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linux-stable/net/iucv/iucv.c
Linus Torvalds f9c035492f more s390 updates for 6.9 merge window 
- Various virtual vs physical address usage fixes
 
 - Add new bitwise types and helper functions and use them in s390 specific
   drivers and code to make it easier to find virtual vs physical address
   usage bugs. Right now virtual and physical addresses are identical for
   s390, except for module, vmalloc, and similar areas. This will be
   changed, hopefully with the next merge window, so that e.g. the kernel
   image and modules will be located close to each other, allowing for
   direct branches and also for some other simplifications.
 
   As a prerequisite this requires to fix all misuses of virtual and
   physical addresses. As it turned out people are so used to the concept
   that virtual and physical addresses are the same, that new bugs got added
   to code which was already fixed. In order to avoid that even more code
   gets merged which adds such bugs add and use new bitwise types, so that
   sparse can be used to find such usage bugs.
 
   Most likely the new types can go away again after some time
 
 - Provide a simple ARCH_HAS_DEBUG_VIRTUAL implementation
 
 - Fix kprobe branch handling: if an out-of-line single stepped relative
   branch instruction has a target address within a certain address area in
   the entry code, the program check handler may incorrectly execute cleanup
   code as if KVM code was executed, leading to crashes
 
 - Fix reference counting of zcrypt card objects
 
 - Various other small fixes and cleanups
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Merge tag 's390-6.9-2' of git://git.kernel.org/pub/scm/linux/kernel/git/s390/linux

Pull more s390 updates from Heiko Carstens:

 - Various virtual vs physical address usage fixes

 - Add new bitwise types and helper functions and use them in s390
   specific drivers and code to make it easier to find virtual vs
   physical address usage bugs.

   Right now virtual and physical addresses are identical for s390,
   except for module, vmalloc, and similar areas. This will be changed,
   hopefully with the next merge window, so that e.g. the kernel image
   and modules will be located close to each other, allowing for direct
   branches and also for some other simplifications.

   As a prerequisite this requires to fix all misuses of virtual and
   physical addresses. As it turned out people are so used to the
   concept that virtual and physical addresses are the same, that new
   bugs got added to code which was already fixed. In order to avoid
   that even more code gets merged which adds such bugs add and use new
   bitwise types, so that sparse can be used to find such usage bugs.

   Most likely the new types can go away again after some time

 - Provide a simple ARCH_HAS_DEBUG_VIRTUAL implementation

 - Fix kprobe branch handling: if an out-of-line single stepped relative
   branch instruction has a target address within a certain address area
   in the entry code, the program check handler may incorrectly execute
   cleanup code as if KVM code was executed, leading to crashes

 - Fix reference counting of zcrypt card objects

 - Various other small fixes and cleanups

* tag 's390-6.9-2' of git://git.kernel.org/pub/scm/linux/kernel/git/s390/linux: (41 commits)
  s390/entry: compare gmap asce to determine guest/host fault
  s390/entry: remove OUTSIDE macro
  s390/entry: add CIF_SIE flag and remove sie64a() address check
  s390/cio: use while (i--) pattern to clean up
  s390/raw3270: make class3270 constant
  s390/raw3270: improve raw3270_init() readability
  s390/tape: make tape_class constant
  s390/vmlogrdr: make vmlogrdr_class constant
  s390/vmur: make vmur_class constant
  s390/zcrypt: make zcrypt_class constant
  s390/mm: provide simple ARCH_HAS_DEBUG_VIRTUAL support
  s390/vfio_ccw_cp: use new address translation helpers
  s390/iucv: use new address translation helpers
  s390/ctcm: use new address translation helpers
  s390/lcs: use new address translation helpers
  s390/qeth: use new address translation helpers
  s390/zfcp: use new address translation helpers
  s390/tape: fix virtual vs physical address confusion
  s390/3270: use new address translation helpers
  s390/3215: use new address translation helpers
  ...
2024-03-19 11:38:27 -07:00

1908 lines
48 KiB
C
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// SPDX-License-Identifier: GPL-2.0-or-later
/*
* IUCV base infrastructure.
*
* Copyright IBM Corp. 2001, 2009
*
* Author(s):
* Original source:
* Alan Altmark (Alan_Altmark@us.ibm.com) Sept. 2000
* Xenia Tkatschow (xenia@us.ibm.com)
* 2Gb awareness and general cleanup:
* Fritz Elfert (elfert@de.ibm.com, felfert@millenux.com)
* Rewritten for af_iucv:
* Martin Schwidefsky <schwidefsky@de.ibm.com>
* PM functions:
* Ursula Braun (ursula.braun@de.ibm.com)
*
* Documentation used:
* The original source
* CP Programming Service, IBM document # SC24-5760
*/
#define KMSG_COMPONENT "iucv"
#define pr_fmt(fmt) KMSG_COMPONENT ": " fmt
#include <linux/kernel_stat.h>
#include <linux/module.h>
#include <linux/moduleparam.h>
#include <linux/spinlock.h>
#include <linux/kernel.h>
#include <linux/slab.h>
#include <linux/init.h>
#include <linux/interrupt.h>
#include <linux/list.h>
#include <linux/errno.h>
#include <linux/err.h>
#include <linux/device.h>
#include <linux/cpu.h>
#include <linux/reboot.h>
#include <net/iucv/iucv.h>
#include <linux/atomic.h>
#include <asm/ebcdic.h>
#include <asm/io.h>
#include <asm/irq.h>
#include <asm/smp.h>
/*
* FLAGS:
* All flags are defined in the field IPFLAGS1 of each function
* and can be found in CP Programming Services.
* IPSRCCLS - Indicates you have specified a source class.
* IPTRGCLS - Indicates you have specified a target class.
* IPFGPID - Indicates you have specified a pathid.
* IPFGMID - Indicates you have specified a message ID.
* IPNORPY - Indicates a one-way message. No reply expected.
* IPALL - Indicates that all paths are affected.
*/
#define IUCV_IPSRCCLS 0x01
#define IUCV_IPTRGCLS 0x01
#define IUCV_IPFGPID 0x02
#define IUCV_IPFGMID 0x04
#define IUCV_IPNORPY 0x10
#define IUCV_IPALL 0x80
static int iucv_bus_match(struct device *dev, struct device_driver *drv)
{
return 0;
}
const struct bus_type iucv_bus = {
.name = "iucv",
.match = iucv_bus_match,
};
EXPORT_SYMBOL(iucv_bus);
struct device *iucv_root;
EXPORT_SYMBOL(iucv_root);
static int iucv_available;
/* General IUCV interrupt structure */
struct iucv_irq_data {
u16 ippathid;
u8 ipflags1;
u8 iptype;
u32 res2[9];
};
struct iucv_irq_list {
struct list_head list;
struct iucv_irq_data data;
};
static struct iucv_irq_data *iucv_irq_data[NR_CPUS];
static cpumask_t iucv_buffer_cpumask = { CPU_BITS_NONE };
static cpumask_t iucv_irq_cpumask = { CPU_BITS_NONE };
/*
* Queue of interrupt buffers lock for delivery via the tasklet
* (fast but can't call smp_call_function).
*/
static LIST_HEAD(iucv_task_queue);
/*
* The tasklet for fast delivery of iucv interrupts.
*/
static void iucv_tasklet_fn(unsigned long);
static DECLARE_TASKLET_OLD(iucv_tasklet, iucv_tasklet_fn);
/*
* Queue of interrupt buffers for delivery via a work queue
* (slower but can call smp_call_function).
*/
static LIST_HEAD(iucv_work_queue);
/*
* The work element to deliver path pending interrupts.
*/
static void iucv_work_fn(struct work_struct *work);
static DECLARE_WORK(iucv_work, iucv_work_fn);
/*
* Spinlock protecting task and work queue.
*/
static DEFINE_SPINLOCK(iucv_queue_lock);
enum iucv_command_codes {
IUCV_QUERY = 0,
IUCV_RETRIEVE_BUFFER = 2,
IUCV_SEND = 4,
IUCV_RECEIVE = 5,
IUCV_REPLY = 6,
IUCV_REJECT = 8,
IUCV_PURGE = 9,
IUCV_ACCEPT = 10,
IUCV_CONNECT = 11,
IUCV_DECLARE_BUFFER = 12,
IUCV_QUIESCE = 13,
IUCV_RESUME = 14,
IUCV_SEVER = 15,
IUCV_SETMASK = 16,
IUCV_SETCONTROLMASK = 17,
};
/*
* Error messages that are used with the iucv_sever function. They get
* converted to EBCDIC.
*/
static char iucv_error_no_listener[16] = "NO LISTENER";
static char iucv_error_no_memory[16] = "NO MEMORY";
static char iucv_error_pathid[16] = "INVALID PATHID";
/*
* iucv_handler_list: List of registered handlers.
*/
static LIST_HEAD(iucv_handler_list);
/*
* iucv_path_table: array of pointers to iucv_path structures.
*/
static struct iucv_path **iucv_path_table;
static unsigned long iucv_max_pathid;
/*
* iucv_lock: spinlock protecting iucv_handler_list and iucv_pathid_table
*/
static DEFINE_SPINLOCK(iucv_table_lock);
/*
* iucv_active_cpu: contains the number of the cpu executing the tasklet
* or the work handler. Needed for iucv_path_sever called from tasklet.
*/
static int iucv_active_cpu = -1;
/*
* Mutex and wait queue for iucv_register/iucv_unregister.
*/
static DEFINE_MUTEX(iucv_register_mutex);
/*
* Counter for number of non-smp capable handlers.
*/
static int iucv_nonsmp_handler;
/*
* IUCV control data structure. Used by iucv_path_accept, iucv_path_connect,
* iucv_path_quiesce and iucv_path_sever.
*/
struct iucv_cmd_control {
u16 ippathid;
u8 ipflags1;
u8 iprcode;
u16 ipmsglim;
u16 res1;
u8 ipvmid[8];
u8 ipuser[16];
u8 iptarget[8];
} __attribute__ ((packed,aligned(8)));
/*
* Data in parameter list iucv structure. Used by iucv_message_send,
* iucv_message_send2way and iucv_message_reply.
*/
struct iucv_cmd_dpl {
u16 ippathid;
u8 ipflags1;
u8 iprcode;
u32 ipmsgid;
u32 iptrgcls;
u8 iprmmsg[8];
u32 ipsrccls;
u32 ipmsgtag;
dma32_t ipbfadr2;
u32 ipbfln2f;
u32 res;
} __attribute__ ((packed,aligned(8)));
/*
* Data in buffer iucv structure. Used by iucv_message_receive,
* iucv_message_reject, iucv_message_send, iucv_message_send2way
* and iucv_declare_cpu.
*/
struct iucv_cmd_db {
u16 ippathid;
u8 ipflags1;
u8 iprcode;
u32 ipmsgid;
u32 iptrgcls;
dma32_t ipbfadr1;
u32 ipbfln1f;
u32 ipsrccls;
u32 ipmsgtag;
dma32_t ipbfadr2;
u32 ipbfln2f;
u32 res;
} __attribute__ ((packed,aligned(8)));
/*
* Purge message iucv structure. Used by iucv_message_purge.
*/
struct iucv_cmd_purge {
u16 ippathid;
u8 ipflags1;
u8 iprcode;
u32 ipmsgid;
u8 ipaudit[3];
u8 res1[5];
u32 res2;
u32 ipsrccls;
u32 ipmsgtag;
u32 res3[3];
} __attribute__ ((packed,aligned(8)));
/*
* Set mask iucv structure. Used by iucv_enable_cpu.
*/
struct iucv_cmd_set_mask {
u8 ipmask;
u8 res1[2];
u8 iprcode;
u32 res2[9];
} __attribute__ ((packed,aligned(8)));
union iucv_param {
struct iucv_cmd_control ctrl;
struct iucv_cmd_dpl dpl;
struct iucv_cmd_db db;
struct iucv_cmd_purge purge;
struct iucv_cmd_set_mask set_mask;
};
/*
* Anchor for per-cpu IUCV command parameter block.
*/
static union iucv_param *iucv_param[NR_CPUS];
static union iucv_param *iucv_param_irq[NR_CPUS];
/**
* __iucv_call_b2f0
* @command: identifier of IUCV call to CP.
* @parm: pointer to a struct iucv_parm block
*
* Calls CP to execute IUCV commands.
*
* Returns the result of the CP IUCV call.
*/
static inline int __iucv_call_b2f0(int command, union iucv_param *parm)
{
unsigned long reg1 = virt_to_phys(parm);
int cc;
asm volatile(
" lgr 0,%[reg0]\n"
" lgr 1,%[reg1]\n"
" .long 0xb2f01000\n"
" ipm %[cc]\n"
" srl %[cc],28\n"
: [cc] "=&d" (cc), "+m" (*parm)
: [reg0] "d" ((unsigned long)command),
[reg1] "d" (reg1)
: "cc", "0", "1");
return cc;
}
static inline int iucv_call_b2f0(int command, union iucv_param *parm)
{
int ccode;
ccode = __iucv_call_b2f0(command, parm);
return ccode == 1 ? parm->ctrl.iprcode : ccode;
}
/*
* iucv_query_maxconn
*
* Determines the maximum number of connections that may be established.
*
* Returns the maximum number of connections or -EPERM is IUCV is not
* available.
*/
static int __iucv_query_maxconn(void *param, unsigned long *max_pathid)
{
unsigned long reg1 = virt_to_phys(param);
int cc;
asm volatile (
" lghi 0,%[cmd]\n"
" lgr 1,%[reg1]\n"
" .long 0xb2f01000\n"
" ipm %[cc]\n"
" srl %[cc],28\n"
" lgr %[reg1],1\n"
: [cc] "=&d" (cc), [reg1] "+&d" (reg1)
: [cmd] "K" (IUCV_QUERY)
: "cc", "0", "1");
*max_pathid = reg1;
return cc;
}
static int iucv_query_maxconn(void)
{
unsigned long max_pathid;
void *param;
int ccode;
param = kzalloc(sizeof(union iucv_param), GFP_KERNEL | GFP_DMA);
if (!param)
return -ENOMEM;
ccode = __iucv_query_maxconn(param, &max_pathid);
if (ccode == 0)
iucv_max_pathid = max_pathid;
kfree(param);
return ccode ? -EPERM : 0;
}
/**
* iucv_allow_cpu
* @data: unused
*
* Allow iucv interrupts on this cpu.
*/
static void iucv_allow_cpu(void *data)
{
int cpu = smp_processor_id();
union iucv_param *parm;
/*
* Enable all iucv interrupts.
* ipmask contains bits for the different interrupts
* 0x80 - Flag to allow nonpriority message pending interrupts
* 0x40 - Flag to allow priority message pending interrupts
* 0x20 - Flag to allow nonpriority message completion interrupts
* 0x10 - Flag to allow priority message completion interrupts
* 0x08 - Flag to allow IUCV control interrupts
*/
parm = iucv_param_irq[cpu];
memset(parm, 0, sizeof(union iucv_param));
parm->set_mask.ipmask = 0xf8;
iucv_call_b2f0(IUCV_SETMASK, parm);
/*
* Enable all iucv control interrupts.
* ipmask contains bits for the different interrupts
* 0x80 - Flag to allow pending connections interrupts
* 0x40 - Flag to allow connection complete interrupts
* 0x20 - Flag to allow connection severed interrupts
* 0x10 - Flag to allow connection quiesced interrupts
* 0x08 - Flag to allow connection resumed interrupts
*/
memset(parm, 0, sizeof(union iucv_param));
parm->set_mask.ipmask = 0xf8;
iucv_call_b2f0(IUCV_SETCONTROLMASK, parm);
/* Set indication that iucv interrupts are allowed for this cpu. */
cpumask_set_cpu(cpu, &iucv_irq_cpumask);
}
/**
* iucv_block_cpu
* @data: unused
*
* Block iucv interrupts on this cpu.
*/
static void iucv_block_cpu(void *data)
{
int cpu = smp_processor_id();
union iucv_param *parm;
/* Disable all iucv interrupts. */
parm = iucv_param_irq[cpu];
memset(parm, 0, sizeof(union iucv_param));
iucv_call_b2f0(IUCV_SETMASK, parm);
/* Clear indication that iucv interrupts are allowed for this cpu. */
cpumask_clear_cpu(cpu, &iucv_irq_cpumask);
}
/**
* iucv_declare_cpu
* @data: unused
*
* Declare a interrupt buffer on this cpu.
*/
static void iucv_declare_cpu(void *data)
{
int cpu = smp_processor_id();
union iucv_param *parm;
int rc;
if (cpumask_test_cpu(cpu, &iucv_buffer_cpumask))
return;
/* Declare interrupt buffer. */
parm = iucv_param_irq[cpu];
memset(parm, 0, sizeof(union iucv_param));
parm->db.ipbfadr1 = virt_to_dma32(iucv_irq_data[cpu]);
rc = iucv_call_b2f0(IUCV_DECLARE_BUFFER, parm);
if (rc) {
char *err = "Unknown";
switch (rc) {
case 0x03:
err = "Directory error";
break;
case 0x0a:
err = "Invalid length";
break;
case 0x13:
err = "Buffer already exists";
break;
case 0x3e:
err = "Buffer overlap";
break;
case 0x5c:
err = "Paging or storage error";
break;
}
pr_warn("Defining an interrupt buffer on CPU %i failed with 0x%02x (%s)\n",
cpu, rc, err);
return;
}
/* Set indication that an iucv buffer exists for this cpu. */
cpumask_set_cpu(cpu, &iucv_buffer_cpumask);
if (iucv_nonsmp_handler == 0 || cpumask_empty(&iucv_irq_cpumask))
/* Enable iucv interrupts on this cpu. */
iucv_allow_cpu(NULL);
else
/* Disable iucv interrupts on this cpu. */
iucv_block_cpu(NULL);
}
/**
* iucv_retrieve_cpu
* @data: unused
*
* Retrieve interrupt buffer on this cpu.
*/
static void iucv_retrieve_cpu(void *data)
{
int cpu = smp_processor_id();
union iucv_param *parm;
if (!cpumask_test_cpu(cpu, &iucv_buffer_cpumask))
return;
/* Block iucv interrupts. */
iucv_block_cpu(NULL);
/* Retrieve interrupt buffer. */
parm = iucv_param_irq[cpu];
iucv_call_b2f0(IUCV_RETRIEVE_BUFFER, parm);
/* Clear indication that an iucv buffer exists for this cpu. */
cpumask_clear_cpu(cpu, &iucv_buffer_cpumask);
}
/*
* iucv_setmask_mp
*
* Allow iucv interrupts on all cpus.
*/
static void iucv_setmask_mp(void)
{
int cpu;
cpus_read_lock();
for_each_online_cpu(cpu)
/* Enable all cpus with a declared buffer. */
if (cpumask_test_cpu(cpu, &iucv_buffer_cpumask) &&
!cpumask_test_cpu(cpu, &iucv_irq_cpumask))
smp_call_function_single(cpu, iucv_allow_cpu,
NULL, 1);
cpus_read_unlock();
}
/*
* iucv_setmask_up
*
* Allow iucv interrupts on a single cpu.
*/
static void iucv_setmask_up(void)
{
cpumask_t cpumask;
int cpu;
/* Disable all cpu but the first in cpu_irq_cpumask. */
cpumask_copy(&cpumask, &iucv_irq_cpumask);
cpumask_clear_cpu(cpumask_first(&iucv_irq_cpumask), &cpumask);
for_each_cpu(cpu, &cpumask)
smp_call_function_single(cpu, iucv_block_cpu, NULL, 1);
}
/*
* iucv_enable
*
* This function makes iucv ready for use. It allocates the pathid
* table, declares an iucv interrupt buffer and enables the iucv
* interrupts. Called when the first user has registered an iucv
* handler.
*/
static int iucv_enable(void)
{
size_t alloc_size;
int cpu, rc;
cpus_read_lock();
rc = -ENOMEM;
alloc_size = iucv_max_pathid * sizeof(*iucv_path_table);
iucv_path_table = kzalloc(alloc_size, GFP_KERNEL);
if (!iucv_path_table)
goto out;
/* Declare per cpu buffers. */
rc = -EIO;
for_each_online_cpu(cpu)
smp_call_function_single(cpu, iucv_declare_cpu, NULL, 1);
if (cpumask_empty(&iucv_buffer_cpumask))
/* No cpu could declare an iucv buffer. */
goto out;
cpus_read_unlock();
return 0;
out:
kfree(iucv_path_table);
iucv_path_table = NULL;
cpus_read_unlock();
return rc;
}
/*
* iucv_disable
*
* This function shuts down iucv. It disables iucv interrupts, retrieves
* the iucv interrupt buffer and frees the pathid table. Called after the
* last user unregister its iucv handler.
*/
static void iucv_disable(void)
{
cpus_read_lock();
on_each_cpu(iucv_retrieve_cpu, NULL, 1);
kfree(iucv_path_table);
iucv_path_table = NULL;
cpus_read_unlock();
}
static int iucv_cpu_dead(unsigned int cpu)
{
kfree(iucv_param_irq[cpu]);
iucv_param_irq[cpu] = NULL;
kfree(iucv_param[cpu]);
iucv_param[cpu] = NULL;
kfree(iucv_irq_data[cpu]);
iucv_irq_data[cpu] = NULL;
return 0;
}
static int iucv_cpu_prepare(unsigned int cpu)
{
/* Note: GFP_DMA used to get memory below 2G */
iucv_irq_data[cpu] = kmalloc_node(sizeof(struct iucv_irq_data),
GFP_KERNEL|GFP_DMA, cpu_to_node(cpu));
if (!iucv_irq_data[cpu])
goto out_free;
/* Allocate parameter blocks. */
iucv_param[cpu] = kmalloc_node(sizeof(union iucv_param),
GFP_KERNEL|GFP_DMA, cpu_to_node(cpu));
if (!iucv_param[cpu])
goto out_free;
iucv_param_irq[cpu] = kmalloc_node(sizeof(union iucv_param),
GFP_KERNEL|GFP_DMA, cpu_to_node(cpu));
if (!iucv_param_irq[cpu])
goto out_free;
return 0;
out_free:
iucv_cpu_dead(cpu);
return -ENOMEM;
}
static int iucv_cpu_online(unsigned int cpu)
{
if (!iucv_path_table)
return 0;
iucv_declare_cpu(NULL);
return 0;
}
static int iucv_cpu_down_prep(unsigned int cpu)
{
cpumask_t cpumask;
if (!iucv_path_table)
return 0;
cpumask_copy(&cpumask, &iucv_buffer_cpumask);
cpumask_clear_cpu(cpu, &cpumask);
if (cpumask_empty(&cpumask))
/* Can't offline last IUCV enabled cpu. */
return -EINVAL;
iucv_retrieve_cpu(NULL);
if (!cpumask_empty(&iucv_irq_cpumask))
return 0;
smp_call_function_single(cpumask_first(&iucv_buffer_cpumask),
iucv_allow_cpu, NULL, 1);
return 0;
}
/**
* iucv_sever_pathid
* @pathid: path identification number.
* @userdata: 16-bytes of user data.
*
* Sever an iucv path to free up the pathid. Used internally.
*/
static int iucv_sever_pathid(u16 pathid, u8 *userdata)
{
union iucv_param *parm;
parm = iucv_param_irq[smp_processor_id()];
memset(parm, 0, sizeof(union iucv_param));
if (userdata)
memcpy(parm->ctrl.ipuser, userdata, sizeof(parm->ctrl.ipuser));
parm->ctrl.ippathid = pathid;
return iucv_call_b2f0(IUCV_SEVER, parm);
}
/**
* __iucv_cleanup_queue
* @dummy: unused dummy argument
*
* Nop function called via smp_call_function to force work items from
* pending external iucv interrupts to the work queue.
*/
static void __iucv_cleanup_queue(void *dummy)
{
}
/**
* iucv_cleanup_queue
*
* Function called after a path has been severed to find all remaining
* work items for the now stale pathid. The caller needs to hold the
* iucv_table_lock.
*/
static void iucv_cleanup_queue(void)
{
struct iucv_irq_list *p, *n;
/*
* When a path is severed, the pathid can be reused immediately
* on a iucv connect or a connection pending interrupt. Remove
* all entries from the task queue that refer to a stale pathid
* (iucv_path_table[ix] == NULL). Only then do the iucv connect
* or deliver the connection pending interrupt. To get all the
* pending interrupts force them to the work queue by calling
* an empty function on all cpus.
*/
smp_call_function(__iucv_cleanup_queue, NULL, 1);
spin_lock_irq(&iucv_queue_lock);
list_for_each_entry_safe(p, n, &iucv_task_queue, list) {
/* Remove stale work items from the task queue. */
if (iucv_path_table[p->data.ippathid] == NULL) {
list_del(&p->list);
kfree(p);
}
}
spin_unlock_irq(&iucv_queue_lock);
}
/**
* iucv_register:
* @handler: address of iucv handler structure
* @smp: != 0 indicates that the handler can deal with out of order messages
*
* Registers a driver with IUCV.
*
* Returns 0 on success, -ENOMEM if the memory allocation for the pathid
* table failed, or -EIO if IUCV_DECLARE_BUFFER failed on all cpus.
*/
int iucv_register(struct iucv_handler *handler, int smp)
{
int rc;
if (!iucv_available)
return -ENOSYS;
mutex_lock(&iucv_register_mutex);
if (!smp)
iucv_nonsmp_handler++;
if (list_empty(&iucv_handler_list)) {
rc = iucv_enable();
if (rc)
goto out_mutex;
} else if (!smp && iucv_nonsmp_handler == 1)
iucv_setmask_up();
INIT_LIST_HEAD(&handler->paths);
spin_lock_bh(&iucv_table_lock);
list_add_tail(&handler->list, &iucv_handler_list);
spin_unlock_bh(&iucv_table_lock);
rc = 0;
out_mutex:
mutex_unlock(&iucv_register_mutex);
return rc;
}
EXPORT_SYMBOL(iucv_register);
/**
* iucv_unregister
* @handler: address of iucv handler structure
* @smp: != 0 indicates that the handler can deal with out of order messages
*
* Unregister driver from IUCV.
*/
void iucv_unregister(struct iucv_handler *handler, int smp)
{
struct iucv_path *p, *n;
mutex_lock(&iucv_register_mutex);
spin_lock_bh(&iucv_table_lock);
/* Remove handler from the iucv_handler_list. */
list_del_init(&handler->list);
/* Sever all pathids still referring to the handler. */
list_for_each_entry_safe(p, n, &handler->paths, list) {
iucv_sever_pathid(p->pathid, NULL);
iucv_path_table[p->pathid] = NULL;
list_del(&p->list);
iucv_path_free(p);
}
spin_unlock_bh(&iucv_table_lock);
if (!smp)
iucv_nonsmp_handler--;
if (list_empty(&iucv_handler_list))
iucv_disable();
else if (!smp && iucv_nonsmp_handler == 0)
iucv_setmask_mp();
mutex_unlock(&iucv_register_mutex);
}
EXPORT_SYMBOL(iucv_unregister);
static int iucv_reboot_event(struct notifier_block *this,
unsigned long event, void *ptr)
{
int i;
if (cpumask_empty(&iucv_irq_cpumask))
return NOTIFY_DONE;
cpus_read_lock();
on_each_cpu_mask(&iucv_irq_cpumask, iucv_block_cpu, NULL, 1);
preempt_disable();
for (i = 0; i < iucv_max_pathid; i++) {
if (iucv_path_table[i])
iucv_sever_pathid(i, NULL);
}
preempt_enable();
cpus_read_unlock();
iucv_disable();
return NOTIFY_DONE;
}
static struct notifier_block iucv_reboot_notifier = {
.notifier_call = iucv_reboot_event,
};
/**
* iucv_path_accept
* @path: address of iucv path structure
* @handler: address of iucv handler structure
* @userdata: 16 bytes of data reflected to the communication partner
* @private: private data passed to interrupt handlers for this path
*
* This function is issued after the user received a connection pending
* external interrupt and now wishes to complete the IUCV communication path.
*
* Returns the result of the CP IUCV call.
*/
int iucv_path_accept(struct iucv_path *path, struct iucv_handler *handler,
u8 *userdata, void *private)
{
union iucv_param *parm;
int rc;
local_bh_disable();
if (cpumask_empty(&iucv_buffer_cpumask)) {
rc = -EIO;
goto out;
}
/* Prepare parameter block. */
parm = iucv_param[smp_processor_id()];
memset(parm, 0, sizeof(union iucv_param));
parm->ctrl.ippathid = path->pathid;
parm->ctrl.ipmsglim = path->msglim;
if (userdata)
memcpy(parm->ctrl.ipuser, userdata, sizeof(parm->ctrl.ipuser));
parm->ctrl.ipflags1 = path->flags;
rc = iucv_call_b2f0(IUCV_ACCEPT, parm);
if (!rc) {
path->private = private;
path->msglim = parm->ctrl.ipmsglim;
path->flags = parm->ctrl.ipflags1;
}
out:
local_bh_enable();
return rc;
}
EXPORT_SYMBOL(iucv_path_accept);
/**
* iucv_path_connect
* @path: address of iucv path structure
* @handler: address of iucv handler structure
* @userid: 8-byte user identification
* @system: 8-byte target system identification
* @userdata: 16 bytes of data reflected to the communication partner
* @private: private data passed to interrupt handlers for this path
*
* This function establishes an IUCV path. Although the connect may complete
* successfully, you are not able to use the path until you receive an IUCV
* Connection Complete external interrupt.
*
* Returns the result of the CP IUCV call.
*/
int iucv_path_connect(struct iucv_path *path, struct iucv_handler *handler,
u8 *userid, u8 *system, u8 *userdata,
void *private)
{
union iucv_param *parm;
int rc;
spin_lock_bh(&iucv_table_lock);
iucv_cleanup_queue();
if (cpumask_empty(&iucv_buffer_cpumask)) {
rc = -EIO;
goto out;
}
parm = iucv_param[smp_processor_id()];
memset(parm, 0, sizeof(union iucv_param));
parm->ctrl.ipmsglim = path->msglim;
parm->ctrl.ipflags1 = path->flags;
if (userid) {
memcpy(parm->ctrl.ipvmid, userid, sizeof(parm->ctrl.ipvmid));
ASCEBC(parm->ctrl.ipvmid, sizeof(parm->ctrl.ipvmid));
EBC_TOUPPER(parm->ctrl.ipvmid, sizeof(parm->ctrl.ipvmid));
}
if (system) {
memcpy(parm->ctrl.iptarget, system,
sizeof(parm->ctrl.iptarget));
ASCEBC(parm->ctrl.iptarget, sizeof(parm->ctrl.iptarget));
EBC_TOUPPER(parm->ctrl.iptarget, sizeof(parm->ctrl.iptarget));
}
if (userdata)
memcpy(parm->ctrl.ipuser, userdata, sizeof(parm->ctrl.ipuser));
rc = iucv_call_b2f0(IUCV_CONNECT, parm);
if (!rc) {
if (parm->ctrl.ippathid < iucv_max_pathid) {
path->pathid = parm->ctrl.ippathid;
path->msglim = parm->ctrl.ipmsglim;
path->flags = parm->ctrl.ipflags1;
path->handler = handler;
path->private = private;
list_add_tail(&path->list, &handler->paths);
iucv_path_table[path->pathid] = path;
} else {
iucv_sever_pathid(parm->ctrl.ippathid,
iucv_error_pathid);
rc = -EIO;
}
}
out:
spin_unlock_bh(&iucv_table_lock);
return rc;
}
EXPORT_SYMBOL(iucv_path_connect);
/**
* iucv_path_quiesce:
* @path: address of iucv path structure
* @userdata: 16 bytes of data reflected to the communication partner
*
* This function temporarily suspends incoming messages on an IUCV path.
* You can later reactivate the path by invoking the iucv_resume function.
*
* Returns the result from the CP IUCV call.
*/
int iucv_path_quiesce(struct iucv_path *path, u8 *userdata)
{
union iucv_param *parm;
int rc;
local_bh_disable();
if (cpumask_empty(&iucv_buffer_cpumask)) {
rc = -EIO;
goto out;
}
parm = iucv_param[smp_processor_id()];
memset(parm, 0, sizeof(union iucv_param));
if (userdata)
memcpy(parm->ctrl.ipuser, userdata, sizeof(parm->ctrl.ipuser));
parm->ctrl.ippathid = path->pathid;
rc = iucv_call_b2f0(IUCV_QUIESCE, parm);
out:
local_bh_enable();
return rc;
}
EXPORT_SYMBOL(iucv_path_quiesce);
/**
* iucv_path_resume:
* @path: address of iucv path structure
* @userdata: 16 bytes of data reflected to the communication partner
*
* This function resumes incoming messages on an IUCV path that has
* been stopped with iucv_path_quiesce.
*
* Returns the result from the CP IUCV call.
*/
int iucv_path_resume(struct iucv_path *path, u8 *userdata)
{
union iucv_param *parm;
int rc;
local_bh_disable();
if (cpumask_empty(&iucv_buffer_cpumask)) {
rc = -EIO;
goto out;
}
parm = iucv_param[smp_processor_id()];
memset(parm, 0, sizeof(union iucv_param));
if (userdata)
memcpy(parm->ctrl.ipuser, userdata, sizeof(parm->ctrl.ipuser));
parm->ctrl.ippathid = path->pathid;
rc = iucv_call_b2f0(IUCV_RESUME, parm);
out:
local_bh_enable();
return rc;
}
/**
* iucv_path_sever
* @path: address of iucv path structure
* @userdata: 16 bytes of data reflected to the communication partner
*
* This function terminates an IUCV path.
*
* Returns the result from the CP IUCV call.
*/
int iucv_path_sever(struct iucv_path *path, u8 *userdata)
{
int rc;
preempt_disable();
if (cpumask_empty(&iucv_buffer_cpumask)) {
rc = -EIO;
goto out;
}
if (iucv_active_cpu != smp_processor_id())
spin_lock_bh(&iucv_table_lock);
rc = iucv_sever_pathid(path->pathid, userdata);
iucv_path_table[path->pathid] = NULL;
list_del_init(&path->list);
if (iucv_active_cpu != smp_processor_id())
spin_unlock_bh(&iucv_table_lock);
out:
preempt_enable();
return rc;
}
EXPORT_SYMBOL(iucv_path_sever);
/**
* iucv_message_purge
* @path: address of iucv path structure
* @msg: address of iucv msg structure
* @srccls: source class of message
*
* Cancels a message you have sent.
*
* Returns the result from the CP IUCV call.
*/
int iucv_message_purge(struct iucv_path *path, struct iucv_message *msg,
u32 srccls)
{
union iucv_param *parm;
int rc;
local_bh_disable();
if (cpumask_empty(&iucv_buffer_cpumask)) {
rc = -EIO;
goto out;
}
parm = iucv_param[smp_processor_id()];
memset(parm, 0, sizeof(union iucv_param));
parm->purge.ippathid = path->pathid;
parm->purge.ipmsgid = msg->id;
parm->purge.ipsrccls = srccls;
parm->purge.ipflags1 = IUCV_IPSRCCLS | IUCV_IPFGMID | IUCV_IPFGPID;
rc = iucv_call_b2f0(IUCV_PURGE, parm);
if (!rc) {
msg->audit = (*(u32 *) &parm->purge.ipaudit) >> 8;
msg->tag = parm->purge.ipmsgtag;
}
out:
local_bh_enable();
return rc;
}
EXPORT_SYMBOL(iucv_message_purge);
/**
* iucv_message_receive_iprmdata
* @path: address of iucv path structure
* @msg: address of iucv msg structure
* @flags: how the message is received (IUCV_IPBUFLST)
* @buffer: address of data buffer or address of struct iucv_array
* @size: length of data buffer
* @residual:
*
* Internal function used by iucv_message_receive and __iucv_message_receive
* to receive RMDATA data stored in struct iucv_message.
*/
static int iucv_message_receive_iprmdata(struct iucv_path *path,
struct iucv_message *msg,
u8 flags, void *buffer,
size_t size, size_t *residual)
{
struct iucv_array *array;
u8 *rmmsg;
size_t copy;
/*
* Message is 8 bytes long and has been stored to the
* message descriptor itself.
*/
if (residual)
*residual = abs(size - 8);
rmmsg = msg->rmmsg;
if (flags & IUCV_IPBUFLST) {
/* Copy to struct iucv_array. */
size = (size < 8) ? size : 8;
for (array = buffer; size > 0; array++) {
copy = min_t(size_t, size, array->length);
memcpy(dma32_to_virt(array->address), rmmsg, copy);
rmmsg += copy;
size -= copy;
}
} else {
/* Copy to direct buffer. */
memcpy(buffer, rmmsg, min_t(size_t, size, 8));
}
return 0;
}
/**
* __iucv_message_receive
* @path: address of iucv path structure
* @msg: address of iucv msg structure
* @flags: how the message is received (IUCV_IPBUFLST)
* @buffer: address of data buffer or address of struct iucv_array
* @size: length of data buffer
* @residual:
*
* This function receives messages that are being sent to you over
* established paths. This function will deal with RMDATA messages
* embedded in struct iucv_message as well.
*
* Locking: no locking
*
* Returns the result from the CP IUCV call.
*/
int __iucv_message_receive(struct iucv_path *path, struct iucv_message *msg,
u8 flags, void *buffer, size_t size, size_t *residual)
{
union iucv_param *parm;
int rc;
if (msg->flags & IUCV_IPRMDATA)
return iucv_message_receive_iprmdata(path, msg, flags,
buffer, size, residual);
if (cpumask_empty(&iucv_buffer_cpumask))
return -EIO;
parm = iucv_param[smp_processor_id()];
memset(parm, 0, sizeof(union iucv_param));
parm->db.ipbfadr1 = virt_to_dma32(buffer);
parm->db.ipbfln1f = (u32) size;
parm->db.ipmsgid = msg->id;
parm->db.ippathid = path->pathid;
parm->db.iptrgcls = msg->class;
parm->db.ipflags1 = (flags | IUCV_IPFGPID |
IUCV_IPFGMID | IUCV_IPTRGCLS);
rc = iucv_call_b2f0(IUCV_RECEIVE, parm);
if (!rc || rc == 5) {
msg->flags = parm->db.ipflags1;
if (residual)
*residual = parm->db.ipbfln1f;
}
return rc;
}
EXPORT_SYMBOL(__iucv_message_receive);
/**
* iucv_message_receive
* @path: address of iucv path structure
* @msg: address of iucv msg structure
* @flags: how the message is received (IUCV_IPBUFLST)
* @buffer: address of data buffer or address of struct iucv_array
* @size: length of data buffer
* @residual:
*
* This function receives messages that are being sent to you over
* established paths. This function will deal with RMDATA messages
* embedded in struct iucv_message as well.
*
* Locking: local_bh_enable/local_bh_disable
*
* Returns the result from the CP IUCV call.
*/
int iucv_message_receive(struct iucv_path *path, struct iucv_message *msg,
u8 flags, void *buffer, size_t size, size_t *residual)
{
int rc;
if (msg->flags & IUCV_IPRMDATA)
return iucv_message_receive_iprmdata(path, msg, flags,
buffer, size, residual);
local_bh_disable();
rc = __iucv_message_receive(path, msg, flags, buffer, size, residual);
local_bh_enable();
return rc;
}
EXPORT_SYMBOL(iucv_message_receive);
/**
* iucv_message_reject
* @path: address of iucv path structure
* @msg: address of iucv msg structure
*
* The reject function refuses a specified message. Between the time you
* are notified of a message and the time that you complete the message,
* the message may be rejected.
*
* Returns the result from the CP IUCV call.
*/
int iucv_message_reject(struct iucv_path *path, struct iucv_message *msg)
{
union iucv_param *parm;
int rc;
local_bh_disable();
if (cpumask_empty(&iucv_buffer_cpumask)) {
rc = -EIO;
goto out;
}
parm = iucv_param[smp_processor_id()];
memset(parm, 0, sizeof(union iucv_param));
parm->db.ippathid = path->pathid;
parm->db.ipmsgid = msg->id;
parm->db.iptrgcls = msg->class;
parm->db.ipflags1 = (IUCV_IPTRGCLS | IUCV_IPFGMID | IUCV_IPFGPID);
rc = iucv_call_b2f0(IUCV_REJECT, parm);
out:
local_bh_enable();
return rc;
}
EXPORT_SYMBOL(iucv_message_reject);
/**
* iucv_message_reply
* @path: address of iucv path structure
* @msg: address of iucv msg structure
* @flags: how the reply is sent (IUCV_IPRMDATA, IUCV_IPPRTY, IUCV_IPBUFLST)
* @reply: address of reply data buffer or address of struct iucv_array
* @size: length of reply data buffer
*
* This function responds to the two-way messages that you receive. You
* must identify completely the message to which you wish to reply. ie,
* pathid, msgid, and trgcls. Prmmsg signifies the data is moved into
* the parameter list.
*
* Returns the result from the CP IUCV call.
*/
int iucv_message_reply(struct iucv_path *path, struct iucv_message *msg,
u8 flags, void *reply, size_t size)
{
union iucv_param *parm;
int rc;
local_bh_disable();
if (cpumask_empty(&iucv_buffer_cpumask)) {
rc = -EIO;
goto out;
}
parm = iucv_param[smp_processor_id()];
memset(parm, 0, sizeof(union iucv_param));
if (flags & IUCV_IPRMDATA) {
parm->dpl.ippathid = path->pathid;
parm->dpl.ipflags1 = flags;
parm->dpl.ipmsgid = msg->id;
parm->dpl.iptrgcls = msg->class;
memcpy(parm->dpl.iprmmsg, reply, min_t(size_t, size, 8));
} else {
parm->db.ipbfadr1 = virt_to_dma32(reply);
parm->db.ipbfln1f = (u32) size;
parm->db.ippathid = path->pathid;
parm->db.ipflags1 = flags;
parm->db.ipmsgid = msg->id;
parm->db.iptrgcls = msg->class;
}
rc = iucv_call_b2f0(IUCV_REPLY, parm);
out:
local_bh_enable();
return rc;
}
EXPORT_SYMBOL(iucv_message_reply);
/**
* __iucv_message_send
* @path: address of iucv path structure
* @msg: address of iucv msg structure
* @flags: how the message is sent (IUCV_IPRMDATA, IUCV_IPPRTY, IUCV_IPBUFLST)
* @srccls: source class of message
* @buffer: address of send buffer or address of struct iucv_array
* @size: length of send buffer
*
* This function transmits data to another application. Data to be
* transmitted is in a buffer and this is a one-way message and the
* receiver will not reply to the message.
*
* Locking: no locking
*
* Returns the result from the CP IUCV call.
*/
int __iucv_message_send(struct iucv_path *path, struct iucv_message *msg,
u8 flags, u32 srccls, void *buffer, size_t size)
{
union iucv_param *parm;
int rc;
if (cpumask_empty(&iucv_buffer_cpumask)) {
rc = -EIO;
goto out;
}
parm = iucv_param[smp_processor_id()];
memset(parm, 0, sizeof(union iucv_param));
if (flags & IUCV_IPRMDATA) {
/* Message of 8 bytes can be placed into the parameter list. */
parm->dpl.ippathid = path->pathid;
parm->dpl.ipflags1 = flags | IUCV_IPNORPY;
parm->dpl.iptrgcls = msg->class;
parm->dpl.ipsrccls = srccls;
parm->dpl.ipmsgtag = msg->tag;
memcpy(parm->dpl.iprmmsg, buffer, 8);
} else {
parm->db.ipbfadr1 = virt_to_dma32(buffer);
parm->db.ipbfln1f = (u32) size;
parm->db.ippathid = path->pathid;
parm->db.ipflags1 = flags | IUCV_IPNORPY;
parm->db.iptrgcls = msg->class;
parm->db.ipsrccls = srccls;
parm->db.ipmsgtag = msg->tag;
}
rc = iucv_call_b2f0(IUCV_SEND, parm);
if (!rc)
msg->id = parm->db.ipmsgid;
out:
return rc;
}
EXPORT_SYMBOL(__iucv_message_send);
/**
* iucv_message_send
* @path: address of iucv path structure
* @msg: address of iucv msg structure
* @flags: how the message is sent (IUCV_IPRMDATA, IUCV_IPPRTY, IUCV_IPBUFLST)
* @srccls: source class of message
* @buffer: address of send buffer or address of struct iucv_array
* @size: length of send buffer
*
* This function transmits data to another application. Data to be
* transmitted is in a buffer and this is a one-way message and the
* receiver will not reply to the message.
*
* Locking: local_bh_enable/local_bh_disable
*
* Returns the result from the CP IUCV call.
*/
int iucv_message_send(struct iucv_path *path, struct iucv_message *msg,
u8 flags, u32 srccls, void *buffer, size_t size)
{
int rc;
local_bh_disable();
rc = __iucv_message_send(path, msg, flags, srccls, buffer, size);
local_bh_enable();
return rc;
}
EXPORT_SYMBOL(iucv_message_send);
/**
* iucv_message_send2way
* @path: address of iucv path structure
* @msg: address of iucv msg structure
* @flags: how the message is sent and the reply is received
* (IUCV_IPRMDATA, IUCV_IPBUFLST, IUCV_IPPRTY, IUCV_ANSLST)
* @srccls: source class of message
* @buffer: address of send buffer or address of struct iucv_array
* @size: length of send buffer
* @answer: address of answer buffer or address of struct iucv_array
* @asize: size of reply buffer
* @residual: ignored
*
* This function transmits data to another application. Data to be
* transmitted is in a buffer. The receiver of the send is expected to
* reply to the message and a buffer is provided into which IUCV moves
* the reply to this message.
*
* Returns the result from the CP IUCV call.
*/
int iucv_message_send2way(struct iucv_path *path, struct iucv_message *msg,
u8 flags, u32 srccls, void *buffer, size_t size,
void *answer, size_t asize, size_t *residual)
{
union iucv_param *parm;
int rc;
local_bh_disable();
if (cpumask_empty(&iucv_buffer_cpumask)) {
rc = -EIO;
goto out;
}
parm = iucv_param[smp_processor_id()];
memset(parm, 0, sizeof(union iucv_param));
if (flags & IUCV_IPRMDATA) {
parm->dpl.ippathid = path->pathid;
parm->dpl.ipflags1 = path->flags; /* priority message */
parm->dpl.iptrgcls = msg->class;
parm->dpl.ipsrccls = srccls;
parm->dpl.ipmsgtag = msg->tag;
parm->dpl.ipbfadr2 = virt_to_dma32(answer);
parm->dpl.ipbfln2f = (u32) asize;
memcpy(parm->dpl.iprmmsg, buffer, 8);
} else {
parm->db.ippathid = path->pathid;
parm->db.ipflags1 = path->flags; /* priority message */
parm->db.iptrgcls = msg->class;
parm->db.ipsrccls = srccls;
parm->db.ipmsgtag = msg->tag;
parm->db.ipbfadr1 = virt_to_dma32(buffer);
parm->db.ipbfln1f = (u32) size;
parm->db.ipbfadr2 = virt_to_dma32(answer);
parm->db.ipbfln2f = (u32) asize;
}
rc = iucv_call_b2f0(IUCV_SEND, parm);
if (!rc)
msg->id = parm->db.ipmsgid;
out:
local_bh_enable();
return rc;
}
EXPORT_SYMBOL(iucv_message_send2way);
struct iucv_path_pending {
u16 ippathid;
u8 ipflags1;
u8 iptype;
u16 ipmsglim;
u16 res1;
u8 ipvmid[8];
u8 ipuser[16];
u32 res3;
u8 ippollfg;
u8 res4[3];
} __packed;
/**
* iucv_path_pending
* @data: Pointer to external interrupt buffer
*
* Process connection pending work item. Called from tasklet while holding
* iucv_table_lock.
*/
static void iucv_path_pending(struct iucv_irq_data *data)
{
struct iucv_path_pending *ipp = (void *) data;
struct iucv_handler *handler;
struct iucv_path *path;
char *error;
BUG_ON(iucv_path_table[ipp->ippathid]);
/* New pathid, handler found. Create a new path struct. */
error = iucv_error_no_memory;
path = iucv_path_alloc(ipp->ipmsglim, ipp->ipflags1, GFP_ATOMIC);
if (!path)
goto out_sever;
path->pathid = ipp->ippathid;
iucv_path_table[path->pathid] = path;
EBCASC(ipp->ipvmid, 8);
/* Call registered handler until one is found that wants the path. */
list_for_each_entry(handler, &iucv_handler_list, list) {
if (!handler->path_pending)
continue;
/*
* Add path to handler to allow a call to iucv_path_sever
* inside the path_pending function. If the handler returns
* an error remove the path from the handler again.
*/
list_add(&path->list, &handler->paths);
path->handler = handler;
if (!handler->path_pending(path, ipp->ipvmid, ipp->ipuser))
return;
list_del(&path->list);
path->handler = NULL;
}
/* No handler wanted the path. */
iucv_path_table[path->pathid] = NULL;
iucv_path_free(path);
error = iucv_error_no_listener;
out_sever:
iucv_sever_pathid(ipp->ippathid, error);
}
struct iucv_path_complete {
u16 ippathid;
u8 ipflags1;
u8 iptype;
u16 ipmsglim;
u16 res1;
u8 res2[8];
u8 ipuser[16];
u32 res3;
u8 ippollfg;
u8 res4[3];
} __packed;
/**
* iucv_path_complete
* @data: Pointer to external interrupt buffer
*
* Process connection complete work item. Called from tasklet while holding
* iucv_table_lock.
*/
static void iucv_path_complete(struct iucv_irq_data *data)
{
struct iucv_path_complete *ipc = (void *) data;
struct iucv_path *path = iucv_path_table[ipc->ippathid];
if (path)
path->flags = ipc->ipflags1;
if (path && path->handler && path->handler->path_complete)
path->handler->path_complete(path, ipc->ipuser);
}
struct iucv_path_severed {
u16 ippathid;
u8 res1;
u8 iptype;
u32 res2;
u8 res3[8];
u8 ipuser[16];
u32 res4;
u8 ippollfg;
u8 res5[3];
} __packed;
/**
* iucv_path_severed
* @data: Pointer to external interrupt buffer
*
* Process connection severed work item. Called from tasklet while holding
* iucv_table_lock.
*/
static void iucv_path_severed(struct iucv_irq_data *data)
{
struct iucv_path_severed *ips = (void *) data;
struct iucv_path *path = iucv_path_table[ips->ippathid];
if (!path || !path->handler) /* Already severed */
return;
if (path->handler->path_severed)
path->handler->path_severed(path, ips->ipuser);
else {
iucv_sever_pathid(path->pathid, NULL);
iucv_path_table[path->pathid] = NULL;
list_del(&path->list);
iucv_path_free(path);
}
}
struct iucv_path_quiesced {
u16 ippathid;
u8 res1;
u8 iptype;
u32 res2;
u8 res3[8];
u8 ipuser[16];
u32 res4;
u8 ippollfg;
u8 res5[3];
} __packed;
/**
* iucv_path_quiesced
* @data: Pointer to external interrupt buffer
*
* Process connection quiesced work item. Called from tasklet while holding
* iucv_table_lock.
*/
static void iucv_path_quiesced(struct iucv_irq_data *data)
{
struct iucv_path_quiesced *ipq = (void *) data;
struct iucv_path *path = iucv_path_table[ipq->ippathid];
if (path && path->handler && path->handler->path_quiesced)
path->handler->path_quiesced(path, ipq->ipuser);
}
struct iucv_path_resumed {
u16 ippathid;
u8 res1;
u8 iptype;
u32 res2;
u8 res3[8];
u8 ipuser[16];
u32 res4;
u8 ippollfg;
u8 res5[3];
} __packed;
/**
* iucv_path_resumed
* @data: Pointer to external interrupt buffer
*
* Process connection resumed work item. Called from tasklet while holding
* iucv_table_lock.
*/
static void iucv_path_resumed(struct iucv_irq_data *data)
{
struct iucv_path_resumed *ipr = (void *) data;
struct iucv_path *path = iucv_path_table[ipr->ippathid];
if (path && path->handler && path->handler->path_resumed)
path->handler->path_resumed(path, ipr->ipuser);
}
struct iucv_message_complete {
u16 ippathid;
u8 ipflags1;
u8 iptype;
u32 ipmsgid;
u32 ipaudit;
u8 iprmmsg[8];
u32 ipsrccls;
u32 ipmsgtag;
u32 res;
u32 ipbfln2f;
u8 ippollfg;
u8 res2[3];
} __packed;
/**
* iucv_message_complete
* @data: Pointer to external interrupt buffer
*
* Process message complete work item. Called from tasklet while holding
* iucv_table_lock.
*/
static void iucv_message_complete(struct iucv_irq_data *data)
{
struct iucv_message_complete *imc = (void *) data;
struct iucv_path *path = iucv_path_table[imc->ippathid];
struct iucv_message msg;
if (path && path->handler && path->handler->message_complete) {
msg.flags = imc->ipflags1;
msg.id = imc->ipmsgid;
msg.audit = imc->ipaudit;
memcpy(msg.rmmsg, imc->iprmmsg, 8);
msg.class = imc->ipsrccls;
msg.tag = imc->ipmsgtag;
msg.length = imc->ipbfln2f;
path->handler->message_complete(path, &msg);
}
}
struct iucv_message_pending {
u16 ippathid;
u8 ipflags1;
u8 iptype;
u32 ipmsgid;
u32 iptrgcls;
struct {
union {
u32 iprmmsg1_u32;
u8 iprmmsg1[4];
} ln1msg1;
union {
u32 ipbfln1f;
u8 iprmmsg2[4];
} ln1msg2;
} rmmsg;
u32 res1[3];
u32 ipbfln2f;
u8 ippollfg;
u8 res2[3];
} __packed;
/**
* iucv_message_pending
* @data: Pointer to external interrupt buffer
*
* Process message pending work item. Called from tasklet while holding
* iucv_table_lock.
*/
static void iucv_message_pending(struct iucv_irq_data *data)
{
struct iucv_message_pending *imp = (void *) data;
struct iucv_path *path = iucv_path_table[imp->ippathid];
struct iucv_message msg;
if (path && path->handler && path->handler->message_pending) {
msg.flags = imp->ipflags1;
msg.id = imp->ipmsgid;
msg.class = imp->iptrgcls;
if (imp->ipflags1 & IUCV_IPRMDATA) {
memcpy(msg.rmmsg, &imp->rmmsg, 8);
msg.length = 8;
} else
msg.length = imp->rmmsg.ln1msg2.ipbfln1f;
msg.reply_size = imp->ipbfln2f;
path->handler->message_pending(path, &msg);
}
}
/*
* iucv_tasklet_fn:
*
* This tasklet loops over the queue of irq buffers created by
* iucv_external_interrupt, calls the appropriate action handler
* and then frees the buffer.
*/
static void iucv_tasklet_fn(unsigned long ignored)
{
typedef void iucv_irq_fn(struct iucv_irq_data *);
static iucv_irq_fn *irq_fn[] = {
[0x02] = iucv_path_complete,
[0x03] = iucv_path_severed,
[0x04] = iucv_path_quiesced,
[0x05] = iucv_path_resumed,
[0x06] = iucv_message_complete,
[0x07] = iucv_message_complete,
[0x08] = iucv_message_pending,
[0x09] = iucv_message_pending,
};
LIST_HEAD(task_queue);
struct iucv_irq_list *p, *n;
/* Serialize tasklet, iucv_path_sever and iucv_path_connect. */
if (!spin_trylock(&iucv_table_lock)) {
tasklet_schedule(&iucv_tasklet);
return;
}
iucv_active_cpu = smp_processor_id();
spin_lock_irq(&iucv_queue_lock);
list_splice_init(&iucv_task_queue, &task_queue);
spin_unlock_irq(&iucv_queue_lock);
list_for_each_entry_safe(p, n, &task_queue, list) {
list_del_init(&p->list);
irq_fn[p->data.iptype](&p->data);
kfree(p);
}
iucv_active_cpu = -1;
spin_unlock(&iucv_table_lock);
}
/*
* iucv_work_fn:
*
* This work function loops over the queue of path pending irq blocks
* created by iucv_external_interrupt, calls the appropriate action
* handler and then frees the buffer.
*/
static void iucv_work_fn(struct work_struct *work)
{
LIST_HEAD(work_queue);
struct iucv_irq_list *p, *n;
/* Serialize tasklet, iucv_path_sever and iucv_path_connect. */
spin_lock_bh(&iucv_table_lock);
iucv_active_cpu = smp_processor_id();
spin_lock_irq(&iucv_queue_lock);
list_splice_init(&iucv_work_queue, &work_queue);
spin_unlock_irq(&iucv_queue_lock);
iucv_cleanup_queue();
list_for_each_entry_safe(p, n, &work_queue, list) {
list_del_init(&p->list);
iucv_path_pending(&p->data);
kfree(p);
}
iucv_active_cpu = -1;
spin_unlock_bh(&iucv_table_lock);
}
/*
* iucv_external_interrupt
*
* Handles external interrupts coming in from CP.
* Places the interrupt buffer on a queue and schedules iucv_tasklet_fn().
*/
static void iucv_external_interrupt(struct ext_code ext_code,
unsigned int param32, unsigned long param64)
{
struct iucv_irq_data *p;
struct iucv_irq_list *work;
inc_irq_stat(IRQEXT_IUC);
p = iucv_irq_data[smp_processor_id()];
if (p->ippathid >= iucv_max_pathid) {
WARN_ON(p->ippathid >= iucv_max_pathid);
iucv_sever_pathid(p->ippathid, iucv_error_no_listener);
return;
}
BUG_ON(p->iptype < 0x01 || p->iptype > 0x09);
work = kmalloc(sizeof(struct iucv_irq_list), GFP_ATOMIC);
if (!work) {
pr_warn("iucv_external_interrupt: out of memory\n");
return;
}
memcpy(&work->data, p, sizeof(work->data));
spin_lock(&iucv_queue_lock);
if (p->iptype == 0x01) {
/* Path pending interrupt. */
list_add_tail(&work->list, &iucv_work_queue);
schedule_work(&iucv_work);
} else {
/* The other interrupts. */
list_add_tail(&work->list, &iucv_task_queue);
tasklet_schedule(&iucv_tasklet);
}
spin_unlock(&iucv_queue_lock);
}
struct iucv_interface iucv_if = {
.message_receive = iucv_message_receive,
.__message_receive = __iucv_message_receive,
.message_reply = iucv_message_reply,
.message_reject = iucv_message_reject,
.message_send = iucv_message_send,
.__message_send = __iucv_message_send,
.message_send2way = iucv_message_send2way,
.message_purge = iucv_message_purge,
.path_accept = iucv_path_accept,
.path_connect = iucv_path_connect,
.path_quiesce = iucv_path_quiesce,
.path_resume = iucv_path_resume,
.path_sever = iucv_path_sever,
.iucv_register = iucv_register,
.iucv_unregister = iucv_unregister,
.bus = NULL,
.root = NULL,
};
EXPORT_SYMBOL(iucv_if);
static enum cpuhp_state iucv_online;
/**
* iucv_init
*
* Allocates and initializes various data structures.
*/
static int __init iucv_init(void)
{
int rc;
if (!MACHINE_IS_VM) {
rc = -EPROTONOSUPPORT;
goto out;
}
system_ctl_set_bit(0, CR0_IUCV_BIT);
rc = iucv_query_maxconn();
if (rc)
goto out_ctl;
rc = register_external_irq(EXT_IRQ_IUCV, iucv_external_interrupt);
if (rc)
goto out_ctl;
iucv_root = root_device_register("iucv");
if (IS_ERR(iucv_root)) {
rc = PTR_ERR(iucv_root);
goto out_int;
}
rc = cpuhp_setup_state(CPUHP_NET_IUCV_PREPARE, "net/iucv:prepare",
iucv_cpu_prepare, iucv_cpu_dead);
if (rc)
goto out_dev;
rc = cpuhp_setup_state(CPUHP_AP_ONLINE_DYN, "net/iucv:online",
iucv_cpu_online, iucv_cpu_down_prep);
if (rc < 0)
goto out_prep;
iucv_online = rc;
rc = register_reboot_notifier(&iucv_reboot_notifier);
if (rc)
goto out_remove_hp;
ASCEBC(iucv_error_no_listener, 16);
ASCEBC(iucv_error_no_memory, 16);
ASCEBC(iucv_error_pathid, 16);
iucv_available = 1;
rc = bus_register(&iucv_bus);
if (rc)
goto out_reboot;
iucv_if.root = iucv_root;
iucv_if.bus = &iucv_bus;
return 0;
out_reboot:
unregister_reboot_notifier(&iucv_reboot_notifier);
out_remove_hp:
cpuhp_remove_state(iucv_online);
out_prep:
cpuhp_remove_state(CPUHP_NET_IUCV_PREPARE);
out_dev:
root_device_unregister(iucv_root);
out_int:
unregister_external_irq(EXT_IRQ_IUCV, iucv_external_interrupt);
out_ctl:
system_ctl_clear_bit(0, 1);
out:
return rc;
}
/**
* iucv_exit
*
* Frees everything allocated from iucv_init.
*/
static void __exit iucv_exit(void)
{
struct iucv_irq_list *p, *n;
spin_lock_irq(&iucv_queue_lock);
list_for_each_entry_safe(p, n, &iucv_task_queue, list)
kfree(p);
list_for_each_entry_safe(p, n, &iucv_work_queue, list)
kfree(p);
spin_unlock_irq(&iucv_queue_lock);
unregister_reboot_notifier(&iucv_reboot_notifier);
cpuhp_remove_state_nocalls(iucv_online);
cpuhp_remove_state(CPUHP_NET_IUCV_PREPARE);
root_device_unregister(iucv_root);
bus_unregister(&iucv_bus);
unregister_external_irq(EXT_IRQ_IUCV, iucv_external_interrupt);
}
subsys_initcall(iucv_init);
module_exit(iucv_exit);
MODULE_AUTHOR("(C) 2001 IBM Corp. by Fritz Elfert <felfert@millenux.com>");
MODULE_DESCRIPTION("Linux for S/390 IUCV lowlevel driver");
MODULE_LICENSE("GPL");
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