_SUCCESS) {
ret = -EIO;
break;
}
pid = FIELD_GET(W1_MASK(47, 32), device_id[1]);
pid = (pid << 32) | device_id[0];
bcr = FIELD_GET(W1_MASK(55, 48), device_id[1]);
dcr = FIELD_GET(W1_MASK(63, 56), device_id[1]);
DBG("assigned address %#x to device PID=0x%llx DCR=%#x BCR=%#x",
next_addr, pid, dcr, bcr);
/*
* TODO: Extend the subsystem layer to allow for registering
* new device and provide BCR/DCR/PID at the same time.
*/
ret = i3c_master_add_i3c_dev_locked(&hci->master, next_addr);
if (ret)
break;
}
hci_free_xfer(xfer, 2);
return ret;
}
const struct hci_cmd_ops mipi_i3c_hci_cmd_v2 = {
.prep_ccc = hci_cmd_v2_prep_ccc,
.prep_i3c_xfer = hci_cmd_v2_prep_i3c_xfer,
.prep_i2c_xfer = hci_cmd_v2_prep_i2c_xfer,
.perform_daa = hci_cmd_v2_daa,
};