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|
/**
* Copyright (c) 2011 Trusted Logic S.A.
* All Rights Reserved.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* version 2 as published by the Free Software Foundation.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston,
* MA 02111-1307 USA
*/
#include <asm/div64.h>
#include <asm/system.h>
#include <linux/version.h>
#include <asm/cputype.h>
#include <linux/interrupt.h>
#include <linux/page-flags.h>
#include <linux/pagemap.h>
#include <linux/vmalloc.h>
#include <linux/jiffies.h>
#include "tf_defs.h"
#include "tf_comm.h"
#include "tf_protocol.h"
#include "tf_util.h"
#include "tf_conn.h"
/*
* Structure common to all SMC operations
*/
struct tf_generic_smc {
u32 reg0;
u32 reg1;
u32 reg2;
u32 reg3;
u32 reg4;
};
/*----------------------------------------------------------------------------
* SMC operations
*----------------------------------------------------------------------------*/
static inline void tf_smc_generic_call(
struct tf_generic_smc *generic_smc)
{
#ifdef CONFIG_SMP
long ret;
cpumask_t saved_cpu_mask;
cpumask_t local_cpu_mask = CPU_MASK_NONE;
cpu_set(0, local_cpu_mask);
sched_getaffinity(0, &saved_cpu_mask);
ret = sched_setaffinity(0, &local_cpu_mask);
if (ret != 0)
dprintk(KERN_ERR "sched_setaffinity #1 -> 0x%lX", ret);
#endif
__asm__ volatile(
"mov r0, %2\n"
"mov r1, %3\n"
"mov r2, %4\n"
"mov r3, %5\n"
"mov r4, %6\n"
".word 0xe1600070 @ SMC 0\n"
"mov %0, r0\n"
"mov %1, r1\n"
: "=r" (generic_smc->reg0), "=r" (generic_smc->reg1)
: "r" (generic_smc->reg0), "r" (generic_smc->reg1),
"r" (generic_smc->reg2), "r" (generic_smc->reg3),
"r" (generic_smc->reg4)
: "r0", "r1", "r2", "r3", "r4");
#ifdef CONFIG_SMP
ret = sched_setaffinity(0, &saved_cpu_mask);
if (ret != 0)
dprintk(KERN_ERR "sched_setaffinity #2 -> 0x%lX", ret);
#endif
}
/*
* Calls the get protocol version SMC.
* Fills the parameter pProtocolVersion with the version number returned by the
* SMC
*/
static inline void tf_smc_get_protocol_version(u32 *protocol_version)
{
struct tf_generic_smc generic_smc;
generic_smc.reg0 = TF_SMC_GET_PROTOCOL_VERSION;
generic_smc.reg1 = 0;
generic_smc.reg2 = 0;
generic_smc.reg3 = 0;
generic_smc.reg4 = 0;
tf_smc_generic_call(&generic_smc);
*protocol_version = generic_smc.reg1;
}
/*
* Calls the init SMC with the specified parameters.
* Returns zero upon successful completion, or an appropriate error code upon
* failure.
*/
static inline int tf_smc_init(u32 shared_page_descriptor)
{
struct tf_generic_smc generic_smc;
generic_smc.reg0 = TF_SMC_INIT;
/* Descriptor for the layer 1 shared buffer */
generic_smc.reg1 = shared_page_descriptor;
generic_smc.reg2 = 0;
generic_smc.reg3 = 0;
generic_smc.reg4 = 0;
tf_smc_generic_call(&generic_smc);
if (generic_smc.reg0 != S_SUCCESS)
printk(KERN_ERR "tf_smc_init:"
" r0=0x%08X upon return (expected 0x%08X)!\n",
generic_smc.reg0,
S_SUCCESS);
return generic_smc.reg0;
}
/*
* Calls the reset irq SMC.
*/
static inline void tf_smc_reset_irq(void)
{
struct tf_generic_smc generic_smc;
generic_smc.reg0 = TF_SMC_RESET_IRQ;
generic_smc.reg1 = 0;
generic_smc.reg2 = 0;
generic_smc.reg3 = 0;
generic_smc.reg4 = 0;
tf_smc_generic_call(&generic_smc);
}
/*
* Calls the WAKE_UP SMC.
* Returns zero upon successful completion, or an appropriate error code upon
* failure.
*/
static inline int tf_smc_wake_up(u32 l1_shared_buffer_descriptor,
u32 shared_mem_start_offset,
u32 shared_mem_size)
{
struct tf_generic_smc generic_smc;
generic_smc.reg0 = TF_SMC_WAKE_UP;
generic_smc.reg1 = shared_mem_start_offset;
/* long form command */
generic_smc.reg2 = shared_mem_size | 0x80000000;
generic_smc.reg3 = l1_shared_buffer_descriptor;
generic_smc.reg4 = 0;
tf_smc_generic_call(&generic_smc);
if (generic_smc.reg0 != S_SUCCESS)
printk(KERN_ERR "tf_smc_wake_up:"
" r0=0x%08X upon return (expected 0x%08X)!\n",
generic_smc.reg0,
S_SUCCESS);
return generic_smc.reg0;
}
/*
* Calls the N-Yield SMC.
*/
static inline void tf_smc_nyield(void)
{
struct tf_generic_smc generic_smc;
generic_smc.reg0 = TF_SMC_N_YIELD;
generic_smc.reg1 = 0;
generic_smc.reg2 = 0;
generic_smc.reg3 = 0;
generic_smc.reg4 = 0;
tf_smc_generic_call(&generic_smc);
}
#ifdef CONFIG_SECURE_TRACES
static void tf_print_secure_traces(struct tf_comm *comm)
{
spin_lock(&(comm->lock));
if (comm->l1_buffer->traces_status != 0) {
if (comm->l1_buffer->traces_status > 1)
pr_info("TF : traces lost...\n");
pr_info("TF : %s", comm->l1_buffer->traces_buffer);
comm->l1_buffer->traces_status = 0;
}
spin_unlock(&(comm->lock));
}
#endif
/* Yields the Secure World */
int tf_schedule_secure_world(struct tf_comm *comm)
{
tf_set_current_time(comm);
/* yield to the Secure World */
tf_smc_nyield();
#ifdef CONFIG_SECURE_TRACES
tf_print_secure_traces(comm);
#endif
return 0;
}
/*
* Returns the L2 descriptor for the specified user page.
*/
#define L2_INIT_DESCRIPTOR_BASE (0x00000003)
#define L2_INIT_DESCRIPTOR_V13_12_SHIFT (4)
static u32 tf_get_l2init_descriptor(u32 vaddr)
{
struct page *page;
u32 paddr;
u32 descriptor;
descriptor = L2_INIT_DESCRIPTOR_BASE;
/* get physical address and add to descriptor */
page = virt_to_page(vaddr);
paddr = page_to_phys(page);
descriptor |= (paddr & L2_DESCRIPTOR_ADDR_MASK);
/* Add virtual address v[13:12] bits to descriptor */
descriptor |= (DESCRIPTOR_V13_12_GET(vaddr)
<< L2_INIT_DESCRIPTOR_V13_12_SHIFT);
descriptor |= tf_get_l2_descriptor_common(vaddr, &init_mm);
return descriptor;
}
/*----------------------------------------------------------------------------
* Power management
*----------------------------------------------------------------------------*/
/*
* Free the memory used by the W3B buffer for the specified comm.
* This function does nothing if no W3B buffer is allocated for the device.
*/
static inline void tf_free_w3b(struct tf_comm *comm)
{
tf_cleanup_shared_memory(
&(comm->w3b_cpt_alloc_context),
&(comm->w3b_shmem_desc),
0);
tf_release_coarse_page_table_allocator(&(comm->w3b_cpt_alloc_context));
internal_vfree((void *)comm->w3b);
comm->w3b = 0;
comm->w3b_shmem_size = 0;
clear_bit(TF_COMM_FLAG_W3B_ALLOCATED, &(comm->flags));
}
/*
* Allocates the W3B buffer for the specified comm.
* Returns zero upon successful completion, or an appropriate error code upon
* failure.
*/
static inline int tf_allocate_w3b(struct tf_comm *comm)
{
int error;
u32 flags;
u32 config_flag_s;
u32 *w3b_descriptors;
u32 w3b_descriptor_count;
u32 w3b_current_size;
config_flag_s = tf_read_reg32(&comm->l1_buffer->config_flag_s);
retry:
if ((test_bit(TF_COMM_FLAG_W3B_ALLOCATED, &(comm->flags))) == 0) {
/*
* Initialize the shared memory for the W3B
*/
tf_init_coarse_page_table_allocator(
&comm->w3b_cpt_alloc_context);
} else {
/*
* The W3B is allocated but do we have to reallocate a bigger
* one?
*/
/* Check H bit */
if ((config_flag_s & (1<<4)) != 0) {
/* The size of the W3B may change after SMC_INIT */
/* Read the current value */
w3b_current_size = tf_read_reg32(
&comm->l1_buffer->w3b_size_current_s);
if (comm->w3b_shmem_size > w3b_current_size)
return 0;
tf_free_w3b(comm);
goto retry;
} else {
return 0;
}
}
/* check H bit */
if ((config_flag_s & (1<<4)) != 0)
/* The size of the W3B may change after SMC_INIT */
/* Read the current value */
comm->w3b_shmem_size = tf_read_reg32(
&comm->l1_buffer->w3b_size_current_s);
else
comm->w3b_shmem_size = tf_read_reg32(
&comm->l1_buffer->w3b_size_max_s);
comm->w3b = (u32) internal_vmalloc(comm->w3b_shmem_size);
if (comm->w3b == 0) {
printk(KERN_ERR "tf_allocate_w3b():"
" Out of memory for W3B buffer (%u bytes)!\n",
(unsigned int)(comm->w3b_shmem_size));
error = -ENOMEM;
goto error;
}
/* initialize the w3b_shmem_desc structure */
comm->w3b_shmem_desc.type = TF_SHMEM_TYPE_PM_HIBERNATE;
INIT_LIST_HEAD(&(comm->w3b_shmem_desc.list));
flags = (TF_SHMEM_TYPE_READ | TF_SHMEM_TYPE_WRITE);
/* directly point to the L1 shared buffer W3B descriptors */
w3b_descriptors = comm->l1_buffer->w3b_descriptors;
/*
* tf_fill_descriptor_table uses the following parameter as an
* IN/OUT
*/
error = tf_fill_descriptor_table(
&(comm->w3b_cpt_alloc_context),
&(comm->w3b_shmem_desc),
comm->w3b,
NULL,
w3b_descriptors,
comm->w3b_shmem_size,
&(comm->w3b_shmem_offset),
false,
flags,
&w3b_descriptor_count);
if (error != 0) {
printk(KERN_ERR "tf_allocate_w3b():"
" tf_fill_descriptor_table failed with "
"error code 0x%08x!\n",
error);
goto error;
}
set_bit(TF_COMM_FLAG_W3B_ALLOCATED, &(comm->flags));
/* successful completion */
return 0;
error:
tf_free_w3b(comm);
return error;
}
/*
* Perform a Secure World shutdown operation.
* The routine does not return if the operation succeeds.
* the routine returns an appropriate error code if
* the operation fails.
*/
int tf_pm_shutdown(struct tf_comm *comm)
{
#ifdef CONFIG_TFN
/* this function is useless for the TEGRA product */
return 0;
#else
int error;
union tf_command command;
union tf_answer answer;
dprintk(KERN_INFO "tf_pm_shutdown()\n");
memset(&command, 0, sizeof(command));
command.header.message_type = TF_MESSAGE_TYPE_MANAGEMENT;
command.header.message_size =
(sizeof(struct tf_command_management) -
sizeof(struct tf_command_header))/sizeof(u32);
command.management.command = TF_MANAGEMENT_SHUTDOWN;
error = tf_send_receive(
comm,
&command,
&answer,
NULL,
false);
if (error != 0) {
dprintk(KERN_ERR "tf_pm_shutdown(): "
"tf_send_receive failed (error %d)!\n",
error);
return error;
}
#ifdef CONFIG_TF_DRIVER_DEBUG_SUPPORT
if (answer.header.error_code != 0)
dprintk(KERN_ERR "tf_driver: shutdown failed.\n");
else
dprintk(KERN_INFO "tf_driver: shutdown succeeded.\n");
#endif
return answer.header.error_code;
#endif
}
/*
* Perform a Secure World hibernate operation.
* The routine does not return if the operation succeeds.
* the routine returns an appropriate error code if
* the operation fails.
*/
int tf_pm_hibernate(struct tf_comm *comm)
{
#ifdef CONFIG_TFN
/* this function is useless for the TEGRA product */
return 0;
#else
int error;
union tf_command command;
union tf_answer answer;
u32 first_command;
u32 first_free_command;
dprintk(KERN_INFO "tf_pm_hibernate()\n");
error = tf_allocate_w3b(comm);
if (error != 0) {
dprintk(KERN_ERR "tf_pm_hibernate(): "
"tf_allocate_w3b failed (error %d)!\n",
error);
return error;
}
/*
* As the polling thread is already hibernating, we
* should send the message and receive the answer ourself
*/
/* build the "prepare to hibernate" message */
command.header.message_type = TF_MESSAGE_TYPE_MANAGEMENT;
command.management.command = TF_MANAGEMENT_HIBERNATE;
/* Long Form Command */
command.management.shared_mem_descriptors[0] = 0;
command.management.shared_mem_descriptors[1] = 0;
command.management.w3b_size =
comm->w3b_shmem_size | 0x80000000;
command.management.w3b_start_offset =
comm->w3b_shmem_offset;
command.header.operation_id = (u32) &answer;
tf_dump_command(&command);
/* find a slot to send the message in */
/* AFY: why not use the function tf_send_receive?? We are
* duplicating a lot of subtle code here. And it's not going to be
* tested because power management is currently not supported by the
* secure world. */
for (;;) {
int queue_words_count, command_size;
spin_lock(&(comm->lock));
first_command = tf_read_reg32(
&comm->l1_buffer->first_command);
first_free_command = tf_read_reg32(
&comm->l1_buffer->first_free_command);
queue_words_count = first_free_command - first_command;
command_size = command.header.message_size
+ sizeof(struct tf_command_header);
if ((queue_words_count + command_size) <
TF_N_MESSAGE_QUEUE_CAPACITY) {
/* Command queue is not full */
memcpy(&comm->l1_buffer->command_queue[
first_free_command %
TF_N_MESSAGE_QUEUE_CAPACITY],
&command,
command_size * sizeof(u32));
tf_write_reg32(&comm->l1_buffer->first_free_command,
first_free_command + command_size);
spin_unlock(&(comm->lock));
break;
}
spin_unlock(&(comm->lock));
(void)tf_schedule_secure_world(comm);
}
/* now wait for the answer, dispatching other answers */
while (1) {
u32 first_answer;
u32 first_free_answer;
/* check all the answers */
first_free_answer = tf_read_reg32(
&comm->l1_buffer->first_free_answer);
first_answer = tf_read_reg32(
&comm->l1_buffer->first_answer);
if (first_answer != first_free_answer) {
int bFoundAnswer = 0;
do {
/* answer queue not empty */
union tf_answer tmp_answer;
struct tf_answer_header header;
/* size of the command in words of 32bit */
int command_size;
/* get the message_size */
memcpy(&header,
&comm->l1_buffer->answer_queue[
first_answer %
TF_S_ANSWER_QUEUE_CAPACITY],
sizeof(struct tf_answer_header));
command_size = header.message_size +
sizeof(struct tf_answer_header);
/*
* NOTE: message_size is the number of words
* following the first word
*/
memcpy(&tmp_answer,
&comm->l1_buffer->answer_queue[
first_answer %
TF_S_ANSWER_QUEUE_CAPACITY],
command_size * sizeof(u32));
tf_dump_answer(&tmp_answer);
if (tmp_answer.header.operation_id ==
(u32) &answer) {
/*
* this is the answer to the "prepare to
* hibernate" message
*/
memcpy(&answer,
&tmp_answer,
command_size * sizeof(u32));
bFoundAnswer = 1;
tf_write_reg32(
&comm->l1_buffer->first_answer,
first_answer + command_size);
break;
} else {
/*
* this is a standard message answer,
* dispatch it
*/
struct tf_answer_struct
*answerStructure;
answerStructure =
(struct tf_answer_struct *)
tmp_answer.header.operation_id;
memcpy(answerStructure->answer,
&tmp_answer,
command_size * sizeof(u32));
answerStructure->answer_copied = true;
}
tf_write_reg32(
&comm->l1_buffer->first_answer,
first_answer + command_size);
} while (first_answer != first_free_answer);
if (bFoundAnswer)
break;
}
/*
* since the Secure World is at least running the "prepare to
* hibernate" message, its timeout must be immediate So there is
* no need to check its timeout and schedule() the current
* thread
*/
(void)tf_schedule_secure_world(comm);
} /* while (1) */
printk(KERN_INFO "tf_driver: hibernate.\n");
return 0;
#endif
}
/*
* Perform a Secure World resume operation.
* The routine returns once the Secure World is active again
* or if an error occurs during the "resume" process
*/
int tf_pm_resume(struct tf_comm *comm)
{
#ifdef CONFIG_TFN
/* this function is useless for the TEGRA product */
return 0;
#else
int error;
u32 status;
dprintk(KERN_INFO "tf_pm_resume()\n");
error = tf_smc_wake_up(
tf_get_l2init_descriptor((u32)comm->l1_buffer),
comm->w3b_shmem_offset,
comm->w3b_shmem_size);
if (error != 0) {
dprintk(KERN_ERR "tf_pm_resume(): "
"tf_smc_wake_up failed (error %d)!\n",
error);
return error;
}
status = ((tf_read_reg32(&(comm->l1_buffer->status_s))
& TF_STATUS_POWER_STATE_MASK)
>> TF_STATUS_POWER_STATE_SHIFT);
while ((status != TF_POWER_MODE_ACTIVE)
&& (status != TF_POWER_MODE_PANIC)) {
tf_smc_nyield();
status = ((tf_read_reg32(&(comm->l1_buffer->status_s))
& TF_STATUS_POWER_STATE_MASK)
>> TF_STATUS_POWER_STATE_SHIFT);
/*
* As this may last quite a while, call the kernel scheduler to
* hand over CPU for other operations
*/
schedule();
}
switch (status) {
case TF_POWER_MODE_ACTIVE:
break;
case TF_POWER_MODE_PANIC:
dprintk(KERN_ERR "tf_pm_resume(): "
"Secure World POWER_MODE_PANIC!\n");
return -EINVAL;
default:
dprintk(KERN_ERR "tf_pm_resume(): "
"unexpected Secure World POWER_MODE (%d)!\n", status);
return -EINVAL;
}
dprintk(KERN_INFO "tf_pm_resume() succeeded\n");
return 0;
#endif
}
/*----------------------------------------------------------------------------
* Communication initialization and termination
*----------------------------------------------------------------------------*/
/*
* Handles the software interrupts issued by the Secure World.
*/
static irqreturn_t tf_soft_int_handler(int irq, void *dev_id)
{
struct tf_comm *comm = (struct tf_comm *) dev_id;
if (comm->l1_buffer == NULL)
return IRQ_NONE;
if ((tf_read_reg32(&comm->l1_buffer->status_s) &
TF_STATUS_P_MASK) == 0)
/* interrupt not issued by the Trusted Foundations Software */
return IRQ_NONE;
tf_smc_reset_irq();
/* signal N_SM_EVENT */
wake_up(&comm->wait_queue);
return IRQ_HANDLED;
}
/*
* Initializes the communication with the Secure World.
* The L1 shared buffer is allocated and the Secure World
* is yielded for the first time.
* returns successfuly once the communication with
* the Secure World is up and running
*
* Returns 0 upon success or appropriate error code
* upon failure
*/
int tf_init(struct tf_comm *comm)
{
int error;
struct page *buffer_page;
u32 protocol_version;
dprintk(KERN_INFO "tf_init()\n");
spin_lock_init(&(comm->lock));
comm->flags = 0;
comm->l1_buffer = NULL;
init_waitqueue_head(&(comm->wait_queue));
/*
* Check the Secure World protocol version is the expected one.
*/
tf_smc_get_protocol_version(&protocol_version);
if ((GET_PROTOCOL_MAJOR_VERSION(protocol_version))
!= TF_S_PROTOCOL_MAJOR_VERSION) {
printk(KERN_ERR "tf_init():"
" Unsupported Secure World Major Version "
"(0x%02X, expected 0x%02X)!\n",
GET_PROTOCOL_MAJOR_VERSION(protocol_version),
TF_S_PROTOCOL_MAJOR_VERSION);
error = -EIO;
goto error;
}
/*
* Register the software interrupt handler if required to.
*/
if (comm->soft_int_irq != -1) {
dprintk(KERN_INFO "tf_init(): "
"Registering software interrupt handler (IRQ %d)\n",
comm->soft_int_irq);
error = request_irq(comm->soft_int_irq,
tf_soft_int_handler,
IRQF_SHARED,
TF_DEVICE_BASE_NAME,
comm);
if (error != 0) {
dprintk(KERN_ERR "tf_init(): "
"request_irq failed for irq %d (error %d)\n",
comm->soft_int_irq, error);
goto error;
}
set_bit(TF_COMM_FLAG_IRQ_REQUESTED, &(comm->flags));
}
/*
* Allocate and initialize the L1 shared buffer.
*/
comm->l1_buffer = (void *) internal_get_zeroed_page(GFP_KERNEL);
if (comm->l1_buffer == NULL) {
printk(KERN_ERR "tf_init():"
" get_zeroed_page failed for L1 shared buffer!\n");
error = -ENOMEM;
goto error;
}
/*
* Ensure the page storing the L1 shared buffer is mapped.
*/
buffer_page = virt_to_page(comm->l1_buffer);
trylock_page(buffer_page);
dprintk(KERN_INFO "tf_init(): "
"L1 shared buffer allocated at virtual:%p, "
"physical:%p (page:%p)\n",
comm->l1_buffer,
(void *)virt_to_phys(comm->l1_buffer),
buffer_page);
set_bit(TF_COMM_FLAG_L1_SHARED_ALLOCATED, &(comm->flags));
/*
* Init SMC
*/
error = tf_smc_init(
tf_get_l2init_descriptor((u32)comm->l1_buffer));
if (error != S_SUCCESS) {
dprintk(KERN_ERR "tf_init(): "
"tf_smc_init failed (error 0x%08X)!\n",
error);
goto error;
}
/*
* check whether the interrupts are actually enabled
* If not, remove irq handler
*/
if ((tf_read_reg32(&comm->l1_buffer->config_flag_s) &
TF_CONFIG_FLAG_S) == 0) {
if (test_and_clear_bit(TF_COMM_FLAG_IRQ_REQUESTED,
&(comm->flags)) != 0) {
dprintk(KERN_INFO "tf_init(): "
"Interrupts not used, unregistering "
"softint (IRQ %d)\n",
comm->soft_int_irq);
free_irq(comm->soft_int_irq, comm);
}
} else {
if (test_bit(TF_COMM_FLAG_IRQ_REQUESTED,
&(comm->flags)) == 0) {
/*
* Interrupts are enabled in the Secure World, but not
* handled by driver
*/
dprintk(KERN_ERR "tf_init(): "
"soft_interrupt argument not provided\n");
error = -EINVAL;
goto error;
}
}
/*
* Successful completion.
*/
/* yield for the first time */
(void)tf_schedule_secure_world(comm);
dprintk(KERN_INFO "tf_init(): Success\n");
return S_SUCCESS;
error:
/*
* Error handling.
*/
dprintk(KERN_INFO "tf_init(): Failure (error %d)\n",
error);
tf_terminate(comm);
return error;
}
/*
* Attempt to terminate the communication with the Secure World.
* The L1 shared buffer is freed.
* Calling this routine terminates definitaly the communication
* with the Secure World : there is no way to inform the Secure World of a new
* L1 shared buffer to be used once it has been initialized.
*/
void tf_terminate(struct tf_comm *comm)
{
dprintk(KERN_INFO "tf_terminate()\n");
set_bit(TF_COMM_FLAG_TERMINATING, &(comm->flags));
if ((test_bit(TF_COMM_FLAG_W3B_ALLOCATED,
&(comm->flags))) != 0) {
dprintk(KERN_INFO "tf_terminate(): "
"Freeing the W3B buffer...\n");
tf_free_w3b(comm);
}
if ((test_bit(TF_COMM_FLAG_L1_SHARED_ALLOCATED,
&(comm->flags))) != 0) {
__clear_page_locked(virt_to_page(comm->l1_buffer));
internal_free_page((unsigned long) comm->l1_buffer);
}
if ((test_bit(TF_COMM_FLAG_IRQ_REQUESTED,
&(comm->flags))) != 0) {
dprintk(KERN_INFO "tf_terminate(): "
"Unregistering softint (IRQ %d)\n",
comm->soft_int_irq);
free_irq(comm->soft_int_irq, comm);
}
}
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