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|
/*
* arch/s390/hypfs/hypfs_diag.c
* Hypervisor filesystem for Linux on s390. Diag 204 and 224
* implementation.
*
* Copyright (C) IBM Corp. 2006
* Author(s): Michael Holzheu <holzheu@de.ibm.com>
*/
#include <linux/types.h>
#include <linux/errno.h>
#include <linux/string.h>
#include <linux/vmalloc.h>
#include <asm/ebcdic.h>
#include "hypfs.h"
#define LPAR_NAME_LEN 8 /* lpar name len in diag 204 data */
#define CPU_NAME_LEN 16 /* type name len of cpus in diag224 name table */
#define TMP_SIZE 64 /* size of temporary buffers */
/* diag 204 subcodes */
enum diag204_sc {
SUBC_STIB4 = 4,
SUBC_RSI = 5,
SUBC_STIB6 = 6,
SUBC_STIB7 = 7
};
/* The two available diag 204 data formats */
enum diag204_format {
INFO_SIMPLE = 0,
INFO_EXT = 0x00010000
};
/* bit is set in flags, when physical cpu info is included in diag 204 data */
#define LPAR_PHYS_FLG 0x80
static char *diag224_cpu_names; /* diag 224 name table */
static enum diag204_sc diag204_store_sc; /* used subcode for store */
static enum diag204_format diag204_info_type; /* used diag 204 data format */
static void *diag204_buf; /* 4K aligned buffer for diag204 data */
static void *diag204_buf_vmalloc; /* vmalloc pointer for diag204 data */
static int diag204_buf_pages; /* number of pages for diag204 data */
/*
* DIAG 204 data structures and member access functions.
*
* Since we have two different diag 204 data formats for old and new s390
* machines, we do not access the structs directly, but use getter functions for
* each struct member instead. This should make the code more readable.
*/
/* Time information block */
struct info_blk_hdr {
__u8 npar;
__u8 flags;
__u16 tslice;
__u16 phys_cpus;
__u16 this_part;
__u64 curtod;
} __attribute__ ((packed));
struct x_info_blk_hdr {
__u8 npar;
__u8 flags;
__u16 tslice;
__u16 phys_cpus;
__u16 this_part;
__u64 curtod1;
__u64 curtod2;
char reserved[40];
} __attribute__ ((packed));
static inline int info_blk_hdr__size(enum diag204_format type)
{
if (type == INFO_SIMPLE)
return sizeof(struct info_blk_hdr);
else /* INFO_EXT */
return sizeof(struct x_info_blk_hdr);
}
static inline __u8 info_blk_hdr__npar(enum diag204_format type, void *hdr)
{
if (type == INFO_SIMPLE)
return ((struct info_blk_hdr *)hdr)->npar;
else /* INFO_EXT */
return ((struct x_info_blk_hdr *)hdr)->npar;
}
static inline __u8 info_blk_hdr__flags(enum diag204_format type, void *hdr)
{
if (type == INFO_SIMPLE)
return ((struct info_blk_hdr *)hdr)->flags;
else /* INFO_EXT */
return ((struct x_info_blk_hdr *)hdr)->flags;
}
static inline __u16 info_blk_hdr__pcpus(enum diag204_format type, void *hdr)
{
if (type == INFO_SIMPLE)
return ((struct info_blk_hdr *)hdr)->phys_cpus;
else /* INFO_EXT */
return ((struct x_info_blk_hdr *)hdr)->phys_cpus;
}
/* Partition header */
struct part_hdr {
__u8 pn;
__u8 cpus;
char reserved[6];
char part_name[LPAR_NAME_LEN];
} __attribute__ ((packed));
struct x_part_hdr {
__u8 pn;
__u8 cpus;
__u8 rcpus;
__u8 pflag;
__u32 mlu;
char part_name[LPAR_NAME_LEN];
char lpc_name[8];
char os_name[8];
__u64 online_cs;
__u64 online_es;
__u8 upid;
char reserved1[3];
__u32 group_mlu;
char group_name[8];
char reserved2[32];
} __attribute__ ((packed));
static inline int part_hdr__size(enum diag204_format type)
{
if (type == INFO_SIMPLE)
return sizeof(struct part_hdr);
else /* INFO_EXT */
return sizeof(struct x_part_hdr);
}
static inline __u8 part_hdr__rcpus(enum diag204_format type, void *hdr)
{
if (type == INFO_SIMPLE)
return ((struct part_hdr *)hdr)->cpus;
else /* INFO_EXT */
return ((struct x_part_hdr *)hdr)->rcpus;
}
static inline void part_hdr__part_name(enum diag204_format type, void *hdr,
char *name)
{
if (type == INFO_SIMPLE)
memcpy(name, ((struct part_hdr *)hdr)->part_name,
LPAR_NAME_LEN);
else /* INFO_EXT */
memcpy(name, ((struct x_part_hdr *)hdr)->part_name,
LPAR_NAME_LEN);
EBCASC(name, LPAR_NAME_LEN);
name[LPAR_NAME_LEN] = 0;
strstrip(name);
}
struct cpu_info {
__u16 cpu_addr;
char reserved1[2];
__u8 ctidx;
__u8 cflag;
__u16 weight;
__u64 acc_time;
__u64 lp_time;
} __attribute__ ((packed));
struct x_cpu_info {
__u16 cpu_addr;
char reserved1[2];
__u8 ctidx;
__u8 cflag;
__u16 weight;
__u64 acc_time;
__u64 lp_time;
__u16 min_weight;
__u16 cur_weight;
__u16 max_weight;
char reseved2[2];
__u64 online_time;
__u64 wait_time;
__u32 pma_weight;
__u32 polar_weight;
char reserved3[40];
} __attribute__ ((packed));
/* CPU info block */
static inline int cpu_info__size(enum diag204_format type)
{
if (type == INFO_SIMPLE)
return sizeof(struct cpu_info);
else /* INFO_EXT */
return sizeof(struct x_cpu_info);
}
static inline __u8 cpu_info__ctidx(enum diag204_format type, void *hdr)
{
if (type == INFO_SIMPLE)
return ((struct cpu_info *)hdr)->ctidx;
else /* INFO_EXT */
return ((struct x_cpu_info *)hdr)->ctidx;
}
static inline __u16 cpu_info__cpu_addr(enum diag204_format type, void *hdr)
{
if (type == INFO_SIMPLE)
return ((struct cpu_info *)hdr)->cpu_addr;
else /* INFO_EXT */
return ((struct x_cpu_info *)hdr)->cpu_addr;
}
static inline __u64 cpu_info__acc_time(enum diag204_format type, void *hdr)
{
if (type == INFO_SIMPLE)
return ((struct cpu_info *)hdr)->acc_time;
else /* INFO_EXT */
return ((struct x_cpu_info *)hdr)->acc_time;
}
static inline __u64 cpu_info__lp_time(enum diag204_format type, void *hdr)
{
if (type == INFO_SIMPLE)
return ((struct cpu_info *)hdr)->lp_time;
else /* INFO_EXT */
return ((struct x_cpu_info *)hdr)->lp_time;
}
static inline __u64 cpu_info__online_time(enum diag204_format type, void *hdr)
{
if (type == INFO_SIMPLE)
return 0; /* online_time not available in simple info */
else /* INFO_EXT */
return ((struct x_cpu_info *)hdr)->online_time;
}
/* Physical header */
struct phys_hdr {
char reserved1[1];
__u8 cpus;
char reserved2[6];
char mgm_name[8];
} __attribute__ ((packed));
struct x_phys_hdr {
char reserved1[1];
__u8 cpus;
char reserved2[6];
char mgm_name[8];
char reserved3[80];
} __attribute__ ((packed));
static inline int phys_hdr__size(enum diag204_format type)
{
if (type == INFO_SIMPLE)
return sizeof(struct phys_hdr);
else /* INFO_EXT */
return sizeof(struct x_phys_hdr);
}
static inline __u8 phys_hdr__cpus(enum diag204_format type, void *hdr)
{
if (type == INFO_SIMPLE)
return ((struct phys_hdr *)hdr)->cpus;
else /* INFO_EXT */
return ((struct x_phys_hdr *)hdr)->cpus;
}
/* Physical CPU info block */
struct phys_cpu {
__u16 cpu_addr;
char reserved1[2];
__u8 ctidx;
char reserved2[3];
__u64 mgm_time;
char reserved3[8];
} __attribute__ ((packed));
struct x_phys_cpu {
__u16 cpu_addr;
char reserved1[2];
__u8 ctidx;
char reserved2[3];
__u64 mgm_time;
char reserved3[80];
} __attribute__ ((packed));
static inline int phys_cpu__size(enum diag204_format type)
{
if (type == INFO_SIMPLE)
return sizeof(struct phys_cpu);
else /* INFO_EXT */
return sizeof(struct x_phys_cpu);
}
static inline __u16 phys_cpu__cpu_addr(enum diag204_format type, void *hdr)
{
if (type == INFO_SIMPLE)
return ((struct phys_cpu *)hdr)->cpu_addr;
else /* INFO_EXT */
return ((struct x_phys_cpu *)hdr)->cpu_addr;
}
static inline __u64 phys_cpu__mgm_time(enum diag204_format type, void *hdr)
{
if (type == INFO_SIMPLE)
return ((struct phys_cpu *)hdr)->mgm_time;
else /* INFO_EXT */
return ((struct x_phys_cpu *)hdr)->mgm_time;
}
static inline __u64 phys_cpu__ctidx(enum diag204_format type, void *hdr)
{
if (type == INFO_SIMPLE)
return ((struct phys_cpu *)hdr)->ctidx;
else /* INFO_EXT */
return ((struct x_phys_cpu *)hdr)->ctidx;
}
/* Diagnose 204 functions */
static int diag204(unsigned long subcode, unsigned long size, void *addr)
{
register unsigned long _subcode asm("0") = subcode;
register unsigned long _size asm("1") = size;
asm volatile (" diag %2,%0,0x204\n"
"0: \n" ".section __ex_table,\"a\"\n"
#ifndef __s390x__
" .align 4\n"
" .long 0b,0b\n"
#else
" .align 8\n"
" .quad 0b,0b\n"
#endif
".previous":"+d" (_subcode), "+d"(_size)
:"d"(addr)
:"memory");
if (_subcode)
return -1;
else
return _size;
}
/*
* For the old diag subcode 4 with simple data format we have to use real
* memory. If we use subcode 6 or 7 with extended data format, we can (and
* should) use vmalloc, since we need a lot of memory in that case. Currently
* up to 93 pages!
*/
static void diag204_free_buffer(void)
{
if (!diag204_buf)
return;
if (diag204_buf_vmalloc) {
vfree(diag204_buf_vmalloc);
diag204_buf_vmalloc = NULL;
} else {
free_pages((unsigned long) diag204_buf, 0);
}
diag204_buf_pages = 0;
diag204_buf = NULL;
}
static void *diag204_alloc_vbuf(int pages)
{
/* The buffer has to be page aligned! */
diag204_buf_vmalloc = vmalloc(PAGE_SIZE * (pages + 1));
if (!diag204_buf_vmalloc)
return ERR_PTR(-ENOMEM);
diag204_buf = (void*)((unsigned long)diag204_buf_vmalloc
& ~0xfffUL) + 0x1000;
diag204_buf_pages = pages;
return diag204_buf;
}
static void *diag204_alloc_rbuf(void)
{
diag204_buf = (void*)__get_free_pages(GFP_KERNEL,0);
if (diag204_buf)
return ERR_PTR(-ENOMEM);
diag204_buf_pages = 1;
return diag204_buf;
}
static void *diag204_get_buffer(enum diag204_format fmt, int *pages)
{
if (diag204_buf) {
*pages = diag204_buf_pages;
return diag204_buf;
}
if (fmt == INFO_SIMPLE) {
*pages = 1;
return diag204_alloc_rbuf();
} else {/* INFO_EXT */
*pages = diag204(SUBC_RSI | INFO_EXT, 0, NULL);
if (*pages <= 0)
return ERR_PTR(-ENOSYS);
else
return diag204_alloc_vbuf(*pages);
}
}
/*
* diag204_probe() has to find out, which type of diagnose 204 implementation
* we have on our machine. Currently there are three possible scanarios:
* - subcode 4 + simple data format (only one page)
* - subcode 4-6 + extended data format
* - subcode 4-7 + extended data format
*
* Subcode 5 is used to retrieve the size of the data, provided by subcodes
* 6 and 7. Subcode 7 basically has the same function as subcode 6. In addition
* to subcode 6 it provides also information about secondary cpus.
* In order to get as much information as possible, we first try
* subcode 7, then 6 and if both fail, we use subcode 4.
*/
static int diag204_probe(void)
{
void *buf;
int pages, rc;
buf = diag204_get_buffer(INFO_EXT, &pages);
if (!IS_ERR(buf)) {
if (diag204((unsigned long)SUBC_STIB7 |
(unsigned long)INFO_EXT, pages, buf) >= 0) {
diag204_store_sc = SUBC_STIB7;
diag204_info_type = INFO_EXT;
goto out;
}
if (diag204((unsigned long)SUBC_STIB6 |
(unsigned long)INFO_EXT, pages, buf) >= 0) {
diag204_store_sc = SUBC_STIB7;
diag204_info_type = INFO_EXT;
goto out;
}
diag204_free_buffer();
}
/* subcodes 6 and 7 failed, now try subcode 4 */
buf = diag204_get_buffer(INFO_SIMPLE, &pages);
if (IS_ERR(buf)) {
rc = PTR_ERR(buf);
goto fail_alloc;
}
if (diag204((unsigned long)SUBC_STIB4 |
(unsigned long)INFO_SIMPLE, pages, buf) >= 0) {
diag204_store_sc = SUBC_STIB4;
diag204_info_type = INFO_SIMPLE;
goto out;
} else {
rc = -ENOSYS;
goto fail_store;
}
out:
rc = 0;
fail_store:
diag204_free_buffer();
fail_alloc:
return rc;
}
static void *diag204_store(void)
{
void *buf;
int pages;
buf = diag204_get_buffer(diag204_info_type, &pages);
if (IS_ERR(buf))
goto out;
if (diag204((unsigned long)diag204_store_sc |
(unsigned long)diag204_info_type, pages, buf) < 0)
return ERR_PTR(-ENOSYS);
out:
return buf;
}
/* Diagnose 224 functions */
static void diag224(void *ptr)
{
asm volatile(" diag %0,%1,0x224\n"
: :"d" (0), "d"(ptr) : "memory");
}
static int diag224_get_name_table(void)
{
/* memory must be below 2GB */
diag224_cpu_names = kmalloc(PAGE_SIZE, GFP_KERNEL | GFP_DMA);
if (!diag224_cpu_names)
return -ENOMEM;
diag224(diag224_cpu_names);
EBCASC(diag224_cpu_names + 16, (*diag224_cpu_names + 1) * 16);
return 0;
}
static void diag224_delete_name_table(void)
{
kfree(diag224_cpu_names);
}
static int diag224_idx2name(int index, char *name)
{
memcpy(name, diag224_cpu_names + ((index + 1) * CPU_NAME_LEN),
CPU_NAME_LEN);
name[CPU_NAME_LEN] = 0;
strstrip(name);
return 0;
}
__init int hypfs_diag_init(void)
{
int rc;
if (diag204_probe()) {
printk(KERN_ERR "hypfs: diag 204 not working.");
return -ENODATA;
}
rc = diag224_get_name_table();
if (rc) {
diag224_delete_name_table();
printk(KERN_ERR "hypfs: could not get name table.\n");
}
return rc;
}
__exit void hypfs_diag_exit(void)
{
diag224_delete_name_table();
diag204_free_buffer();
}
/*
* Functions to create the directory structure
* *******************************************
*/
static int hypfs_create_cpu_files(struct super_block *sb,
struct dentry *cpus_dir, void *cpu_info)
{
struct dentry *cpu_dir;
char buffer[TMP_SIZE];
void *rc;
snprintf(buffer, TMP_SIZE, "%d", cpu_info__cpu_addr(diag204_info_type,
cpu_info));
cpu_dir = hypfs_mkdir(sb, cpus_dir, buffer);
rc = hypfs_create_u64(sb, cpu_dir, "mgmtime",
cpu_info__acc_time(diag204_info_type, cpu_info) -
cpu_info__lp_time(diag204_info_type, cpu_info));
if (IS_ERR(rc))
return PTR_ERR(rc);
rc = hypfs_create_u64(sb, cpu_dir, "cputime",
cpu_info__lp_time(diag204_info_type, cpu_info));
if (IS_ERR(rc))
return PTR_ERR(rc);
if (diag204_info_type == INFO_EXT) {
rc = hypfs_create_u64(sb, cpu_dir, "onlinetime",
cpu_info__online_time(diag204_info_type,
cpu_info));
if (IS_ERR(rc))
return PTR_ERR(rc);
}
diag224_idx2name(cpu_info__ctidx(diag204_info_type, cpu_info), buffer);
rc = hypfs_create_str(sb, cpu_dir, "type", buffer);
if (IS_ERR(rc))
return PTR_ERR(rc);
return 0;
}
static void *hypfs_create_lpar_files(struct super_block *sb,
struct dentry *systems_dir, void *part_hdr)
{
struct dentry *cpus_dir;
struct dentry *lpar_dir;
char lpar_name[LPAR_NAME_LEN + 1];
void *cpu_info;
int i;
part_hdr__part_name(diag204_info_type, part_hdr, lpar_name);
lpar_name[LPAR_NAME_LEN] = 0;
lpar_dir = hypfs_mkdir(sb, systems_dir, lpar_name);
if (IS_ERR(lpar_dir))
return lpar_dir;
cpus_dir = hypfs_mkdir(sb, lpar_dir, "cpus");
if (IS_ERR(cpus_dir))
return cpus_dir;
cpu_info = part_hdr + part_hdr__size(diag204_info_type);
for (i = 0; i < part_hdr__rcpus(diag204_info_type, part_hdr); i++) {
int rc;
rc = hypfs_create_cpu_files(sb, cpus_dir, cpu_info);
if (rc)
return ERR_PTR(rc);
cpu_info += cpu_info__size(diag204_info_type);
}
return cpu_info;
}
static int hypfs_create_phys_cpu_files(struct super_block *sb,
struct dentry *cpus_dir, void *cpu_info)
{
struct dentry *cpu_dir;
char buffer[TMP_SIZE];
void *rc;
snprintf(buffer, TMP_SIZE, "%i", phys_cpu__cpu_addr(diag204_info_type,
cpu_info));
cpu_dir = hypfs_mkdir(sb, cpus_dir, buffer);
if (IS_ERR(cpu_dir))
return PTR_ERR(cpu_dir);
rc = hypfs_create_u64(sb, cpu_dir, "mgmtime",
phys_cpu__mgm_time(diag204_info_type, cpu_info));
if (IS_ERR(rc))
return PTR_ERR(rc);
diag224_idx2name(phys_cpu__ctidx(diag204_info_type, cpu_info), buffer);
rc = hypfs_create_str(sb, cpu_dir, "type", buffer);
if (IS_ERR(rc))
return PTR_ERR(rc);
return 0;
}
static void *hypfs_create_phys_files(struct super_block *sb,
struct dentry *parent_dir, void *phys_hdr)
{
int i;
void *cpu_info;
struct dentry *cpus_dir;
cpus_dir = hypfs_mkdir(sb, parent_dir, "cpus");
if (IS_ERR(cpus_dir))
return cpus_dir;
cpu_info = phys_hdr + phys_hdr__size(diag204_info_type);
for (i = 0; i < phys_hdr__cpus(diag204_info_type, phys_hdr); i++) {
int rc;
rc = hypfs_create_phys_cpu_files(sb, cpus_dir, cpu_info);
if (rc)
return ERR_PTR(rc);
cpu_info += phys_cpu__size(diag204_info_type);
}
return cpu_info;
}
int hypfs_diag_create_files(struct super_block *sb, struct dentry *root)
{
struct dentry *systems_dir, *hyp_dir;
void *time_hdr, *part_hdr;
int i, rc;
void *buffer, *ptr;
buffer = diag204_store();
if (IS_ERR(buffer))
return PTR_ERR(buffer);
systems_dir = hypfs_mkdir(sb, root, "systems");
if (IS_ERR(systems_dir)) {
rc = PTR_ERR(systems_dir);
goto err_out;
}
time_hdr = (struct x_info_blk_hdr *)buffer;
part_hdr = time_hdr + info_blk_hdr__size(diag204_info_type);
for (i = 0; i < info_blk_hdr__npar(diag204_info_type, time_hdr); i++) {
part_hdr = hypfs_create_lpar_files(sb, systems_dir, part_hdr);
if (IS_ERR(part_hdr)) {
rc = PTR_ERR(part_hdr);
goto err_out;
}
}
if (info_blk_hdr__flags(diag204_info_type, time_hdr) & LPAR_PHYS_FLG) {
ptr = hypfs_create_phys_files(sb, root, part_hdr);
if (IS_ERR(ptr)) {
rc = PTR_ERR(ptr);
goto err_out;
}
}
hyp_dir = hypfs_mkdir(sb, root, "hyp");
if (IS_ERR(hyp_dir)) {
rc = PTR_ERR(hyp_dir);
goto err_out;
}
ptr = hypfs_create_str(sb, hyp_dir, "type", "LPAR Hypervisor");
if (IS_ERR(ptr)) {
rc = PTR_ERR(ptr);
goto err_out;
}
rc = 0;
err_out:
return rc;
}
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