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android-kvm / linux / d8e45f2929b94099913eb66c3ebb18b5063e9421 / . / drivers / platform / x86 / hp / hp-bioscfg / int-attributes.c
blob: 86b7ac63fec20e0dbabbb53888516d03d165fc3e [file] [log] [blame]
// SPDX-License-Identifier: GPL-2.0
/*
* Functions corresponding to integer type attributes under
* BIOS Enumeration GUID for use with hp-bioscfg driver.
*
* Copyright (c) 2022 Hewlett-Packard Inc.
*/
#include "bioscfg.h"
GET_INSTANCE_ID(integer);
static ssize_t current_value_show(struct kobject *kobj, struct kobj_attribute *attr, char *buf)
{
int instance_id = get_integer_instance_id(kobj);
if (instance_id < 0)
return -EIO;
return sysfs_emit(buf, "%d\n",
bioscfg_drv.integer_data[instance_id].current_value);
}
/**
* validate_integer_input() -
* Validate input of current_value against lower and upper bound
*
* @instance_id: The instance on which input is validated
* @buf: Input value
*/
static int validate_integer_input(int instance_id, char *buf)
{
int in_val;
int ret;
struct integer_data *integer_data = &bioscfg_drv.integer_data[instance_id];
/* BIOS treats it as a read only attribute */
if (integer_data->common.is_readonly)
return -EIO;
ret = kstrtoint(buf, 10, &in_val);
if (ret < 0)
return ret;
if (in_val < integer_data->lower_bound ||
in_val > integer_data->upper_bound)
return -ERANGE;
return 0;
}
static void update_integer_value(int instance_id, char *attr_value)
{
int in_val;
int ret;
struct integer_data *integer_data = &bioscfg_drv.integer_data[instance_id];
ret = kstrtoint(attr_value, 10, &in_val);
if (ret == 0)
integer_data->current_value = in_val;
else
pr_warn("Invalid integer value found: %s\n", attr_value);
}
ATTRIBUTE_S_COMMON_PROPERTY_SHOW(display_name, integer);
static struct kobj_attribute integer_display_name =
__ATTR_RO(display_name);
ATTRIBUTE_PROPERTY_STORE(current_value, integer);
static struct kobj_attribute integer_current_val =
__ATTR_RW_MODE(current_value, 0644);
ATTRIBUTE_N_PROPERTY_SHOW(lower_bound, integer);
static struct kobj_attribute integer_lower_bound =
__ATTR_RO(lower_bound);
ATTRIBUTE_N_PROPERTY_SHOW(upper_bound, integer);
static struct kobj_attribute integer_upper_bound =
__ATTR_RO(upper_bound);
ATTRIBUTE_N_PROPERTY_SHOW(scalar_increment, integer);
static struct kobj_attribute integer_scalar_increment =
__ATTR_RO(scalar_increment);
static ssize_t type_show(struct kobject *kobj, struct kobj_attribute *attr,
char *buf)
{
return sysfs_emit(buf, "integer\n");
}
static struct kobj_attribute integer_type =
__ATTR_RO(type);
static struct attribute *integer_attrs[] = {
&common_display_langcode.attr,
&integer_display_name.attr,
&integer_current_val.attr,
&integer_lower_bound.attr,
&integer_upper_bound.attr,
&integer_scalar_increment.attr,
&integer_type.attr,
NULL
};
static const struct attribute_group integer_attr_group = {
.attrs = integer_attrs,
};
int hp_alloc_integer_data(void)
{
bioscfg_drv.integer_instances_count = hp_get_instance_count(HP_WMI_BIOS_INTEGER_GUID);
bioscfg_drv.integer_data = kcalloc(bioscfg_drv.integer_instances_count,
sizeof(*bioscfg_drv.integer_data), GFP_KERNEL);
if (!bioscfg_drv.integer_data) {
bioscfg_drv.integer_instances_count = 0;
return -ENOMEM;
}
return 0;
}
/* Expected Values types associated with each element */
static const acpi_object_type expected_integer_types[] = {
[NAME] = ACPI_TYPE_STRING,
[VALUE] = ACPI_TYPE_STRING,
[PATH] = ACPI_TYPE_STRING,
[IS_READONLY] = ACPI_TYPE_INTEGER,
[DISPLAY_IN_UI] = ACPI_TYPE_INTEGER,
[REQUIRES_PHYSICAL_PRESENCE] = ACPI_TYPE_INTEGER,
[SEQUENCE] = ACPI_TYPE_INTEGER,
[PREREQUISITES_SIZE] = ACPI_TYPE_INTEGER,
[PREREQUISITES] = ACPI_TYPE_STRING,
[SECURITY_LEVEL] = ACPI_TYPE_INTEGER,
[INT_LOWER_BOUND] = ACPI_TYPE_INTEGER,
[INT_UPPER_BOUND] = ACPI_TYPE_INTEGER,
[INT_SCALAR_INCREMENT] = ACPI_TYPE_INTEGER,
};
static int hp_populate_integer_elements_from_package(union acpi_object *integer_obj,
int integer_obj_count,
int instance_id)
{
char *str_value = NULL;
int value_len;
int ret;
u32 int_value = 0;
int elem;
int reqs;
int eloc;
int size;
struct integer_data *integer_data = &bioscfg_drv.integer_data[instance_id];
if (!integer_obj)
return -EINVAL;
for (elem = 1, eloc = 1; elem < integer_obj_count; elem++, eloc++) {
/* ONLY look at the first INTEGER_ELEM_CNT elements */
if (eloc == INT_ELEM_CNT)
goto exit_integer_package;
switch (integer_obj[elem].type) {
case ACPI_TYPE_STRING:
if (elem != PREREQUISITES) {
ret = hp_convert_hexstr_to_str(integer_obj[elem].string.pointer,
integer_obj[elem].string.length,
&str_value, &value_len);
if (ret)
continue;
}
break;
case ACPI_TYPE_INTEGER:
int_value = (u32)integer_obj[elem].integer.value;
break;
default:
pr_warn("Unsupported object type [%d]\n", integer_obj[elem].type);
continue;
}
/* Check that both expected and read object type match */
if (expected_integer_types[eloc] != integer_obj[elem].type) {
pr_err("Error expected type %d for elem %d, but got type %d instead\n",
expected_integer_types[eloc], elem, integer_obj[elem].type);
kfree(str_value);
return -EIO;
}
/* Assign appropriate element value to corresponding field*/
switch (eloc) {
case VALUE:
ret = kstrtoint(str_value, 10, &int_value);
if (ret)
continue;
integer_data->current_value = int_value;
break;
case PATH:
strscpy(integer_data->common.path, str_value,
sizeof(integer_data->common.path));
break;
case IS_READONLY:
integer_data->common.is_readonly = int_value;
break;
case DISPLAY_IN_UI:
integer_data->common.display_in_ui = int_value;
break;
case REQUIRES_PHYSICAL_PRESENCE:
integer_data->common.requires_physical_presence = int_value;
break;
case SEQUENCE:
integer_data->common.sequence = int_value;
break;
case PREREQUISITES_SIZE:
if (int_value > MAX_PREREQUISITES_SIZE) {
pr_warn("Prerequisites size value exceeded the maximum number of elements supported or data may be malformed\n");
int_value = MAX_PREREQUISITES_SIZE;
}
integer_data->common.prerequisites_size = int_value;
/*
* This step is needed to keep the expected
* element list pointing to the right obj[elem].type
* when the size is zero. PREREQUISITES
* object is omitted by BIOS when the size is
* zero.
*/
if (integer_data->common.prerequisites_size == 0)
eloc++;
break;
case PREREQUISITES:
size = min_t(u32, integer_data->common.prerequisites_size, MAX_PREREQUISITES_SIZE);
for (reqs = 0; reqs < size; reqs++) {
if (elem >= integer_obj_count) {
pr_err("Error elem-objects package is too small\n");
return -EINVAL;
}
ret = hp_convert_hexstr_to_str(integer_obj[elem + reqs].string.pointer,
integer_obj[elem + reqs].string.length,
&str_value, &value_len);
if (ret)
continue;
strscpy(integer_data->common.prerequisites[reqs],
str_value,
sizeof(integer_data->common.prerequisites[reqs]));
kfree(str_value);
str_value = NULL;
}
break;
case SECURITY_LEVEL:
integer_data->common.security_level = int_value;
break;
case INT_LOWER_BOUND:
integer_data->lower_bound = int_value;
break;
case INT_UPPER_BOUND:
integer_data->upper_bound = int_value;
break;
case INT_SCALAR_INCREMENT:
integer_data->scalar_increment = int_value;
break;
default:
pr_warn("Invalid element: %d found in Integer attribute or data may be malformed\n", elem);
break;
}
kfree(str_value);
str_value = NULL;
}
exit_integer_package:
kfree(str_value);
return 0;
}
/**
* hp_populate_integer_package_data() -
* Populate all properties of an instance under integer attribute
*
* @integer_obj: ACPI object with integer data
* @instance_id: The instance to enumerate
* @attr_name_kobj: The parent kernel object
*/
int hp_populate_integer_package_data(union acpi_object *integer_obj,
int instance_id,
struct kobject *attr_name_kobj)
{
struct integer_data *integer_data = &bioscfg_drv.integer_data[instance_id];
integer_data->attr_name_kobj = attr_name_kobj;
hp_populate_integer_elements_from_package(integer_obj,
integer_obj->package.count,
instance_id);
hp_update_attribute_permissions(integer_data->common.is_readonly,
&integer_current_val);
hp_friendly_user_name_update(integer_data->common.path,
attr_name_kobj->name,
integer_data->common.display_name,
sizeof(integer_data->common.display_name));
return sysfs_create_group(attr_name_kobj, &integer_attr_group);
}
static int hp_populate_integer_elements_from_buffer(u8 *buffer_ptr, u32 *buffer_size,
int instance_id)
{
char *dst = NULL;
int dst_size = *buffer_size / sizeof(u16);
struct integer_data *integer_data = &bioscfg_drv.integer_data[instance_id];
int ret = 0;
dst = kcalloc(dst_size, sizeof(char), GFP_KERNEL);
if (!dst)
return -ENOMEM;
/*
* Only data relevant to this driver and its functionality is
* read. BIOS defines the order in which each * element is
* read. Element 0 data is not relevant to this
* driver hence it is ignored. For clarity, all element names
* (DISPLAY_IN_UI) which defines the order in which is read
* and the name matches the variable where the data is stored.
*
* In earlier implementation, reported errors were ignored
* causing the data to remain uninitialized. It is not
* possible to determine if data read from BIOS is valid or
* not. It is for this reason functions may return a error
* without validating the data itself.
*/
// VALUE:
integer_data->current_value = 0;
hp_get_string_from_buffer(&buffer_ptr, buffer_size, dst, dst_size);
ret = kstrtoint(dst, 10, &integer_data->current_value);
if (ret)
pr_warn("Unable to convert string to integer: %s\n", dst);
kfree(dst);
// COMMON:
ret = hp_get_common_data_from_buffer(&buffer_ptr, buffer_size, &integer_data->common);
if (ret < 0)
goto buffer_exit;
// INT_LOWER_BOUND:
ret = hp_get_integer_from_buffer(&buffer_ptr, buffer_size,
&integer_data->lower_bound);
if (ret < 0)
goto buffer_exit;
// INT_UPPER_BOUND:
ret = hp_get_integer_from_buffer(&buffer_ptr, buffer_size,
&integer_data->upper_bound);
if (ret < 0)
goto buffer_exit;
// INT_SCALAR_INCREMENT:
ret = hp_get_integer_from_buffer(&buffer_ptr, buffer_size,
&integer_data->scalar_increment);
buffer_exit:
return ret;
}
/**
* hp_populate_integer_buffer_data() -
* Populate all properties of an instance under integer attribute
*
* @buffer_ptr: Buffer pointer
* @buffer_size: Buffer size
* @instance_id: The instance to enumerate
* @attr_name_kobj: The parent kernel object
*/
int hp_populate_integer_buffer_data(u8 *buffer_ptr, u32 *buffer_size, int instance_id,
struct kobject *attr_name_kobj)
{
struct integer_data *integer_data = &bioscfg_drv.integer_data[instance_id];
int ret = 0;
integer_data->attr_name_kobj = attr_name_kobj;
/* Populate integer elements */
ret = hp_populate_integer_elements_from_buffer(buffer_ptr, buffer_size,
instance_id);
if (ret < 0)
return ret;
hp_update_attribute_permissions(integer_data->common.is_readonly,
&integer_current_val);
hp_friendly_user_name_update(integer_data->common.path,
attr_name_kobj->name,
integer_data->common.display_name,
sizeof(integer_data->common.display_name));
return sysfs_create_group(attr_name_kobj, &integer_attr_group);
}
/**
* hp_exit_integer_attributes() - Clear all attribute data
*
* Clears all data allocated for this group of attributes
*/
void hp_exit_integer_attributes(void)
{
int instance_id;
for (instance_id = 0; instance_id < bioscfg_drv.integer_instances_count;
instance_id++) {
struct kobject *attr_name_kobj =
bioscfg_drv.integer_data[instance_id].attr_name_kobj;
if (attr_name_kobj)
sysfs_remove_group(attr_name_kobj, &integer_attr_group);
}
bioscfg_drv.integer_instances_count = 0;
kfree(bioscfg_drv.integer_data);
bioscfg_drv.integer_data = NULL;
}