OpenCloudOS-Kernel/net/nfc/nci/ntf.c

825 lines
23 KiB
C
Raw Normal View History

// SPDX-License-Identifier: GPL-2.0-only
/*
* The NFC Controller Interface is the communication protocol between an
* NFC Controller (NFCC) and a Device Host (DH).
*
* Copyright (C) 2014 Marvell International Ltd.
* Copyright (C) 2011 Texas Instruments, Inc.
*
* Written by Ilan Elias <ilane@ti.com>
*
* Acknowledgements:
* This file is based on hci_event.c, which was written
* by Maxim Krasnyansky.
*/
#define pr_fmt(fmt) KBUILD_MODNAME ": %s: " fmt, __func__
#include <linux/types.h>
#include <linux/interrupt.h>
#include <linux/bitops.h>
#include <linux/skbuff.h>
#include "../nfc.h"
#include <net/nfc/nci.h>
#include <net/nfc/nci_core.h>
#include <linux/nfc.h>
/* Handle NCI Notification packets */
net/nfc/nci: Support NCI 2.x initial sequence implement the NCI 2.x initial sequence to support NCI 2.x NFCC. Since NCI 2.0, CORE_RESET and CORE_INIT sequence have been changed. If NFCEE supports NCI 2.x, then NCI 2.x initial sequence will work. In NCI 1.0, Initial sequence and payloads are as below: (DH) (NFCC) | -- CORE_RESET_CMD --> | | <-- CORE_RESET_RSP -- | | -- CORE_INIT_CMD --> | | <-- CORE_INIT_RSP -- | CORE_RESET_RSP payloads are Status, NCI version, Configuration Status. CORE_INIT_CMD payloads are empty. CORE_INIT_RSP payloads are Status, NFCC Features, Number of Supported RF Interfaces, Supported RF Interface, Max Logical Connections, Max Routing table Size, Max Control Packet Payload Size, Max Size for Large Parameters, Manufacturer ID, Manufacturer Specific Information. In NCI 2.0, Initial Sequence and Parameters are as below: (DH) (NFCC) | -- CORE_RESET_CMD --> | | <-- CORE_RESET_RSP -- | | <-- CORE_RESET_NTF -- | | -- CORE_INIT_CMD --> | | <-- CORE_INIT_RSP -- | CORE_RESET_RSP payloads are Status. CORE_RESET_NTF payloads are Reset Trigger, Configuration Status, NCI Version, Manufacturer ID, Manufacturer Specific Information Length, Manufacturer Specific Information. CORE_INIT_CMD payloads are Feature1, Feature2. CORE_INIT_RSP payloads are Status, NFCC Features, Max Logical Connections, Max Routing Table Size, Max Control Packet Payload Size, Max Data Packet Payload Size of the Static HCI Connection, Number of Credits of the Static HCI Connection, Max NFC-V RF Frame Size, Number of Supported RF Interfaces, Supported RF Interfaces. Signed-off-by: Bongsu Jeon <bongsu.jeon@samsung.com> Link: https://lore.kernel.org/r/20201202223147.3472-1-bongsu.jeon@samsung.com Signed-off-by: Jakub Kicinski <kuba@kernel.org>
2020-12-03 06:31:47 +08:00
static void nci_core_reset_ntf_packet(struct nci_dev *ndev,
const struct sk_buff *skb)
net/nfc/nci: Support NCI 2.x initial sequence implement the NCI 2.x initial sequence to support NCI 2.x NFCC. Since NCI 2.0, CORE_RESET and CORE_INIT sequence have been changed. If NFCEE supports NCI 2.x, then NCI 2.x initial sequence will work. In NCI 1.0, Initial sequence and payloads are as below: (DH) (NFCC) | -- CORE_RESET_CMD --> | | <-- CORE_RESET_RSP -- | | -- CORE_INIT_CMD --> | | <-- CORE_INIT_RSP -- | CORE_RESET_RSP payloads are Status, NCI version, Configuration Status. CORE_INIT_CMD payloads are empty. CORE_INIT_RSP payloads are Status, NFCC Features, Number of Supported RF Interfaces, Supported RF Interface, Max Logical Connections, Max Routing table Size, Max Control Packet Payload Size, Max Size for Large Parameters, Manufacturer ID, Manufacturer Specific Information. In NCI 2.0, Initial Sequence and Parameters are as below: (DH) (NFCC) | -- CORE_RESET_CMD --> | | <-- CORE_RESET_RSP -- | | <-- CORE_RESET_NTF -- | | -- CORE_INIT_CMD --> | | <-- CORE_INIT_RSP -- | CORE_RESET_RSP payloads are Status. CORE_RESET_NTF payloads are Reset Trigger, Configuration Status, NCI Version, Manufacturer ID, Manufacturer Specific Information Length, Manufacturer Specific Information. CORE_INIT_CMD payloads are Feature1, Feature2. CORE_INIT_RSP payloads are Status, NFCC Features, Max Logical Connections, Max Routing Table Size, Max Control Packet Payload Size, Max Data Packet Payload Size of the Static HCI Connection, Number of Credits of the Static HCI Connection, Max NFC-V RF Frame Size, Number of Supported RF Interfaces, Supported RF Interfaces. Signed-off-by: Bongsu Jeon <bongsu.jeon@samsung.com> Link: https://lore.kernel.org/r/20201202223147.3472-1-bongsu.jeon@samsung.com Signed-off-by: Jakub Kicinski <kuba@kernel.org>
2020-12-03 06:31:47 +08:00
{
/* Handle NCI 2.x core reset notification */
const struct nci_core_reset_ntf *ntf = (void *)skb->data;
net/nfc/nci: Support NCI 2.x initial sequence implement the NCI 2.x initial sequence to support NCI 2.x NFCC. Since NCI 2.0, CORE_RESET and CORE_INIT sequence have been changed. If NFCEE supports NCI 2.x, then NCI 2.x initial sequence will work. In NCI 1.0, Initial sequence and payloads are as below: (DH) (NFCC) | -- CORE_RESET_CMD --> | | <-- CORE_RESET_RSP -- | | -- CORE_INIT_CMD --> | | <-- CORE_INIT_RSP -- | CORE_RESET_RSP payloads are Status, NCI version, Configuration Status. CORE_INIT_CMD payloads are empty. CORE_INIT_RSP payloads are Status, NFCC Features, Number of Supported RF Interfaces, Supported RF Interface, Max Logical Connections, Max Routing table Size, Max Control Packet Payload Size, Max Size for Large Parameters, Manufacturer ID, Manufacturer Specific Information. In NCI 2.0, Initial Sequence and Parameters are as below: (DH) (NFCC) | -- CORE_RESET_CMD --> | | <-- CORE_RESET_RSP -- | | <-- CORE_RESET_NTF -- | | -- CORE_INIT_CMD --> | | <-- CORE_INIT_RSP -- | CORE_RESET_RSP payloads are Status. CORE_RESET_NTF payloads are Reset Trigger, Configuration Status, NCI Version, Manufacturer ID, Manufacturer Specific Information Length, Manufacturer Specific Information. CORE_INIT_CMD payloads are Feature1, Feature2. CORE_INIT_RSP payloads are Status, NFCC Features, Max Logical Connections, Max Routing Table Size, Max Control Packet Payload Size, Max Data Packet Payload Size of the Static HCI Connection, Number of Credits of the Static HCI Connection, Max NFC-V RF Frame Size, Number of Supported RF Interfaces, Supported RF Interfaces. Signed-off-by: Bongsu Jeon <bongsu.jeon@samsung.com> Link: https://lore.kernel.org/r/20201202223147.3472-1-bongsu.jeon@samsung.com Signed-off-by: Jakub Kicinski <kuba@kernel.org>
2020-12-03 06:31:47 +08:00
ndev->nci_ver = ntf->nci_ver;
pr_debug("nci_ver 0x%x, config_status 0x%x\n",
ntf->nci_ver, ntf->config_status);
ndev->manufact_id = ntf->manufact_id;
ndev->manufact_specific_info =
__le32_to_cpu(ntf->manufact_specific_info);
nci_req_complete(ndev, NCI_STATUS_OK);
}
static void nci_core_conn_credits_ntf_packet(struct nci_dev *ndev,
struct sk_buff *skb)
{
struct nci_core_conn_credit_ntf *ntf = (void *) skb->data;
struct nci_conn_info *conn_info;
int i;
pr_debug("num_entries %d\n", ntf->num_entries);
if (ntf->num_entries > NCI_MAX_NUM_CONN)
ntf->num_entries = NCI_MAX_NUM_CONN;
/* update the credits */
for (i = 0; i < ntf->num_entries; i++) {
ntf->conn_entries[i].conn_id =
nci_conn_id(&ntf->conn_entries[i].conn_id);
pr_debug("entry[%d]: conn_id %d, credits %d\n",
i, ntf->conn_entries[i].conn_id,
ntf->conn_entries[i].credits);
conn_info = nci_get_conn_info_by_conn_id(ndev,
ntf->conn_entries[i].conn_id);
if (!conn_info)
return;
atomic_add(ntf->conn_entries[i].credits,
&conn_info->credits_cnt);
}
/* trigger the next tx */
if (!skb_queue_empty(&ndev->tx_q))
queue_work(ndev->tx_wq, &ndev->tx_work);
}
static void nci_core_generic_error_ntf_packet(struct nci_dev *ndev,
const struct sk_buff *skb)
{
__u8 status = skb->data[0];
pr_debug("status 0x%x\n", status);
if (atomic_read(&ndev->state) == NCI_W4_HOST_SELECT) {
/* Activation failed, so complete the request
(the state remains the same) */
nci_req_complete(ndev, status);
}
}
static void nci_core_conn_intf_error_ntf_packet(struct nci_dev *ndev,
struct sk_buff *skb)
{
struct nci_core_intf_error_ntf *ntf = (void *) skb->data;
ntf->conn_id = nci_conn_id(&ntf->conn_id);
pr_debug("status 0x%x, conn_id %d\n", ntf->status, ntf->conn_id);
/* complete the data exchange transaction, if exists */
if (test_bit(NCI_DATA_EXCHANGE, &ndev->flags))
nci_data_exchange_complete(ndev, NULL, ntf->conn_id, -EIO);
}
static const __u8 *
nci_extract_rf_params_nfca_passive_poll(struct nci_dev *ndev,
struct rf_tech_specific_params_nfca_poll *nfca_poll,
const __u8 *data)
{
nfca_poll->sens_res = __le16_to_cpu(*((__le16 *)data));
data += 2;
nfca_poll->nfcid1_len = min_t(__u8, *data++, NFC_NFCID1_MAXSIZE);
pr_debug("sens_res 0x%x, nfcid1_len %d\n",
nfca_poll->sens_res, nfca_poll->nfcid1_len);
memcpy(nfca_poll->nfcid1, data, nfca_poll->nfcid1_len);
data += nfca_poll->nfcid1_len;
nfca_poll->sel_res_len = *data++;
if (nfca_poll->sel_res_len != 0)
nfca_poll->sel_res = *data++;
pr_debug("sel_res_len %d, sel_res 0x%x\n",
nfca_poll->sel_res_len,
nfca_poll->sel_res);
return data;
}
static const __u8 *
nci_extract_rf_params_nfcb_passive_poll(struct nci_dev *ndev,
struct rf_tech_specific_params_nfcb_poll *nfcb_poll,
const __u8 *data)
{
nfcb_poll->sensb_res_len = min_t(__u8, *data++, NFC_SENSB_RES_MAXSIZE);
pr_debug("sensb_res_len %d\n", nfcb_poll->sensb_res_len);
memcpy(nfcb_poll->sensb_res, data, nfcb_poll->sensb_res_len);
data += nfcb_poll->sensb_res_len;
return data;
}
static const __u8 *
nci_extract_rf_params_nfcf_passive_poll(struct nci_dev *ndev,
struct rf_tech_specific_params_nfcf_poll *nfcf_poll,
const __u8 *data)
{
nfcf_poll->bit_rate = *data++;
nfcf_poll->sensf_res_len = min_t(__u8, *data++, NFC_SENSF_RES_MAXSIZE);
pr_debug("bit_rate %d, sensf_res_len %d\n",
nfcf_poll->bit_rate, nfcf_poll->sensf_res_len);
memcpy(nfcf_poll->sensf_res, data, nfcf_poll->sensf_res_len);
data += nfcf_poll->sensf_res_len;
return data;
}
static const __u8 *
nci_extract_rf_params_nfcv_passive_poll(struct nci_dev *ndev,
struct rf_tech_specific_params_nfcv_poll *nfcv_poll,
const __u8 *data)
{
++data;
nfcv_poll->dsfid = *data++;
memcpy(nfcv_poll->uid, data, NFC_ISO15693_UID_MAXSIZE);
data += NFC_ISO15693_UID_MAXSIZE;
return data;
}
static const __u8 *
nci_extract_rf_params_nfcf_passive_listen(struct nci_dev *ndev,
struct rf_tech_specific_params_nfcf_listen *nfcf_listen,
const __u8 *data)
{
nfcf_listen->local_nfcid2_len = min_t(__u8, *data++,
NFC_NFCID2_MAXSIZE);
memcpy(nfcf_listen->local_nfcid2, data, nfcf_listen->local_nfcid2_len);
data += nfcf_listen->local_nfcid2_len;
return data;
}
static __u32 nci_get_prop_rf_protocol(struct nci_dev *ndev, __u8 rf_protocol)
{
if (ndev->ops->get_rfprotocol)
return ndev->ops->get_rfprotocol(ndev, rf_protocol);
return 0;
}
static int nci_add_new_protocol(struct nci_dev *ndev,
struct nfc_target *target,
__u8 rf_protocol,
__u8 rf_tech_and_mode,
const void *params)
{
const struct rf_tech_specific_params_nfca_poll *nfca_poll;
const struct rf_tech_specific_params_nfcb_poll *nfcb_poll;
const struct rf_tech_specific_params_nfcf_poll *nfcf_poll;
const struct rf_tech_specific_params_nfcv_poll *nfcv_poll;
__u32 protocol;
if (rf_protocol == NCI_RF_PROTOCOL_T1T)
protocol = NFC_PROTO_JEWEL_MASK;
else if (rf_protocol == NCI_RF_PROTOCOL_T2T)
protocol = NFC_PROTO_MIFARE_MASK;
else if (rf_protocol == NCI_RF_PROTOCOL_ISO_DEP)
if (rf_tech_and_mode == NCI_NFC_A_PASSIVE_POLL_MODE)
protocol = NFC_PROTO_ISO14443_MASK;
else
protocol = NFC_PROTO_ISO14443_B_MASK;
else if (rf_protocol == NCI_RF_PROTOCOL_T3T)
protocol = NFC_PROTO_FELICA_MASK;
else if (rf_protocol == NCI_RF_PROTOCOL_NFC_DEP)
protocol = NFC_PROTO_NFC_DEP_MASK;
else if (rf_protocol == NCI_RF_PROTOCOL_T5T)
protocol = NFC_PROTO_ISO15693_MASK;
else
protocol = nci_get_prop_rf_protocol(ndev, rf_protocol);
if (!(protocol & ndev->poll_prots)) {
pr_err("the target found does not have the desired protocol\n");
return -EPROTO;
}
if (rf_tech_and_mode == NCI_NFC_A_PASSIVE_POLL_MODE) {
nfca_poll = (struct rf_tech_specific_params_nfca_poll *)params;
target->sens_res = nfca_poll->sens_res;
target->sel_res = nfca_poll->sel_res;
target->nfcid1_len = nfca_poll->nfcid1_len;
if (target->nfcid1_len > ARRAY_SIZE(target->nfcid1))
return -EPROTO;
if (target->nfcid1_len > 0) {
memcpy(target->nfcid1, nfca_poll->nfcid1,
target->nfcid1_len);
}
} else if (rf_tech_and_mode == NCI_NFC_B_PASSIVE_POLL_MODE) {
nfcb_poll = (struct rf_tech_specific_params_nfcb_poll *)params;
target->sensb_res_len = nfcb_poll->sensb_res_len;
if (target->sensb_res_len > ARRAY_SIZE(target->sensb_res))
return -EPROTO;
if (target->sensb_res_len > 0) {
memcpy(target->sensb_res, nfcb_poll->sensb_res,
target->sensb_res_len);
}
} else if (rf_tech_and_mode == NCI_NFC_F_PASSIVE_POLL_MODE) {
nfcf_poll = (struct rf_tech_specific_params_nfcf_poll *)params;
target->sensf_res_len = nfcf_poll->sensf_res_len;
if (target->sensf_res_len > ARRAY_SIZE(target->sensf_res))
return -EPROTO;
if (target->sensf_res_len > 0) {
memcpy(target->sensf_res, nfcf_poll->sensf_res,
target->sensf_res_len);
}
} else if (rf_tech_and_mode == NCI_NFC_V_PASSIVE_POLL_MODE) {
nfcv_poll = (struct rf_tech_specific_params_nfcv_poll *)params;
target->is_iso15693 = 1;
target->iso15693_dsfid = nfcv_poll->dsfid;
memcpy(target->iso15693_uid, nfcv_poll->uid, NFC_ISO15693_UID_MAXSIZE);
} else {
pr_err("unsupported rf_tech_and_mode 0x%x\n", rf_tech_and_mode);
return -EPROTO;
}
target->supported_protocols |= protocol;
pr_debug("protocol 0x%x\n", protocol);
return 0;
}
static void nci_add_new_target(struct nci_dev *ndev,
const struct nci_rf_discover_ntf *ntf)
{
struct nfc_target *target;
int i, rc;
for (i = 0; i < ndev->n_targets; i++) {
target = &ndev->targets[i];
if (target->logical_idx == ntf->rf_discovery_id) {
/* This target already exists, add the new protocol */
nci_add_new_protocol(ndev, target, ntf->rf_protocol,
ntf->rf_tech_and_mode,
&ntf->rf_tech_specific_params);
return;
}
}
/* This is a new target, check if we've enough room */
if (ndev->n_targets == NCI_MAX_DISCOVERED_TARGETS) {
pr_debug("not enough room, ignoring new target...\n");
return;
}
target = &ndev->targets[ndev->n_targets];
rc = nci_add_new_protocol(ndev, target, ntf->rf_protocol,
ntf->rf_tech_and_mode,
&ntf->rf_tech_specific_params);
if (!rc) {
target->logical_idx = ntf->rf_discovery_id;
ndev->n_targets++;
pr_debug("logical idx %d, n_targets %d\n", target->logical_idx,
ndev->n_targets);
}
}
void nci_clear_target_list(struct nci_dev *ndev)
{
memset(ndev->targets, 0,
(sizeof(struct nfc_target)*NCI_MAX_DISCOVERED_TARGETS));
ndev->n_targets = 0;
}
static void nci_rf_discover_ntf_packet(struct nci_dev *ndev,
const struct sk_buff *skb)
{
struct nci_rf_discover_ntf ntf;
const __u8 *data = skb->data;
bool add_target = true;
ntf.rf_discovery_id = *data++;
ntf.rf_protocol = *data++;
ntf.rf_tech_and_mode = *data++;
ntf.rf_tech_specific_params_len = *data++;
pr_debug("rf_discovery_id %d\n", ntf.rf_discovery_id);
pr_debug("rf_protocol 0x%x\n", ntf.rf_protocol);
pr_debug("rf_tech_and_mode 0x%x\n", ntf.rf_tech_and_mode);
pr_debug("rf_tech_specific_params_len %d\n",
ntf.rf_tech_specific_params_len);
if (ntf.rf_tech_specific_params_len > 0) {
switch (ntf.rf_tech_and_mode) {
case NCI_NFC_A_PASSIVE_POLL_MODE:
data = nci_extract_rf_params_nfca_passive_poll(ndev,
&(ntf.rf_tech_specific_params.nfca_poll), data);
break;
case NCI_NFC_B_PASSIVE_POLL_MODE:
data = nci_extract_rf_params_nfcb_passive_poll(ndev,
&(ntf.rf_tech_specific_params.nfcb_poll), data);
break;
case NCI_NFC_F_PASSIVE_POLL_MODE:
data = nci_extract_rf_params_nfcf_passive_poll(ndev,
&(ntf.rf_tech_specific_params.nfcf_poll), data);
break;
case NCI_NFC_V_PASSIVE_POLL_MODE:
data = nci_extract_rf_params_nfcv_passive_poll(ndev,
&(ntf.rf_tech_specific_params.nfcv_poll), data);
break;
default:
pr_err("unsupported rf_tech_and_mode 0x%x\n",
ntf.rf_tech_and_mode);
data += ntf.rf_tech_specific_params_len;
add_target = false;
}
}
ntf.ntf_type = *data++;
pr_debug("ntf_type %d\n", ntf.ntf_type);
if (add_target == true)
nci_add_new_target(ndev, &ntf);
if (ntf.ntf_type == NCI_DISCOVER_NTF_TYPE_MORE) {
atomic_set(&ndev->state, NCI_W4_ALL_DISCOVERIES);
} else {
atomic_set(&ndev->state, NCI_W4_HOST_SELECT);
nfc_targets_found(ndev->nfc_dev, ndev->targets,
ndev->n_targets);
}
}
static int nci_extract_activation_params_iso_dep(struct nci_dev *ndev,
struct nci_rf_intf_activated_ntf *ntf,
const __u8 *data)
{
struct activation_params_nfca_poll_iso_dep *nfca_poll;
struct activation_params_nfcb_poll_iso_dep *nfcb_poll;
switch (ntf->activation_rf_tech_and_mode) {
case NCI_NFC_A_PASSIVE_POLL_MODE:
nfca_poll = &ntf->activation_params.nfca_poll_iso_dep;
nfca_poll->rats_res_len = min_t(__u8, *data++, 20);
pr_debug("rats_res_len %d\n", nfca_poll->rats_res_len);
if (nfca_poll->rats_res_len > 0) {
memcpy(nfca_poll->rats_res,
data, nfca_poll->rats_res_len);
}
break;
case NCI_NFC_B_PASSIVE_POLL_MODE:
nfcb_poll = &ntf->activation_params.nfcb_poll_iso_dep;
nfcb_poll->attrib_res_len = min_t(__u8, *data++, 50);
pr_debug("attrib_res_len %d\n", nfcb_poll->attrib_res_len);
if (nfcb_poll->attrib_res_len > 0) {
memcpy(nfcb_poll->attrib_res,
data, nfcb_poll->attrib_res_len);
}
break;
default:
pr_err("unsupported activation_rf_tech_and_mode 0x%x\n",
ntf->activation_rf_tech_and_mode);
return NCI_STATUS_RF_PROTOCOL_ERROR;
}
return NCI_STATUS_OK;
}
static int nci_extract_activation_params_nfc_dep(struct nci_dev *ndev,
struct nci_rf_intf_activated_ntf *ntf,
const __u8 *data)
{
struct activation_params_poll_nfc_dep *poll;
struct activation_params_listen_nfc_dep *listen;
switch (ntf->activation_rf_tech_and_mode) {
case NCI_NFC_A_PASSIVE_POLL_MODE:
case NCI_NFC_F_PASSIVE_POLL_MODE:
poll = &ntf->activation_params.poll_nfc_dep;
poll->atr_res_len = min_t(__u8, *data++,
NFC_ATR_RES_MAXSIZE - 2);
pr_debug("atr_res_len %d\n", poll->atr_res_len);
if (poll->atr_res_len > 0)
memcpy(poll->atr_res, data, poll->atr_res_len);
break;
case NCI_NFC_A_PASSIVE_LISTEN_MODE:
case NCI_NFC_F_PASSIVE_LISTEN_MODE:
listen = &ntf->activation_params.listen_nfc_dep;
listen->atr_req_len = min_t(__u8, *data++,
NFC_ATR_REQ_MAXSIZE - 2);
pr_debug("atr_req_len %d\n", listen->atr_req_len);
if (listen->atr_req_len > 0)
memcpy(listen->atr_req, data, listen->atr_req_len);
break;
default:
pr_err("unsupported activation_rf_tech_and_mode 0x%x\n",
ntf->activation_rf_tech_and_mode);
return NCI_STATUS_RF_PROTOCOL_ERROR;
}
return NCI_STATUS_OK;
}
static void nci_target_auto_activated(struct nci_dev *ndev,
const struct nci_rf_intf_activated_ntf *ntf)
{
struct nfc_target *target;
int rc;
target = &ndev->targets[ndev->n_targets];
rc = nci_add_new_protocol(ndev, target, ntf->rf_protocol,
ntf->activation_rf_tech_and_mode,
&ntf->rf_tech_specific_params);
if (rc)
return;
target->logical_idx = ntf->rf_discovery_id;
ndev->n_targets++;
pr_debug("logical idx %d, n_targets %d\n",
target->logical_idx, ndev->n_targets);
nfc_targets_found(ndev->nfc_dev, ndev->targets, ndev->n_targets);
}
static int nci_store_general_bytes_nfc_dep(struct nci_dev *ndev,
const struct nci_rf_intf_activated_ntf *ntf)
{
ndev->remote_gb_len = 0;
if (ntf->activation_params_len <= 0)
return NCI_STATUS_OK;
switch (ntf->activation_rf_tech_and_mode) {
case NCI_NFC_A_PASSIVE_POLL_MODE:
case NCI_NFC_F_PASSIVE_POLL_MODE:
ndev->remote_gb_len = min_t(__u8,
(ntf->activation_params.poll_nfc_dep.atr_res_len
- NFC_ATR_RES_GT_OFFSET),
NFC_ATR_RES_GB_MAXSIZE);
memcpy(ndev->remote_gb,
(ntf->activation_params.poll_nfc_dep.atr_res
+ NFC_ATR_RES_GT_OFFSET),
ndev->remote_gb_len);
break;
case NCI_NFC_A_PASSIVE_LISTEN_MODE:
case NCI_NFC_F_PASSIVE_LISTEN_MODE:
ndev->remote_gb_len = min_t(__u8,
(ntf->activation_params.listen_nfc_dep.atr_req_len
- NFC_ATR_REQ_GT_OFFSET),
NFC_ATR_REQ_GB_MAXSIZE);
memcpy(ndev->remote_gb,
(ntf->activation_params.listen_nfc_dep.atr_req
+ NFC_ATR_REQ_GT_OFFSET),
ndev->remote_gb_len);
break;
default:
pr_err("unsupported activation_rf_tech_and_mode 0x%x\n",
ntf->activation_rf_tech_and_mode);
return NCI_STATUS_RF_PROTOCOL_ERROR;
}
return NCI_STATUS_OK;
}
static void nci_rf_intf_activated_ntf_packet(struct nci_dev *ndev,
const struct sk_buff *skb)
{
struct nci_conn_info *conn_info;
struct nci_rf_intf_activated_ntf ntf;
const __u8 *data = skb->data;
int err = NCI_STATUS_OK;
ntf.rf_discovery_id = *data++;
ntf.rf_interface = *data++;
ntf.rf_protocol = *data++;
ntf.activation_rf_tech_and_mode = *data++;
ntf.max_data_pkt_payload_size = *data++;
ntf.initial_num_credits = *data++;
ntf.rf_tech_specific_params_len = *data++;
pr_debug("rf_discovery_id %d\n", ntf.rf_discovery_id);
pr_debug("rf_interface 0x%x\n", ntf.rf_interface);
pr_debug("rf_protocol 0x%x\n", ntf.rf_protocol);
pr_debug("activation_rf_tech_and_mode 0x%x\n",
ntf.activation_rf_tech_and_mode);
pr_debug("max_data_pkt_payload_size 0x%x\n",
ntf.max_data_pkt_payload_size);
pr_debug("initial_num_credits 0x%x\n",
ntf.initial_num_credits);
pr_debug("rf_tech_specific_params_len %d\n",
ntf.rf_tech_specific_params_len);
/* If this contains a value of 0x00 (NFCEE Direct RF
* Interface) then all following parameters SHALL contain a
* value of 0 and SHALL be ignored.
*/
if (ntf.rf_interface == NCI_RF_INTERFACE_NFCEE_DIRECT)
goto listen;
if (ntf.rf_tech_specific_params_len > 0) {
switch (ntf.activation_rf_tech_and_mode) {
case NCI_NFC_A_PASSIVE_POLL_MODE:
data = nci_extract_rf_params_nfca_passive_poll(ndev,
&(ntf.rf_tech_specific_params.nfca_poll), data);
break;
case NCI_NFC_B_PASSIVE_POLL_MODE:
data = nci_extract_rf_params_nfcb_passive_poll(ndev,
&(ntf.rf_tech_specific_params.nfcb_poll), data);
break;
case NCI_NFC_F_PASSIVE_POLL_MODE:
data = nci_extract_rf_params_nfcf_passive_poll(ndev,
&(ntf.rf_tech_specific_params.nfcf_poll), data);
break;
case NCI_NFC_V_PASSIVE_POLL_MODE:
data = nci_extract_rf_params_nfcv_passive_poll(ndev,
&(ntf.rf_tech_specific_params.nfcv_poll), data);
break;
case NCI_NFC_A_PASSIVE_LISTEN_MODE:
/* no RF technology specific parameters */
break;
case NCI_NFC_F_PASSIVE_LISTEN_MODE:
data = nci_extract_rf_params_nfcf_passive_listen(ndev,
&(ntf.rf_tech_specific_params.nfcf_listen),
data);
break;
default:
pr_err("unsupported activation_rf_tech_and_mode 0x%x\n",
ntf.activation_rf_tech_and_mode);
err = NCI_STATUS_RF_PROTOCOL_ERROR;
goto exit;
}
}
ntf.data_exch_rf_tech_and_mode = *data++;
ntf.data_exch_tx_bit_rate = *data++;
ntf.data_exch_rx_bit_rate = *data++;
ntf.activation_params_len = *data++;
pr_debug("data_exch_rf_tech_and_mode 0x%x\n",
ntf.data_exch_rf_tech_and_mode);
pr_debug("data_exch_tx_bit_rate 0x%x\n", ntf.data_exch_tx_bit_rate);
pr_debug("data_exch_rx_bit_rate 0x%x\n", ntf.data_exch_rx_bit_rate);
pr_debug("activation_params_len %d\n", ntf.activation_params_len);
if (ntf.activation_params_len > 0) {
switch (ntf.rf_interface) {
case NCI_RF_INTERFACE_ISO_DEP:
err = nci_extract_activation_params_iso_dep(ndev,
&ntf, data);
break;
case NCI_RF_INTERFACE_NFC_DEP:
err = nci_extract_activation_params_nfc_dep(ndev,
&ntf, data);
break;
case NCI_RF_INTERFACE_FRAME:
/* no activation params */
break;
default:
pr_err("unsupported rf_interface 0x%x\n",
ntf.rf_interface);
err = NCI_STATUS_RF_PROTOCOL_ERROR;
break;
}
}
exit:
if (err == NCI_STATUS_OK) {
conn_info = ndev->rf_conn_info;
if (!conn_info)
return;
conn_info->max_pkt_payload_len = ntf.max_data_pkt_payload_size;
conn_info->initial_num_credits = ntf.initial_num_credits;
/* set the available credits to initial value */
atomic_set(&conn_info->credits_cnt,
conn_info->initial_num_credits);
/* store general bytes to be reported later in dep_link_up */
if (ntf.rf_interface == NCI_RF_INTERFACE_NFC_DEP) {
err = nci_store_general_bytes_nfc_dep(ndev, &ntf);
if (err != NCI_STATUS_OK)
pr_err("unable to store general bytes\n");
}
}
if (!(ntf.activation_rf_tech_and_mode & NCI_RF_TECH_MODE_LISTEN_MASK)) {
/* Poll mode */
if (atomic_read(&ndev->state) == NCI_DISCOVERY) {
/* A single target was found and activated
* automatically */
atomic_set(&ndev->state, NCI_POLL_ACTIVE);
if (err == NCI_STATUS_OK)
nci_target_auto_activated(ndev, &ntf);
} else { /* ndev->state == NCI_W4_HOST_SELECT */
/* A selected target was activated, so complete the
* request */
atomic_set(&ndev->state, NCI_POLL_ACTIVE);
nci_req_complete(ndev, err);
}
} else {
listen:
/* Listen mode */
atomic_set(&ndev->state, NCI_LISTEN_ACTIVE);
if (err == NCI_STATUS_OK &&
ntf.rf_protocol == NCI_RF_PROTOCOL_NFC_DEP) {
err = nfc_tm_activated(ndev->nfc_dev,
NFC_PROTO_NFC_DEP_MASK,
NFC_COMM_PASSIVE,
ndev->remote_gb,
ndev->remote_gb_len);
if (err != NCI_STATUS_OK)
pr_err("error when signaling tm activation\n");
}
}
}
static void nci_rf_deactivate_ntf_packet(struct nci_dev *ndev,
const struct sk_buff *skb)
{
const struct nci_conn_info *conn_info;
const struct nci_rf_deactivate_ntf *ntf = (void *)skb->data;
pr_debug("entry, type 0x%x, reason 0x%x\n", ntf->type, ntf->reason);
conn_info = ndev->rf_conn_info;
if (!conn_info)
return;
/* drop tx data queue */
skb_queue_purge(&ndev->tx_q);
/* drop partial rx data packet */
if (ndev->rx_data_reassembly) {
kfree_skb(ndev->rx_data_reassembly);
ndev->rx_data_reassembly = NULL;
}
/* complete the data exchange transaction, if exists */
if (test_bit(NCI_DATA_EXCHANGE, &ndev->flags))
nci_data_exchange_complete(ndev, NULL, NCI_STATIC_RF_CONN_ID,
-EIO);
switch (ntf->type) {
case NCI_DEACTIVATE_TYPE_IDLE_MODE:
nci_clear_target_list(ndev);
atomic_set(&ndev->state, NCI_IDLE);
break;
case NCI_DEACTIVATE_TYPE_SLEEP_MODE:
case NCI_DEACTIVATE_TYPE_SLEEP_AF_MODE:
atomic_set(&ndev->state, NCI_W4_HOST_SELECT);
break;
case NCI_DEACTIVATE_TYPE_DISCOVERY:
nci_clear_target_list(ndev);
atomic_set(&ndev->state, NCI_DISCOVERY);
break;
}
nci_req_complete(ndev, NCI_STATUS_OK);
}
static void nci_nfcee_discover_ntf_packet(struct nci_dev *ndev,
const struct sk_buff *skb)
{
u8 status = NCI_STATUS_OK;
const struct nci_nfcee_discover_ntf *nfcee_ntf =
(struct nci_nfcee_discover_ntf *)skb->data;
/* NFCForum NCI 9.2.1 HCI Network Specific Handling
* If the NFCC supports the HCI Network, it SHALL return one,
* and only one, NFCEE_DISCOVER_NTF with a Protocol type of
* HCI Access, even if the HCI Network contains multiple NFCEEs.
*/
ndev->hci_dev->nfcee_id = nfcee_ntf->nfcee_id;
ndev->cur_params.id = nfcee_ntf->nfcee_id;
nci_req_complete(ndev, status);
}
void nci_ntf_packet(struct nci_dev *ndev, struct sk_buff *skb)
{
__u16 ntf_opcode = nci_opcode(skb->data);
pr_debug("NCI RX: MT=ntf, PBF=%d, GID=0x%x, OID=0x%x, plen=%d\n",
nci_pbf(skb->data),
nci_opcode_gid(ntf_opcode),
nci_opcode_oid(ntf_opcode),
nci_plen(skb->data));
/* strip the nci control header */
skb_pull(skb, NCI_CTRL_HDR_SIZE);
if (nci_opcode_gid(ntf_opcode) == NCI_GID_PROPRIETARY) {
if (nci_prop_ntf_packet(ndev, ntf_opcode, skb) == -ENOTSUPP) {
pr_err("unsupported ntf opcode 0x%x\n",
ntf_opcode);
}
goto end;
}
switch (ntf_opcode) {
net/nfc/nci: Support NCI 2.x initial sequence implement the NCI 2.x initial sequence to support NCI 2.x NFCC. Since NCI 2.0, CORE_RESET and CORE_INIT sequence have been changed. If NFCEE supports NCI 2.x, then NCI 2.x initial sequence will work. In NCI 1.0, Initial sequence and payloads are as below: (DH) (NFCC) | -- CORE_RESET_CMD --> | | <-- CORE_RESET_RSP -- | | -- CORE_INIT_CMD --> | | <-- CORE_INIT_RSP -- | CORE_RESET_RSP payloads are Status, NCI version, Configuration Status. CORE_INIT_CMD payloads are empty. CORE_INIT_RSP payloads are Status, NFCC Features, Number of Supported RF Interfaces, Supported RF Interface, Max Logical Connections, Max Routing table Size, Max Control Packet Payload Size, Max Size for Large Parameters, Manufacturer ID, Manufacturer Specific Information. In NCI 2.0, Initial Sequence and Parameters are as below: (DH) (NFCC) | -- CORE_RESET_CMD --> | | <-- CORE_RESET_RSP -- | | <-- CORE_RESET_NTF -- | | -- CORE_INIT_CMD --> | | <-- CORE_INIT_RSP -- | CORE_RESET_RSP payloads are Status. CORE_RESET_NTF payloads are Reset Trigger, Configuration Status, NCI Version, Manufacturer ID, Manufacturer Specific Information Length, Manufacturer Specific Information. CORE_INIT_CMD payloads are Feature1, Feature2. CORE_INIT_RSP payloads are Status, NFCC Features, Max Logical Connections, Max Routing Table Size, Max Control Packet Payload Size, Max Data Packet Payload Size of the Static HCI Connection, Number of Credits of the Static HCI Connection, Max NFC-V RF Frame Size, Number of Supported RF Interfaces, Supported RF Interfaces. Signed-off-by: Bongsu Jeon <bongsu.jeon@samsung.com> Link: https://lore.kernel.org/r/20201202223147.3472-1-bongsu.jeon@samsung.com Signed-off-by: Jakub Kicinski <kuba@kernel.org>
2020-12-03 06:31:47 +08:00
case NCI_OP_CORE_RESET_NTF:
nci_core_reset_ntf_packet(ndev, skb);
break;
case NCI_OP_CORE_CONN_CREDITS_NTF:
nci_core_conn_credits_ntf_packet(ndev, skb);
break;
case NCI_OP_CORE_GENERIC_ERROR_NTF:
nci_core_generic_error_ntf_packet(ndev, skb);
break;
case NCI_OP_CORE_INTF_ERROR_NTF:
nci_core_conn_intf_error_ntf_packet(ndev, skb);
break;
case NCI_OP_RF_DISCOVER_NTF:
nci_rf_discover_ntf_packet(ndev, skb);
break;
case NCI_OP_RF_INTF_ACTIVATED_NTF:
nci_rf_intf_activated_ntf_packet(ndev, skb);
break;
case NCI_OP_RF_DEACTIVATE_NTF:
nci_rf_deactivate_ntf_packet(ndev, skb);
break;
case NCI_OP_NFCEE_DISCOVER_NTF:
nci_nfcee_discover_ntf_packet(ndev, skb);
break;
case NCI_OP_RF_NFCEE_ACTION_NTF:
break;
default:
pr_err("unknown ntf opcode 0x%x\n", ntf_opcode);
break;
}
nci_core_ntf_packet(ndev, ntf_opcode, skb);
end:
kfree_skb(skb);
}