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Qualcomm ARM Based Driver Updates for v4.16 - Redo 

* Fix error handling code in SMP2P probe
 * Update SMP2P to use ACPS as mailbox client
 * Add QMI support
 * Fixups for Qualcomm SCM
 * Fix licensing on rmtfs_mem
 * Correct SMSM child node lookup
 * Populate firmware nodes during platform init
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Merge tag 'qcom-drivers-for-4.16' of ssh://gitolite.kernel.org/pub/scm/linux/kernel/git/agross/linux into next/drivers

Pull "Qualcomm ARM Based Driver Updates for v4.16 - Redo" from Andy Gross:

* Fix error handling code in SMP2P probe
* Update SMP2P to use ACPS as mailbox client
* Add QMI support
* Fixups for Qualcomm SCM
* Fix licensing on rmtfs_mem
* Correct SMSM child node lookup
* Populate firmware nodes during platform init

* tag 'qcom-drivers-for-4.16' of ssh://gitolite.kernel.org/pub/scm/linux/kernel/git/agross/linux:
  of: platform: populate /firmware/ node from of_platform_default_populate_init()
  soc: qcom: smp2p: Use common error handling code in qcom_smp2p_probe()
  soc: qcom: Introduce QMI helpers
  soc: qcom: Introduce QMI encoder/decoder
  firmware: qcom_scm: Add dependent headers to qcom_scm.h
  soc: qcom: smp2p: Access APCS as mailbox client
  soc: qcom: rmtfs_mem: add missing MODULE_DESCRIPTION/AUTHOR/LICENSE
  soc: qcom: smsm: fix child-node lookup
  firmware: qcom_scm: drop redandant of_platform_populate
This commit is contained in:
Arnd Bergmann 2018-01-05 12:22:53 +01:00
parent 57e36159cc 3aa0582fdb
commit 830ebd37c5
12 changed files with 2010 additions and 41 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

8
Documentation/devicetree/bindings/soc/qcom/qcom,smp2p.txt
View File

@ -17,9 +17,15 @@ processor ID) and a string identifier.
Value type: <prop-encoded-array>
Definition: one entry specifying the smp2p notification interrupt
- qcom,ipc:
- mboxes:
Usage: required
Value type: <prop-encoded-array>
Definition: reference to the associated doorbell in APCS, as described
in mailbox/mailbox.txt
- qcom,ipc:
Usage: required, unless mboxes is specified
Value type: <prop-encoded-array>
Definition: three entries specifying the outgoing ipc bit used for
signaling the remote end of the smp2p edge:
- phandle to a syscon node representing the apcs registers

24
drivers/firmware/qcom_scm.c
View File

@ -622,30 +622,6 @@ static struct platform_driver qcom_scm_driver = {
static int __init qcom_scm_init(void)
{
struct device_node *np, *fw_np;
int ret;
fw_np = of_find_node_by_name(NULL, "firmware");
if (!fw_np)
return -ENODEV;
np = of_find_matching_node(fw_np, qcom_scm_dt_match);
if (!np) {
of_node_put(fw_np);
return -ENODEV;
}
of_node_put(np);
ret = of_platform_populate(fw_np, qcom_scm_dt_match, NULL, NULL);
of_node_put(fw_np);
if (ret)
return ret;
return platform_driver_register(&qcom_scm_driver);
}
subsys_initcall(qcom_scm_init);

4
drivers/of/platform.c
View File

@ -518,6 +518,10 @@ static int __init of_platform_default_populate_init(void)
for_each_matching_node(node, reserved_mem_matches)
of_platform_device_create(node, NULL, NULL);
node = of_find_node_by_path("/firmware");
if (node)
of_platform_populate(node, NULL, NULL, NULL);
/* Populate everything else. */
of_platform_default_populate(NULL, NULL, NULL);

10
drivers/soc/qcom/Kconfig
View File

@ -35,6 +35,15 @@ config QCOM_PM
modes. It interface with various system drivers to put the cores in
low power modes.
config QCOM_QMI_HELPERS
tristate
depends on ARCH_QCOM
help
Helper library for handling QMI encoded messages. QMI encoded
messages are used in communication between the majority of QRTR
clients and this helpers provide the common functionality needed for
doing this from a kernel driver.
config QCOM_RMTFS_MEM
tristate "Qualcomm Remote Filesystem memory driver"
depends on ARCH_QCOM
@ -75,6 +84,7 @@ config QCOM_SMEM_STATE
config QCOM_SMP2P
tristate "Qualcomm Shared Memory Point to Point support"
depends on MAILBOX
depends on QCOM_SMEM
select QCOM_SMEM_STATE
help

2
drivers/soc/qcom/Makefile
View File

@ -3,6 +3,8 @@ obj-$(CONFIG_QCOM_GLINK_SSR) += glink_ssr.o
obj-$(CONFIG_QCOM_GSBI) += qcom_gsbi.o
obj-$(CONFIG_QCOM_MDT_LOADER) += mdt_loader.o
obj-$(CONFIG_QCOM_PM) += spm.o
obj-$(CONFIG_QCOM_QMI_HELPERS) += qmi_helpers.o
qmi_helpers-y += qmi_encdec.o qmi_interface.o
obj-$(CONFIG_QCOM_RMTFS_MEM) += rmtfs_mem.o
obj-$(CONFIG_QCOM_SMD_RPM) += smd-rpm.o
obj-$(CONFIG_QCOM_SMEM) += smem.o

816
drivers/soc/qcom/qmi_encdec.c Normal file
View File

@ -0,0 +1,816 @@
// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (c) 2012-2015, The Linux Foundation. All rights reserved.
* Copyright (C) 2017 Linaro Ltd.
*/
#include <linux/slab.h>
#include <linux/uaccess.h>
#include <linux/module.h>
#include <linux/kernel.h>
#include <linux/errno.h>
#include <linux/string.h>
#include <linux/soc/qcom/qmi.h>
#define QMI_ENCDEC_ENCODE_TLV(type, length, p_dst) do { \
*p_dst++ = type; \
*p_dst++ = ((u8)((length) & 0xFF)); \
*p_dst++ = ((u8)(((length) >> 8) & 0xFF)); \
} while (0)
#define QMI_ENCDEC_DECODE_TLV(p_type, p_length, p_src) do { \
*p_type = (u8)*p_src++; \
*p_length = (u8)*p_src++; \
*p_length |= ((u8)*p_src) << 8; \
} while (0)
#define QMI_ENCDEC_ENCODE_N_BYTES(p_dst, p_src, size) \
do { \
memcpy(p_dst, p_src, size); \
p_dst = (u8 *)p_dst + size; \
p_src = (u8 *)p_src + size; \
} while (0)
#define QMI_ENCDEC_DECODE_N_BYTES(p_dst, p_src, size) \
do { \
memcpy(p_dst, p_src, size); \
p_dst = (u8 *)p_dst + size; \
p_src = (u8 *)p_src + size; \
} while (0)
#define UPDATE_ENCODE_VARIABLES(temp_si, buf_dst, \
encoded_bytes, tlv_len, encode_tlv, rc) \
do { \
buf_dst = (u8 *)buf_dst + rc; \
encoded_bytes += rc; \
tlv_len += rc; \
temp_si = temp_si + 1; \
encode_tlv = 1; \
} while (0)
#define UPDATE_DECODE_VARIABLES(buf_src, decoded_bytes, rc) \
do { \
buf_src = (u8 *)buf_src + rc; \
decoded_bytes += rc; \
} while (0)
#define TLV_LEN_SIZE sizeof(u16)
#define TLV_TYPE_SIZE sizeof(u8)
#define OPTIONAL_TLV_TYPE_START 0x10
static int qmi_encode(struct qmi_elem_info *ei_array, void *out_buf,
const void *in_c_struct, u32 out_buf_len,
int enc_level);
static int qmi_decode(struct qmi_elem_info *ei_array, void *out_c_struct,
const void *in_buf, u32 in_buf_len, int dec_level);
/**
* skip_to_next_elem() - Skip to next element in the structure to be encoded
* @ei_array: Struct info describing the element to be skipped.
* @level: Depth level of encoding/decoding to identify nested structures.
*
* This function is used while encoding optional elements. If the flag
* corresponding to an optional element is not set, then encoding the
* optional element can be skipped. This function can be used to perform
* that operation.
*
* Return: struct info of the next element that can be encoded.
*/
static struct qmi_elem_info *skip_to_next_elem(struct qmi_elem_info *ei_array,
int level)
{
struct qmi_elem_info *temp_ei = ei_array;
u8 tlv_type;
if (level > 1) {
temp_ei = temp_ei + 1;
} else {
do {
tlv_type = temp_ei->tlv_type;
temp_ei = temp_ei + 1;
} while (tlv_type == temp_ei->tlv_type);
}
return temp_ei;
}
/**
* qmi_calc_min_msg_len() - Calculate the minimum length of a QMI message
* @ei_array: Struct info array describing the structure.
* @level: Level to identify the depth of the nested structures.
*
* Return: Expected minimum length of the QMI message or 0 on error.
*/
static int qmi_calc_min_msg_len(struct qmi_elem_info *ei_array,
int level)
{
int min_msg_len = 0;
struct qmi_elem_info *temp_ei = ei_array;
if (!ei_array)
return min_msg_len;
while (temp_ei->data_type != QMI_EOTI) {
/* Optional elements do not count in minimum length */
if (temp_ei->data_type == QMI_OPT_FLAG) {
temp_ei = skip_to_next_elem(temp_ei, level);
continue;
}
if (temp_ei->data_type == QMI_DATA_LEN) {
min_msg_len += (temp_ei->elem_size == sizeof(u8) ?
sizeof(u8) : sizeof(u16));
temp_ei++;
continue;
} else if (temp_ei->data_type == QMI_STRUCT) {
min_msg_len += qmi_calc_min_msg_len(temp_ei->ei_array,
(level + 1));
temp_ei++;
} else if (temp_ei->data_type == QMI_STRING) {
if (level > 1)
min_msg_len += temp_ei->elem_len <= U8_MAX ?
sizeof(u8) : sizeof(u16);
min_msg_len += temp_ei->elem_len * temp_ei->elem_size;
temp_ei++;
} else {
min_msg_len += (temp_ei->elem_len * temp_ei->elem_size);
temp_ei++;
}
/*
* Type & Length info. not prepended for elements in the
* nested structure.
*/
if (level == 1)
min_msg_len += (TLV_TYPE_SIZE + TLV_LEN_SIZE);
}
return min_msg_len;
}
/**
* qmi_encode_basic_elem() - Encodes elements of basic/primary data type
* @buf_dst: Buffer to store the encoded information.
* @buf_src: Buffer containing the elements to be encoded.
* @elem_len: Number of elements, in the buf_src, to be encoded.
* @elem_size: Size of a single instance of the element to be encoded.
*
* This function encodes the "elem_len" number of data elements, each of
* size "elem_size" bytes from the source buffer "buf_src" and stores the
* encoded information in the destination buffer "buf_dst". The elements are
* of primary data type which include u8 - u64 or similar. This
* function returns the number of bytes of encoded information.
*
* Return: The number of bytes of encoded information.
*/
static int qmi_encode_basic_elem(void *buf_dst, const void *buf_src,
u32 elem_len, u32 elem_size)
{
u32 i, rc = 0;
for (i = 0; i < elem_len; i++) {
QMI_ENCDEC_ENCODE_N_BYTES(buf_dst, buf_src, elem_size);
rc += elem_size;
}
return rc;
}
/**
* qmi_encode_struct_elem() - Encodes elements of struct data type
* @ei_array: Struct info array descibing the struct element.
* @buf_dst: Buffer to store the encoded information.
* @buf_src: Buffer containing the elements to be encoded.
* @elem_len: Number of elements, in the buf_src, to be encoded.
* @out_buf_len: Available space in the encode buffer.
* @enc_level: Depth of the nested structure from the main structure.
*
* This function encodes the "elem_len" number of struct elements, each of
* size "ei_array->elem_size" bytes from the source buffer "buf_src" and
* stores the encoded information in the destination buffer "buf_dst". The
* elements are of struct data type which includes any C structure. This
* function returns the number of bytes of encoded information.
*
* Return: The number of bytes of encoded information on success or negative
* errno on error.
*/
static int qmi_encode_struct_elem(struct qmi_elem_info *ei_array,
void *buf_dst, const void *buf_src,
u32 elem_len, u32 out_buf_len,
int enc_level)
{
int i, rc, encoded_bytes = 0;
struct qmi_elem_info *temp_ei = ei_array;
for (i = 0; i < elem_len; i++) {
rc = qmi_encode(temp_ei->ei_array, buf_dst, buf_src,
out_buf_len - encoded_bytes, enc_level);
if (rc < 0) {
pr_err("%s: STRUCT Encode failure\n", __func__);
return rc;
}
buf_dst = buf_dst + rc;
buf_src = buf_src + temp_ei->elem_size;
encoded_bytes += rc;
}
return encoded_bytes;
}
/**
* qmi_encode_string_elem() - Encodes elements of string data type
* @ei_array: Struct info array descibing the string element.
* @buf_dst: Buffer to store the encoded information.
* @buf_src: Buffer containing the elements to be encoded.
* @out_buf_len: Available space in the encode buffer.
* @enc_level: Depth of the string element from the main structure.
*
* This function encodes a string element of maximum length "ei_array->elem_len"
* bytes from the source buffer "buf_src" and stores the encoded information in
* the destination buffer "buf_dst". This function returns the number of bytes
* of encoded information.
*
* Return: The number of bytes of encoded information on success or negative
* errno on error.
*/
static int qmi_encode_string_elem(struct qmi_elem_info *ei_array,
void *buf_dst, const void *buf_src,
u32 out_buf_len, int enc_level)
{
int rc;
int encoded_bytes = 0;
struct qmi_elem_info *temp_ei = ei_array;
u32 string_len = 0;
u32 string_len_sz = 0;
string_len = strlen(buf_src);
string_len_sz = temp_ei->elem_len <= U8_MAX ?
sizeof(u8) : sizeof(u16);
if (string_len > temp_ei->elem_len) {
pr_err("%s: String to be encoded is longer - %d > %d\n",
__func__, string_len, temp_ei->elem_len);
return -EINVAL;
}
if (enc_level == 1) {
if (string_len + TLV_LEN_SIZE + TLV_TYPE_SIZE >
out_buf_len) {
pr_err("%s: Output len %d > Out Buf len %d\n",
__func__, string_len, out_buf_len);
return -ETOOSMALL;
}
} else {
if (string_len + string_len_sz > out_buf_len) {
pr_err("%s: Output len %d > Out Buf len %d\n",
__func__, string_len, out_buf_len);
return -ETOOSMALL;
}
rc = qmi_encode_basic_elem(buf_dst, &string_len,
1, string_len_sz);
encoded_bytes += rc;
}
rc = qmi_encode_basic_elem(buf_dst + encoded_bytes, buf_src,
string_len, temp_ei->elem_size);
encoded_bytes += rc;
return encoded_bytes;
}
/**
* qmi_encode() - Core Encode Function
* @ei_array: Struct info array describing the structure to be encoded.
* @out_buf: Buffer to hold the encoded QMI message.
* @in_c_struct: Pointer to the C structure to be encoded.
* @out_buf_len: Available space in the encode buffer.
* @enc_level: Encode level to indicate the depth of the nested structure,
* within the main structure, being encoded.
*
* Return: The number of bytes of encoded information on success or negative
* errno on error.
*/
static int qmi_encode(struct qmi_elem_info *ei_array, void *out_buf,
const void *in_c_struct, u32 out_buf_len,
int enc_level)
{
struct qmi_elem_info *temp_ei = ei_array;
u8 opt_flag_value = 0;
u32 data_len_value = 0, data_len_sz;
u8 *buf_dst = (u8 *)out_buf;
u8 *tlv_pointer;
u32 tlv_len;
u8 tlv_type;
u32 encoded_bytes = 0;
const void *buf_src;
int encode_tlv = 0;
int rc;
if (!ei_array)
return 0;
tlv_pointer = buf_dst;
tlv_len = 0;
if (enc_level == 1)
buf_dst = buf_dst + (TLV_LEN_SIZE + TLV_TYPE_SIZE);
while (temp_ei->data_type != QMI_EOTI) {
buf_src = in_c_struct + temp_ei->offset;
tlv_type = temp_ei->tlv_type;
if (temp_ei->array_type == NO_ARRAY) {
data_len_value = 1;
} else if (temp_ei->array_type == STATIC_ARRAY) {
data_len_value = temp_ei->elem_len;
} else if (data_len_value <= 0 ||
temp_ei->elem_len < data_len_value) {
pr_err("%s: Invalid data length\n", __func__);
return -EINVAL;
}
switch (temp_ei->data_type) {
case QMI_OPT_FLAG:
rc = qmi_encode_basic_elem(&opt_flag_value, buf_src,
1, sizeof(u8));
if (opt_flag_value)
temp_ei = temp_ei + 1;
else
temp_ei = skip_to_next_elem(temp_ei, enc_level);
break;
case QMI_DATA_LEN:
memcpy(&data_len_value, buf_src, temp_ei->elem_size);
data_len_sz = temp_ei->elem_size == sizeof(u8) ?
sizeof(u8) : sizeof(u16);
/* Check to avoid out of range buffer access */
if ((data_len_sz + encoded_bytes + TLV_LEN_SIZE +
TLV_TYPE_SIZE) > out_buf_len) {
pr_err("%s: Too Small Buffer @DATA_LEN\n",
__func__);
return -ETOOSMALL;
}
rc = qmi_encode_basic_elem(buf_dst, &data_len_value,
1, data_len_sz);
UPDATE_ENCODE_VARIABLES(temp_ei, buf_dst,
encoded_bytes, tlv_len,
encode_tlv, rc);
if (!data_len_value)
temp_ei = skip_to_next_elem(temp_ei, enc_level);
else
encode_tlv = 0;
break;
case QMI_UNSIGNED_1_BYTE:
case QMI_UNSIGNED_2_BYTE:
case QMI_UNSIGNED_4_BYTE:
case QMI_UNSIGNED_8_BYTE:
case QMI_SIGNED_2_BYTE_ENUM:
case QMI_SIGNED_4_BYTE_ENUM:
/* Check to avoid out of range buffer access */
if (((data_len_value * temp_ei->elem_size) +
encoded_bytes + TLV_LEN_SIZE + TLV_TYPE_SIZE) >
out_buf_len) {
pr_err("%s: Too Small Buffer @data_type:%d\n",
__func__, temp_ei->data_type);
return -ETOOSMALL;
}
rc = qmi_encode_basic_elem(buf_dst, buf_src,
data_len_value,
temp_ei->elem_size);
UPDATE_ENCODE_VARIABLES(temp_ei, buf_dst,
encoded_bytes, tlv_len,
encode_tlv, rc);
break;
case QMI_STRUCT:
rc = qmi_encode_struct_elem(temp_ei, buf_dst, buf_src,
data_len_value,
out_buf_len - encoded_bytes,
enc_level + 1);
if (rc < 0)
return rc;
UPDATE_ENCODE_VARIABLES(temp_ei, buf_dst,
encoded_bytes, tlv_len,
encode_tlv, rc);
break;
case QMI_STRING:
rc = qmi_encode_string_elem(temp_ei, buf_dst, buf_src,
out_buf_len - encoded_bytes,
enc_level);
if (rc < 0)
return rc;
UPDATE_ENCODE_VARIABLES(temp_ei, buf_dst,
encoded_bytes, tlv_len,
encode_tlv, rc);
break;
default:
pr_err("%s: Unrecognized data type\n", __func__);
return -EINVAL;
}
if (encode_tlv && enc_level == 1) {
QMI_ENCDEC_ENCODE_TLV(tlv_type, tlv_len, tlv_pointer);
encoded_bytes += (TLV_TYPE_SIZE + TLV_LEN_SIZE);
tlv_pointer = buf_dst;
tlv_len = 0;
buf_dst = buf_dst + TLV_LEN_SIZE + TLV_TYPE_SIZE;
encode_tlv = 0;
}
}
return encoded_bytes;
}
/**
* qmi_decode_basic_elem() - Decodes elements of basic/primary data type
* @buf_dst: Buffer to store the decoded element.
* @buf_src: Buffer containing the elements in QMI wire format.
* @elem_len: Number of elements to be decoded.
* @elem_size: Size of a single instance of the element to be decoded.
*
* This function decodes the "elem_len" number of elements in QMI wire format,
* each of size "elem_size" bytes from the source buffer "buf_src" and stores
* the decoded elements in the destination buffer "buf_dst". The elements are
* of primary data type which include u8 - u64 or similar. This
* function returns the number of bytes of decoded information.
*
* Return: The total size of the decoded data elements, in bytes.
*/
static int qmi_decode_basic_elem(void *buf_dst, const void *buf_src,
u32 elem_len, u32 elem_size)
{
u32 i, rc = 0;
for (i = 0; i < elem_len; i++) {
QMI_ENCDEC_DECODE_N_BYTES(buf_dst, buf_src, elem_size);
rc += elem_size;
}
return rc;
}
/**
* qmi_decode_struct_elem() - Decodes elements of struct data type
* @ei_array: Struct info array descibing the struct element.
* @buf_dst: Buffer to store the decoded element.
* @buf_src: Buffer containing the elements in QMI wire format.
* @elem_len: Number of elements to be decoded.
* @tlv_len: Total size of the encoded inforation corresponding to
* this struct element.
* @dec_level: Depth of the nested structure from the main structure.
*
* This function decodes the "elem_len" number of elements in QMI wire format,
* each of size "(tlv_len/elem_len)" bytes from the source buffer "buf_src"
* and stores the decoded elements in the destination buffer "buf_dst". The
* elements are of struct data type which includes any C structure. This
* function returns the number of bytes of decoded information.
*
* Return: The total size of the decoded data elements on success, negative
* errno on error.
*/
static int qmi_decode_struct_elem(struct qmi_elem_info *ei_array,
void *buf_dst, const void *buf_src,
u32 elem_len, u32 tlv_len,
int dec_level)
{
int i, rc, decoded_bytes = 0;
struct qmi_elem_info *temp_ei = ei_array;
for (i = 0; i < elem_len && decoded_bytes < tlv_len; i++) {
rc = qmi_decode(temp_ei->ei_array, buf_dst, buf_src,
tlv_len - decoded_bytes, dec_level);
if (rc < 0)
return rc;
buf_src = buf_src + rc;
buf_dst = buf_dst + temp_ei->elem_size;
decoded_bytes += rc;
}
if ((dec_level <= 2 && decoded_bytes != tlv_len) ||
(dec_level > 2 && (i < elem_len || decoded_bytes > tlv_len))) {
pr_err("%s: Fault in decoding: dl(%d), db(%d), tl(%d), i(%d), el(%d)\n",
__func__, dec_level, decoded_bytes, tlv_len,
i, elem_len);
return -EFAULT;
}
return decoded_bytes;
}
/**
* qmi_decode_string_elem() - Decodes elements of string data type
* @ei_array: Struct info array descibing the string element.
* @buf_dst: Buffer to store the decoded element.
* @buf_src: Buffer containing the elements in QMI wire format.
* @tlv_len: Total size of the encoded inforation corresponding to
* this string element.
* @dec_level: Depth of the string element from the main structure.
*
* This function decodes the string element of maximum length
* "ei_array->elem_len" from the source buffer "buf_src" and puts it into
* the destination buffer "buf_dst". This function returns number of bytes
* decoded from the input buffer.
*
* Return: The total size of the decoded data elements on success, negative
* errno on error.
*/
static int qmi_decode_string_elem(struct qmi_elem_info *ei_array,
void *buf_dst, const void *buf_src,
u32 tlv_len, int dec_level)
{
int rc;
int decoded_bytes = 0;
u32 string_len = 0;
u32 string_len_sz = 0;
struct qmi_elem_info *temp_ei = ei_array;
if (dec_level == 1) {
string_len = tlv_len;
} else {
string_len_sz = temp_ei->elem_len <= U8_MAX ?
sizeof(u8) : sizeof(u16);
rc = qmi_decode_basic_elem(&string_len, buf_src,
1, string_len_sz);
decoded_bytes += rc;
}
if (string_len > temp_ei->elem_len) {
pr_err("%s: String len %d > Max Len %d\n",
__func__, string_len, temp_ei->elem_len);
return -ETOOSMALL;
} else if (string_len > tlv_len) {
pr_err("%s: String len %d > Input Buffer Len %d\n",
__func__, string_len, tlv_len);
return -EFAULT;
}
rc = qmi_decode_basic_elem(buf_dst, buf_src + decoded_bytes,
string_len, temp_ei->elem_size);
*((char *)buf_dst + string_len) = '\0';
decoded_bytes += rc;
return decoded_bytes;
}
/**
* find_ei() - Find element info corresponding to TLV Type
* @ei_array: Struct info array of the message being decoded.
* @type: TLV Type of the element being searched.
*
* Every element that got encoded in the QMI message will have a type
* information associated with it. While decoding the QMI message,
* this function is used to find the struct info regarding the element
* that corresponds to the type being decoded.
*
* Return: Pointer to struct info, if found
*/
static struct qmi_elem_info *find_ei(struct qmi_elem_info *ei_array,
u32 type)
{
struct qmi_elem_info *temp_ei = ei_array;
while (temp_ei->data_type != QMI_EOTI) {
if (temp_ei->tlv_type == (u8)type)
return temp_ei;
temp_ei = temp_ei + 1;
}
return NULL;
}
/**
* qmi_decode() - Core Decode Function
* @ei_array: Struct info array describing the structure to be decoded.
* @out_c_struct: Buffer to hold the decoded C struct
* @in_buf: Buffer containing the QMI message to be decoded
* @in_buf_len: Length of the QMI message to be decoded
* @dec_level: Decode level to indicate the depth of the nested structure,
* within the main structure, being decoded
*
* Return: The number of bytes of decoded information on success, negative
* errno on error.
*/
static int qmi_decode(struct qmi_elem_info *ei_array, void *out_c_struct,
const void *in_buf, u32 in_buf_len,
int dec_level)
{
struct qmi_elem_info *temp_ei = ei_array;
u8 opt_flag_value = 1;
u32 data_len_value = 0, data_len_sz = 0;
u8 *buf_dst = out_c_struct;
const u8 *tlv_pointer;
u32 tlv_len = 0;
u32 tlv_type;
u32 decoded_bytes = 0;
const void *buf_src = in_buf;
int rc;
while (decoded_bytes < in_buf_len) {
if (dec_level >= 2 && temp_ei->data_type == QMI_EOTI)
return decoded_bytes;
if (dec_level == 1) {
tlv_pointer = buf_src;
QMI_ENCDEC_DECODE_TLV(&tlv_type,
&tlv_len, tlv_pointer);
buf_src += (TLV_TYPE_SIZE + TLV_LEN_SIZE);
decoded_bytes += (TLV_TYPE_SIZE + TLV_LEN_SIZE);
temp_ei = find_ei(ei_array, tlv_type);
if (!temp_ei && tlv_type < OPTIONAL_TLV_TYPE_START) {
pr_err("%s: Inval element info\n", __func__);
return -EINVAL;
} else if (!temp_ei) {
UPDATE_DECODE_VARIABLES(buf_src,
decoded_bytes, tlv_len);
continue;
}
} else {
/*
* No length information for elements in nested
* structures. So use remaining decodable buffer space.
*/
tlv_len = in_buf_len - decoded_bytes;
}
buf_dst = out_c_struct + temp_ei->offset;
if (temp_ei->data_type == QMI_OPT_FLAG) {
memcpy(buf_dst, &opt_flag_value, sizeof(u8));
temp_ei = temp_ei + 1;
buf_dst = out_c_struct + temp_ei->offset;
}
if (temp_ei->data_type == QMI_DATA_LEN) {
data_len_sz = temp_ei->elem_size == sizeof(u8) ?
sizeof(u8) : sizeof(u16);
rc = qmi_decode_basic_elem(&data_len_value, buf_src,
1, data_len_sz);
memcpy(buf_dst, &data_len_value, sizeof(u32));
temp_ei = temp_ei + 1;
buf_dst = out_c_struct + temp_ei->offset;
tlv_len -= data_len_sz;
UPDATE_DECODE_VARIABLES(buf_src, decoded_bytes, rc);
}
if (temp_ei->array_type == NO_ARRAY) {
data_len_value = 1;
} else if (temp_ei->array_type == STATIC_ARRAY) {
data_len_value = temp_ei->elem_len;
} else if (data_len_value > temp_ei->elem_len) {
pr_err("%s: Data len %d > max spec %d\n",
__func__, data_len_value, temp_ei->elem_len);
return -ETOOSMALL;
}
switch (temp_ei->data_type) {
case QMI_UNSIGNED_1_BYTE:
case QMI_UNSIGNED_2_BYTE:
case QMI_UNSIGNED_4_BYTE:
case QMI_UNSIGNED_8_BYTE:
case QMI_SIGNED_2_BYTE_ENUM:
case QMI_SIGNED_4_BYTE_ENUM:
rc = qmi_decode_basic_elem(buf_dst, buf_src,
data_len_value,
temp_ei->elem_size);
UPDATE_DECODE_VARIABLES(buf_src, decoded_bytes, rc);
break;
case QMI_STRUCT:
rc = qmi_decode_struct_elem(temp_ei, buf_dst, buf_src,
data_len_value, tlv_len,
dec_level + 1);
if (rc < 0)
return rc;
UPDATE_DECODE_VARIABLES(buf_src, decoded_bytes, rc);
break;
case QMI_STRING:
rc = qmi_decode_string_elem(temp_ei, buf_dst, buf_src,
tlv_len, dec_level);
if (rc < 0)
return rc;
UPDATE_DECODE_VARIABLES(buf_src, decoded_bytes, rc);
break;
default:
pr_err("%s: Unrecognized data type\n", __func__);
return -EINVAL;
}
temp_ei = temp_ei + 1;
}
return decoded_bytes;
}
/**
* qmi_encode_message() - Encode C structure as QMI encoded message
* @type: Type of QMI message
* @msg_id: Message ID of the message
* @len: Passed as max length of the message, updated to actual size
* @txn_id: Transaction ID
* @ei: QMI message descriptor
* @c_struct: Reference to structure to encode
*
* Return: Buffer with encoded message, or negative ERR_PTR() on error
*/
void *qmi_encode_message(int type, unsigned int msg_id, size_t *len,
unsigned int txn_id, struct qmi_elem_info *ei,
const void *c_struct)
{
struct qmi_header *hdr;
ssize_t msglen = 0;
void *msg;
int ret;
/* Check the possibility of a zero length QMI message */
if (!c_struct) {
ret = qmi_calc_min_msg_len(ei, 1);
if (ret) {
pr_err("%s: Calc. len %d != 0, but NULL c_struct\n",
__func__, ret);
return ERR_PTR(-EINVAL);
}
}
msg = kzalloc(sizeof(*hdr) + *len, GFP_KERNEL);
if (!msg)
return ERR_PTR(-ENOMEM);
/* Encode message, if we have a message */
if (c_struct) {
msglen = qmi_encode(ei, msg + sizeof(*hdr), c_struct, *len, 1);
if (msglen < 0) {
kfree(msg);
return ERR_PTR(msglen);
}
}
hdr = msg;
hdr->type = type;
hdr->txn_id = txn_id;
hdr->msg_id = msg_id;
hdr->msg_len = msglen;
*len = sizeof(*hdr) + msglen;
return msg;
}
EXPORT_SYMBOL(qmi_encode_message);
/**
* qmi_decode_message() - Decode QMI encoded message to C structure
* @buf: Buffer with encoded message
* @len: Amount of data in @buf
* @ei: QMI message descriptor
* @c_struct: Reference to structure to decode into
*
* Return: The number of bytes of decoded information on success, negative
* errno on error.
*/
int qmi_decode_message(const void *buf, size_t len,
struct qmi_elem_info *ei, void *c_struct)
{
if (!ei)
return -EINVAL;
if (!c_struct || !buf || !len)
return -EINVAL;
return qmi_decode(ei, c_struct, buf + sizeof(struct qmi_header),
len - sizeof(struct qmi_header), 1);
}
EXPORT_SYMBOL(qmi_decode_message);
/* Common header in all QMI responses */
struct qmi_elem_info qmi_response_type_v01_ei[] = {
{
.data_type = QMI_SIGNED_2_BYTE_ENUM,
.elem_len = 1,
.elem_size = sizeof(u16),
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
.offset = offsetof(struct qmi_response_type_v01, result),
.ei_array = NULL,
},
{
.data_type = QMI_SIGNED_2_BYTE_ENUM,
.elem_len = 1,
.elem_size = sizeof(u16),
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
.offset = offsetof(struct qmi_response_type_v01, error),
.ei_array = NULL,
},
{
.data_type = QMI_EOTI,
.elem_len = 0,
.elem_size = 0,
.array_type = NO_ARRAY,
.tlv_type = QMI_COMMON_TLV_TYPE,
.offset = 0,
.ei_array = NULL,
},
};
EXPORT_SYMBOL(qmi_response_type_v01_ei);
MODULE_DESCRIPTION("QMI encoder/decoder helper");
MODULE_LICENSE("GPL v2");

848
drivers/soc/qcom/qmi_interface.c Normal file
View File

@ -0,0 +1,848 @@
// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (C) 2017 Linaro Ltd.
*/
#include <linux/kernel.h>
#include <linux/module.h>
#include <linux/device.h>
#include <linux/qrtr.h>
#include <linux/net.h>
#include <linux/completion.h>
#include <linux/idr.h>
#include <linux/string.h>
#include <net/sock.h>
#include <linux/workqueue.h>
#include <linux/soc/qcom/qmi.h>
static struct socket *qmi_sock_create(struct qmi_handle *qmi,
struct sockaddr_qrtr *sq);
/**
* qmi_recv_new_server() - handler of NEW_SERVER control message
* @qmi: qmi handle
* @service: service id of the new server
* @instance: instance id of the new server
* @node: node of the new server
* @port: port of the new server
*
* Calls the new_server callback to inform the client about a newly registered
* server matching the currently registered service lookup.
*/
static void qmi_recv_new_server(struct qmi_handle *qmi,
unsigned int service, unsigned int instance,
unsigned int node, unsigned int port)
{
struct qmi_ops *ops = &qmi->ops;
struct qmi_service *svc;
int ret;
if (!ops->new_server)
return;
/* Ignore EOF marker */
if (!node && !port)
return;
svc = kzalloc(sizeof(*svc), GFP_KERNEL);
if (!svc)
return;
svc->service = service;
svc->version = instance & 0xff;
svc->instance = instance >> 8;
svc->node = node;
svc->port = port;
ret = ops->new_server(qmi, svc);
if (ret < 0)
kfree(svc);
else
list_add(&svc->list_node, &qmi->lookup_results);
}
/**
* qmi_recv_del_server() - handler of DEL_SERVER control message
* @qmi: qmi handle
* @node: node of the dying server, a value of -1 matches all nodes
* @port: port of the dying server, a value of -1 matches all ports
*
* Calls the del_server callback for each previously seen server, allowing the
* client to react to the disappearing server.
*/
static void qmi_recv_del_server(struct qmi_handle *qmi,
unsigned int node, unsigned int port)
{
struct qmi_ops *ops = &qmi->ops;
struct qmi_service *svc;
struct qmi_service *tmp;
list_for_each_entry_safe(svc, tmp, &qmi->lookup_results, list_node) {
if (node != -1 && svc->node != node)
continue;
if (port != -1 && svc->port != port)
continue;
if (ops->del_server)
ops->del_server(qmi, svc);
list_del(&svc->list_node);
kfree(svc);
}
}
/**
* qmi_recv_bye() - handler of BYE control message
* @qmi: qmi handle
* @node: id of the dying node
*
* Signals the client that all previously registered services on this node are
* now gone and then calls the bye callback to allow the client client further
* cleaning up resources associated with this remote.
*/
static void qmi_recv_bye(struct qmi_handle *qmi,
unsigned int node)
{
struct qmi_ops *ops = &qmi->ops;
qmi_recv_del_server(qmi, node, -1);
if (ops->bye)
ops->bye(qmi, node);
}
/**
* qmi_recv_del_client() - handler of DEL_CLIENT control message
* @qmi: qmi handle
* @node: node of the dying client
* @port: port of the dying client
*
* Signals the client about a dying client, by calling the del_client callback.
*/
static void qmi_recv_del_client(struct qmi_handle *qmi,
unsigned int node, unsigned int port)
{
struct qmi_ops *ops = &qmi->ops;
if (ops->del_client)
ops->del_client(qmi, node, port);
}
static void qmi_recv_ctrl_pkt(struct qmi_handle *qmi,
const void *buf, size_t len)
{
const struct qrtr_ctrl_pkt *pkt = buf;
if (len < sizeof(struct qrtr_ctrl_pkt)) {
pr_debug("ignoring short control packet\n");
return;
}
switch (le32_to_cpu(pkt->cmd)) {
case QRTR_TYPE_BYE:
qmi_recv_bye(qmi, le32_to_cpu(pkt->client.node));
break;
case QRTR_TYPE_NEW_SERVER:
qmi_recv_new_server(qmi,
le32_to_cpu(pkt->server.service),
le32_to_cpu(pkt->server.instance),
le32_to_cpu(pkt->server.node),
le32_to_cpu(pkt->server.port));
break;
case QRTR_TYPE_DEL_SERVER:
qmi_recv_del_server(qmi,
le32_to_cpu(pkt->server.node),
le32_to_cpu(pkt->server.port));
break;
case QRTR_TYPE_DEL_CLIENT:
qmi_recv_del_client(qmi,
le32_to_cpu(pkt->client.node),
le32_to_cpu(pkt->client.port));
break;
}
}
static void qmi_send_new_lookup(struct qmi_handle *qmi, struct qmi_service *svc)
{
struct qrtr_ctrl_pkt pkt;
struct sockaddr_qrtr sq;
struct msghdr msg = { };
struct kvec iv = { &pkt, sizeof(pkt) };
int ret;
memset(&pkt, 0, sizeof(pkt));
pkt.cmd = cpu_to_le32(QRTR_TYPE_NEW_LOOKUP);
pkt.server.service = cpu_to_le32(svc->service);
pkt.server.instance = cpu_to_le32(svc->version | svc->instance << 8);
sq.sq_family = qmi->sq.sq_family;
sq.sq_node = qmi->sq.sq_node;
sq.sq_port = QRTR_PORT_CTRL;
msg.msg_name = &sq;
msg.msg_namelen = sizeof(sq);
mutex_lock(&qmi->sock_lock);
if (qmi->sock) {
ret = kernel_sendmsg(qmi->sock, &msg, &iv, 1, sizeof(pkt));
if (ret < 0)
pr_err("failed to send lookup registration: %d\n", ret);
}
mutex_unlock(&qmi->sock_lock);
}
/**
* qmi_add_lookup() - register a new lookup with the name service
* @qmi: qmi handle
* @service: service id of the request
* @instance: instance id of the request
* @version: version number of the request
*
* Registering a lookup query with the name server will cause the name server
* to send NEW_SERVER and DEL_SERVER control messages to this socket as
* matching services are registered.
*
* Return: 0 on success, negative errno on failure.
*/
int qmi_add_lookup(struct qmi_handle *qmi, unsigned int service,
unsigned int version, unsigned int instance)
{
struct qmi_service *svc;
svc = kzalloc(sizeof(*svc), GFP_KERNEL);
if (!svc)
return -ENOMEM;
svc->service = service;
svc->version = version;
svc->instance = instance;
list_add(&svc->list_node, &qmi->lookups);
qmi_send_new_lookup(qmi, svc);
return 0;
}
EXPORT_SYMBOL(qmi_add_lookup);
static void qmi_send_new_server(struct qmi_handle *qmi, struct qmi_service *svc)
{
struct qrtr_ctrl_pkt pkt;
struct sockaddr_qrtr sq;
struct msghdr msg = { };
struct kvec iv = { &pkt, sizeof(pkt) };
int ret;
memset(&pkt, 0, sizeof(pkt));
pkt.cmd = cpu_to_le32(QRTR_TYPE_NEW_SERVER);
pkt.server.service = cpu_to_le32(svc->service);
pkt.server.instance = cpu_to_le32(svc->version | svc->instance << 8);
pkt.server.node = cpu_to_le32(qmi->sq.sq_node);
pkt.server.port = cpu_to_le32(qmi->sq.sq_port);
sq.sq_family = qmi->sq.sq_family;
sq.sq_node = qmi->sq.sq_node;
sq.sq_port = QRTR_PORT_CTRL;
msg.msg_name = &sq;
msg.msg_namelen = sizeof(sq);
mutex_lock(&qmi->sock_lock);
if (qmi->sock) {
ret = kernel_sendmsg(qmi->sock, &msg, &iv, 1, sizeof(pkt));
if (ret < 0)
pr_err("send service registration failed: %d\n", ret);
}
mutex_unlock(&qmi->sock_lock);
}
/**
* qmi_add_server() - register a service with the name service
* @qmi: qmi handle
* @service: type of the service
* @instance: instance of the service
* @version: version of the service
*
* Register a new service with the name service. This allows clients to find
* and start sending messages to the client associated with @qmi.
*
* Return: 0 on success, negative errno on failure.
*/
int qmi_add_server(struct qmi_handle *qmi, unsigned int service,
unsigned int version, unsigned int instance)
{
struct qmi_service *svc;
svc = kzalloc(sizeof(*svc), GFP_KERNEL);
if (!svc)
return -ENOMEM;
svc->service = service;
svc->version = version;
svc->instance = instance;
list_add(&svc->list_node, &qmi->services);
qmi_send_new_server(qmi, svc);
return 0;
}
EXPORT_SYMBOL(qmi_add_server);
/**
* qmi_txn_init() - allocate transaction id within the given QMI handle
* @qmi: QMI handle
* @txn: transaction context
* @ei: description of how to decode a matching response (optional)
* @c_struct: pointer to the object to decode the response into (optional)
*
* This allocates a transaction id within the QMI handle. If @ei and @c_struct
* are specified any responses to this transaction will be decoded as described
* by @ei into @c_struct.
*
* A client calling qmi_txn_init() must call either qmi_txn_wait() or
* qmi_txn_cancel() to free up the allocated resources.
*
* Return: Transaction id on success, negative errno on failure.
*/
int qmi_txn_init(struct qmi_handle *qmi, struct qmi_txn *txn,
struct qmi_elem_info *ei, void *c_struct)
{
int ret;
memset(txn, 0, sizeof(*txn));
mutex_init(&txn->lock);
init_completion(&txn->completion);
txn->qmi = qmi;
txn->ei = ei;
txn->dest = c_struct;
mutex_lock(&qmi->txn_lock);
ret = idr_alloc_cyclic(&qmi->txns, txn, 0, INT_MAX, GFP_KERNEL);
if (ret < 0)
pr_err("failed to allocate transaction id\n");
txn->id = ret;
mutex_unlock(&qmi->txn_lock);
return ret;
}
EXPORT_SYMBOL(qmi_txn_init);
/**
* qmi_txn_wait() - wait for a response on a transaction
* @txn: transaction handle
* @timeout: timeout, in jiffies
*
* If the transaction is decoded by the means of @ei and @c_struct the return
* value will be the returned value of qmi_decode_message(), otherwise it's up
* to the specified message handler to fill out the result.
*
* Return: the transaction response on success, negative errno on failure.
*/
int qmi_txn_wait(struct qmi_txn *txn, unsigned long timeout)
{
struct qmi_handle *qmi = txn->qmi;
int ret;
ret = wait_for_completion_interruptible_timeout(&txn->completion,
timeout);
mutex_lock(&qmi->txn_lock);
mutex_lock(&txn->lock);
idr_remove(&qmi->txns, txn->id);
mutex_unlock(&txn->lock);
mutex_unlock(&qmi->txn_lock);
if (ret < 0)
return ret;
else if (ret == 0)
return -ETIMEDOUT;
else
return txn->result;
}
EXPORT_SYMBOL(qmi_txn_wait);
/**
* qmi_txn_cancel() - cancel an ongoing transaction
* @txn: transaction id
*/
void qmi_txn_cancel(struct qmi_txn *txn)
{
struct qmi_handle *qmi = txn->qmi;
mutex_lock(&qmi->txn_lock);
mutex_lock(&txn->lock);
idr_remove(&qmi->txns, txn->id);
mutex_unlock(&txn->lock);
mutex_unlock(&qmi->txn_lock);
}
EXPORT_SYMBOL(qmi_txn_cancel);
/**
* qmi_invoke_handler() - find and invoke a handler for a message
* @qmi: qmi handle
* @sq: sockaddr of the sender
* @txn: transaction object for the message
* @buf: buffer containing the message
* @len: length of @buf
*
* Find handler and invoke handler for the incoming message.
*/
static void qmi_invoke_handler(struct qmi_handle *qmi, struct sockaddr_qrtr *sq,
struct qmi_txn *txn, const void *buf, size_t len)
{
const struct qmi_msg_handler *handler;
const struct qmi_header *hdr = buf;
void *dest;
int ret;
if (!qmi->handlers)
return;
for (handler = qmi->handlers; handler->fn; handler++) {
if (handler->type == hdr->type &&
handler->msg_id == hdr->msg_id)
break;
}
if (!handler->fn)
return;
dest = kzalloc(handler->decoded_size, GFP_KERNEL);
if (!dest)
return;
ret = qmi_decode_message(buf, len, handler->ei, dest);
if (ret < 0)
pr_err("failed to decode incoming message\n");
else
handler->fn(qmi, sq, txn, dest);
kfree(dest);
}
/**
* qmi_handle_net_reset() - invoked to handle ENETRESET on a QMI handle
* @qmi: the QMI context
*
* As a result of registering a name service with the QRTR all open sockets are
* flagged with ENETRESET and this function will be called. The typical case is
* the initial boot, where this signals that the local node id has been
* configured and as such any bound sockets needs to be rebound. So close the
* socket, inform the client and re-initialize the socket.
*
* For clients it's generally sufficient to react to the del_server callbacks,
* but server code is expected to treat the net_reset callback as a "bye" from
* all nodes.
*
* Finally the QMI handle will send out registration requests for any lookups
* and services.
*/
static void qmi_handle_net_reset(struct qmi_handle *qmi)
{
struct sockaddr_qrtr sq;
struct qmi_service *svc;
struct socket *sock;
sock = qmi_sock_create(qmi, &sq);
if (IS_ERR(sock))
return;
mutex_lock(&qmi->sock_lock);
sock_release(qmi->sock);
qmi->sock = NULL;
mutex_unlock(&qmi->sock_lock);
qmi_recv_del_server(qmi, -1, -1);
if (qmi->ops.net_reset)
qmi->ops.net_reset(qmi);
mutex_lock(&qmi->sock_lock);
qmi->sock = sock;
qmi->sq = sq;
mutex_unlock(&qmi->sock_lock);
list_for_each_entry(svc, &qmi->lookups, list_node)
qmi_send_new_lookup(qmi, svc);
list_for_each_entry(svc, &qmi->services, list_node)
qmi_send_new_server(qmi, svc);
}
static void qmi_handle_message(struct qmi_handle *qmi,
struct sockaddr_qrtr *sq,
const void *buf, size_t len)
{
const struct qmi_header *hdr;
struct qmi_txn tmp_txn;
struct qmi_txn *txn = NULL;
int ret;
if (len < sizeof(*hdr)) {
pr_err("ignoring short QMI packet\n");
return;
}
hdr = buf;
/* If this is a response, find the matching transaction handle */
if (hdr->type == QMI_RESPONSE) {
mutex_lock(&qmi->txn_lock);
txn = idr_find(&qmi->txns, hdr->txn_id);
/* Ignore unexpected responses */
if (!txn) {
mutex_unlock(&qmi->txn_lock);
return;
}
mutex_lock(&txn->lock);
mutex_unlock(&qmi->txn_lock);
if (txn->dest && txn->ei) {
ret = qmi_decode_message(buf, len, txn->ei, txn->dest);
if (ret < 0)
pr_err("failed to decode incoming message\n");
txn->result = ret;
complete(&txn->completion);
} else {
qmi_invoke_handler(qmi, sq, txn, buf, len);
}
mutex_unlock(&txn->lock);
} else {
/* Create a txn based on the txn_id of the incoming message */
memset(&tmp_txn, 0, sizeof(tmp_txn));
tmp_txn.id = hdr->txn_id;
qmi_invoke_handler(qmi, sq, &tmp_txn, buf, len);
}
}
static void qmi_data_ready_work(struct work_struct *work)
{
struct qmi_handle *qmi = container_of(work, struct qmi_handle, work);
struct qmi_ops *ops = &qmi->ops;
struct sockaddr_qrtr sq;
struct msghdr msg = { .msg_name = &sq, .msg_namelen = sizeof(sq) };
struct kvec iv;
ssize_t msglen;
for (;;) {
iv.iov_base = qmi->recv_buf;
iv.iov_len = qmi->recv_buf_size;
mutex_lock(&qmi->sock_lock);
if (qmi->sock)
msglen = kernel_recvmsg(qmi->sock, &msg, &iv, 1,
iv.iov_len, MSG_DONTWAIT);
else
msglen = -EPIPE;
mutex_unlock(&qmi->sock_lock);
if (msglen == -EAGAIN)
break;
if (msglen == -ENETRESET) {
qmi_handle_net_reset(qmi);
/* The old qmi->sock is gone, our work is done */
break;
}
if (msglen < 0) {
pr_err("qmi recvmsg failed: %zd\n", msglen);
break;
}
if (sq.sq_node == qmi->sq.sq_node &&
sq.sq_port == QRTR_PORT_CTRL) {
qmi_recv_ctrl_pkt(qmi, qmi->recv_buf, msglen);
} else if (ops->msg_handler) {
ops->msg_handler(qmi, &sq, qmi->recv_buf, msglen);
} else {
qmi_handle_message(qmi, &sq, qmi->recv_buf, msglen);
}
}
}
static void qmi_data_ready(struct sock *sk)
{
struct qmi_handle *qmi = sk->sk_user_data;
/*
* This will be NULL if we receive data while being in
* qmi_handle_release()
*/
if (!qmi)
return;
queue_work(qmi->wq, &qmi->work);
}
static struct socket *qmi_sock_create(struct qmi_handle *qmi,
struct sockaddr_qrtr *sq)
{
struct socket *sock;
int sl = sizeof(*sq);
int ret;
ret = sock_create_kern(&init_net, AF_QIPCRTR, SOCK_DGRAM,
PF_QIPCRTR, &sock);
if (ret < 0)
return ERR_PTR(ret);
ret = kernel_getsockname(sock, (struct sockaddr *)sq, &sl);
if (ret < 0) {
sock_release(sock);
return ERR_PTR(ret);
}
sock->sk->sk_user_data = qmi;
sock->sk->sk_data_ready = qmi_data_ready;
sock->sk->sk_error_report = qmi_data_ready;
return sock;
}
/**
* qmi_handle_init() - initialize a QMI client handle
* @qmi: QMI handle to initialize
* @recv_buf_size: maximum size of incoming message
* @ops: reference to callbacks for QRTR notifications
* @handlers: NULL-terminated list of QMI message handlers
*
* This initializes the QMI client handle to allow sending and receiving QMI
* messages. As messages are received the appropriate handler will be invoked.
*
* Return: 0 on success, negative errno on failure.
*/
int qmi_handle_init(struct qmi_handle *qmi, size_t recv_buf_size,
const struct qmi_ops *ops,
const struct qmi_msg_handler *handlers)
{
int ret;
mutex_init(&qmi->txn_lock);
mutex_init(&qmi->sock_lock);
idr_init(&qmi->txns);
INIT_LIST_HEAD(&qmi->lookups);
INIT_LIST_HEAD(&qmi->lookup_results);
INIT_LIST_HEAD(&qmi->services);
INIT_WORK(&qmi->work, qmi_data_ready_work);
qmi->handlers = handlers;
if (ops)
qmi->ops = *ops;
if (recv_buf_size < sizeof(struct qrtr_ctrl_pkt))
recv_buf_size = sizeof(struct qrtr_ctrl_pkt);
else
recv_buf_size += sizeof(struct qmi_header);
qmi->recv_buf_size = recv_buf_size;
qmi->recv_buf = kzalloc(recv_buf_size, GFP_KERNEL);
if (!qmi->recv_buf)
return -ENOMEM;
qmi->wq = alloc_workqueue("qmi_msg_handler", WQ_UNBOUND, 1);
if (!qmi->wq) {
ret = -ENOMEM;
goto err_free_recv_buf;
}
qmi->sock = qmi_sock_create(qmi, &qmi->sq);
if (IS_ERR(qmi->sock)) {
pr_err("failed to create QMI socket\n");
ret = PTR_ERR(qmi->sock);
goto err_destroy_wq;
}
return 0;
err_destroy_wq:
destroy_workqueue(qmi->wq);
err_free_recv_buf:
kfree(qmi->recv_buf);
return ret;
}
EXPORT_SYMBOL(qmi_handle_init);
/**
* qmi_handle_release() - release the QMI client handle
* @qmi: QMI client handle
*
* This closes the underlying socket and stops any handling of QMI messages.
*/
void qmi_handle_release(struct qmi_handle *qmi)
{
struct socket *sock = qmi->sock;
struct qmi_service *svc, *tmp;
sock->sk->sk_user_data = NULL;
cancel_work_sync(&qmi->work);
qmi_recv_del_server(qmi, -1, -1);
mutex_lock(&qmi->sock_lock);
sock_release(sock);
qmi->sock = NULL;
mutex_unlock(&qmi->sock_lock);
destroy_workqueue(qmi->wq);
idr_destroy(&qmi->txns);
kfree(qmi->recv_buf);
/* Free registered lookup requests */
list_for_each_entry_safe(svc, tmp, &qmi->lookups, list_node) {
list_del(&svc->list_node);
kfree(svc);
}
/* Free registered service information */
list_for_each_entry_safe(svc, tmp, &qmi->services, list_node) {
list_del(&svc->list_node);
kfree(svc);
}
}
EXPORT_SYMBOL(qmi_handle_release);
/**
* qmi_send_message() - send a QMI message
* @qmi: QMI client handle
* @sq: destination sockaddr
* @txn: transaction object to use for the message
* @type: type of message to send
* @msg_id: message id
* @len: max length of the QMI message
* @ei: QMI message description
* @c_struct: object to be encoded
*
* This function encodes @c_struct using @ei into a message of type @type,
* with @msg_id and @txn into a buffer of maximum size @len, and sends this to
* @sq.
*
* Return: 0 on success, negative errno on failure.
*/
static ssize_t qmi_send_message(struct qmi_handle *qmi,
struct sockaddr_qrtr *sq, struct qmi_txn *txn,
int type, int msg_id, size_t len,
struct qmi_elem_info *ei, const void *c_struct)
{
struct msghdr msghdr = {};
struct kvec iv;
void *msg;
int ret;
msg = qmi_encode_message(type,
msg_id, &len,
txn->id, ei,
c_struct);
if (IS_ERR(msg))
return PTR_ERR(msg);
iv.iov_base = msg;
iv.iov_len = len;
if (sq) {
msghdr.msg_name = sq;
msghdr.msg_namelen = sizeof(*sq);
}
mutex_lock(&qmi->sock_lock);
if (qmi->sock) {
ret = kernel_sendmsg(qmi->sock, &msghdr, &iv, 1, len);
if (ret < 0)
pr_err("failed to send QMI message\n");
} else {
ret = -EPIPE;
}
mutex_unlock(&qmi->sock_lock);
kfree(msg);
return ret < 0 ? ret : 0;
}
/**
* qmi_send_request() - send a request QMI message
* @qmi: QMI client handle
* @sq: destination sockaddr
* @txn: transaction object to use for the message
* @msg_id: message id
* @len: max length of the QMI message
* @ei: QMI message description
* @c_struct: object to be encoded
*
* Return: 0 on success, negative errno on failure.
*/
ssize_t qmi_send_request(struct qmi_handle *qmi, struct sockaddr_qrtr *sq,
struct qmi_txn *txn, int msg_id, size_t len,
struct qmi_elem_info *ei, const void *c_struct)
{
return qmi_send_message(qmi, sq, txn, QMI_REQUEST, msg_id, len, ei,
c_struct);
}
EXPORT_SYMBOL(qmi_send_request);
/**
* qmi_send_response() - send a response QMI message
* @qmi: QMI client handle
* @sq: destination sockaddr
* @txn: transaction object to use for the message
* @msg_id: message id
* @len: max length of the QMI message
* @ei: QMI message description
* @c_struct: object to be encoded
*
* Return: 0 on success, negative errno on failure.
*/
ssize_t qmi_send_response(struct qmi_handle *qmi, struct sockaddr_qrtr *sq,
struct qmi_txn *txn, int msg_id, size_t len,
struct qmi_elem_info *ei, const void *c_struct)
{
return qmi_send_message(qmi, sq, txn, QMI_RESPONSE, msg_id, len, ei,
c_struct);
}
EXPORT_SYMBOL(qmi_send_response);
/**
* qmi_send_indication() - send an indication QMI message
* @qmi: QMI client handle
* @sq: destination sockaddr
* @msg_id: message id
* @len: max length of the QMI message
* @ei: QMI message description
* @c_struct: object to be encoded
*
* Return: 0 on success, negative errno on failure.
*/
ssize_t qmi_send_indication(struct qmi_handle *qmi, struct sockaddr_qrtr *sq,
int msg_id, size_t len, struct qmi_elem_info *ei,
const void *c_struct)
{
struct qmi_txn txn;
ssize_t rval;
int ret;
ret = qmi_txn_init(qmi, &txn, NULL, NULL);
if (ret < 0)
return ret;
rval = qmi_send_message(qmi, sq, &txn, QMI_INDICATION, msg_id, len, ei,
c_struct);
/* We don't care about future messages on this txn */
qmi_txn_cancel(&txn);
return rval;
}
EXPORT_SYMBOL(qmi_send_indication);

4
drivers/soc/qcom/rmtfs_mem.c
View File

@ -267,3 +267,7 @@ static void qcom_rmtfs_mem_exit(void)
unregister_chrdev_region(qcom_rmtfs_mem_major, QCOM_RMTFS_MEM_DEV_MAX);
}
module_exit(qcom_rmtfs_mem_exit);
MODULE_AUTHOR("Linaro Ltd");
MODULE_DESCRIPTION("Qualcomm Remote Filesystem memory driver");
MODULE_LICENSE("GPL v2");

55
drivers/soc/qcom/smp2p.c
View File

@ -18,6 +18,7 @@
#include <linux/of.h>
#include <linux/irq.h>
#include <linux/irqdomain.h>
#include <linux/mailbox_client.h>
#include <linux/mfd/syscon.h>
#include <linux/module.h>
#include <linux/platform_device.h>
@ -126,6 +127,8 @@ struct smp2p_entry {
* @ipc_regmap: regmap for the outbound ipc
* @ipc_offset: offset within the regmap
* @ipc_bit: bit in regmap@offset to kick to signal remote processor
* @mbox_client: mailbox client handle
* @mbox_chan: apcs ipc mailbox channel handle
* @inbound: list of inbound entries
* @outbound: list of outbound entries
*/
@ -146,6 +149,9 @@ struct qcom_smp2p {
int ipc_offset;
int ipc_bit;
struct mbox_client mbox_client;
struct mbox_chan *mbox_chan;
struct list_head inbound;
struct list_head outbound;
};
@ -154,7 +160,13 @@ static void qcom_smp2p_kick(struct qcom_smp2p *smp2p)
{
/* Make sure any updated data is written before the kick */
wmb();
regmap_write(smp2p->ipc_regmap, smp2p->ipc_offset, BIT(smp2p->ipc_bit));
if (smp2p->mbox_chan) {
mbox_send_message(smp2p->mbox_chan, NULL);
mbox_client_txdone(smp2p->mbox_chan, 0);
} else {
regmap_write(smp2p->ipc_regmap, smp2p->ipc_offset, BIT(smp2p->ipc_bit));
}
}
/**
@ -453,10 +465,6 @@ static int qcom_smp2p_probe(struct platform_device *pdev)
platform_set_drvdata(pdev, smp2p);
ret = smp2p_parse_ipc(smp2p);
if (ret)
return ret;
key = "qcom,smem";
ret = of_property_read_u32_array(pdev->dev.of_node, key,
smp2p->smem_items, 2);
@ -465,17 +473,13 @@ static int qcom_smp2p_probe(struct platform_device *pdev)
key = "qcom,local-pid";
ret = of_property_read_u32(pdev->dev.of_node, key, &smp2p->local_pid);
if (ret < 0) {
dev_err(&pdev->dev, "failed to read %s\n", key);
return -EINVAL;
}
if (ret)
goto report_read_failure;
key = "qcom,remote-pid";
ret = of_property_read_u32(pdev->dev.of_node, key, &smp2p->remote_pid);
if (ret < 0) {
dev_err(&pdev->dev, "failed to read %s\n", key);
return -EINVAL;
}
if (ret)
goto report_read_failure;
irq = platform_get_irq(pdev, 0);
if (irq < 0) {
@ -483,9 +487,23 @@ static int qcom_smp2p_probe(struct platform_device *pdev)
return irq;
}
smp2p->mbox_client.dev = &pdev->dev;
smp2p->mbox_client.knows_txdone = true;
smp2p->mbox_chan = mbox_request_channel(&smp2p->mbox_client, 0);
if (IS_ERR(smp2p->mbox_chan)) {
if (PTR_ERR(smp2p->mbox_chan) != -ENODEV)
return PTR_ERR(smp2p->mbox_chan);
smp2p->mbox_chan = NULL;
ret = smp2p_parse_ipc(smp2p);
if (ret)
return ret;
}
ret = qcom_smp2p_alloc_outbound_item(smp2p);
if (ret < 0)
return ret;
goto release_mbox;
for_each_available_child_of_node(pdev->dev.of_node, node) {
entry = devm_kzalloc(&pdev->dev, sizeof(*entry), GFP_KERNEL);
@ -540,7 +558,14 @@ unwind_interfaces:
smp2p->out->valid_entries = 0;
release_mbox:
mbox_free_channel(smp2p->mbox_chan);
return ret;
report_read_failure:
dev_err(&pdev->dev, "failed to read %s\n", key);
return -EINVAL;
}
static int qcom_smp2p_remove(struct platform_device *pdev)
@ -554,6 +579,8 @@ static int qcom_smp2p_remove(struct platform_device *pdev)
list_for_each_entry(entry, &smp2p->outbound, node)
qcom_smem_state_unregister(entry->state);
mbox_free_channel(smp2p->mbox_chan);
smp2p->out->valid_entries = 0;
return 0;

6
drivers/soc/qcom/smsm.c
View File

@ -496,8 +496,10 @@ static int qcom_smsm_probe(struct platform_device *pdev)
if (!smsm->hosts)
return -ENOMEM;
local_node = of_find_node_with_property(of_node_get(pdev->dev.of_node),
"#qcom,smem-state-cells");
for_each_child_of_node(pdev->dev.of_node, local_node) {
if (of_find_property(local_node, "#qcom,smem-state-cells", NULL))
break;
}
if (!local_node) {
dev_err(&pdev->dev, "no state entry\n");
return -EINVAL;

3
include/linux/qcom_scm.h
View File

@ -13,6 +13,9 @@
#ifndef __QCOM_SCM_H
#define __QCOM_SCM_H
#include <linux/types.h>
#include <linux/cpumask.h>
#define QCOM_SCM_VERSION(major, minor) (((major) << 16) | ((minor) & 0xFF))
#define QCOM_SCM_CPU_PWR_DOWN_L2_ON 0x0
#define QCOM_SCM_CPU_PWR_DOWN_L2_OFF 0x1

271
include/linux/soc/qcom/qmi.h Normal file
View File

@ -0,0 +1,271 @@
// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (c) 2012-2014, The Linux Foundation. All rights reserved.
* Copyright (c) 2017, Linaro Ltd.
*/
#ifndef __QMI_HELPERS_H__
#define __QMI_HELPERS_H__
#include <linux/completion.h>
#include <linux/idr.h>
#include <linux/list.h>
#include <linux/qrtr.h>
#include <linux/types.h>
#include <linux/workqueue.h>
struct socket;
/**
* qmi_header - wireformat header of QMI messages
* @type: type of message
* @txn_id: transaction id
* @msg_id: message id
* @msg_len: length of message payload following header
*/
struct qmi_header {
u8 type;
u16 txn_id;
u16 msg_id;
u16 msg_len;
} __packed;
#define QMI_REQUEST 0
#define QMI_RESPONSE 2
#define QMI_INDICATION 4
#define QMI_COMMON_TLV_TYPE 0
enum qmi_elem_type {
QMI_EOTI,
QMI_OPT_FLAG,
QMI_DATA_LEN,
QMI_UNSIGNED_1_BYTE,
QMI_UNSIGNED_2_BYTE,
QMI_UNSIGNED_4_BYTE,
QMI_UNSIGNED_8_BYTE,
QMI_SIGNED_2_BYTE_ENUM,
QMI_SIGNED_4_BYTE_ENUM,
QMI_STRUCT,
QMI_STRING,
};
enum qmi_array_type {
NO_ARRAY,
STATIC_ARRAY,
VAR_LEN_ARRAY,
};
/**
* struct qmi_elem_info - describes how to encode a single QMI element
* @data_type: Data type of this element.
* @elem_len: Array length of this element, if an array.
* @elem_size: Size of a single instance of this data type.
* @array_type: Array type of this element.
* @tlv_type: QMI message specific type to identify which element
* is present in an incoming message.
* @offset: Specifies the offset of the first instance of this
* element in the data structure.
* @ei_array: Null-terminated array of @qmi_elem_info to describe nested
* structures.
*/
struct qmi_elem_info {
enum qmi_elem_type data_type;
u32 elem_len;
u32 elem_size;
enum qmi_array_type array_type;
u8 tlv_type;
u32 offset;
struct qmi_elem_info *ei_array;
};
#define QMI_RESULT_SUCCESS_V01 0
#define QMI_RESULT_FAILURE_V01 1
#define QMI_ERR_NONE_V01 0
#define QMI_ERR_MALFORMED_MSG_V01 1
#define QMI_ERR_NO_MEMORY_V01 2
#define QMI_ERR_INTERNAL_V01 3
#define QMI_ERR_CLIENT_IDS_EXHAUSTED_V01 5
#define QMI_ERR_INVALID_ID_V01 41
#define QMI_ERR_ENCODING_V01 58
#define QMI_ERR_INCOMPATIBLE_STATE_V01 90
#define QMI_ERR_NOT_SUPPORTED_V01 94
/**
* qmi_response_type_v01 - common response header (decoded)
* @result: result of the transaction
* @error: error value, when @result is QMI_RESULT_FAILURE_V01
*/
struct qmi_response_type_v01 {
u16 result;
u16 error;
};
extern struct qmi_elem_info qmi_response_type_v01_ei[];
/**
* struct qmi_service - context to track lookup-results
* @service: service type
* @version: version of the @service
* @instance: instance id of the @service
* @node: node of the service
* @port: port of the service
* @priv: handle for client's use
* @list_node: list_head for house keeping
*/
struct qmi_service {
unsigned int service;
unsigned int version;
unsigned int instance;
unsigned int node;
unsigned int port;
void *priv;
struct list_head list_node;
};
struct qmi_handle;
/**
* struct qmi_ops - callbacks for qmi_handle
* @new_server: inform client of a new_server lookup-result, returning
* successfully from this call causes the library to call
* @del_server as the service is removed from the
* lookup-result. @priv of the qmi_service can be used by
* the client
* @del_server: inform client of a del_server lookup-result
* @net_reset: inform client that the name service was restarted and
* that and any state needs to be released
* @msg_handler: invoked for incoming messages, allows a client to
* override the usual QMI message handler
* @bye: inform a client that all clients from a node are gone
* @del_client: inform a client that a particular client is gone
*/
struct qmi_ops {
int (*new_server)(struct qmi_handle *qmi, struct qmi_service *svc);
void (*del_server)(struct qmi_handle *qmi, struct qmi_service *svc);
void (*net_reset)(struct qmi_handle *qmi);
void (*msg_handler)(struct qmi_handle *qmi, struct sockaddr_qrtr *sq,
const void *data, size_t count);
void (*bye)(struct qmi_handle *qmi, unsigned int node);
void (*del_client)(struct qmi_handle *qmi,
unsigned int node, unsigned int port);
};
/**
* struct qmi_txn - transaction context
* @qmi: QMI handle this transaction is associated with
* @id: transaction id
* @lock: for synchronization between handler and waiter of messages
* @completion: completion object as the transaction receives a response
* @result: result code for the completed transaction
* @ei: description of the QMI encoded response (optional)
* @dest: destination buffer to decode message into (optional)
*/
struct qmi_txn {
struct qmi_handle *qmi;
int id;
struct mutex lock;
struct completion completion;
int result;
struct qmi_elem_info *ei;
void *dest;
};
/**
* struct qmi_msg_handler - description of QMI message handler
* @type: type of message
* @msg_id: message id
* @ei: description of the QMI encoded message
* @decoded_size: size of the decoded object
* @fn: function to invoke as the message is decoded
*/
struct qmi_msg_handler {
unsigned int type;
unsigned int msg_id;
struct qmi_elem_info *ei;
size_t decoded_size;
void (*fn)(struct qmi_handle *qmi, struct sockaddr_qrtr *sq,
struct qmi_txn *txn, const void *decoded);
};
/**
* struct qmi_handle - QMI context
* @sock: socket handle
* @sock_lock: synchronization of @sock modifications
* @sq: sockaddr of @sock
* @work: work for handling incoming messages
* @wq: workqueue to post @work on
* @recv_buf: scratch buffer for handling incoming messages
* @recv_buf_size: size of @recv_buf
* @lookups: list of registered lookup requests
* @lookup_results: list of lookup-results advertised to the client
* @services: list of registered services (by this client)
* @ops: reference to callbacks
* @txns: outstanding transactions
* @txn_lock: lock for modifications of @txns
* @handlers: list of handlers for incoming messages
*/
struct qmi_handle {
struct socket *sock;
struct mutex sock_lock;
struct sockaddr_qrtr sq;
struct work_struct work;
struct workqueue_struct *wq;
void *recv_buf;
size_t recv_buf_size;
struct list_head lookups;
struct list_head lookup_results;
struct list_head services;
struct qmi_ops ops;
struct idr txns;
struct mutex txn_lock;
const struct qmi_msg_handler *handlers;
};
int qmi_add_lookup(struct qmi_handle *qmi, unsigned int service,
unsigned int version, unsigned int instance);
int qmi_add_server(struct qmi_handle *qmi, unsigned int service,
unsigned int version, unsigned int instance);
int qmi_handle_init(struct qmi_handle *qmi, size_t max_msg_len,
const struct qmi_ops *ops,
const struct qmi_msg_handler *handlers);
void qmi_handle_release(struct qmi_handle *qmi);
ssize_t qmi_send_request(struct qmi_handle *qmi, struct sockaddr_qrtr *sq,
struct qmi_txn *txn, int msg_id, size_t len,
struct qmi_elem_info *ei, const void *c_struct);
ssize_t qmi_send_response(struct qmi_handle *qmi, struct sockaddr_qrtr *sq,
struct qmi_txn *txn, int msg_id, size_t len,
struct qmi_elem_info *ei, const void *c_struct);
ssize_t qmi_send_indication(struct qmi_handle *qmi, struct sockaddr_qrtr *sq,
int msg_id, size_t len, struct qmi_elem_info *ei,
const void *c_struct);
void *qmi_encode_message(int type, unsigned int msg_id, size_t *len,
unsigned int txn_id, struct qmi_elem_info *ei,
const void *c_struct);
int qmi_decode_message(const void *buf, size_t len,
struct qmi_elem_info *ei, void *c_struct);
int qmi_txn_init(struct qmi_handle *qmi, struct qmi_txn *txn,
struct qmi_elem_info *ei, void *c_struct);
int qmi_txn_wait(struct qmi_txn *txn, unsigned long timeout);
void qmi_txn_cancel(struct qmi_txn *txn);
#endif