Move and include mem read/write functions

2024-11-15 03:34:01 +01:00 · 2021-09-13 21:26:12 +02:00 · 2021-09-13 21:26:12 +02:00 · 57ebb3a9fe
parent 0da37ce0ca
commit 57ebb3a9fe
1 changed files with 244 additions and 2 deletions
--- a/src/uniwill_wmi.c
+++ b/src/uniwill_wmi.c
@ -21,12 +21,254 @@
 #include <linux/module.h>
 #include <linux/wmi.h>
 #include <linux/version.h>
 #include <linux/delay.h>
 #include "uniwill_interfaces.h"
 #define UNIWILL_EC_REG_LDAT	0x8a
 #define UNIWILL_EC_REG_HDAT	0x8b
 #define UNIWILL_EC_REG_FLAGS	0x8c
 #define UNIWILL_EC_REG_CMDL	0x8d
 #define UNIWILL_EC_REG_CMDH	0x8e
 #define UNIWILL_EC_BIT_RFLG	0
 #define UNIWILL_EC_BIT_WFLG	1
 #define UNIWILL_EC_BIT_BFLG	2
 #define UNIWILL_EC_BIT_CFLG	3
 #define UNIWILL_EC_BIT_DRDY	7
 #define UW_EC_WAIT_CYCLES	0x50
 union uw_ec_read_return {
 	u32 dword;
 	struct {
 		u8 data_low;
 		u8 data_high;
 	} bytes;
 };
 union uw_ec_write_return {
 	u32 dword;
 	struct {
 		u8 addr_low;
 		u8 addr_high;
 		u8 data_low;
 		u8 data_high;
 	} bytes;
 };
 static bool uniwill_ec_direct = true;
 DEFINE_MUTEX(uniwill_ec_lock);
 static u32 uw_wmi_ec_evaluate(u8 addr_low, u8 addr_high, u8 data_low, u8 data_high, u8 read_flag, u32 *return_buffer)
 {
 	acpi_status status;
 	union acpi_object *out_acpi;
 	u32 e_result = 0;
 	// Kernel buffer for input argument
 	u32 *wmi_arg = (u32 *) kmalloc(sizeof(u32)*10, GFP_KERNEL);
 	// Byte reference to the input buffer
 	u8 *wmi_arg_bytes = (u8 *) wmi_arg;
 	u8 wmi_instance = 0x00;
 	u32 wmi_method_id = 0x04;
 	struct acpi_buffer wmi_in = { (acpi_size) sizeof(wmi_arg), wmi_arg};
 	struct acpi_buffer wmi_out = { ACPI_ALLOCATE_BUFFER, NULL };
 	mutex_lock(&uniwill_ec_lock);
 	// Zero input buffer
 	memset(wmi_arg, 0x00, 10 * sizeof(u32));
 	// Configure the input buffer
 	wmi_arg_bytes[0] = addr_low;
 	wmi_arg_bytes[1] = addr_high;
 	wmi_arg_bytes[2] = data_low;
 	wmi_arg_bytes[3] = data_high;
 	if (read_flag != 0) {
 		wmi_arg_bytes[5] = 0x01;
 	}
 	status = wmi_evaluate_method(UNIWILL_WMI_MGMT_GUID_BC, wmi_instance, wmi_method_id, &wmi_in, &wmi_out);
 	out_acpi = (union acpi_object *) wmi_out.pointer;
 	if (out_acpi && out_acpi->type == ACPI_TYPE_BUFFER) {
 		memcpy(return_buffer, out_acpi->buffer.pointer, out_acpi->buffer.length);
 	} /* else if (out_acpi && out_acpi->type == ACPI_TYPE_INTEGER) {
 		e_result = (u32) out_acpi->integer.value;
 	}*/
 	if (ACPI_FAILURE(status)) {
 		pr_err("uniwill_wmi.h: Error evaluating method\n");
 		e_result = -EIO;
 	}
 	kfree(out_acpi);
 	kfree(wmi_arg);
 	mutex_unlock(&uniwill_ec_lock);
 	return e_result;
 }
 /**
 * EC address read through WMI
 */
 static u32 uw_ec_read_addr_wmi(u8 addr_low, u8 addr_high, union uw_ec_read_return *output)
 {
 	u32 uw_data[10];
 	u32 ret = uw_wmi_ec_evaluate(addr_low, addr_high, 0x00, 0x00, 1, uw_data);
 	output->dword = uw_data[0];
 	// pr_debug("addr: 0x%02x%02x value: %0#4x (high: %0#4x) result: %d\n", addr_high, addr_low, output->bytes.data_low, output->bytes.data_high, ret);
 	return ret;
 }
 /**
 * EC address write through WMI
 */
 static u32 uw_ec_write_addr_wmi(u8 addr_low, u8 addr_high, u8 data_low, u8 data_high, union uw_ec_write_return *output)
 {
 	u32 uw_data[10];
 	u32 ret = uw_wmi_ec_evaluate(addr_low, addr_high, data_low, data_high, 0, uw_data);
 	output->dword = uw_data[0];
 	return ret;
 }
 /**
 * Direct EC address read
 */
 static u32 uw_ec_read_addr_direct(u8 addr_low, u8 addr_high, union uw_ec_read_return *output)
 {
 	u32 result;
 	u8 tmp, count, flags;
 	mutex_lock(&uniwill_ec_lock);
 	ec_write(UNIWILL_EC_REG_LDAT, addr_low);
 	ec_write(UNIWILL_EC_REG_HDAT, addr_high);
 	flags = (0 << UNIWILL_EC_BIT_DRDY) | (1 << UNIWILL_EC_BIT_RFLG);
 	ec_write(UNIWILL_EC_REG_FLAGS, flags);
 	// Wait for ready flag
 	count = UW_EC_WAIT_CYCLES;
 	ec_read(UNIWILL_EC_REG_FLAGS, &tmp);
 	while (((tmp & (1 << UNIWILL_EC_BIT_DRDY)) == 0) && count != 0) {
 		msleep(1);
 		ec_read(UNIWILL_EC_REG_FLAGS, &tmp);
 		count -= 1;
 	}
 	if (count != 0) {
 		output->dword = 0;
 		ec_read(UNIWILL_EC_REG_CMDL, &tmp);
 		output->bytes.data_low = tmp;
 		ec_read(UNIWILL_EC_REG_CMDH, &tmp);
 		output->bytes.data_high = tmp;
 		result = 0;
 	} else {
 		output->dword = 0xfefefefe;
 		result = -EIO;
 	}
 	ec_write(UNIWILL_EC_REG_FLAGS, 0x00);
 	mutex_unlock(&uniwill_ec_lock);
 	// pr_debug("addr: 0x%02x%02x value: %0#4x result: %d\n", addr_high, addr_low, output->bytes.data_low, result);
 	return result;
 }
 static u32 uw_ec_write_addr_direct(u8 addr_low, u8 addr_high, u8 data_low, u8 data_high, union uw_ec_write_return *output)
 {
 	u32 result = 0;
 	u8 tmp, count, flags;
 	mutex_lock(&uniwill_ec_lock);
 	ec_write(UNIWILL_EC_REG_LDAT, addr_low);
 	ec_write(UNIWILL_EC_REG_HDAT, addr_high);
 	ec_write(UNIWILL_EC_REG_CMDL, data_low);
 	ec_write(UNIWILL_EC_REG_CMDH, data_high);
 	flags = (0 << UNIWILL_EC_BIT_DRDY) | (1 << UNIWILL_EC_BIT_WFLG);
 	ec_write(UNIWILL_EC_REG_FLAGS, flags);
 	// Wait for ready flag
 	count = UW_EC_WAIT_CYCLES;
 	ec_read(UNIWILL_EC_REG_FLAGS, &tmp);
 	while (((tmp & (1 << UNIWILL_EC_BIT_DRDY)) == 0) && count != 0) {
 		msleep(1);
 		ec_read(UNIWILL_EC_REG_FLAGS, &tmp);
 		count -= 1;
 	}
 	// Replicate wmi output depending on success
 	if (count != 0) {
 		output->bytes.addr_low = addr_low;
 		output->bytes.addr_high = addr_high;
 		output->bytes.data_low = data_low;
 		output->bytes.data_high = data_high;
 		result = 0;
 	} else {
 		output->dword = 0xfefefefe;
 		result = -EIO;
 	}
 	ec_write(UNIWILL_EC_REG_FLAGS, 0x00);
 	mutex_unlock(&uniwill_ec_lock);
 	return result;
 }
 u32 uw_wmi_read_ec_ram(u16 addr, u8 *data)
 {
 	u32 result;
 	u8 addr_low, addr_high;
 	union uw_ec_read_return output;
 	if (IS_ERR_OR_NULL(data))
 		return -EINVAL;
 	addr_low = addr & 0xff;
 	addr_high = (addr >> 8) & 0xff;
 	if (uniwill_ec_direct) {
 		result = uw_ec_read_addr_direct(addr_low, addr_high, &output);
 	} else {
 		result = uw_ec_read_addr_wmi(addr_low, addr_high, &output);
 	}
 	*data = output.bytes.data_low;
 	return result;
 }
 u32 uw_wmi_write_ec_ram(u16 addr, u8 data)
 {
 	u32 result;
 	u8 addr_low, addr_high, data_low, data_high;
 	union uw_ec_write_return output;
 	addr_low = addr & 0xff;
 	addr_high = (addr >> 8) & 0xff;
 	data_low = data;
 	data_high = 0x00;
 	if (uniwill_ec_direct)
 		result = uw_ec_write_addr_direct(addr_low, addr_high, data_low, data_high, &output);
 	else
 		result = uw_ec_write_addr_wmi(addr_low, addr_high, data_low, data_high, &output);
 	return result;
 }
 struct uniwill_interface_t uniwill_wmi_interface = {
 	.string_id = UNIWILL_INTERFACE_WMI_STRID,
-	.read_ec_ram = NULL, //uw_wmi_read_ec_ram,
+	.read_ec_ram = uw_wmi_read_ec_ram,
-	.write_ec_ram = NULL //uw_wmi_write_ec_ram
+	.write_ec_ram = uw_wmi_write_ec_ram
 };
 #if LINUX_VERSION_CODE < KERNEL_VERSION(5, 3, 0)